My Research Programme (2002 - Now)

Implantable Medical Device Tells All

Implantable Medical Device Tells All: Uberveillance Gets to the Heart of the Matter

In 2015, I provided evidence at an Australian inquiry into the use of subsection 313(3) of the Telecommunications Act of 1997 by government agencies to disrupt the operation of illegal online services [1]. I stated to the Standing Committee on Infrastructure and Communications that mandatory metadata retention laws meant blanket coverage surveillance for Australians and visitors to Australia. The intent behind asking Australian service providers to keep subscriber search history data for up to two years was to grant government and law enforcement organizations the ability to search Internet Protocol–based records in the event of suspected criminal activity.

Importantly, I told the committee that, while instituting programs of surveillance through metadata retention laws would likely help to speed up criminal investigations, we should also note that every individual is a consumer, and such programs ultimately come back to bite innocent people through some breach of privacy or security. Enter the idea of uberveillance, which, I told the committee, is “exaggerated surveillance” that allows for interference [1] that I believe is a threat to our human rights [2]. I strongly advised that evoking section 313 of the Telecommunications Act 1997 requires judicial oversight through the process of a search warrant. My recommendations fell on deaf ears, and, today, we even have the government deliberating over whether or not they should relax metadata laws to allow information to be accessed for both criminal and civil litigation [3], which includes divorces, child custody battles, and business disputes. In June 2017, Australian Prime Minister Malcolm Turnbull even stated that “global social media and messaging companies” need to assist security services’ efforts to fight terrorism by “providing access to encrypted communications” [52].

Consumer Electronics Leave Digital Data Footprints

Of course, Australia is not alone in having metadata retention laws. Numerous countries have adopted these laws or similar directives since 2005, keeping certain types of data for anywhere between 30 days and indefinitely, although the standard length is somewhere between one and two years. For example, since 2005, Italy has retained subscriber information at Internet cafes for 30 days. I recall traveling to Verona in 2008 for the European Conference on Information Systems, forgetting my passport in my hotel room, and being unable to use an Internet cafe to send a message back home because I was carrying no recognized identity information. When I asked why I was unable to send a simple message, I was handed an antiterrorism information leaflet. Italy also retains telephone data for up to two years and Internet service provider (ISP) data for up to 12 months.

Similarly, the United Kingdom retains all telecommunications data for one to two years. It also maintains postal information (sender, receiver data), banking data for up to seven years, and vehicle movements for up to two years. In Germany, metadata retention was established in 2008 under the directive Gesetz zur Neuregelung der Telekommunikationsüberwachung und anderer verdeckter Ermittlungsmaßnahmen sowie zur Umsetzung der Richtlinie 2006/24/EG, but it was overturned in 2010 by the Federal Constitutional Court of Germany, which ruled the law was unconstitutional because it violated a fundamental right, in that correspondence should remain secret. In 2015, this violation was challenged again, and a compromise was reached to retain telecommunications metadata for up to ten weeks. Mandatory data retention in Sweden was challenged by one holdout ISP, Bahnhof, which was threatened with an approximately US$605,000 fine in November 2014 if it did not comply [4]. They defended their stance to protect the privacy and integrity of their customers by offering a no-logs virtual private network free of charge [5].

Some European Union countries have been deliberating whether to extend metadata retention to chats and social media, but, in the United States, many corporations voluntarily retain subscriber data, including market giants Amazon and Google. It was reported in The Guardian in 2014 that the United States records Internet metadata for not only itself but the world at large through the National Security Agency (NSA) using its MARINA database to conduct pattern-of-life analysis [6]. Additionally, with the Amendments Act in 2008 of the Foreign Intelligence Surveillance Act 1978, the time allotted for warrantless surveillance was increased, and additional provisions were made for emergency eavesdropping. Under section 702 of the Foreign Intelligence Surveillance Act of 1978 Amendments Act, now all American citizens’ metadata is stored. Phone records are kept by the NSA in the MAINWAY telephony metadata collection database [53], and short message service and other text messaging worldwide are retained in DISHFIRE [7], [8].

Emerging Forms of Metadata in an Internet of Things World

Figure 1. An artificial pacemaker (serial number 1723182) from St. Jude medical, with electrode, which was removed from a deceased patient prior to cremation. (Photo courtesy of wikimedia commons.)

The upward movement toward a highly interconnected world through the Web of Things and people [9] will only mean that even greater amounts of data will be retained by corporations and government agencies around the world, extending beyond traditional forms of telecommunications data (e.g., phone records, e-mail correspondence, Internet search histories, metadata of images, videos, and other forms of multimedia). It should not surprise us that even medical devices are being touted as soon to be connected to the Internet of Things (IoT) [10]. Heart pacemakers, for instance, already send a steady stream of data back to the manufacturer’s data warehouse (Figure 1). Cardiac rhythmic data is stored on the implantable cardioverter-defibrillator’s (ICD’s) memory and is transmitted wirelessly to a home bedside monitor. Via a network connection, the data find their way to the manufacturer’s data store (Figure 2).

The standard setup for an EKG. A patient lies in a bed with EKG electrodes attached to his chest, upper arms, and legs. A nurse oversees the painless procedure. The ICD in a patient produces an EKG (A) which can automatically be sent to a ICD manufacturer's data store (B). (Image courtesy of wikimedia commons.)

In health speak, the ICD set up in the patient’s home is a type of remote monitoring that happens usually when the ICD recipient is in a state of rest, most often while sleeping overnight. It is a bit like how normal computer data backups happen, when network traffic is at its lowest. In the future, an ICD’s proprietary firmware updates may well travel back up to the device, remote from the manufacturer, like installing a Windows operating system update on a desktop. In the following section, we will explore the implications of access to personal cardiac data emanating from heart pacemakers in two cases.

CASE 1: HUGO CAMPOS DENIED ACCESS TO HIS PERSONAL CARDIAC DATA

Figure 3. The conventional radiography of a single-chamber pacemaker. (Photo courtesy of wikimedia commons.)

In 2007, scientist Hugo Campos collapsed at a train station and later was horrified to find out that he had to get an ICD for his genetic heart condition. ICDs usually last about seven years before they require replacement (Figure 3). A few years into wearing the device, being a high-end quantifiedself user who measured his sleep, exercise, and even alcohol consumption, Campos became inquisitive over how he might gain access to the data generated by his ICD (Figure 4). He made some requests to the ICD’s manufacturer and was told that he was unable to receive the information he sought, despite his doctor having full access. Some doctors could even remotely download the patient’s historical data on a mobile app for 24/7 support during emergency situations (Figure 5). Campos’s heart specialist did grant him access to written interrogation reports, but Campos only saw him about once every six months after his conditioned stabilized. Additionally, the logs were of no consequence to him on paper, and the fields and layout were predominantly decipherable only by a doctor (Figure 6).

Figure 4. The Nike FuelBand is a wearable computer that has become one of the most popular devices driving the so-called quantified-self trend. (Photo courtesy of wikimedia commons.)

Dissatisfied by his denied access, Campos took matters into his own hands and purchased a device on eBay that could help him get the data. He also went to a specialist ICD course and then intercepted the cardiac rhythms being recorded [11]. He got to the data stream but realized that to make sense of it from a patient perspective, a patient-centric app had to be built. Campos quickly deduced that regulatory and liability concerns were at the heart of the matter from the manufacturer’s perspective. How does a manufacturer continue to improve its product if it does not continually get feedback from the actual ICDs in the field? If manufacturers offered mobile apps for patients, might patients misread their own diagnoses? Is a manufacturer there to enhance life alone or to make a patient feel better about bearing an ICD? Can an ICD be misused by a patient? Or, in the worst case scenario, what happens in the case of device failure? Or patient death? Would the proof lie onboard? Would the data tell the true story? These are all very interesting questions.

Figure 5. The medical waveform format encoding rule software on a Blackberry device. It displays medical waveforms, such as EKG (shown), electroencephalogram, and blood pressure. Some doctors have software that allows them to interrogate EKG information, but patients presently do not have access to their own ICD data. (Photo courtesy of wikimedia commons.)

Campos might well have acted to not only get what he wanted (access to his data his own way) but to raise awareness globally as to the type of data being stored remotely by ICDs in patients. He noted in his TEDxCambridge talk in 2011 [12]:

the ICD does a lot more than just prevent a sudden cardiac arrest: it collects a lot of data about its own function and about the patient’s clinical status; it monitors its own battery life; the amount of time it takes to deliver a life-saving shock; it monitors a patient’s heart rhythm, daily activity; and even looks at variations in chest impedance to look if there is build-up of fluids in the chest; so it is a pretty complex little computer you have built into your body. Unfortunately, none of this invaluable data is available to the patient who originates it. I have absolutely no access to it, no knowledge of it.

Doctors, on the other hand, have full 24/7 unrestricted access to this information; even some of the manufacturers of these medical devices offer the ability for doctors to access this information through mobile devices. Compare this with the patients’ experience who have no access to this information. The best we can do is to get a printout or a hardcopy of an interrogation report when you go into the doctor’s office.

Figure 6. An EKG chart. Twelve different derivations of an EKG of a 23-year-old japanese man. A similar log was provided to hugo campos upon his request for six months worth of EKG readings. (Photo courtesy of wikimedia commons.)

Campos decided to sue the manufacturer after he was informed that the data being generated from his ICD measuring his own heart activity was “proprietary data” [13]. Perhaps this is the new side of big data. But it is fraught with legal implications and, as far as I am concerned, blatantly dangerous. If we deduce that a person’s natural biometric data (in this instance, the cardiac rhythm of an individual) belong to a third party, then we are headed into murky waters when we speak of even more invasive technology like deepbrain stimulators [14]. It not only means that the device is not owned by the electrophorus (the bearer of technology) [15], [16], but quite possibly the cardiac rhythms unique to the individual are also owned by the device manufacturer. We should not be surprised. In Google Glass’s “Software and Services” section of its terms of use, it states that Google has the right to “remotely disable or remove any such Glass service from user systems” at its “sole discretion” [17]. Placing this in the context of ICDs means that a third party almost indelibly has the right to switch someone off.

CASE 2: ROSS COMPTON’S PACEMAKER DATA IS SUBPOENAED FOR CRIMINAL INVESTIGATIONS

Enter the Ross Compton case of Middletown, Ohio. M.G. Michael and I have dubbed it one of the first authentic uberveillance cases in the world, because the technology was not just wearable but embedded. The story goes something like this: On 27 January 2017, 59-year-old Ross Compton was indicted on arson and insurance fraud charges. Police gained a search warrant to obtain his heart pacemaker readings (heart and cardiac rhythms) and called his alibi into question. Data from Compton’s pacemaker before, during, and after the fire in his home broke out were disclosed by the heart pacemaker manufacturer after a subpoena was served. The insurer’s bill for the damage was estimated at about US$400,000. Police became suspicious of Compton when they traced gasoline to Compton’s shoes, trousers, and shirt.

In his statement of events to police, Compton told a story that misaligned and conflicted with his call to 911. Forensic analysts found traces of multiple fires having been lit in various locations in the home. Yet, Compton told police he had rushed his escape, breaking a window with his walking stick to throw some hastily packed bags out and then fleeing the flames himself to safety. Compton also told police that he had an artificial heart with a pump attached, a fact that he thought might help his cause but that was to be his undoing. In this instance, his pacemaker acted akin to a black box recording on an airplane [18].

After securing the heart pacemaker data set, an independent cardiologist was asked to assess the telemetry data and determine if Compton’s heart function was commensurate with the exertion needed to make a break with personal belongings during a life-threatening fire [19]. The cardiologist noted that, based on the evidence he was given to interpret, it was “highly improbable” that a man who suffered with the medical conditions that Compton did could manage to collect, pack, and remove the number of items that he did from his bedroom window, escape himself, and then proceed to carry these items in front of his house, out of harm’s way (see “Columbo, How to Dial a Murder”). Compton’s own cardio readings, in effect, snitched on him, and none were happier than the law enforcement officer in charge of the case, Lieutenant Jimmy Cunningham, who noted that the pacemaker data, while only a supporting piece of evidence, was vital in proving Compton’s guilt after gasoline was found on his clothing. Evidence-based policing has now well outstripped the more traditional intelligence-led policing approach, entrenched given the new realm of big data availability [20], [21].

Columbo, How to Dial a Murder [S1] Columbo says to the murderer:
“You claim that you were at the physicians getting your heart examined…which was true [Columbo unravels a roll of EKG readings]…the electrocardiogram, Sir. Just before three o’clock your physician left you alone for a resting trace. At that moment you were lying down in a restful position and your heart showed a calm, slow, easy beat [pointing to the EKG readout]. Look at this part, right here [Columbo points to the reading], lots of sudden stress, lots of excitement, right here at three o’clock, your heart beating like a hammer just before the dogs attacked…Oh you killed him with a phone call, Sir…I’ll bet my life on it. Very simple case. Not that I’m particularly bright, Sir…I must say, I found you disappointing, I mean your incompetence, you left enough clues to sink a ship. Motive. Opportunity. And for a man of your intelligence Sir, you got caught on a lot of stupid lies. A lot.” [S1] Columbo: How to Dial a Murder. Directed by James Frawley. 1978. Los Angeles, CA: Universal Pictures Home Entertainment, 2006. DVD.

Consumer Electronics Tell a Story

Several things are now of interest to the legal community: first and foremost, how is the search warrant for a person’s pacemaker data executed? In case 1, Campos was denied access to his own ICD data stream by the manufacturer, and yet his doctor had full access. In case 2, Compton’s own data provided authorities with the extra evidence they needed to accuse him of fraud. This is yet another example of seemingly private data being used against an individual (in this instance, the person from whose body the data emanated), but in the future, for instance, the data from one person’s pacemaker might well implicate other members of the public. For example, the pacemaker might be able to prove that someone’s heart rate substantially increased during an episode of domestic violence [22] or that an individual was unfaithful in a marriage based on the cross matching of his or her time stamp and heart rate data with another.

Of course, a consumer electronic does not have to be embedded to tell a story (Figure 7). It can also be wearable or luggable, as in the case of a Fitbit that was used as a truthdetector in an alleged rape case that turned out to be completely fabricated [23]. Lawyers are now beginning to experiment with other wearable gadgetry that helps to show the impact of personal injury cases from accidents (work and nonwork related) on a person’s ability to return to his or her normal course of activities [24] (Figure 8). We can certainly expect to see a rise in criminal and civil litigation that makes use of a person’s Android S Health data, for instance, which measure things like steps taken, stress, heart rate, SpO2, and even location and time (Figure 9). But cases like Compton’s open the floodgates.

Figure 7. A Fitbit, which measures calories, steps, distance, and floors. (Photo courtesy of wikimedia commons.)

Figure 8. A closeup of a patient wearing the iRhythm ZIO XT patch, nine days after its placement. (Photo courtesy of wikimedia commons.)

I have pondered on the evidence itself: are heart rate data really any different from other biometric data, such as deoxyribonucleic acid (DNA)? Is it perhaps more revealing than DNA? Should it be dealt with in the same way? For example, is the chain of custody coming from a pacemaker equal to that of a DNA sample and profile? In some way, heart rates can be considered a behavioral biometric [25], whereas DNA is actually a cellular sample [26]. No doubt we will be debating the challenges, and extreme perspectives will be hotly contested. But it seems nothing is off limits. If it exists, it can be used for or against you.

Figure 9. (a) and (b) The health-related data from Samsung's S Health application. Unknown to most is that Samsung has diversified its businesses to be a parent company to one of the world's largest health insurers. (Photos courtesy of katina michael.)

The Paradox of Uberveillance

In 2006, M.G. Michael coined the term uberveillance to denote “an omnipresent electronic surveillance facilitated by technology that makes it possible to embed surveillance devices in the human body” [27]. No doubt Michael’s background as a former police officer in the early 1980s, together with his cross-disciplinary studies, had something to do with his insights into the creation of the term [28]. This kind of surveillance does not watch from above, rather it penetrates the body and watches from the inside, looking out [29].

Furthermore, uberveillance “takes that which was static or discrete…and makes it constant and embedded” [30]. It is real-time location and condition monitoring and “has to do with the fundamental who (ID), where (location), and when (time) questions in an attempt to derive why (motivation), what (result), and even how (method/plan/thought)” [30]. Uberveillance can be used prospectively or retrospectively. It can be applied as a “predictive mechanism for a person’s expected behavior, traits, likes, or dislikes; or it can be based on historical fact” [30].

In 2008, the term uberveillance was entered into the official Macquarie Dictionary of Australia [31]. In research that has spanned more than two decades on the social implications of implantable devices for medical and nonmedical applications, I predicted [15] that the technological trajectory of implantable devices that were once used solely for care purposes would one day be used retrospectively for tracking and monitoring purposes. Even if the consumer electronics in question were there to provide health care (e.g., the pacemaker example) or convenience (e.g., a near-field-communication-enabled smartphone), the underlying dominant function of the service would be control [32]. The socioethical implications of pervasive and persuasive emerging technologies have yet to really be understood, but increasingly, they will emerge to take center stage in court hearings, like the emergence of DNA evidence and then subsequently global positioning system (GPS) data [33].

Medical device implants provide a very rich source of human activity monitoring, such as the electrocardiogram (EKG), heart rate, and more. Companies like Medtronics, among others specializing in implantables, have proposed a future where even healthy people carry a medical implant packed with sensors that could be life sustaining and detect heart problems (among others), reporting them to a care provider and signaling when assistance might be required [34]. Heart readings provide an individual’s rhythmic biometrics and, at the same time, can record increases and decreases in activity. One could extrapolate that it won’t be long before our health insurance providers are asking for the same evidence for reduced premiums.

Figure 10. A pacemaker cemetery. (Photo courtesy of wikimedia commons.)

The future might well be one where we all carry a black box implantable recorder of some sort [35], an alibi that proves our innocence or guilt, minute by minute (Figure 10). Of course, an electronic eye constantly recording our every move brings a new connotation to the wise words expressed in the story of Pinocchio: always let your conscience be your guide. The future black boxes may not be as forgiving as Jiminy Cricket and more like Black Mirror’s “The Entire History of You” [36]. But if we assume that these technologies are to be completely trusted, whether they are implantable, wearable, or even luggable, then we are wrong.

The contribution of M.G. Michael’s uberveillance is in the emphasis that the uberveillance equation is a paradox. Yes, there are near-real-time data flowing continuously from more points of view than ever [37], closed-circuit TV looking down, smartphones in our pockets recording location and movement, and even implantables in some of us ensuring nontransferability of identity [38]. The proposition is that all this technology in sum total is bulletproof and foolproof, omniscient and omnipresent, a God’s eye view that cannot be challenged but for the fact that the infrastructure and the devices, and the software, are all too human. And while uberveillance is being touted for good through an IoT world that will collectively make us and our planet more sustainable, there is one big crack in the utopian vision: the data can misrepresent, misinform, and be subject to information manipulation [39]. Researchers are already studying the phenomenon on complex visual information manipulation, how to tell whether data has been tampered with, a suspect introduced or removed from a scene of a crime, and other forensic visual analytics [40]. It is why Vladimir Radunovic, director of cybersecurity and e-diplomacy programs in the DiploFoundation, cited M.G. Michael’s contribution that “big data must be followed by big judgment” [41].

What happens in the future if we go down the path of constant bodily monitoring of vital organs and vital signs, where we are all bearing some device or at least wearing one? Will we be in control of our own data, or, as is seemingly obvious at present, will we not be in control? And how might selfincrimination play a role in our daily lives, or even worse, individual expectations that can be achieved by only playing to a theater 24/7 so our health statistics can stack up to whatever measure and cross-examination they are put under personally or publicly [42]? Can we believe the authenticity of every data stream coming out of a sensor onboard consumer electronics? The answer is no.

Having run many years of GPS data-logging experiments, I can say that a lot can go wrong with sensors, and they are susceptible to outside environmental conditions. For instance, they can log your location miles away (even in another continent), the temperature gauge can play up, time stamps can revert to different time zones, the speed of travel can be wildly inaccurate due to propagation delays in satellites, readings may not be at regular intervals due to some kind of interference, and memory overflow and battery issues, while getting better, are still problematic. The short and long of it is that technology cannot be trusted. At best, it can act as supporting evidence but should never replace eyewitness accounts. Additionally, “the inherent problem with uberveillance is that facts do not always add up to truth (i.e., as in the case of an exclusive disjunction T 1 T 5 F), and predictions based on uberveillance are not always correct” [30].

Conclusion

While device manufacturers are challenging the possibility that their ICDs are hackable in courts [43], highly revered security experts like Bruce Schneier are heavily cautioning about going down the IoT path, no matter how inviting it might look. In his acclaimed blog, Schneier recently wrote [44]:

All computers are hackable…The industry is filled with market failures that, until now, have been largely ignorable. As computers continue to permeate our homes, cars, businesses, these market failures will no longer be tolerable. Our only solution will be regulation, and that regulation will be foisted on us by a government desperate to “do something” in the face of disaster…We also need to reverse the trend to connect everything to the internet. And if we risk harm and even death, we need to think twice about what we connect and what we deliberately leave uncomputerized. If we get this wrong, the computer industry will look like the pharmaceutical industry, or the aircraft industry. But if we get this right, we can maintain the innovative environment of the internet that has given us so much.

The cardiac implantables market by 2020 is predicted to become a US$43 billion industry [45]. Obviously, the stakes are high and getting higher with every breakthrough implantable innovation we develop and bring to market. We will need to address some very pressing questions at hand, as Schneier suggests, through some form of regulation if we are to maintain consumer privacy rights and data security. Joe Carvalko, a former telecommunications engineer and U.S. patent attorney as well as an associate editor of IEEE Technology and Society Magazine and pacemaker recipient, has added much to this discussion already [46], [47]. I highly recommend several of his publications, including “Who Should Own In-the-Body Medical Data in the Age of eHealth?” [48] and an ABA publication coauthored with Cara Morris, The Science and Technology Guidebook for Lawyers [49]. Carvalko is a thought leader in this space, and I encourage you to listen to his podcast [50] and also to read his speculative fiction novel, Death by Internet, [51] which is hot off the press and wrestles with some of the issues raised in this article.

REFERENCES

[1] K. Michael, M. Thistlethwaite, M. Rowland, and K. Pitt. (2015, Mar. 6). Standing Committee on Infrastructure and Communications, Section 313 of the Telecommunications Act 1997. [Online]. Available: http:// parlinfo.aph.gov.au/parlInfo/search/display/display.w3p;db=COMMITT EES;id=committees%2Fcommrep%2Fd8727a07-ba09-4a91-9920-73d21 e446d1d%2F0006;query=Id%3A%22committees%2Fcommrep%2Fd872 7a07-ba09-4a91-9920-73d21e446d1d%2F0000%22

[2] S. Bronitt and K. Michael, “Human rights, regulation, and national security,” IEEE Technol. Soc. Mag., vol. 31, pp. 15–16, 2012.

[3] B. Hall. (2016, Dec. 22). Australians’ phone and email records could be used in civil lawsuits. Sydney Morning Herald. [Online]. Available: http:// www.smh.com.au/federal-politics/political-news/australians-phone-andemail-records-could-be-used-in-civil-lawsuits-20161222-gtgdy6.html

[4] PureVPN. (2015, Oct. 14). Data retention laws—an update. [Online]. Available: https://www.purevpn.com/blog/data-retention-laws-by-countries/

[5] D. Crawford. (2014, Nov. 18). Renegade Swedish ISP offers all customers VPN. Best VPN. [Online]. Available: https://www.bestvpn.com/ blog/11806/renegade-swedish-isp-offers-customers-vpn/

[6] J. Ball. (2013, Oct. 1). NSA stores metadata of millions of web users for up to a year, secret files show. Guardian. [Online]. Available: https://www .theguardian.com/world/2013/sep/30/nsa-americans-metadata-year-documents

[7] J. S. Granick, American Spies: Modern Surveillance, Why You Should Care, and What to Do About It. Cambridge, U.K.: Cambridge Univ. Press, 2017.

[8] A. Gregory, American Surveillance: Intelligence, Privacy, and the Fourth Amendment. Madison: Univ. of Wisconsin Press, 2016.

[9] K. Michael, G. Roussos, G. Q. Huang, A. Chattopadhyay, R. Gadh, B. S. Prabhu, and P. Chu, “Planetary-scale RFID services in an age of uberveillance,” Proc. IEEE, vol. 98, no. 9, pp. 1663–1671, 2010.

[10] N. Lars. (2015, Mar. 26). Connected medical devices, apps: Are they leading the IOT revolution—or vice versa? Wired. [Online]. Available: https://www.wired.com/insights/2014/06/connected-medical-devicesapps-leading-iot-revolution-vice-versa/

[11] H. Campos. (2015). The heart of the matter. Slate. [Online]. Available: http://www.slate.com/articles/technology/future_tense/2015/03/ patients_should_be_allowed_to_access_data_generated_by_implanted_ devices.html

[12] H. Campos. (2011). Fighting for the right to open his heart data: Hugo Campos at TEDxCambridge 2011. [Online]. Available: https:// www.youtube.com/watch?v=oro19-l5M8k

[13] D. Hinckley. (2016, Feb. 22). This big brother/big data business goes way beyond Apple and the FBI. Huffington Post. [Online]. Available: http://www.huffingtonpost.com/david-hinckley/this-big-brotherbigdata_b_9292744.html october 2017 ^ IEEE Consumer Electronics Magazine 115

[14] K. Michael, “Mental health, implantables, and side effects,” IEEE Technol. Soc. Mag., vol. 34, no. 2, pp. 5–17, 2015.

[15] K. Michael, “The technological trajectory of the automatic identification industry: The application of the systems of innovation (SI) framework for the characterisation and prediction of the auto-ID industry,” Ph.D. dissertation, School of Information Technology and Computer Science, Univ. of Wollongong, Wollongong, Australia, 2003.

[16] K. Michael and M. G. Michael, “Homo electricus and the continued speciation of humans,” in The Encyclopedia of Information Ethics and Security, M. Quigley, Ed. Hershey, PA: IGI Global, 2007, pp. 312–318.

[17] Google Glass. (2014, Aug. 19). Glass terms of use. [Online]. Available: https://www.google.com/glass/termsofuse/

[18] K. Michael and M. G. Michael, “Implementing ‘namebers’ using microchip implants: The black box beneath the skin,” in This Pervasive Day: The Potential and Perils of Pervasive Computing, J. Pitt, Ed. London, U.K.: Imperial College Press, 2011.

[19] D. Smith. (2017, Feb. 4). Pacemaker data used to charge alleged arsonist. Jonathan Turley. [Online]. Available: https://jonathanturley .org/2017/02/04/pacemaker-data-used-to-charge-alleged-arsonist/

[20] K. Michael, “Big data and policing: The pros and cons of using situational awareness for proactive criminalisation,” presented at the Human Rights and Policing Conf,. Australian National University, Canberra, Apr. 16, 2013.

[21] K. Michael and G. L. Rose, “Human tracking technology in mutual legal assistance and police inter-state cooperation in international crimes,” in From Dataveillance to Überveillance and the Realpolitik of the Transparent Society (The Second Workshop on Social Implications of National Security), K. Michael and M. G. Michael, Eds. Wollongong, Australia: University of Wollongong, 2007.

[22] F. Gerry, “Using data to combat human rights abuses,” IEEE Technol. Soc. Mag., vol. 33, no. 4, pp. 42–43, 2014.

[23] J. Gershman. (2016, Apr. 21). Prosecutors say Fitbit device exposed fibbing in rape case. Wall Street Journal. [Online]. Available: http:// blogs.wsj.com/law/2016/04/21/prosecutors-say-fitbit-device-exposedfibbing-in-rape-case/

[24] P. Olson. (2014, Nov. 16). Fitbit data now being used in the courtroom. Forbes. [Online]. Available: https://www.forbes.com/sites/parmyolson/ 2014/11/16/fitbit-data-court-room-personal-injury-claim/#459434e37379

[25] K. Michael and M. G. Michael, “The social and behavioural implications of location-based services,” J. Location Based Services, vol. 5, no. 3–4, pp. 121–137, Sept.–Dec. 2011.

[26] K. Michael, “The European court of human rights ruling against the policy of keeping fingerprints and DNA samples of criminal suspects in Britain, Wales and Northern Ireland: The case of S. and Marper v United Kingdom,” in The Social Implications of Covert Policing (Workshop on the Social Implications of National Security, 2009), S. Bronitt, C. Harfield, and K. Michael, Eds. Wollongong, Australia: University of Wollongong, 2010, pp. 131–155.

[27] M. G. Michael and K. Michael, “National security: The social implications of the politics of transparency,” Prometheus, vol. 24, no. 4, pp. 359–364, 2006.

[28] M. G. Michael, “On the ‘birth’ of uberveillance,” in Uberveillance and the Social Implications of Microchip Implants, M. G. Michael and K. Michael, Eds. Hershey, PA: IGI Global, 2014.

[29] M. G. Michael and K. Michael, “A note on uberveillance,” in From Dataveillance to Überveillance and the Realpolitik of the Transparent Society (The Second Workshop on Social Implications of National Security), M. G. Michael and K. Michael, Eds. Wollongong, Australia: University of Wollongong, 2007.

[30] M. G. Michael and K. Michael, “Toward a state of uberveillance,” IEEE Technol. Soc. Mag., vol. 29, pp. 9–16, 2010.

[31] M. G. Michael and K. Michael, “Uberveillance,” in Fifth Edition of the Macquarie Dictionary, S. Butler, Ed. Sydney, Australia: Sydney University, 2009.

[32] A. Masters and K. Michael, “Lend me your arms: The use and implications of humancentric RFID,” Electron. Commerce Res. Applicat., vol. 6, no. 1, pp. 29–39, 2007.

[33] K. D. Stephan, K. Michael, M. G. Michael, L. Jacob, and E. P. Anesta, “Social implications of technology: The past, the present, and the future,” Proc. IEEE, vol. 100, pp. 1752–1781, 2012. [34] E. Strickland. (2014, June 10). Medtronic wants to implant sensors in everyone. IEEE Spectrum. [Online]. Available: http://spectrum.ieee .org/tech-talk/biomedical/devices/medtronic-wants-to-implant-sensorsin-everyone

[35] K. Michael, “The benefits and harms of national security technologies,” presented at the Int. Women in Law Enforcement Conf., Hyderabad, India, 2015. [36] J. A. Brian Welsh. (2011). The entire history of you,” Black Mirror, C. Brooker, Ed. [Online]. Available: https://www.youtube.com/watch?v= Sw3GIR70HAY

[37] K. Michael, “Sousveillance and point of view technologies in law enforcement,” presented at the Sixth Workshop on the Social Implications of National Security: Sousveillance and Point of View Technologies in Law Enforcement, University of Sydney, Australia, 2012.

[38] K. Albrecht and K. Michael, “Connected: To everyone and everything,” IEEE Technology and Soc. Mag., vol. 32, pp. 31–34, 2013.

[39] M. G. Michael, “The paradox of the uberveillance equation,” IEEE Technol. Soc. Mag., vol. 35, no. 3, pp. 14–16, 20, 2016.

[40] K. Michael, “The final cut—tampering with direct evidence from wearable computers,” presented at the Fifth Int. Conf. Multimedia Information Networking and Security (MINES 2013), Beijing, China, 2013.

[41] V. Radunovic, “Internet governance, security, privacy and the ethical dimension of ICTs in 2030,” IEEE Technol. Soc. Mag., vol. 35, no. 3, pp. 12–14, 2016.

[42] K. Michael. (2011, Sept. 12). The microchipping of people and the uberveillance trajectory. Social Interface. [Online]. Available: http:// socialinterface.blogspot.com.au/2011/08/microchipping-of-people-and .html

[43] O. Ford. (2017, Jan. 12). Post-merger Abbott moves into 2017 with renewed focus, still faces hurdles. J.P. Morgan Healthcare Conf. 2017. [Online]. Available: http://www.medicaldevicedaily.com/servlet/com .accumedia.web.Dispatcher?next=bioWorldHeadlines_article& forceid=94497

[44] B. Schneier. (2017, Feb. 1). Security and the Internet of Things: Schneier on security. [Online]. Available: https://www.schneier.com/ blog/archives/2017/02/security_and_th.html

[45] IndustryARC. (2015, July 30). Cardiac implantable devices market to reach $43 billion by 2020. GlobeNewswire. [Online]. Available: https://globenewswire.com/news-release/2015/07/30/756345/10143745/ en/Cardiac-Implantable-Devices-Market-to-Reach-43-Billion-By-2020 .html

[46] J. Carvalko, The Techno-Human Shell: A Jump in the Evolutionary Gap. Mechanicsburg, PA: Sunbury Press, 2013.

[47] J. Carvalko and C. Morris, “Crowdsourcing biological specimen identification: Consumer technology applied to health-care access,” IEEE Consum. Electron. Mag., vol. 4, no. 1, pp. 90–93, 2014.

[48] J. Carvalko, “Who should own in-the-body medical data in the age of ehealth?” IEEE Technol. Soc. Mag., vol. 33, no. 2, pp. 36–37, 2014.

[49] J. Carvalko and C. Morris, The Science and Technology Guidebook for Lawyers. New York: ABA, 2014.

[50] K. Michael and J. Carvalko. (2016, June 20). Joseph Carvalko speaks with Katina Michael on his non-fiction and fiction pieces. [Online]. Available: https://www.youtube.com/watch?v=p4JyVCba6VM

[51] J. Carvalko, Death by Internet. Mechanicsburg, PA: Sunbury Press, 2016.

[52] R. Pearce. (2017, June 7). “No-one’s talking about backdoors” for encrypted services, says PM’s cyber guy. Computerworld. [Online]. Available: https://www.computerworld.com.au/article/620329/no-onetalking-about-backdoors-says-pm-cyber-guy/

[53] M. Ambinder. (2013, Aug. 14). An educated guess about how the NSA is structured. The Atlantic. [Online]. Available: https://www .theatlantic.com/technology/archive/2013/08/an-educated-guess-abouthow-the-nsa-is-structured/278697/

Acknowledgment

A short form of this article was presented as a video keynote speech for the Fourth International Conference on Innovations in Information, Embedded and Communication Systems in Coimbatore, India, on 17 March 2017. The video is available at https://www.youtube.com/watch?v=bEKLDhNfZio.

Keywords

Metadata, Electrocardiography, Pacemakers, Heart beat, Telecommunication services, Implants, Biomedical equipment, biomedical equipment, cardiology, criminal law, medical computing, police data processing, transport protocols, implantable medical device, heart, Australian inquiry, government agencies, illegal online services,mandatory metadata retention laws, government organizations, law enforcement organizations, Internet protocol

Citation: Katina Michael, 2017, "Implantable Medical Device Tells All: Uberveillance Gets to the Heart of the Matter", IEEE Consumer Electronics Magazine, Vol. 6, No. 4, Oct. 2017, pp. 107 - 115, DOI: 10.1109/MCE.2017.2714279.

 

Social-technical issues facing humancentric RFID implantees

Social-technical issues facing the humancentric RFID implantee sub-culture through the eyes of Amal Graafstra

Abstract

Radio-frequency identification (RFID) tags and transponders have traditionally been used to identify domesticated animals so that they can be reunited with their owners in the event that they stray. In the late 1990s, industry started to investigate the benefits of using RFID to identifying non-living things throughout the supply chain toward new efficiencies in business operations. Not long after, people began to consider the possibilities of getting RFID tag or transponder implants for themselves. Mr Amal Graafstra of the United States is one of the first, and probably most well-known ‘do it yourselfer’ (DIY) implantees, who enjoys building customized projects which enable him to interact with his private social living space. Since 2005, hundreds of people have embarked on a mission to interact with their mobile phones, their cars, and their house via a chip implant, providing personalized settings for their own ultimate convenience. This paper presents some of the socio-technical issues facing the RFID implantee sub-culture, namely health and safety, privacy, security, regulation, and societal perceptions. The paper concludes with a list of recommendations related to implantables for hobbyists.

Section 1. Introduction

While some cultures embrace the practice of decorating the human body with tattoos and brands, others still perform the age-old art of scarification [1]. Of greater currency today however is the act of body piercing using a plethora of metallic materials, including titanium. Some have even opted to modify the body in outward appearance by using large subdermal or transdermal implants on their heads and forearms [2]. But beyond the purely cosmetic body modifications that some subcultures engage in [3], there are now techno-hobbyists who are transforming the manner in which they interact with their personal social living space through the use of functional high-tech devices known as radio-frequency identification (RFID) tags and transponders.

On the 22nd of March 2005, Mr Amal Graafstra was implanted with his first radio-frequency identification tag [4]. Anecdotal evidence from other do-it-yourselfer implantees agree that Graafstra has been a pioneer in this field, doing things “first” and also “better” than most other implantees meddling in the high-tech art. In the Beginning of 2006 Graafstra even published a book about the applications he had built [5]. Other high profile implantees [6], some of whom preceded Graafstra, include: Kevin Warwick (University of Reading academic) [7], Scott Silverman (CEO of VeriChip Corporation) [8], Rafael Macedo de la Concha (Mexico's Attorney General) [9], Dr. John Halamka (Harvard Medical School's CIO) [10], Gary Retherford (employee at CityWatcher.com) [11], Mikey Sklar (a UNIX engineer) [12], Jonathan Oxer (a LINUX guru) [13], and Meghan Trainor (doctoral student and artist) [14]. This paper however is not concerned with professional “research-oriented” RFID implantees, such as Kevin Warwick, nor with consumers/customers who have been implanted with commercially available Veri Chip technology, nor with individuals who have used RFID for their artistic performances, such as Eduardo Kac [15]. Rather, this paper is concerned with understanding do it yourselfer (DIY) implantees who are usually technically-savvy citizens and are predominantly interested in novel convenience-oriented solutions. This paper focuses on the challenging socio-technical issues and questions that DIY implantees are faced with, related to health and safety, privacy, security, regulation and societal perceptions.

Section 2. Literature Review

A number of academic articles and book chapters have been published on the life and works of Amal Graafstra, including his own full-length book titled RFID Toys [5]. Graafstra featured in his own IEEE Spectrum article in 2007 [16] and several other academic works about him have been written between 2008 and 2009 [17], [18]. He has also figured in hundreds of popular stories in all forms of media-print, radio and television that have received worldwide coverage, e.g. [19], [20], [21], [22]. Most recently Fox News wrote about him [23] and the Discovery Channel interviewed him. While anyone in Graafstra's position would have probably commercialized their ideas by now, Graafstra remains content in pursuing things that are ‘fun’ rather than things which ‘make money,’ although he admittedly does have an entrepreneurial streak about him. Despite the attention, Graafstra remains level-headed, and it is clear upon speaking with him, that he is more about innovation than he is about becoming famous.

Section 3. Methodology

This paper takes on a non-traditional ICT methodological form in that it is written in two voices; Part A is written in the first person voice of Amal Graafstra where he describes events as a participant and Part B is written in the third person voice where Michael and Michael are relating events about Graafstra, and Graafstra is relating events about others. In 2007, Michael and Michael embarked on a full-length interview with Graafstra [24]. Some two years after the interview was conducted, the interviewers requested that Graafstra reflect on his own ideas and commentary as stated in the original interview transcript [25], and make amendments as he saw fit. Time is a very important element when one considers new radical technologies and applications, especially those that seem to evoke a great deal of interdisciplinary debate. Take the launch of the ENIAC in 1948 for instance, and the misconceptions that ensued [26], although few could have possibly predicted that such awesome machinery would find its way into humans.

In Part A, Graafstra’ s story is depicted “uncut”, and Michael and Michael do not interrupt the flow or stream of ideas but can be credited with evoking responses to questions that Graafstra is seldom asked. The usual media hype disappointingly focuses on whether Graafstra is the ‘devil’ and falls short of those all important philosophical questions about the future trajectory of technology. K. Michael has a background in information and communication technology (ICT) and law, while M.G. Michael has qualifications in philosophy, history and theology and has written on topics related to bioethics and the misuse of new technologies by society. The rich combination of backgrounds and experiences has brought about an interdisciplinary discussion between the three authors in Part B. It does not mean that the authors agree on all points, but new research should not necessarily bring about agreement, but debate toward further discussion. In some sense, this is what the IEEE ISTASIO Conference is about, respecting diverse opinions and looking at new technologies in an interdisciplinary manner that may help to shed light on future developments and how society is to absorb them.

3.1. Case Study: Amal Graafstra

According to Yin (1984, p. 23) a case study “investigates a contemporary phenomenon within its real-life context”. The case study in this paper is of a human subject, Mr Amal Graafstra. Graafstra can be considered a participant-researcher in this study while Michael and Michael act as independent observers of the subject within his real-life context.

3.1.1. Background

Amal Graafstra is the Director of Information Technology for OutBack Power Systems. He is the owner of several technology and mobile communications companies. Amal loves thinking up interesting ways to combine and apply various technologies in his daily life. A self-starter, Amal dropped out of community college and started his first company at the age of seventeen. The company was called The Guild, and it provided dial-up Internet access to customers, while small set-ups were still feasible.

Some years later, Amal started his second company Morpheus, which specialized in web hosting and web development. For some time the company did well, but as cheaper hosting services became available, it became more and more difficult to compete in the market. Amal then decided to rebuild Morpheus by supplying managed computing services to the medical industry. In parallel, Amal did some work for WireCutter, a wireless mobile messaging company that were involved in creating mobile marketing campaigns for various radio stations, sending SMS text messages to mobile phones. Graafstra decided to pour his heart and soul into the company he called txtGroups but this too was unable to make ends meet, and soon Twitter rapidly overtook txtGroups as a social text platform. His most recent employment is as the head of an information technology (IT) department where he enjoys creating novel and innovative solutions that enable the business to grow.

3.2. Interview

The interview conducted in 2007 between Graafstra (the subject) and K. Michael (the interviewer) was semistructured and contained 25 questions. The main themes addressed included:

  • Background (upbringing, schooling, qualifications, employment, age and place of residence)

  • Adoption of technology habits, value proposition for RFID implants, and prospects of commercialising intellectual property around humancentric chip implants

  • Motivations for going with an implantable technology as opposed to wearable or luggable device

  • Self-perceptions, whether he is a hobbyist or entrepreneur and what words, terms or phrases he uses to refer to himself (i.e. cyborg versus electrophorus)

  • Thoughts on implantation, who was to conduct the procedure, any barriers or challenges to overcome, and whether or not he had to ask permission to get the implant

  • Feelings on the actual implant process, how it made him feel, whether it was painful or painless and how he dealt with the aftermath of the implantation

  • Attitudes and perceptions towards the application of microchip implants in humans and ethical issues, discussed in terms of specific scenarios and stakeholders

  • Values on mandatory, voluntary, commercial and noncommercial and government-mandated humancentric applications pertaining to issues of consent, opting in/out

  • Views on the location of implantation, the type of tag that should be used, the durability of the tag, and its potential functionality

  • Experiences with Christians or civil libertarians who oppose his use of RFID and his counter-arguments to such notions as the fulfillment of prophecy/“mark of the beast”

  • Personal philosophical and spiritual perspectives

  • Knowledge on the prospect of RFID implant viruses spreading, relationship impacts, potential health risks and security breaches, and other general concerns.

3.3. Ethnography and Participant Observation

Graafstra was asked by Michael and Michael to write a reflection on the original transcript, in actual fact to take on the role of a participant observer. This reflection was integrated into the original transcript, forming Part A of this paper. The reflection remains ‘untouched’ save for changes in formatting and expression. These are the raw thoughts of Amal Graafstra, captured in an ethnographic style [27]: “[i]t is a distinctive feature of social research that the ‘objects’ studied are in fact ‘subjects’ … unlike physical objects or animals, they produce accounts of themselves and their worlds.” Michael and Michael have added relevant bibliographic sources to Part A, and in Part B the content from the original interview conducted with Graafstra is qualitatively analyzed to draw out anthropological and sociological orientations. It is here where the third person voice is used by the authors but where also, events related to Graafstra himself, are cited through direct quotation.

Part A-Participant Observation

In Part A, Amal Graafstra tells his DIY tagger story as a participant observer. He is both the object and subject of his narrative. Graafstra takes us on a tour of where and how it all began-his early interest in computing, in what he calls fun “projects”, and finally what led him to get an RFID tag implanted into his left hand in 2005. Graafstra then takes us on a journey of how he acquired his implant, and how it makes him feel to be a bearer of beneath-the-skin technology. He dedicates a great deal of space discussing health and safety issues relevant to RFID implants and concludes by emphasizing the importance for DIYers to take personal responsibility for their actions.

Section 4. In the Beginning…

Technology has always been an interest of mine. From a very early age I was doing what lots of other inquisitive toddlers were doing … tearing things apart out of curiosity and not being able to put them back together. I was intrigued with seemingly magical things. Wood blocks can only hold one's interest for so long. But a record player or a telephone, those things just held some kind of mystery that needed exploration.

It was not until third grade however, where two very unlikely set of circumstances occurred which introduced me to the boundless potential the world of computers had to offer. I had the privilege of going to a country school. It was literally nestled in a forest, the trees of which we would build forts in during recess. It was very small with only four rooms, one for each grade. Oddly enough, the third grade classroom had a PET computer in it - the only one in the entire school. It had no disk or cassette tape storage and no operating system, just a PET version of BASIC in read only memory (ROM). For the greater part, it sat unused in the corner, a simple and momentary curiosity for most… but not to me. I turned it on and got a simple flashing cursor. What could it mean? What does it want me to type? The mystery was just too great to resist, but without any book or instruction manual, or anyone who knew anything about it at the entire school, I did not get far at all and started to lose interest.

Luckily, that year the school started a new program called Reading Is Fundamental (R.I.F.), where each student was allowed to pick out and keep a free book twice a year. I loved choose-your-own-adventure (CYOA) books, and started picking through the piles to find all the CYOA books available. I noticed there were two books in my stack of potential keepers that said “Computer Programs” on the cover. As I thumbed through those two books I saw there was “programming code” for IBM and Apple II computers, and I wondered if the PET would understand any of it. I picked one out and brought it back to the classroom, and that is when the fun began. If either the IBM or Apple code had worked perfectly “as-is”, it may not have captured my imagination. The fact was, I had to ask for a PET programming book from the teacher, who did manage to track one down. With it, I could cross reference the code in the CYOA book with the PET BASIC book to make the code actually work. By the end of third grade, I was obsessed with the notion I could use a special language to tell the computer exactly what to do and it would do it. I felt like anything was possible! I immediately started begging my parents to buy a computer.

4.1. Technology and Having Fun

There is something special about the latest gadget that comes out or the next release of a fondly regarded software application. It is more than just being able to get a greater number of tasks done; it is also about exploring new possibilities. The creativity one can express through building solutions that work well and people use offers a sense of accomplishment and even pride. That building process might turn out to require creating an entirely new technology of some sort, but for most that process is about extending existing technologies in some way.

Typically, extending a technology is done through standardized channels such as software components, libraries, software development kits (SDKs), and application programming interfaces (APls). In the hardware realm one uses integrated circuits (ICs) with integrated functions, or entire original equipment manufacturer (OEM) hardware modules designed to be integrated into products. What I really love to do however is take an existing product and enhance it, sometimes using methods outside the typical channels. Some people might call that “hacking” but to me it is more about getting into the nuts and bolts of a product and making it do what you want it to do.

For example, I wanted to change out the deadbolt in the front door of my home to work without a key. I purchased an electronic deadbolt that worked with a key or by entering a PIN code by keypad. That was fine for a couple days, but the first time I had a handful of groceries and tried to enter the PIN code, I knew I wanted more. I wanted the deadbolt to unlock faster, without a key and without having to enter a PIN code. I just wanted it to know it was me and let me in, even if I had a handful of groceries. I ended up enhancing that electronic deadbolt to also accept RFID tags as a form of authentication. Later I expanded this idea further to allow a PC to log entries, allow me to set alerts, and even allow me to use other forms of authentication like email and text messages to unlock the door (great for letting neighbors in to check on your pets while you are away). There is no way I would be able to find a residential deadbolt that could do all that, let alone pay less than I did to build it myself.

4.2. Hobbyist or Entrepreneur?

I definitely have an entrepreneurial streak in me. I have started several service-based technology businesses and essentially worked for myself for 15 of the last 17 years or so. When it comes to RFID however, it's mostly just a hobby. I've done some consulting here and there, but when everyday people hear about my implants and the little projects I have built, they tend to ask me if I have any patents and/or plan to market some of these ideas.

The truth is most people have no idea what constitutes a good idea versus a patentable idea versus a marketable idea, or the amount of hard work and risk it takes to bring that little idea all the way to a market successfully. I have not had a good enough idea or met the right people yet with the business experience who could really take these things as far as they would need to go to be successful. Currently my now out-of-print niche market book RFID Toys has been the only commercial venture I have undertaken with regard to RFID, and for the time I have put into it I have basically made around $0.75 USD per hour. Not to mention the whole process was more stressful than it was fun. It seems to be a universal law that states “when you turn a fun hobby into a job, it usually stops being fun”.

So at this point I am much more content with running my little RFID forum, answering people's questions as best I can, helping to solve problems, and putting out some good quality examples others can use to get a basic understanding of hobbyist RFID.

Section 5. Getting the RFID Tag Implant

5.1. The Idea

When I think back to when I first heard about RFID implants, I was very young, perhaps seven or eight years old. I remember my mother telling me how pets were getting these new computer chips and that she did not think it was right. She, and basically everyone I grew up around, thought these things were evil and they would end up controlling humanity via satellite. I remember trodding around in the back yard contemplating the end of civilization as I knew it because of these “horrible devices”. I did not doubt that point of view or those technological misconceptions for quite some time.

The thought of RFID implantation did not resurface until years later when I was faced with the decision of whether or not to implant my own pets with a “tracking chip” (a term still used by vets which does not help dislodge ever-prevalent misconceptions about RFID implantation). By then though I was much more sensible about my approach to technology, and I thoroughly annoyed the veterinarian by asking a ton of technical questions he could not answer. After doing more research (without the aid of a content rich Internet in the early 90s) and really looking into how it worked, I had my pets implanted and I came away with a much better understanding of what the technology could and could not do.

Over a decade later, in March 2005, I found myself moving heavy equipment in and out of my office almost every day. My office door had one of those latches that locked every time it closed, and I really hated having to fish around for my keys all the time. That got me thinking about how archaic the idea of a standard metal key really was. A key is nothing more than a hunk of metal, cut with a certain pattern that identifies me as “authorized”. The typical key and lock system is also lock-centric, meaning the lock is the unique bit and each key that accesses it has to be duplicated from that unique key pattern. Once a unique key pattern is duplicated and distributed, tight control over that lock is essentially lost. I wanted a key-centric solution, meaning each key would be unique and that unique key could be used with various locks. Being unique myself, ideally I wanted that unique key to be me.

I started looking into biometrics, things like face recognition technologies and fingerprint readers. The problem I ran into was the fact that these solutions, when done the right way, were very expensive and resource intensi ve to implement. At the time, there were also serious and valid concerns over the security and reliability of biometric solutions. Also, because I would need to put the camera or fingerprint reader outside, I was also concerned about vandalism. At the time, there were not many reliable biometric options rated for outdoor use that could tell the difference between my real face and a picture of my face, or my fingerprint versus a latex glove fingertip filled with water pressed against the sensor where the remnants of my own fingerprint left on the sensor would betray me. However, I did find a variety of very inexpensive RFID readers, and writing my own software to work with them was a no-brainer. The only down side to RFID was the fact I had to carry around an access card. That got me thinking about pet implants again, and I realized I could get the benefits of RFID without having to carry around anything.

5.2. The RFID Tag Acquisition

The first thing I did was look into getting an actual pet tag implanted, but there were a few issues with pet tags. I discovered there were many different kinds of RFID, and they did not all play well with each other. As it turned out, I could not find any cheap readers that would read the pet tags, and nothing really existed in the OEM hardware space which would have allowed me to easily integrate the pet tag into a custom built access control solution. Another issue was that pet tags have a special porous “anti - migration” coating on them that is designed to allow flesh to grow into and lock the implant in place, making removal or replacement nearly impossible.

There was another option for RFID implantation; the Veri Chip. I had already heard about how the Food and Drug Administration (FDA) had approved the VeriChip for implantation into humans, but the Veri Chip had the same issues pet tags had. Hardware options were very limited and expensive, and the tags also had anti-migration coating on them. I also found out that you must be registered in the Veri Chip database to receive one of their implants, which I had issues with considering my goals and intended uses were all private in nature.

Left hand with EM4102 implant and USB reader

So, I figured I would just start with a basic keycard system and find some cheap RFID readers that were easy to interface with or were designed as OEM hardware I could easily integrate into my project. I found several reader options that read EM4102 based tags, so I started looking around for RFID tags based on the EM4102 chip. What I found just about made me jump out of my seat. I found a website that sold EM4102 based RFID tags that came in a glass ampoule form factor just like the pet tags! In addition, these did not have any coating on them. I immediately ordered the reader hardware and a few glass tags (figure 1).

 

While I waited for the equipment to arrive, I started calling tag manufacturers to find out what differences there might be between the glass tags I ordered (which were not designed for implantation) and implantable pet and human glass tags. It turns out there were only a few insignificant differences, the first of which was that tags did not have the anti-migration coating on them. Second, the EM 4102 based tags did not use the International Organization for Standardization (ISO) animal implant data protocol, which I did not care about either. Finally, they were not manufactured or sold as sterile equipment. After several difficult conversations with various manufacturers, I found out the glass used in the tags I ordered and the animal (pet/livestock/human) implantable tags were the same stuff. That was good enough for me, so as soon as the tags arrived, I was arranging my first implant procedure. At the time I was running a managed computing service designed for medical clinics and had several doctors as clients. Once I confirmed the glass tags worked, I scheduled the implant procedure with one of my clients, a cosmetic surgeon, and started building projects. At the time, I did not tell anyone that I was scheduled for an implant procedure, partly because I was so busy creating my first access control project and partly because at the time I did not consider getting an RFID tag implanted in my left hand to be that novel of an idea. A couple days later after a five minute procedure my left hand was RFID enabled and I had a basic access control system built for my office door.

5.3. A Cyborg or an Electrophorus?

People often ask if I feel any different now, or if I can feel the tags under my skin. Over 5 years later, the answer to both questions is no, not really. I do not feel any different, nor can I feel either implant unless I physically poke one with my finger. In fact, I often forget they are there until I have to use them.

At first it was kind of weird though, and during times of boredom I found myself mindlessly poking at them and feeling the implants under my skin. There was this kind of this cool factor to using them. I would put my hand to the front door and it would unlock, and people would be like “What!? Hold on … what just happened?” and at the time I kind of did feel like a cyborg of sorts.

But over time, the novelty wore off, and now they are just the useful tools I always wanted them to be. Even the interesting conversations I used get into with people regarding safety, security, privacy, religious concerns, and the future of the technology itself now tend to be redundant and repeat themselves constantly. Even my definition of what a cyborg is has changed.

The well-known Professor Kevin Warwick underwent the first human implantation of an RFID tag long before I even thought about doing it. He called that project Cyborg 1.0, which captured both headlines and imaginations. My definition of cyborg is a bit different however. A person with a cochlear implant or even a pace maker, those people are truly mixing technology with biology to become a cybernetic-organism (cyborg). What I have done is simply move an RFID tag from my pants pocket to a skin pocket. There is no biological interaction, and to me that interaction is what defines a cyborg. Michael and Michael [28] distinguish between what is traditionally considered a cybernetic-organism and DIY implantees who are merely “bearers” of technology (i.e. an electrophorus). I think that it is a good idea to have a term that separates us from cyborgs.

So why even bother with implanting a tag in the first place? A lot of people also ask me why “take the risk” putting it under my skin? Why not wear a watch or ring or something with a tag in it? The simple answer is-I won't wear a watch or a ring for very long without losing it. It would be like wearing a backpack everywhere you went; you would just want to take it off all the time due to it being uncomfortable. When I looked at what was possible with glass encased tags and the history these types of RFID implants had with pets, I really did not think twice about getting one implanted. Not to say that I did not do my research first [29], but the actual decision to get a tag implanted was made in a matter of seconds, and I have never regretted it.

Section 6. Is Implanting an Rfid Tag in the Body a “Safe” Practice?

Safety is a big issue, and is still a concern for every do-it-yourselfer (DIY) tagger that is considering or has already undergone an implantation procedure. Given DIY tagging is done through the sheer will of one's own accord, every tagger must take full responsibility for their decisions and actions, their health, safety, and the ultimate outcome of their RFID implantation endeavors.

Table 1. Primary safety concerns for DIY taggers

As the DIY community grows, and more people get non-FDA approved glass tags implanted in non-FDA approved locations, so too the concerns over the safety of RFID implants will grow (Table 1).

6.1. Sterilization

A common method for sterilizing medical equipment is to place it into an autoclave, where heat and pressure destroy any pathogens. The temperature reached inside an autoclave however, is well above acceptable operational and storage specifications for most RFID tags. Due to this, I did not autoclave my glass tags. Both my implants were sterilized by soaking them in a liquid antiseptic for a few minutes before the implantation procedure. As others learnt of what I had done and expressed interest in getting a RFID implant, I suggested they avoid using the autoclave to sterilize their tags as the heat may damage them.

I later performed a test, placing five 2×12mm EM4102 based glass tags in an autoclave for a full one hour cycle. All five tags came out sterile and in working order. On the RFID Toys forum, other users reported similar success with the autoclave and EM4102 tags, leading me to now suggest purchasing at least two tags and putting them through the autoclave prior to implantation. Of course, testing the tags after the sterilization process and before implantation is strongly suggested.

I believe read-only EM4102 tags are able to withstand the high temperatures of the autoclave because the IC chips typically have their unique IDs laser etched into ROM at the factory. Other tag families such as the Philips HITAG with writable memory blocks may not fare as well with such high temperatures, and significant damage to the writable blocks may occur.

6.2. Location

For his Cyborg 1.0 project, Professor Kevin Warwick decided to implant a glass encased tag into the upper inside of his left arm, beneath the inner layer of skin and on top of the muscle [31]. The location seemed to offer a safe haven for the fragile glass casing. Nine days later the tag was removed without complication.

Unlike the typical VeriChip or pet identification applications where a handheld reader is brought in close proximity to the implant, I use my implants in applications where the tag must typically be brought to a fixed reader. Because the normal operational range of small cylindrical glass tags is anywhere from one to four inches, I chose to implant both my tags (one in each hand) into the webbed area between my thumb and index finger, just under the dermis layer. This location allows me to easily position my RFID tags very close to a reader, while still providing an amount of soft tissue to cushion and protect the tags from blunt force impact. Being just under the skin and not in muscle tissue also allows for easy removal or replacement. Most, but not all, DIY taggers have chosen the same location for their implants.

6.3. Migration

Glass encased RFID tags which are designed for implantation in animals or humans typically have an anti-migration coating of some sort affixed to the glass casing. This porous material allows the implantee's flesh to grow into the material which stops the tag from moving around in the body.

The primary purpose of keeping the glass RFID tag located at the selected implantation site has more to do with consistency and ease of use than potential health risks. Veterinarians need to be able to reliably scan the same area on every pet to determine if the animal has a microchip. If tags were able to migrate from their implantation site, vets may fail to successfully scan and identify a tagged pet. In the case of tagging livestock, you do not want to accidentally have a tag migrate into a piece of meat that ends up on the consumer dining table or in scrap pieces of carcass which may be rendered for a variety of food chain-related uses.

Like myself, the DIY tagger community has taken to using glass tags which are not designed for implantation, and as such do not utilize this coating. The lack of coating allows tags to be removed or replaced much more easily than if they had this coating, and after five years neither of my tags have migrated from their implant sites. This may be due to the fact that my tags rest in congruous elastic skin tissue rather than fibrous muscle tissue which is bundled into separate strands that an implant could move between.

6.4. Structural Compromise

The thought of a glass capsule being crushed into small sharp shards while it is still inside one's body does not produce feelings of excitement or enthusiasm. Concern over the structural resilience are warranted, since the cylindrical glass capsules encasing the RFID tag's electrical components (IC, antenna coil, etc.) have very thin walls and are easily crushed using common medical instruments like forceps.

The FDA initially considered the Veri Chip as a class II device which requires special control testing [32]. However this testing did not include any sort of structural integrity test. No crush/penetration tests were performed, and key factors such as lateral stress or compression limits. are unknown. Later, the FDA reclassified the Veri Chip [33], placing it in the type III group of devices which has even fewer controls. The health risks specifically identified in the K033440 reclassification include [34]; adverse tissue reaction, migration of implanted transponder, failure of inserter, failure of electronic scanner, electromagnetic interference, electrical hazards, magnetic resonance imaging incompatibility, and needle stick. No mention of glass casing fracture or structural compromise.

After five years using my own implants and talking to many DIY taggers who have followed suit, I have not heard of anyone having any issue with crushed or compromised tags. Still, the concern is valid, and the choice of implant size, location, orientation, proximity to bone and other inflexible tissues all play a role in avoiding structural compromise.

6.5. Removal and Replacement

At the time of this writing, I have not observed any accounts of DIY taggers getting their implants removed or replaced. However, the implantation of glass tags that do not make use of a polypropylene polymer based anti-migration coating should enable the tags to remain detached and separate from the body, making removal easier.

Rather than implanting tags deep into muscle tissue, which would require invasive surgery to locate and remove, DIY taggers tend to prefer shallow implantation just under the skin. This reduces both the complexity of locating and the size and nature of the incision required to remove the tag. It also means the body is less prone to inflammation and infection-related side effects.

6.6. Cancer Risk

What started off the recent cancer discussion surrounding animal identification RFID implants was a paper published about a French bulldog who received an RFID “pet microchip” implant in September of 2003 at age 9. In April of 2004 he was examined and found to have a “lump” at the implant site [30]:

“[o]n April 2004, Leon, a 9-year-old male French Bulldog, was examined by the referring veterinarian, based in Guelph, Ontario (Canada), for the sudden growth of a subcutaneous 3×3-cm mass located on the dorsal midline of the neck, just cranial to the shoulders. The dog was regularly vaccinated against the most common canine infectious diseases and rabies, and was micro chipped (Indexel, Merial, Lyon, France) in September 2003.”

This news spread quickly, and older studies were dug up revealing similar links in laboratory mice and soon the firestorm was in full swing. I started getting all kinds of concerned emails from DIY taggers, media interview requests, and more hate mail from concerned members of the public. After reading the studies however, it became clear to me that the risks were not as exaggerated as the media and RFID critics made them out to be.

For example, many articles citing the above-mentioned study claimed the French bulldog “had a giant tumor surrounding the implant” and that the dog had died “an untimely death” from that cancer. Upon simply reading the paper I found both those assertions were false [30];

“The microchip was found, not embedded within the tumor, but immediately adjacent to it, surrounded by a very thin fibrous wall (approximately 1 mm thick) and some fresh hemorrhage.”

Reading further I found [30];

“After surgery, the dog was not vaccinated or microchipped again. Up to now, the dog is well, and no recurrence has been observed.”

So basically the dog was doing fine two years later when the study was published in 2006, and the paper calls out various other possible causes such as postinjection fibrosarcoma (a well-known pathologic entity) characterized by inflammatory peritumoral infiltration, multinucleated giant cells, and myofibroblastic cells.

The plainly published facts did not seem to matter though. Both mainstream media and RFID critics alike jumped all over the academic paper and dug up other studies from which to pull completely out of context findings. However, other papers cited within that French bulldog study do point out implants which were embedded in the center of neoplasms. So what is going on here? I started looking into other studies after visiting sites like antichips.com [35] publishing statements like the following:

“[i]n almost all cases, the malignant tumors, typically sarcomas, arose at the site of the implants and grew to surround and fully encase the devices. These fast-growing, malignant tumors often led to the death of the afflicted animals. In many cases, the tumors metastasized or spread to other parts of the animals. The implants were unequivocally identified as the cause of the cancers.”

The bottom line for myself and other DIY taggers was simple: should we be concerned about this? For the most part, what I found after digging into many of these studies was that these laboratory mice were either genetically prone to cancerous growths or subjected to radiation and/or chemical carcinogens in an effort to intentionally stimulate cancerous growth. So now the question becomes, what would cause cancer to grow around an implant? There could only be two things; the glass used to encase the RFID tag or the anti-migration coating used to lock the implant in place in the flesh. In both instances more research is needed, however it is my personal opinion that the porous coating will likely be revealed as the leading factor in stimulating cancerous growth in the area immediately surrounding implantation sites in predisposed specimens.

6.7. Taking Personal Responsibility

While I believe everyone today needs to take a bit more personal responsibility when it comes to the decisions they make, for a DIY tagger this is especially true. A draft DIY tagger code is depicted in Table 2.

Table 2. DIY tagger code

Part B-Socio-Technical Issues

In Part B, Michael and Michael relate events about Graafstra, and Graafstra relates events about others. The whole Part is written in the third person voice. Where direct quotes are used, Graafstra's sentiments and interview responses are captured verbatim. In this part the main socio-technical issues facing RFID implantees is discussed, including security, privacy, data ownership (personal versus commercial), social issues (e.g. religious responses and socio-political concerns), law and policy. Due to space limitations the authors do not go into great detail in each of the socio-technical issues addressed, rather, this remains the aim of a future work-in-progress. Part B concludes by acknowledging the role of all the stakeholders in the feedback mechanism towards social innovation.

Section 7. RFID, Implantees and Security

RFID is a very broad term that encompasses a plethora of technologies that are all designed differently but do one thing; identify something via radio frequency (RF) communication. That includes everything from the World War II identification friend or foe (IFF) systems to implantable tags to RFID enabled credit cards. As recent as 2006, the United States Department of Homeland Security (DHS) was debating the use of RFID for humans. In reports [37] and [38], it is clear that while one DHS full committee found that deployment of RFID for human identification should be done with caution, the second report by a subcommittee ruled that the practice was inappropriate [39]. The recommendation by the DHS subcommittee read [38]:

“[t]here appear to be specific, narrowly defined situations in which RFID is appropriate for human identification. Miners or firefighters might be appropriately identified using RFID because speed of identification is at a premium in dangerous situations and the need to verify the connection between a card and bearer is low. But for other applications related to human beings, RFID appears to offer little benefit when compared to the consequences it brings for privacy and data integrity. Instead, it increases risks to personal privacy and security, with no commensurate benefit for performance or national security. Most difficult and troubling is the situation in which RFID is ostensibly used for tracking objects (medicine containers, for example), but can in fact be used for monitoring human behavior “For these reasons, we recommend that RFID be disfavored for identifying and tracking human beings. When DHS does choose to use RFID to identify and track individuals, we recommend the implementation of the specific security and privacy safeguards …”

Many RFID technologies are insecure by design, or employ weak or flawed encryption methods. However, that is not to say that an RFID system using an insecure RFID technology is itself insecure by default. Despite the early 2006 findings of the DHS reports, there are U.S. RFID-based schemes which are now in widespread use. Graafstra points to the “trusted traveler” RFID-enabled NEXUS card as an example [40]. The NEXUS card is a U.S. government issued travel card that has an ultra high frequency (UHF) RFID tag inside, which does not employ any encryption technology. Any Generation 2 (Gen 2) UHF reader can read the unique code stored in the tag. The RF technology used by the NEXUS system is insecure, but the NEXUS system that allows one to travel across various borders is not inherently insecure, so one's identity is theoretically not at risk. Graafstra elaborates: “[t]he Gen 2 ID stored in my card is a unique number, but that number in no way gives up any information about me to an attacker who may be able to read it-it is just a number. The systems that link that ID number to actual important information about me are secured in far superior ways than the systems that store your library card account, or in some states, even your dri ver license information.”

Like NEXUS travel cards, the VeriChip medical implant does not employ encryption in any way. Any passive 134 kHz reader capable of understanding the VeriChip data protocol can read the ID of any VeriChip implant. Even though these IDs are tied to medical records, the ID itself is useless to a random attacker because access to those records also requires both access to a medical network and a health professional's account password. Systems that employ encrypted RFID tags have, in the past, relied heavily on the crypto algorithms in the RFID tags themselves to secure the system in which RFID technology was integrated into.

Graafstra uses the example of ExxonMobil's pay-at-the-pump SpeedPass system and the many vehicle immobilizer systems that make use of the 134 kHz TI DST tag, which secures communication through a challenge/response mechanism. The problem with these systems Graafstra outlines is that because they do not possess any other security mechanisms outside of the RFID tag's encryption, the systems are vulnerable to fraud by cracking the encryption algorithm used by tags to generate proper responses to the challenges issued by commercial readers. Once the DST tag crypto had been cracked [41], ExxonMobil had to redesign their SpeedPass payment system to implement credit card style fraud detection to detect and prevent fraudulent transactions. Other tag chipsets that employ encryption mechanisms like MiFare and HIT AG S have also been compromised, leading systems designers to rethink security and start balancing RFID encryption with other security mechanisms.

Graafstra points to the fact that his left hand contains an EM4102 tag, which by design does not utilize any security measures. The tag ID is readable by any 125 kHz reader able to understand EM4102 tags and get close enough to read the tag. He comments, “[e]ven so, I use that tag to unlock my back door when I get home from work. Many would argue that my home is completely insecure because my implanted tag is not secure. I do not disagree, but I also do not believe that I am at any greater risk of home invasion as a result.”

7.1. Security Context

Quite often people think security is a pass/fail scenario. Either something is secure or it is not. In reality, a security policy is a collection of systems, methods, and procedures that protect an asset by removing enough value and/or applying enough deterrence that a potential attacker will not even bother or quit trying. To get to the heart of the matter, you have to start with the premise that nothing is truly secure. If there is enough desire, determination, and resources available to an attacker, they will eventually succeed.

The inherent lack of encryption in many RFID tags impacts DIY taggers building personal use applications differently than it does commercial enterprises like Veri Chip, ExxonMobil, and VISA/MasterCard with their public use applications. Graafstra argues that despite the fact that he uses an insecure RFID tag to unlock the back door of his house, if a random attacker were to get close enough to read the ID of the EM4102 tag implanted in his left hand, they would not have any way to derive his identity (e.g. name), his home location (e.g. where he lives), or his phone number. This is however discounting the simple fact that one can be covertly followed in a public space. Graafstra believes an attacker intent on entering his home would generally use more mundane approaches such as breaking a window, than going to the effort of a technical approach. Graafstra's observations are quite correct, for the time being, until more and more DIY taggers start to rig up their personal living spaces with readers.

7.2. Designing with Security in Mind

7.2.1 RFID Cards in the Corporation

Assuming the encryption algorithms used by “secure tags” today have been or will soon be cracked, system designers need to shift from exclusive reliance on tag encryption and incorporate other features to make their systems more secure. Starting with the RFID tag itself, several businesses integrate RFID access control tags with their employee name badges. These can be constructed with a simple push button membrane or switch that connects the RFID antenna to the tag IC. Graafstra recommends that given the user already has to handle their name badge in order to place it close enough to a reader to get a valid read, why not require a simultaneous press of a switch while doing so? For Graafstra, such a simple design change would eliminate almost every possibility for a non-consensual read by malicious users.

Access control systems can also be designed with more intelligence than they currently possess. Graafstra relates the following scenario with respect to physical access control to a corporation. Assume Dave of XYZ Corp has been the victim of a malicious card scan. The attacker intends to emulate Dave's card ID to gain access to the building by mixing in with the morning rush of people. Dave enters the building first, and then the attacker enters five minutes later. Dave goes to his desk by way of the elevator and a couple of other security doors where his badge is used. The attacker takes a different route to his target, using his emulated Dave badge. The system should be able to recognize the odd access pattern through validation and alert security, possibly offering up an employee photo along side a time stamped video of the various RFID access events. Security personnel could then quickly determine if there was an attempted security breach they needed to address. If so, they could lock down Dave's badge so it no longer functioned, and even set up real-time mobile alerts to tell roving security guards if and where the badge was trying to be used. In theory, Graafstra is correct, system designers for the greater part are not thinking foolproof security blueprints but the reality is that budgeting and security staff resourcing would possibly not allow for such sophisticated security interventions; detection is one thing, acting on an email or mobile alert is another.

7.2.2. RFID Implants and Diy Tagger Protection

Graafstra has spent a great deal of time thinking how DIY taggers could protect themselves from what he terms “casual” security attacks. He has documented his solution as follows. Using the read/write memory blocks that many types of tags have is a good way to increase both the risk and the amount of effort an attacker would have to exert in order to successfully execute an attack. For example, the HIT AG S 2048 tag in his right hand uses 40 bit encryption to protect the contents of its 255 byte read/write memory blocks. The 40 bit encryption will not stop a serious attacker but it will diminish the casual attacker's ability.

Graafstra elaborates in detail: to enhance the security of a system, the memory space can contain a pseudo-random rotating hash which is used in conjunction with the tag's read onl y unique serial number to confirm authorized entry. The hash is generated based on a secret key that only your system knows, coupled with an incrementing counter used to salt the hash. When the hash is read, the system uses much more powerful encryption algorithms to calculate and match the hash stored on the tag than the tag itself is capable of utilizing. The counter value is derived and checked against the system counter to ensure the encrypted hash is correct for the tag IDand to ensure the counter value is moving forward and not staying still or moving backward. Upon successful authentication, the counter is updated and a new hash is written to the memory blocks. If an attacker were able to break the 40 bit encryption to gain access to the memory contents, a successful attack is still orders of magnitude more difficult to pull off than plainly emulating an unencrypted tag. Also, a successful attack would provide a very small window of opportunity as any use of the original card would invalidate the cloned tag's counter/hash combination.

Section 8. RFID Implantees and Privacy

8.1. Misconceptions About RFID Technology

There are a lot of misconceptions in the general community about how various RFID technologies work, prompting unfounded fears of global positioning system (GPS) satellites tracking embedded tags and implants. This is not to say that in the future RFID tags will not be able to interface with a number of different mobile technologies but for now this kind of global tracking is unavailable. And this not because it is not technically feasible to do so, but rather because large-scale agreements have not yet been entered into between a variety of stakeholders.

Active RFID tags can transmit data very long distances, anywhere from a few feet to 10 miles or more, but they use battery power to do so and are bigger and bulkier than passive RFID tags. Inversely, passive tags like those used in retail inventory applications and glass encased implants are typically smaller. They do not have internal power sources, and can generally communicate with readers from only a few inches to a few feet away depending on chipset, size, and frequency used. Certain experiments have shown, under ideal conditions, that passive UHF tags can be read from several hundred feet, but those are special test cases not practical real-world scenarios. Even so, the prevalent fear amongst every day consumers is that, somehow, carrying an RFID tag of any kind will allow “them” (e.g. government agencies) to track your every move.

Today, people's activities are logged constantly. From every non-cash purchase you make to every RFID “fast pay” toll booth archway driven under to every phone call made, something somewhere is logging that activity. Graafstra points out the potential for data mining through a variety of sources, emphasizing that “[n]obody is upset about this type of information gathering as they are about RFID technology … [and that] the backlash from specific segments of the public seems to center on embedded tags, whether they are embedded in clothes, in driver license cards, or people's bodies.” For Graafstra, the stated concerns indicate people believe RFID is capable of more than it really is, and that those perceived capabilities culminate as fear of massive privacy invasion on an unprecedented scale.

8.2. Some Consumer Concerns Warranted

Although Graafstra does acknowledge that some consumer concerns with respect to RFID are valid, he believes the concern is misdirected at the technology itself rather than on human factor issues, e.g. consent. He emphasizes that unobtrusive reads amount to privacy problems, and that to some extent history has already proven that this is a valid concern. Clothing manufacturer Benetton, for example, was found to be embedding RFID tags into women's garments in an effort to quickly identify past customers as they walked into their storefronts [42]. Graafstra also singles out the idea of function creep, inferring that consent given for one use may be extended at a later date as the application grows. People who have to travel over toll roads and bridges may opt to use an RFID tag permanently affixed to their windscreen for automatic payment may find that the terms and conditions they originally signed up for have changed, and in some instances without warning. For example, some state governments collect data from RFID tollway tags to monitor traffic patterns on their roadways without notifying users. Furthermore, logs of which tags passed what checkpoint at what time are kept for undisclosed periods of time and log data could potentially be shared with an unknown number of requestors. Graafstra questions whether the next step will indeed be to issue speeding fines based on how fast people have traveled from checkpoint A to B.

8.3. RFID Tags: Personal Versus Commercial Use

Now let us take a hypothetical look at RFID privacy in a hostile environment, and the differences between personal use and commercial use contexts. When you sign up for a commercial service that utilizes RFID in some way, you surrender your personal information which is tied to that unique tag ID. Assuming the company does not share your tag ID or your information with any other person or company, your information is still associated with that tag ID and could be used to violate your privacy through nonconsensual reading of the tag. The problem gets worse if that company sells or shares that data with other companies or people.

In a personal use context, you never surrender your personal information to anyone, and your tag ID is in no way associated with you. The best any snoopy corporation or government could do would be to aggregate non-identifiable data together to determine patterns of anonymous tag IDs. Of course, there is always the concern that associations could be made through other means. For example, suppose a checkpoint was set up that could read a large cross-section of tags from RFID enabled credit cards, access cards, various tag types in UHF, high frequency (HF), and low frequency (LF) frequency ranges, etc. A properly read and decrypted RFID credit card will reveal the cardholder's name, and if other tag IDs always showed up in logs when “Dave's” unprotected RFID-enabled credit card did, then one could assume that all those RFID tags resided in Dave's wallet with his credit card. While this fact may be disconcerting, Dave can still take measures to protect himself, by choosing to shield his tags and cards [43], or even leave them at home. But what about implanted RFID tags? Leaving those at home is not possible and shielding them could be socially awkward (always explaining why you're wearing tin foil gloves), even though increasingly sentinel jackets are coming onto the market.

Implantable tags like VeriChip which are sold to the public for use within commercial systems do present different privacy challenges than the glass tags implanted by DIY taggers. A commercial system means uniformity when it comes to things like implant location, type of chip, data protocol, and frequency. Since the implant location is common to all users (e.g. in the case of the VeriChip it is the triceps muscle of the right arm), Graafstra believes that a simple reader can be set up at typical arm height in a doorway to casually capture tag IDs from passers-by. With enough people using a common system and enough readers placed in enough doorways, unique traffic profiles could be created for each tag ID much more easily.

Section 9. RFID Implantees and Society

9.1. PET and Animal Identification Systems

Whether people like to admit to it or not, society today is full of RFID tag and transponder technologies embedded in buildings, in vehicles, in packages, in clothing, in animals, and in people's wallets. This diffusion will continue to grow annually with predictions that 26.1 billion units will be sold in 2011 alone [44]. Passive RFID tags designed to be implanted into animals have been around since the early 1980s. After being widely tested by several companies in the early 1990s (such as Destron's LifeChip [45]), the number of pets with implanted RFID tags has skyrocketed as local councils and state governments move to make the chipping of domesticated animals compulsory [46]. To date this practice, above all else, has done more to raise public awareness of the positive applications of implantables than any other use of implantable RFID tags.

Today RFID tags, both passive and active, are used to keep tabs on everything from pets to livestock to wild animals on land, in the air, and in the sea. Graafstra notes, that the U.S. Fish and Wildlife Service uses “microchipping” in its research of wild bison, black-footed ferrets, grizzly bears, elk, white-tailed deer, giant land tortoises and armadillos. New developments in sensors, RF, and power harvesting technologies are also leading the way to “implantable” RF enabled sensors embedded into trees (e.g. orchards). These “tree tags” relay information about the health of the tree, the surrounding forest environment, and raise an alarm in the event of a forest fire [47].

9.2. Is it Hip to Get the Chip?

Since Michael and Michael began their research into non-medical ICT implantables in the mid-1990s, they were preoccupied by the question of diffusion, and predominantly the notion of who influenced whom within the context of an actor network. For example, who was the first DIY tagger implantee? What inspired them to get an implant? How did they come to know of other implantees? When Graafstra received his first implant, he knew he was not the first. Professor Kevin Warwick had long since completed his Cyborg 1.0 project, and VeriChip had received FDA approval and was already implanting customers. Graafstra believes what he embarked on in early 2005 created such a media interest because he got the implant on his own accord, and he self-reported it all using photographs and video via the web. He also was comprehensive in his documentation of what he planned to do with his implant, and quickly demonstrated its functionality. Finally, he also believes implanting a RFID device in the hand, and not in the upper arm, sparked more intrigue and inquiry.

Since that time Veri Chip (now PositivelD [48]) have been marketing their products, and to date allegedly have between 1000 and 2000 people registered in their medical implant database, although some estimates are much lower and some much higher. The size of the DIY community is, by its very nature, unknown. Yet shortly after news of Graafstra's implant became public, he was contacted by lots of members from the general community who wanted to know how to obtain an implant themselves. Graafstra is frank, when he states: “today, anyone can buy glass encased RFID tags and watch self-implantation procedures online, and then go to their local piercing shop to get it done”. One is left pondering, however, whether DIYers are engaged in the act of blueprint copying or idea diffusion, and the repercussions that this might have on how RFID implants are utilized in the future. Jared Diamond describes blueprint copying as the act of copying or modifying an available detailed blueprint. At the opposite end of the spectrum lies idea diffusion, which is when one receives little more than the basic idea and has to reinvent the fine details [49].

Graafstra estimates there could be roughly 200 or 300 DIY taggers around the world who have opted to get a non-commercial RFID implant. Graafstra is reflective, that while he does not know the exact number of DIYers, he does know (or at least understands) the inner motivations of some DIYers to get an implant is less than technical. He said:

“I've been contacted by 16 year old kids who have had to wait until they are 18 to get this done due to - what I think are - valid parental concerns. On my RFID forum, I have repeatedly suggested that it is not worth taking even a minor health risk to get this done if you do not really know why you want it and what your goals are once you have it. Even so, when I asked a couple of these kids why they wanted to get an implant and what they were going to do with it, in both cases their responses were something along the lines of “because it's cool” and “I'm not sure what I'm going to do with it”. I have also been contacted by body-madders who, after getting their fifteenth cosmetic subcutaneous silicone implant, wanted something different … something that was actually functional in some way, even if they did not have any plans to actually use it.”

However most DIY taggers tend to view their implant as a utilitarian tool to be used in daily life with projects they have built themselves. In this loose-knit community [50] of practical DIY taggers, one could argue it is actually “hip to get the chip,” even though the best place for it is unanimously the hand!

9.3. RFID Implants for Families: Peace of Mind?

When considering the applications that Applied Digital Solutions were marketing in 2003, and those that were subsequently marketed by the VeriChip Corporation, Graafstra circumspectly calls the “brochureware” confusing from a marketing perspective at least. For Graafstra, any sort of communication that misleads the public about pinpoint location positioning via the RFID chip is widely fantastical and utterly disappointing. He does not understand, how on the basis of a commercial vision, the Mexican Attorney General allowed himself and some of his staff to be Veri Chipped with an “anti-kidnapping chip”. Parents, like that of Jeffrey and Leslie Jacobs were also lead to believe, probably through mainstream public misconceptions about the function of RFID, that getting a Veri Chip implant would provide their whole family with security and “piece of mind” [51].

The fact is, no RFID implant can provide that kind of security and “traceability” that certain members of society are looking for or are afraid of. The best an RFID implant can do today, is identify the person sitting two inches away from the scanner. That may help identify a corpse, but it will not help find missing persons. This is not to say that in the not-to-distant future, technological convergence might enable very sophisticated applications to be built. The idea of implanting prisoners, persons on parole or persons on extended supervision orders (ESOs), or military service-people with digital implantable dog tags has been considered but has yet to take place. Again, Graafstra points to public polls where consumers believe that implanting prisoners or parolees would make society “safer” because it would make implantees easier to track down and keep in confined zones if required, but he is adamant that these kinds of solutions are not yet possible using implanted RFID tags. The permanency of FDA approved implantables is especially disconcerting as they possibly do not give one-time offenders, or once military service personnel, an opportunity to rehabilitate or move onto other professions [52]. For Graafstra this is a violation of service terms, since imposed subcutaneous FDA approved commercial implants are long lasting physical remnant of requirements that have long since expired, and no longer valid.

9.4. RFID Implants for Employees and the Law

To date, no employer has required an employee or potential employee to obtain an RFID implant in order to become or remain employed. Critics jumped on inaccurate media reports that CityWatcher.com, a now defunct municipal surveillance company, had required employees to get implants to access sensitive datacenters. The fact is three employees did receive VeriChip implants and the company paid for their procedures [53]. However, five employees opted to simply carry around an access card to access those same areas. Implantation was optional, not compulsory. There was a similar optional implantation of employees at the Baja Beach Club in Barcelona, Spain but this was not really publicized.

As a preemptive measure several states in the U.S.A passed laws that banned enforced implantation by employers [54]. For Graafstra the problem has more to do with laws and regulations which target a technology than the very ‘act’ of surveillance. Graafstra notes the law passed in California (Senate Bill 362) that banned employers from mandating that employees or potential employees must get an identifying implant in order to perform their work [55]. The law is written with a heavy slant toward a “radio frequency device”, but an argument could be made that this law also covers biometric technologies and other location based mobile technologies. Intentional or not, the definitions section states;

“Identification device” means any item, application, or product that is passively or actively capable of transmitting personal information, including, but not limited to, devices using radio frequency technology.

“Subcutaneous” means existing, performed, or introduced under or on the skin.

For Graafstra such laws do not do anything for employee workplace rights as a plethora of other technologies exist to determine the whereabouts of workers within campus-based facilities like manufacturing plants. For Graafstra, it has less to do with implantables, and more to do with employee privacy.

9.5. Is Getting an RFID Implant Evil?

Many people believe that RFID implants will harm society and/or humanity in some way. The two most vocal groups are people expressing their religious views, and people expressing their socio-political fears [56]‥

9.5.1. Religious Concerns-“Mark of the Beast”

The interpretation of the Book of Revelation, the last book of the New Testament, by some Christians has caused Graafstra to be the target of backlash by some members of the believing community. Graafstra points to the following verses that RFID critics with a religious orientation invariably point to (Revelation 13: 16–18):

Also it causes all, both small and great, both rich and poor, both free and slave, to be marked on the right hand or the forehead, so that no one can buy or sell unless he has the mark, that is, the name of the beast or the number of its name. This calls for wisdom: let him who has understanding reckon the number of the beast, for it is a human number, its number is six hundred and sixty-six.

From the correspondence that Graafstra has received, he has deduced that some Christians believe that “the devil” will require all of humanity to receive a mark of some kind in order to be able to participate in day-to-day societal transactions. And that furthermore, wise people will recognize that mark and attempt to refuse it. Those who are most vocal about such beliefs have gone so far as to insult and threaten Graafstra, and other DIY taggers about their involvement in ICT implants. Graafstra has spent some time reviewing the passages himself countering:

“[s]ince so many people seem to take the Bible so very literally, in my opinion there are a few things they are either ignoring or do not realize. In verse 16, it says “he causeth all” which means everyone will receive “the mark” regardless of whether they want it or not. In verse 17 it says “no man might buy or sell [without the mark]”, meaning absolutely nobody will be able to do this, even if you are living in an igloo on the North Pole trying to do it illegally. In verse 18 it says nothing about wise people refusing the mark or even being able to, it only discusses how to recognize it.”

There are, however, a number of places in Revelation (16:2, 19:20, 20:10) where it seems evident enough that people will indeed have to make a choice, viz., “the mark”. This was certainly the interpretation of all the early church exegetes who dealt with the prophecy [57]. For Graafstra, however, the mark and the beast are potent warnings about willing subscription to oppressive systems, and how using the tools of those systems will only strengthen such systems. It is very important to distinguish between oppressive systems that use technologies to subjugate a people, and technologies that liberate them, or those being used in a private, personal context.

9.5.2. Socio-Political Fears

Some people believe that RFID implants may one day be mandated on the general populace, instituted by totalitarian governments and other authoritarian regimes [58]. Such persons, firmly believe that RFID technology, particularly implant technology, will in some way enslave humanity and cause a major digital divide. These groups generally point to the involvement of large-scale corporations in the conception, development and implementation of RFID implant technology, and to some extent generate conspiracy theory-like scenarios about the future.

Graafstra also notes that he has been threatened both directly and indirectly by some people harboring sociopolitical fears. He elaborates:

“I have been accused of aiding the government and private corporations in their efforts to deploy RFID implants on a wide scale. I very strongly feel it is a priority to attempt to engage these accusers in civil discussion and attempt, however futile, to impart a bit of knowledge so they might understand how these implants function and ultimately the difference between and separation of DIY taggers from commercial solutions by corporations like VeriChip.”

Simply put, some advocacy groups are not helping the debate and whatever valuable insights they might have is lost in a host of “background noise”. The practice of

‘attracting’ hate mail is common among implantees (both in academia and DIYers), and as Graafstra emphasizes, it often does not encourage a healthy exchange of ideas, although it does alert developers to the social realities that may be stifling adoption and potential ethical liabilities development make need to address.

Section 10. RFID Versus Other Technologies

In Graafstra's opinion it is not so much that consumers should be wary of what RFID can do, but of the widespread diffusion of powerful biometrics and pinpoint positioning technologies. Despite that biometric identification is used extensively all over the world to identify and log all kinds of things, Graafstra notes that it does not receive the same amount of attention that RFID does from advocacy groups. Graafstra sums it up very well when he reflects:

“I think the reason for this is that RFID requires a tangible object carried by or implanted in the object to be identified. Biometric identification does not require this because the identifier is your own body. As biometric monitoring devices get more and more unobtrusive and fade further into the urban landscape, I fear lack of motivation will continue to get worse until a series of very serious civil rights violations occur, but by then we might have a social environment so riddled with circumstances where privacy and basic rights have been traded away for the illusion of security that the general public may actually be afraid to turn off and live without these systems.”

Today's biometric technology can identify you by your full body [59], face, voice, fingerprints, chemical scent, gait mechanics, emotional expressions, your DNA, and even your own shadow [60]. Video cameras are very cheap and easy to deploy, and developments in video processing enable face recognition systems to accurately identify entire crowds of people much faster and more accurately than ever before. If your face is not visible, gait analysis systems can still tell it is “you”, based on the way you walk or your body language. The U.S. military, among others, have been working with satellite imaging to successfully identify key targets based on the shadow they cast on the ground [61].

But beyond biometrics, there is now a plethora of positioning technologies entering the market at different levels of precision [62], [63]. Even the mobile phone (whether 3G-enabled or not) has become a potential privacy-invasive tool. In the U.S., President Barrack Obama recently suggested that U.S. citizens have “no expectation of privacy” with respect to their mobile phones, even when not making a call [64]. Graafstra is not alone in his belief that the idea that anyone from local police to government agencies should be allowed to request-without a warrant-your phone's location at any time (even if it is sitting idle in your home) “is a very scary step that moves the U.S. further toward a surveillance state”. The question as Graafstra has rightly put it is why are these issues not receiving the same attention as RFID tags and implantables? There is an obvious mismatch between perceived encroachments in privacy and actual encroachments in privacy. Advocacy groups might be lobbying for “no RFID implants” but what is here “now” is far worse.

10.1. Opting Out of Commercial ID Systems

If one wishes to opt out of an RFID-based system, users can issue requests to any third parties they enrolled with to have their account information destroyed. While this process and its full compliance is entirely in the hands of those third parties, destruction of the RFID tag is within the control of the users themselves. Tags can be returned to vendors, left at home, thrown out, physically destroyed, or in the case of implants physically removed from the body. However, removal of some RFID implants is more difficult than others. According to the company's product documentation, the FDA approved VeriChip is designed for permanent human implantation. Its Bio-Bond® anti-migration coating and the implantation procedure which seats the tag very deep into muscle tissue create a painful and expensive removal experience. The lack of anti-migration coating on the glass tags used by DIY taggers and their typically shallow implant locations allow easy removal that, in an emergency, could even be done with a sharp knife by the taggers themselves. With biometric systems however, the process of opting out is entirely handled by the third parties whose systems you have been enrolled in. Identifying all of these parties can be impossible if you have passively been enrolled in one or more systems without your knowledge. Furthermore, changing or destroying your biological identifiers can be extremely difficult, expensive, painful, or just plain impossible with today's technology.

Section 11. Conclusion

There is some truth in the belief that technology can be used for well intentioned purposes and not-so-well intentioned purposes alike; see for example the differences between two opposing schools of thought-technological determinism and the social shaping of technology. Graafstra believes that most, if not all technologies are neutral: “[i]t is the people who implement and use a particular technology that determine its effect on humanity.” In that regard, Graafstra is one of the first to acknowledge why some people might have a fear of the potential for wide-scale use of RFID implants, especially when claims are made by persons with limited knowledge of what the technology is capable of, or in other circumstances persons who are completely ignorant of technological capabilities.

In reality, people who rise up so fervently to speak out against RFID do provide valuable feedback to the social innovation process. Graafstra knows too well that there will always be people who can and will build and/or use technology in a way that may be or become oppressive to end-users. The role of the critic is to help in the provision of a balanced view and to ask the very questions that may have been ignored during the development process. Perhaps, in the end, it is even quite irrelevant that some of these opponents understand the technology's true capabilities or limitations. The challenge rather to technologists is to usefully harness the criticism, the feedback, in order to build into their products and solutions design safeguards that mean that identified “potential” threats or harms are minimized or eradicated. Religious advocates against RFID, or those that have socio-political fears about the potential uses of RFID, should attempt to enter into intelligent dialogue rather than burn energy in campaigning against global computer giants or writing disrespectful messages to individual persons who are said to be aiding in the fulfillment of prophecy. The same can be said for law and policymakers, who must be open to discussion and who must arrive at intelligent legislation and industry regulation that targets behavior and the misconduct a technology might enable, not the technology itself. For example, some anti-chipping laws in the U.S. only refer to “injectable” RFID implants but we already have swallowable sensor technologies being patented, and what of the future of nanotechnology for healthcare? Policy that singles out technology as the problem, only limits the scope and effectiveness of the policy per se, while not addressing the real issues lurking beneath the surface.

References

1. C. Grognard, The Tattoo: graffiti for the soul, Spain:The Promotional Reprint Company, 1994.

2. K. MacKendrick, "Technoflesh or “Didn't That Hurt?”", Fashion Theory: The Journal of Dress Body & Culture, vol. 2, pp. 3-24, 1998.

3. C. R. Sanders, Customising the Body: the art and culture of tattooing, Philadelphia:Temple University Press, 1989.

4. A. Graafstra, "One small step for hand: My first RFID implant", Blog, March 2005, [online] Available: http://blog.amal.net/?p=8.

5. A. Graafstra, RFID Toys: 11 Cool Projects for Home Office and Entertainment (Extreme'Tech], New York:John Wiley and Sons, 2006.

6. "10 People or Groups Who Have Been Microchipped", RFID Gazette, September 2006, [online] Available: http://www.rfidgazette.org/2006/09/10_people_or_gr.html.

7. K. Warwick, Professor Kevin Warwick, University of Reading, 2010.

8. J. C. Havens, "Hear and Know” –– Scott Silverman and VeriChip –– (RFID) Security Under The Skin", Association for Automatic Identification and Mobility, June 2006, [online] Available: http://www.aimglobal.org/members/news/templates/template.aspx?articleid=1279&zoneid=45.

9. W. D. Gardner, RFID Chips Implanted In Mexican Law-Enforcement Workers, July 2004, [online] Available: http://www.informationweek.com/news/global-cio/showArticle.jhtml?articleID=23901004.

10. J. Halarnka, A. Juels, A. Stubblefield, J. Westhues, "The Security Implications of VeriChip Cloning", The Journal of the American Medical Informatics Association, vol. 13, pp. 601-607, 2006.

11. T. Lewan, Chips: High tech aids or tracking tools?, July 2007, [online] Available: http://www.usatoday.comltech/products/2007-07-21-928096800_x.htm.

12. A. Leo, "RFID Tags: Convenient Technology or Path to Government Monitoring?", Users of RFID Technology Grapple With Concerns, May 2006, [online] Available: http://abcnews.go.com/Technology/story?id=1913574&page=1.

13. J. Oxer, Blog, 2010, [online] Available: http://jon.oxer.com.au/.

14. M. Trainor, RFID Art, 2010, [online] Available: http://meghantrainor.com/index.html.

15. E. Kac, Time Capsule, November 1997, [online] Available: http://www.ekac.org/figs.html.

16. A. Graafstra, "Hands On: How radio-frequency identification and I got personal", IEEE Spectrum, March 2007, [online] Available: http://spectrum.ieee.org/computing/hardware/hands-on.

17. R. Ip, K. Michael, M. G. Michael, "Amal Graafstra The Do-It-Yourselfer RFID Implantee: The culture values and ethics of hobbyist implantees", Cultural Attitudes Towards Technology and Communication (CATAC08), 2008.

18. K. Michael, M. G. Michael, Innovative Automatic Identification and Location Based Services: From Bar Codes to Chip Implants, Hershey, PA:IGI Global, 2009.

19. K. Heim, "Man grips future with microchip implants in hands", Seattle Times, March 2006, [online] Available: http://seattletimes.nwsource.com/html/localnews/2002835871_chipimplant01.html.

20. Staff Sun, "Implants turn humans into cyborgs", Vancouver Sun, January 2006, [online] Available: http://www.canada.com/vancouversun/news/story.html?id=d4f47afb-6ee3-460d-b4e3-834770fa886b&k=85038.

21. Reuters Staff, "Computer chips get under skin of US enthusiasts", ABC News Online, January 2006, [online] Available: http://www.abc.net.au/cgi-bin/common/printfriendly.pl?http://www.abc.net.au/news/newsitems/200601/s1542754.htm.

22. A. Bahney, "High Tech Under the Skin", New York Times, February 2006, [online] Available: http://query.nytimes.com/gst/fullpage.html?res=9F05E0DB1F3FF931A35751C0A9609C8B63&sec=&spon=&pagewanted=2.

23. G. J. Koprowski, "Where's Jimmy? Just Google His Bar Code", FOXNews.com, May 2010, [online] Available: http://www.foxnews.com/scitech12010/05/14/radio-frequency-rfid-implant/.

24. A. Graafstra, "Interview with Katina Michael…", Blog, May 2007, [online] Available: http://blog.amal.net/?p=36.

25. K. Michael, A. Graafstra, K. Michael, M. G. Michael, "Interview 14.2: The Do-It-Yourselfer RFID Implantee" in Innovative Automatic Identification and Location Based Services: from Bar Codes to Chip Implants, Hershey, PA:Information Science Reference, pp. 427-449, 2009.

26. C. D. Martin, "The myth of the awesome thinking machine", Communications of the ACM, vol. 36, pp. 120-133, 1993.

27. P. Atkinson, M. Hammersley, Ethnography: principles in practice, Abingdon, Oxon: Routledge, 1995.

28. K. Michael, M. G. Michael, M. Quigley, "Homo Electricus and the Continued Speciation of Humans" in The Encyclopedia of Information Ethics and Security, IGI Global, pp. 312-318, 2007.

29. A. Graafstra, "I take credit for that one …", Blog, March 2009, [online] Available: http://blog.amal.net/?p=516.

30. M. Vascellari, E. Melchiotti, F. Mutinelli, "Fibrosarcoma with Typical Features of Postinjection Sarcoma at Site of Microchip Implant in a Dog: Histologic and Immunohistochemical Study", Veterinary Pathology, vol. 43, pp. 545-548, 2006.

31Cyborg 1.0 Wired, no. 8.02, 2000.

32. "Guidance for Industry and FDA Staff (Class II Special Controls Guidance Document: Implantable Radiofrequency Transponder System for Patient Identification and Health Information)", U.S. Department of Health and Human Services Food and Drug Administration Center for Devices and Radiological Health General Hospital Devices Branch Division of Anesthesiology General Hospital Infection Control and Dental Devices Office of Device Evaluation, December 2004, [online] Available: http://www.fda.gov/downloads/MedicaIDevices/DeviceRegulationandGuidance/GuidanceDocuments/ucm072191.pdf.

33US Department of Health and Human Services, vol. K033440, October 2004.

34Google Search “K033440”, 2010, [online] Available: http://google2.fda.gov/search?q=K033440.

35. K. Albrecht, AntiChips.com, November 2007, [online] Available: http://www.antichips.com/cancer.

36. A. Graafstra, "Release form for RFID implantation", Blog, December 2009, [online] Available: http://blog.amal.net/?p=2108.

37The Use of RFID for Human Identity Verification, December 2006, [online] Available: http://www.dhs.gov/xlibrary/assets/privacy/privacy_advcom_12-2006_rpt_RFID.pdf.

38The use of RFID for Human Identification. A draft report from DHS Emerging Applications and Technology subcommittee to the Full Data Privacy and Integrity Advisory Committee Version 1.0 Department of Homeland Security, 2006.

39. G. M. Koien, "RFID and Privacy", Telenor R&I (Network Technologies Group), February 2007, [online] Available: http://www.telenor.comlen/resources/images/077-083_RFID-Privacy_tcm28-36799.pdf.

40. "Trusted Traveler Programs", US Department of Homeland Security: U.S. Customs and Border Protection, December 2009, [online] Available: http://www.cbp.gov/xp/cgov/travel/trusted_traveler/.

41. S. Bono, M. Green, A. Stubblefield, A. Rubin, A. Juels, M. Szydlo, Analysis of the Texas Instruments DST RFID, May 2007, [online] Available: http://rfidtoys.net/downloads/rfidanalysis.org/rfidanalysis.pdf.

42. "Benetton to Tag 15 Million Items", RFID Journal, March 2003, [online] Available: http://www.rfidjournal.comlarticle/view/344/1/1.

43. "RFID blocking sleeves and holders", Smart Card Focus, 2010, [online] Available: http://www.smartcardfocus.comlshop/ilp/se~102/p/index.shtml?gclid=CLWixrPx36ECFQcupAodL1BuKA.

44. "RFID Chip Market to Grow 63% Annually Through 2011", RFID Update, February 2008, [online] Available: http://www.rfidupdate.comlarticles/index.php?id=1538.

45. "Welcome to LifeChip", Destron LifeChip, 2010, [online] Available: http://www.lifechip.com.au/index.php.

46. "Companion Animals Act 1998", Compulsory microchipping in NSW, 1998, [online] Available: http://www.dlg.nsw.gov.au/dlg/dlghome/dlg_InformationIndex.asp?areaindex=CA&index=311.

47. J. Siden, A. Koptyug, M. Gulliksson, H.-E. Nilsson, "An Action Activated and Self Powered Wireless Forest Fire Detector" in Wireless Sensor and Actor Networks, Boston: Springer, pp. 1571-5736, December 2007.

48Positive ID, 2010, [online] Available: http://positiveidcorp.comlabout-us.html.

49. J. Diamond, Guns Germs and Steel: A Short History of Everybody for the Last 13000 Years, London: Vintage, 1997.

50. "Social Consequences and Effects of RFID Implants?", SlashDot, May 2006, [online] Available: http://ask.slashdot.org/article.pI?sid=06/05/04/0030212.

51. J. Scheeres, "They Want Their ID Chips Now", Wired, June 2002, [online] Available: http://www.wired.comlpolitics/security/news/2002/02/50187.

52. K. Michael, M. G. Michael, R. Abbas, "The Dilemmas of Using Wearable Computing to Monitor People: An Extended Metaphor on the Tracking of Prison Inmates and Parolees", Australia and New Zealand Society of Criminology Conference: Crime and Justice Challenges in the 21 st Century, 2009.

53. M. C. O'Connor, "Tag Implants May Be Dangerous for Security Apps Says Group", RFID Journal, August 2006, [online] Available: http://www.rfidjournal.comlarticle/articleview/2607/2/1/.

54. A. Friggieri, K. Michael, M. G. Michael, "The Legal Ramifications of Microchipping People in the United States of America-a State Legislative Comparison", International Symposium on Technology and Society, 2009.

55. Simitian. Identification devices: subcutaneous implanting", Filed with Secretary of State, vol. SB 362, October 2007.

56. K. Michael, M. G. Michael, "The social cultural religious and ethical implications of automatic identification", Proceedings of the Seventh International Conference in Electronic Commerce Research, 2004.

57. M. G. Michael, "The Canonical Adventure of the Apocalypse of John: An Eastern Orthodox Perspective" in Faculty of Theology and Philosophy vol. Doctor of Philosophy, Brisbane, Queensland:, 2002.

58. G. Nikolettos, We the People Will Not Be Chipped, 2010, [online] Available: http://www.wethepeoplewillnotbechipped.comlmain/news.php.

59. D. Welch, "US raises full body scanners in fly-by visit over terrorism", Sydney Morning Herald, January 2010, [online] Available: http://www.smh.com.au/national/us-raises-full-body-scanners-in-flyby-visit-over-terrorism-20100110-mOu6.html.

60. A. Graafstra, "I'm in “Tagged” a New Canadian Documentary", Blog, September 2009, [online] Available: http://blog.amal.net/?p=1476.

61. A. Stoica, "Towards Recognition of Humans and their Behaviors from Space and Airborne Platforms: Extracting the Information in the Dynamics of Human Shadows", ECSIS Symposium on Bioinspired Learning and Intelligent Systems for Security, 2008.

62. K. Michael, A. Masters, "Realised Applications of Positioning Technologies in Defense Intelligence" in H. Abbass, D. Essam, Applications of Information Systems to Homeland Security and Defense, Hershey, USA:Idea Group Publishing Press, pp. 167-195, 2006.

63. K. Michael, A. Masters, "The Advancement of Positioning Technologies in Defense Intelligence" in H. Abbass, D. Essam Applications of Information Systems to Homeland Security and Defense, Hershey, USA:Idea Group Publishing, pp. 196-220, 2006.

64. D. McCullagh, "Feds push for tracking cell phones", cnet news, February 2010, [online] Available: http://news.cnet.com/8301-13578_3-10451518-38.html.

Keywords

Radiofrequency identification, Eyes, RFID tags, Transponders, Implants, Radio frequency, Animals,Supply chains, Mobile handsets, Health and safety, social sciences, radiofrequency identification, chip implant, sociotechnical issues, humancentric RFID implantee subculture, Amal Graafstra,radiofrequency identification tags

Citation: Amal Graafstra, Katina Michael, M.G. Michael, 2010, "Social-technical issues facing the humancentric RFID implantee sub-culture through the eyes of Amal Graafstra", International Symposium on Technology and Society, 7-10 June, 2010, pp. 498 - 516 , Wollongong, Australia.

The Social, Cultural, Religious and Ethical Implications of Automatic Identification

Katina Michael, School of Information Technology & Computer Science, University of Wollongong, NSW, Australia 2500, katina@uow.edu.au

M.G. Michael, American Academy of Religion, PO Box U184, University of Wollongong, NSW, Australia 2500, mgm@uow.edu.au

Full Citation: Katina Michael, M.G. Michael, 2004, The Social, Cultural, Religious and Ethical Implications of Automatic Identification, Seventh International Conference on Electronic Commerce Research (ICER-7), University of Texas, Dallas, Texas, USA, June 10-13. Sponsored by ATSMA, IFIP Working Group 7.3, INFORMS Information Society.

Abstract

The number of automatic identification (auto-ID) technologies being utilized in eBusiness applications is growing rapidly. With an increasing trend toward miniaturization and wireless capabilities, auto-ID technologies are becoming more and more pervasive. The pace at which new product innovations are being introduced far outweighs the ability for citizens to absorb what these changes actually mean, and what their likely impact will be upon future generations. This paper attempts to cover a broad spectrum of issues ranging from the social, cultural, religious and ethical implications of auto-ID with an emphasis on human transponder implants. Previous work is brought together and presented in a way that offers a holistic view of the current state of proceedings, granting an up-to-date bibliography on the topic. The concluding point of this paper is that the long-term side effects of new auto-ID technologies should be considered at the outset and not after it has enjoyed widespread diffusion.

1.  Introduction

Automatic identification is the process of identifying a living or nonliving object without direct human intervention. Before auto-ID only manual identification techniques existed, such as tattoos [[i]] and fingerprints, which did not allow for the automatic capture of data (see exhibit 1.1). Auto-ID becomes an e-business application enabler when authorization or verification is required before a transaction can take place. Many researchers credit the vision of a cashless society to the capabilities of auto-ID. Since the 1960s automatic identification has proliferated especially for mass-market applications such as electronic banking and citizen ID. Together with increases in computer processing power, storage equipment and networking capabilities, miniaturization and mobility have heightened the significance of auto-ID to e-business, especially mobile commerce. Citizens are now carrying multiple devices with multiple IDs, including ATM cards, credit cards, private and public health insurance cards, retail loyalty cards, school student cards, library cards, gym cards, licenses to drive automobiles, passports to travel by air and ship, voting cards etc. More sophisticated auto-ID devices like smart card and radio-frequency identification (RFID) tags and transponders that house unique lifetime identifiers (ULI) or biometric templates are increasingly being considered for business-to-consumer (B2C) and government-to-citizen (G2C) transactions. For example, the United States (US) is enforcing the use of biometrics on passports due to the increasing threats of terrorism, and Britain has openly announced plans to begin implanting illegal immigrants with RFID transponders. Internationally, countries are also taking measures to decrease the multi-million dollar costs of fraudulent claims made to social security by updating their citizen identification systems.

Exhibit 1.1     Manual versus Automatic Identification Techniques

Exhibit 1.1     Manual versus Automatic Identification Techniques

2.  Literature Review

The relative ease of performing electronic transactions by using auto-ID has raised a number of social, cultural, religious and ethical issues. Among others, civil libertarians, religious advocates and conspiracy theorists have long cast doubts on the technology and the ultimate use of the information gathered by it. Claims that auto-ID technology impinges on human rights, the right to privacy, and that eventually it will lead to totalitarian control of the populace have been put forward since the 1970s. This paper aims to explore these themes with a particular emphasis on emerging human transponder implant technology. At present, several US companies are marketing e-business services that allow for the tracking and monitoring of individuals using RFID implants in the subcutaneous layer of the skin or Global Positioning System (GPS) wristwatches worn by enrollees. To date previous literature has not consistently addressed philosophical issues related to chip implants for humans in the context of e-business. In fact, popular online news sources like CNN [[ii]] and the BBC [[iii]] are among the few mainline publishers discussing the topic seriously, albeit in a fragmented manner. The credible articles on implanting humans are mostly interviews conducted with proponents of the technology, such as Applied Digital Solutions (ADSX) [[iv]] representatives who are makers of the VeriChip system solution [[v]]; Professor Kevin Warwick of the University of Reading who is known for his Cyborg 1.0 and 2.0 projects [[vi]]; and implantees like the Jacobs family in the US who bear RF/ID transponder implants [[vii]]. Block passages from these interviews are quoted throughout this paper to bring some of the major issues to the fore using a holistic approach.

More recently academic papers on human transponder implants covering various perspectives have surfaced on the following topics: legal and privacy [[viii], [ix]], ethics and culture [[x]], technological problems and health concerns [[xi]], technological progress [[xii]], trajectories [[xiii], [xiv]]. While there is a considerable amount of other popular material available especially on the Internet related to human chip implants, much of it is subjective and not properly sourced. One major criticism of these reports is that the reader is left pondering as to the authenticity of the accounts provided with little evidence to support respective claims and conclusions. Authorship of this literature is another problem. Often these articles are contributed anonymously, and when they do cite an author’s name, the level of technical understanding portrayed by the individual is severely lacking to the detriment of what he/she is trying to convey, even if there is a case to be argued. Thus, the gap this paper seeks to fill is to provide a sober presentation of cross-disciplinary perspectives on topical auto-ID issues with an emphasis on human transponder implants, and second to document some of the more thought-provoking discussion which has already taken place on the topic, complemented by a complete introductory bibliography.

3.  Method

Articles on auto-ID in general have failed to address the major philosophical issues using a holistic approach. For instance, Woodward [[xv]] is one of the few authors to have mentioned anything overly substantial about religious issues, with respect to biometric technology in a recognized journal. Previously the focus has basically been on privacy concerns and Big Brother fears. While such themes are discussed in this paper as well, the goal is to cover a broader list of issues than the commonplace. This is the very reason why two researchers with two very different backgrounds, one in science and the other in humanities, have collaborated to write this paper. A qualitative strategy is employed in this investigation to explore the major themes identified in the literature review. It should be noted however that legal, regulatory, economic and related policy issues such as standards, have been omitted because the aim of this paper is not to inform a purely technical audience or an audience which is strictly concerned with policy. It is aimed rather at the potential end-user of auto-ID devices and at technology companies who are continually involved in the process of auto-ID innovation.

Original material is quoted extensively to ensure that the facts are presented “as is.” There is nothing lost in simplified translations and the full weight of argument is retained, raw and uncut. The authors therefore cannot be accused of bias or misrepresentation. The sheer breadth of literature used for this investigation ensures reliability and validity in the findings. The narrative reporting style helps to guide readers through the paper, allowing individuals to form their own opinions and interpretations of what is being presented. Evidence for the issues discussed has been gathered from a wide variety of sources including offline and online documentation. High level content analysis has been performed to aid in the grouping of categories of discussion including social, cultural, religious and ethical issues that form the skeleton of the main body of the article as a way to identify emerging trends and patterns. Subcategories are also useful in identifying the second tier themes covered, helping to reduce complexity in analysis. The subcategories also allow for links to be made between themes. A highly intricate thread runs through the whole paper telling the story of not just auto-ID but the impacts of the information technology and telecommunications (IT&T) revolution [[xvi]]. There is therefore a predictive element to the paper as well which is meant to confront the reader with some present and future scenarios. The ‘what if’ questions are important as it is hoped they will generate public debate on the major social, cultural, religious and ethical implications of RFID implants in humans.

4. Towards Ubiquitous Computing

Section 4 is wholly dedicated to providing a background in which to understand auto-ID innovation; it will also grant some perspective to the tremendous pace of change in IT&T; and note some of the more grounded predictions about the future of computing. The focus is on wearable and ubiquitous computing within which auto-ID will play a crucial role. This section will help the reader place the evidence presented in the main body of the article into an appropriate context. The reader will thus be able to interpret the findings more precisely once the basic setting has been established, allowing each individual to form their own opinions about the issues being presented.

From personal computers (PCs) to laptops to personal digital assistants (PDAs) and from landline phones to cellular phones to wireless wristwatches, miniaturization and mobility have acted to shift the way in which computing is perceived by humans. Lemonick [[xvii]] captures this pace of change well in the following excerpt:

[i]t took humanity more than 2 million years to invent wheels but only about 5,000 years more to drive those wheels with a steam engine. The first computers filled entire rooms, and it took 35 years to make the machines fit on a desk- but the leap from desktop to laptop took less than a decade… What will the next decade bring, as we move into a new millennium? That’s getting harder and harder to predict.

Once a stationary medium, computers are now portable, they go wherever humans go [[xviii]]. This can be described as technology becoming more human-centric, “where products are designed to work for us, and not us for them” [[xix]]. Thus, the paradigm shift is from desktop computing to wearable computing [[xx]]. Quite remarkably in the pursuit of miniaturization, little has been lost in terms of processing power. “The enormous progress in electronic miniaturization make it possible to fit many components and complex interconnection structures into an extremely small area using high-density printed circuit and multichip substrates” [[xxi]]. We now have so-named Matchbox PCs that are no larger than a box of matches with the ability to house fully functional operating systems [[xxii]]. “The development of wearable computer systems has been rapid. Salonen [[xxiii]], among others [[xxiv]] are of the belief that “quite soon we will see a wide range of unobtrusive wearable and ubiquitous computing equipment integrated into our everyday wear”. The next ten years will see wearable computing devices become an integral part of our daily lives, especially as the price for devices keeps falling. Whether noticeable or not by users, the change has already begun. Technology is increasingly becoming an extension of the human body, whether it is by carrying smart cards or electronic tags [[xxv]] or even PDAs and mobile phones. Furui [[xxvi]] predicts that “[p]eople will actually walk through their day-to-day lives wearing several computers at a time.” Cochrane described this phenomenon as technology being an omnipresent part of our lives. Not only will devices become small and compact but they will be embedded in our bodies, invisible to anyone else [[xxvii]]. For the time being however, we are witnessing the transition period in which auto-ID devices especially are being trialled upon those who either i) desperately require their use for medical purposes or ii) who cannot challenge their application, such as in the case of armed forces or prison inmates. Eventually, the new technology will be opened to the wider market in a voluntary nature but will most likely become a de facto compulsory standard (i.e. such as in the case of the mobile phone today), and inevitably mandatory as it is linked to some kind of requirement for survival. Upon reflection, this is the pattern that most successful high-tech innovations throughout history have followed.

Mark Weiser first conceived the term “ubiquitous computing” to espouse all those small information systems (IS) devices, including calculators, electronic calendars and communicators that users would carry with them every day [[xxviii]]. It is important to make the distinction between ubiquitous and wearable computing. They “have been posed as polar opposites even though they are often applied in very similar applications” [[xxix]]. Kaku [[xxx]] stated that ubiquitous computing, is the time “when computers are all connected to each other and the ratio of computers to people flips the other way, with as many as one hundred computers for every person.” This latter definition implies a ubiquitous environment that allows the user to seamlessly interface with computer systems around them. Environments of the future are predicted to be context-aware so that users are not disturbed in every context, save for when it is suitable [[xxxi]]. Kortuem [[xxxii]] stated that “[s]uch environments might be found at the home, at the office, at factory floors, or even vehicles.” There is some debate however of where to place sensors in these environments. For example, should they be located around the room or should they be located on the individual. Locating sensors around the room enforces certain conditions on an individual, while locating sensors on an individual means that that person is actually in control of their context. The latter case also requires less localized infrastructure and a greater degree of freedom. Rhodes et al. [29] argue that by “properly combining wearable computing and ubiquitous computing, a system can have the advantages of both.”

5.  Social Issues

5.1 Privacy Concerns and Big Brother Fears

Starner [[xxxiii]] makes the distinction between privacy and security concerns. “Security involves the protection of information from unauthorized users; privacy is the individual’s right to control the collection and use of personal information.” Mills [[xxxiv]] is of the opinion that some technology, like communications, is not non-neutral but totalitarian in nature and that it can make citizens passive. “These glamorous technologies extend and integrate cradle-to-grave surveillance, annihilating all concept of a right to personal privacy, and help consolidate the power of the national security state… every technology, being a form of power, has implicit values and politics…” Over the years terms like Big Brother [[xxxv], [xxxvi]] and function creep [[xxxvii]] have proliferated to correspond to the all-seeing eyes of government and to the misuse and abuse of data. In most western countries data matching programs were constructed, linked to a unique citizen ID, to cross-check details provided by citizens, claims made, and benefits distributed [[xxxviii], [xxxix]]. More recently however, the trend has tended towards information centralization between government agencies based around the auspices of a national ID to reduce fraud [[xl]] and to combat terrorism [[xli]]. Currently computers allow for the storage and searching of data gathered like never before [[xlii]]. The range of automated data collection devices continues to increase to include systems such as bar codes (with RF capabilities), magnetic-stripe card, smart card and a variety of biometric techniques, increasing the rapidity and ease at which information is gathered. RFID transponders especially have added a greater granularity of precision in in-building and campus-wide solutions, given the wireless edge, allowing information to be gathered within a closed environment, anywhere/ anytime, transparent to the individual carrying the RFID badge or tag.

Now, while auto-ID itself is supposed to ensure privacy, it is the ease with which data can be collected that has some advocates concerned about the ultimate use of personal information. While the devices are secure, breaches in privacy can happen at any level- especially at the database level where information is ultimately stored after it is collected [[xliii]]. How this information is used, how it is matched with other data, who has access to it, is what has caused many citizens to be cautious about auto-ID in general [[xliv]]. Data mining also has altered how data is filtered, sifted and utilized all in the name of customer relationship management (CRM). It is not difficult to obtain telemarketing lists, census information aggregated to a granular level, and mapping tools to represent market segments visually. Rothfeder [[xlv]] states:

[m]edical files, financial and personnel records, Social Security numbers, and telephone call histories- as well as information about our lifestyle preferences, where we shop, and even what car we drive- are available quickly and cheaply.

Looking forward, the potential for privacy issues linked to chip implants is something that has been considered but mostly granted attention by the media. Privacy advocates warn that such a chip would impact civil liberties in a disastrous way [[xlvi]]. Even Warwick, himself, is aware that chip implants do not promote an air of assurance:

Looking back, Warwick admits that the whole experiment [Cyborg 1.0] “smacked of Big Brother.” He insists, however, that it’s important to raise awareness of what’s already technically possible so that we can remain in the driver’s seat. “I have a sneaking suspicion,” he says, “that as long as we’re gaining things, we’ll yell ‘Let’s have Big Brother now!’ It’s when we’re locked in and the lights start going off- then Big Brother is a problem.” [[xlvii]]

In this instance, Warwick has made an important observation. So long as individuals are “gaining” they generally will voluntarily part with a little more information. It is when they stop gaining and blatantly start being taken advantage of that the idea of Big Brother is raised. On that point, chip implants promise the convenience of not having to carry a multitude of auto-ID devices, perhaps not even a wallet or purse.

According to McGinity [18] “[e]xperts say it [the chip] could carry all your personal information, medical background, insurance, banking information, passport information, address, phone number, social security number, birth certificate, marriage license.” This kind of data collection is considered by civil libertarians to be “crypto-fascism or high-tech slavery” [[xlviii]]. The potential for abuse cannot be overstated [[xlix]]. Salkowski agrees pointing to the ADSX VeriChip system, stating that police, parents and ADSX employees could abuse their power. “It might even be possible for estranged spouses, employers and anyone else with a grudge to get their hands on tracking data through a civil subpoena” [[l]]. Hackers too, could try their hand at collecting data without the knowledge of the individual, given that wireless transmission is susceptible to interception. At the same time, the chip implant may become a prerequisite to health insurance and other services. “You could have a scenario where insurance companies refuse to insure you unless you agree to have a chip implant to monitor the level of physical activity you do” says Pearson of British Telecom [[li]]. This should not be surprising given that insurance companies already ask individuals for a medical history of illnesses upon joining a new plan. Proponents say the chip would just contain this information more accurately [7]. Furthermore, “[c]ost-conscious insurance companies are sure to be impressed, because the portability of biomems [i.e., a type of medical chip implant] would allow even a seriously ill patient to be monitored after surgery or treatment on an outpatient basis” [[lii]]. Now a chip storing personal information is quite different to one used to monitor health 24x7x365 and then to relay diagnoses to relevant stakeholders. As Chris Hoofnagle, an attorney for the Electronic Privacy Information Centre in Washington, D.C., pointed out, “[y]ou always have to think about what the device will be used for tomorrow” [[liii]]. In its essential aspect, this is exactly the void this paper has tried to fill.

5.2 Mandatory Proof of Identification

In the US in 2001 several bills were passed in Congress to allow for the creation of three new Acts related to biometric identification of citizens and aliens, including the Patriot Act, Aviation and Transport Security Act, and the Enhanced Border Security and Visa Entry Reform Act. If terrorism attacks continue to increase in frequency, there is a growing prospect in the use of chip implants for identification purposes and GPS for tracking and monitoring. It is not an impossible scenario to consider that one day these devices may be incorporated into national identification schemes. During the SARS (severe acute respiratory syndrome) outbreak, Singapore [[liv]] and Taiwan [[lv]] considered going as far as tagging their whole population with RFID devices to monitor automatically the spread of the virus. Yet, independent of such random and sporadic events, governments worldwide are already moving toward the introduction of a single unique ID to cater for a diversity of citizen applications. Opinions on the possibility of widespread chip implants in humans range from “it would be a good idea,” to “it would be a good idea, but only for commercial applications not government applications,” to “this should never be allowed to happen”. Leslie Jacobs, who was one of the first to receive a VeriChip told Scheeres [[lvi]], “[t]he world would be a safer place if authorities had a tamper-proof way of identifying people… I have nothing to hide, so I wouldn’t mind having the chip for verification… I already have an ID card, so why not have a chip?” It should be noted that some tracking and monitoring systems can be turned off and on by the wearer, making monitoring theoretically voluntary [[lvii]]. Sullivan a spokesperson for ADSX, said: “[i]t will not intrude on personal privacy except in applications applied to the tracking of criminals” [49]. ADSX have claimed on a number of occasions that it has received more than two thousand emails from teenagers volunteering to be the next to be “chipped” [[lviii]]. There are others like McClimans [[lix]] that believe that everyone should get chipped. Cunha Lima, a Brazilian politician who also has a chip implant is not ignorant of the potential for invasion of privacy but believes the benefits outweigh the costs and that so long as the new technology is voluntary and not mandatory there is nothing to worry about. He has said, “[i]f one chooses to ‘be chipped,’ then one has considered the consequences of that action” [[lx]]. Lima argues that he feels more secure with an implant given the number of kidnappings in South America of high profile people each year- at least this way his location is always known.

Professor Brad Meyers of the Computer Science Department at Carnegie Mellon University believes that the chip implant technology has a place but should not be used by governments. Yet the overriding sentiment is that chip implants will be used by government before too long. Salkowski [50] has said, “[i]f you doubt there are governments that would force at least some of their citizens to carry tracking implants, you need to start reading the news a little more often.” Black [53] echoes these sentiments: “Strictly voluntary? So far so good. But now imagine that same chip being used by a totalitarian government to keep track of or round up political activists or others who are considered enemies of the state. In the wrong hands, the VeriChip could empower the wrong people.” In a report written by Ramesh [[lxi]] for the Franklin Pierce Law Centre the prediction is made that: 

[a] national identification system via microchip implants could be achieved in two stages: Upon introduction as a voluntary system, the microchip implantation will appear to be palatable. After there is a familiarity with the procedure and a knowledge of its benefits, implantation would be mandatory.

Bob Gellman, a Washington privacy consultant, likens this to “a sort of modern version of tattooing people, something that for obvious reasons- the Nazis tattooed numbers of people- no one proposes” [49, [lxii], [lxiii]]. The real issue at hand as Gellman sees it is “who will be able to demand that a chip be implanted in another person.” Mieszkowski supports Gray by observing how quickly a new technological “option” can become a requirement. Resistance after the voluntary adoption stage can be rather futile if momentum is leading the device towards a mandatory role.

McMurchie [[lxiv]] reveals the subtle progression toward embedded devices:

[a]s we look at wearable computers, it’s not a big jump to say, ‘OK, you have a wearable, why not just embed the device?’… And no one can rule out the possibility that employees might one day be asked to sport embedded chips for ultimate access control and security…

Professor Chris Hables Gray uses the example of prospective military chip implant applications. How can a marine, for instance, resist implantation? Timothy McVeigh, convicted Oklahoma bomber, claimed that during the Gulf War, he was implanted with a microchip against his will. The claims have been denied by the U.S. military [[lxv]], however the British Army is supposedly considering projects such as APRIL (Army Personnel Rationalization Individual Listings) [51]. Some cyberpunks have attempted to counteract the possibility of enforced implantation. One punk known by the name of “Z.L” is an avid reader of MIT specialist publications like open|DOOR MIT magazine on bioengineering and beyond. Z.L.’s research has indicated that:

[i]t is only a matter of time… before technology is integrated within the body. Anticipating the revolution, he has already taught himself how to do surgical implants and other operations. “The state uses technology to strengthen its control over us,” he says. “By opposing this control, I remain a punk. When the first electronic tags are implanted in the bodies of criminals, maybe in the next five years, I’ll know how to remove them, deactivate them and spread viruses to roll over Big Brother” [25].

5.3 Health Risks

Public concern about electromagnetic fields from cellular phones was a contentious issue in the late 1990s. Now it seems that the majority of people in More Developing Countries (MDCs) have become so dependent on mobile phones that they are disregarding the potential health risks associated with the technology [[lxvi]]. Though very little has been proven concretely, most terminal manufacturers do include a warning with their packaging, encouraging users not to touch the antenna of the phone during transmission [[lxvii]]. Covacio [11] is among the few authors to discuss the potential technological problems associated with microchips for human ID from a health perspective. In his paper he provides evidence why implants may impact humans adversely, categorizing these into thermal (i.e. whole/partial rise in body heating), stimulation (i.e. excitation of nerves and muscles) and other effects most of which are currently unknown. He states that research into RFID and mobile telephone technology [11]:

...has revealed a growing concern with the effects of radio frequency and non-ionizing radiation on organic matter. It has been revealed a number of low-level, and possible high-level risks are associated with the use of radio-frequency technology. Effects of X-rays and gamma rays have been well documented in medical and electronic journals…

In considering future wearable devices, Salonen [[lxviii]] puts forward the idea of directing antenna away from the head where “there may be either a thermal insult produced by power deposition in tissue (acute effects) or other (long-term) effects” to midway between the shoulder and elbow where radiation can be pushed outward from the body. Yet chip implants may also pose problems, particularly if they are active implants that contain batteries and are prone to leakage if transponders are accidentally broken. Geers et al. [[lxix]] write the following regarding animal implants.

Another important aspect is the potential toxic effect of the battery when using active transponders. Although it should be clear that pieces of glass or copper from passive tags are not allowed to enter the food chain. When using electronic monitoring with the current available technology, a battery is necessary to guarantee correct functioning of sensors when the transponder is outside the antenna field. If the transponder should break in the animal’s body, battery fluid may escape, and the question of toxological effects has to be answered.

In fact, we need only consider the very real problems that women with failed silicon breast implants have had to suffer. Will individuals with chip implants, twenty years down the track, be tied up in similar court battles and with severe medical problems? Surgical implantation, it must also be stated, causes some degree of stress in an animal and it takes between four to seven days for the animal to return to equilibrium [69]. Most certainly some discomfort must be felt by humans as well. In the Cyborg 1.0 project, Warwick was advised to leave the implant under his skin for only ten days. According to Trull [[lxx]], Warwick was taking antibiotics to fight the possibility of infection. Warwick also reportedly told his son while playing squash during Cyborg 1.0: “Whatever you do, don’t hit my arm. The implant could just shatter, and you’ll have ruined your father’s arm for life” [[lxxi]]. It is also worthwhile noting Warwick’s appearance after the Cyborg 2.0 experiment. He looked pale and weary in press release photographs, like someone who had undergone a major operation. Covacio [11] believes ultimately that widespread implantation of microchips in humans will lead to detrimental effects to them and the environment at large. Satellite technology (i.e. the use of GPS to locate individuals), microwave RF and related technological gadgetry will ultimately “increase health problems and consequentially increase pressure on health services already under economic duress.”

6. Cultural Issues

6.1 The Net Generation

When the ENIAC was first made known to the public in February of 1946 reporters used “anthropomorphic” and “awesome characterizations” to describe the computer. The news was received with skepticism by citizens who feared the unknown. In an article titled “The Myth of the Awesome Thinking Machine”, Martin [[lxxii]] stated that the ENIAC was referred to in headlines as “a child, a Frankenstein, a whiz kid, a predictor and controller of weather, and a wizard”. Photographs of the ENIAC used in publications usually depicted the computer to completely fill a small room, from wall-to-wall and floor-to-ceiling. People are usually shown interacting with the machine, feeding it with instructions, waiting for results and monitoring its behavior. One could almost imagine that the persons in the photographs are ‘inside the body’ of the ENIAC [[lxxiii]]. Sweeping changes have taken place since that time, particularly since the mid 1980s. Consumers now own personal computers (PCs) in their homes- these are increasingly being networked- they carry laptop computers and mobile phones and chip cards, and closely interact with public automated kiosks. Relatively speaking, it has not taken long for people to adapt to the changes that this new technology has heralded. Today we speak of a Net Generation (N-Geners) who never knew a world without computers or the Internet [[lxxiv]]; for them the digital world is as ubiquitous as the air that they breathe. What is important to N-Geners is not how they got to where they are today but what digital prospects the future holds.

“[O]ur increasing cultural acceptance of high-tech gadgetry has led to a new way of thinking: robotic implants could be so advantageous that people might actually want to become cybernetic organisms, by choice. The popularization of the cyberpunk genre has demonstrated that it can be hip to have a chip in your head” [70].

6.2 Science Fiction Genre

The predictions of science fiction writers have often been promoted through the use of print, sound and visual mediums. Below is a list of sci-fi novels, films and television series that undoubtedly have influenced and are still influencing the trajectory of auto-ID. Chris Hables Gray tells his students “…that a lot of the best cyborgology has been done in the mass media and in fiction by science fiction writers, and science fiction movie producers, because they’re thinking through these things” [[lxxv]]. The popular 1970s series of Six Million Dollar Man, for instance, began as follows: “We can rebuild him. We have the technology. We have the capability to make the world’s first Bionic man.” Today bionic limbs are a reality and no longer science fiction [[lxxvi]]. More recently AT&T’s Wireless mMode magazine alluded to Start Trek [[lxxvii]]:

They also talked about their expectations- one media executive summed it up best, saying, “Remember that little box that Mr. Spock had on Star Trek? The one that did everything? That’s what I’d like my phone to be…”

Beyond auto-ID we find a continuing legacy in sci-fi genre toward the electrification of humans- from Frankenstein to Davros in Dr Who, and from Total Recall to Johnny Mnemonic (see exhibit 1.2). While all this is indeed ‘merely’ sci-fi, it is giving some form to the word, allowing the imagination to be captured in powerful images, sounds and models. What next? A vision of a mechanized misery [[lxxviii]] as portrayed in Fritz Lang’s 1927 cult film classic Metropolis? Only this time instead of being at the mercy of the Machine, we have gone one step further and invited the Machine to reside inside the body, and marked it as a ‘technological breakthrough’ as well. As several commentators have noted, “[w]e live in an era that… itself often seems like science fiction, and Metropolis has contributed powerfully to that seeming” [[lxxix]].

Exhibit 1.2     Sci-Fi Film Genre Pointing to the Electrification of Humans

Exhibit 1.2     Sci-Fi Film Genre Pointing to the Electrification of Humans

Some of the more notable predictions and social critiques are contained within the following novels: Frankenstein (Shelley 1818), Paris in the 20th Century (Verne 1863), Looking Backward (Bellamy 1888), The Time Machine (Wells 1895), R.U.R. (Kapek 1917), Brave New World (Huxley 1932), 1984 (Orwell 1949), I, Robot (Asimov 1950), Foundation (Asimov 1951-53, 1982), 2001: A Space Odyssey (Clarke 1968), Blade Runner (Dick 1968), Neuromancer (Gibson 1984), The Marked Man (Ingrid 1989), The Silicon Man (Platt 1991), Silicon Karma (Easton 1997). The effects of film have been even more substantial on the individual as they have put some form to the predictions. These include: Metropolis (Fritz Lang 1927), Forbidden Planet (Fred Wilcox 1956), Fail Safe (Sidney Lumet 1964), THX-1138 (George Lucas 1971), 2001: A Space Odyssey (Stanley Kubrick 1968), The Terminal Man (George Lucas 1974), Zardoz (John Boorman 1974), Star Wars (George Lucas 1977), Moonraker (Lewis Gilbert II 1979), Star Trek (Robert Wise 1979), For Your Eyes Only (John Glen II 1981), Blade Runner (Ridley Scott 1982), War Games (John Badham 1983), 2010: The Year We Make Contact (Peter Hyams 1984), RoboCop (Paul Verhoeven, 1987), Total Recall (Paul Verhoeven 1990), The Terminator Series, Sneakers (Phil Alden Robinson 1992), Patriot Games (Phillip Noyce 1992), The Lawnmower Man (Brett Leonard 1992), Demolition Man (Marco Brambilla 1993), Jurassic Park (Steven Speilberg 1993), Hackers (Iain Softley 1995), Johnny Mnemonic (Robert Longo 1995), The NET (Irwin Winkler 1995) [[lxxx]], Gattaca (Andrew Niccol 1997) Enemy of the State (Tony Scott 1998), Fortress 2 (Geoff Murphy 1999), The Matrix (L. Wachowski & A. Wachowski 1999), Mission Impossible 2 (John Woo 2000), The 6th Day (Roger Spottiswoode 2000). Other notable television series include: Dr Who, Lost in Space, Dick Tracy, The Jetsons, Star Trek, Batman, Get Smart, Six Million Dollar Man, Andromeda, Babylon 5, Gasaraki, Stargate SG-1, Neon Genesis Evangelion, FarScape, and X-Files.  

6.3 Shifting Cultural Values

Auto-ID and more generally computer and network systems have influenced changes in language, art [[lxxxi]], music and film. An article by Branwyn [[lxxxii]] summarizes these changes well.

Language [[lxxxiii]]: “Computer network and hacker slang is filled with references to “being wired” or “jacking in” (to a computer network), “wetware” (the brain), and “meat” the body”.
Music: “Recent albums by digital artists Brian Eno, Clock DVA, and Frontline Assembly sport names like Nerve Net, Man Amplified and Tactical Neural Implant.” See also the 1978 album by Kraftwerk titled “The Man Machine”.
Film: “Science fiction films, from Robocop to the recent Japanese cult film Tetsuo: The Iron Man, imprint our imaginations with images of the new.”

Apart from the plethora of new terms that have been born from the widespread use of IT&T and more specifically from extropians (much of which have religious connotations or allusions [[lxxxiv]]), it is art, especially body art that is being heavily influenced by chip implant technology. Mieszkowski [49] believes that “chipification” will be the next big wave in place of tattoos, piercing and scarification (see exhibit 1.3). In the U.S. it was estimated in 2001 that about two hundred Americans had permanently changed their bodies at around nine hundred dollars per implant, following a method developed by Steve Hayworth and Jon Cobb [25].

Exhibit 1.3     The New Fashion: Bar Code Tattoos, Piercing & Chips

Exhibit 1.3     The New Fashion: Bar Code Tattoos, Piercing & Chips

Canadian artist Nancy Nisbet has implanted microchips in her hands to better understand how implant technology may affect the human identity. The artist told Scheeres [[lxxxv]], “I am expecting the merger between human and machines to proceed whether we want it to or not…” As far back as 1997, Eduardo Kac “inserted a chip into his ankle during a live performance in Sao Paulo, then registered himself in an online pet database as both owner and animal” [86]. Perhaps the actual implant ceremony was not Kac’s main contribution but the subsequent registration onto a pet database. Other artists like Natasha Vita More and Stelarc have ventured beyond localized chip implants. Their vision is of a complete prosthetic body that will comprise of nanotechnology, artificial intelligence, robotics, cloning, and even nanobots [75]. More calls her future body design Primo 3M Plus. Stelarc’s live performances however, have been heralded as the closest thing there is to imagining a world where the human body will become obsolete [[lxxxvi]].

A Stelarc performance… usually involves a disturbing mix of amplified sounds of human organs and techno beats, an internal camera projecting images of his innards, perhaps a set of robotic legs or an extra arm, or maybe tubes and wires connecting the performer’s body to the internet with people in another country manipulating the sensors, jerking him into a spastic dance. It’s a dark vision, but it definitely makes you think [75].

Warwick [[lxxxvii]] believes that the new technologies “will dramatically change [art], but not destroy it.”

6.4 Medical Marvels or Human Evolution

As Sacleman wrote in 1967 “...the impact of automation on the individual involve[d] a reconstruction of his values, his outlook and his way of life” [[lxxxviii]]. Marshall McLuhan [[lxxxix], [xc]] was one of the first explorers to probe how the psycho-social complex was influenced by electricity. “Electricity continually transforms everything, especially the way people think, and confirms the power of uncertainty in the quest for absolute knowledge.” [[xci]]. Numerous examples can be given to illustrate these major cultural changes- from the use of electricity for household warmth, to wide area networks (WAN) enabling voice and data communications across long distances, to magnetic-stripe cards used for credit transactions [[xcii], [xciii], [xciv], [xcv]]. But what of the direct unification of humans and technology, i.e., the fusion between flesh and electronic circuitry [[xcvi], [xcvii], [xcviii]]? Consider for a moment the impact that chip implants have had on the estimated 23,000 cochlear recipients in the US. A medical marvel perhaps but it too, not without controversy. There are potentially 500,000 hearing impaired persons that could benefit from cochlear implants [[xcix]] but not every deaf person wants one.

Some deaf activists… are critical of parents who subject children to such surgery [cochlear implants] because, as one charged, the prosthesis imparts “the nonhealthy self-concept of having had something wrong with one’s body” rather than the “healthy self-concept of [being] a proud Deaf” [[c]].

Assistant Professor Scott Bally of Audiology at Gallaudet University has said: “Many deaf people feel as though deafness is not a handicap. They are culturally deaf individuals who have successfully adapted themselves to being deaf and feel as though things like cochlear implants would take them out of their deaf culture, a culture which provides a significant degree of support” [82].

Putting this delicate debate aside it is here that some delineation can be made between implants that are used to treat an ailment or disability (i.e. giving sight to the blind and hearing to the deaf), and implants that may be used for enhancing human function (i.e. memory). Some citizens are concerned about the direction of the human species as future predictions of fully functional neural implants are being made by credible scientists. “[Q]uestions are raised as to how society as a whole will relate to people walking around with plugs and wires sprouting out of their heads. And who will decide which segments of the society become the wire-heads” [82]? Those who can afford the procedures perhaps? And what of the possibility of brain viruses that could be fatal and technological obsolescence that may require people to undergo frequent operations? Maybury [[ci]] believes that humans are already beginning to suffer from a type of “mental atrophy” worse than that that occurred during the industrial revolution and that the only way to fight it is to hang on to those essential skills that are required for human survival. The question remains whether indeed it is society that shapes technology [[cii]] or technology that shapes society [[ciii]]. Inevitably it is a dynamic process of push and pull that causes cultural transformations over time.

7 Religious Issues

7.1 The Mark of the Beast

Ever since the bar code symbology UPC (Universal Product Code) became widespread some Christian groups have linked auto-ID to the “mark” in the Book of Revelation (13:18): “the number of the beast… is 666” [[civ], [cv], [cvi]]. Coincidentally, the left (101), centre (01010) and right (101) border codes of the UPC bars are encoded 6, 6, 6 (see exhibit 1.4). As it is now an established standard for every non-perishable item to be bar coded there was a close association with the prophecy: “so that no one could buy or sell unless he had the mark” (Rev 13:17). In full, verses 16-18 of chapter 13 of Revelation read as follows:

He also forced everyone, small and great, rich and poor, free and slave, to receive a mark on his right hand or on his forehead, so that no one could buy or sell unless he had the mark, which is the name of the beast or the number of his name. This calls for wisdom. If anyone has insight, let him calculate the number of the beast, for it is man’s number. His number is 666. [[cvii]]

According to some Christians, this reference would appear to be alluding to a mark on or in the human body, the prediction being made that the UPC would eventually end up on or under human skin [[cviii]]. As the selection environment of auto-ID devices grew, the interpretation of the prophecy further developed as to the actual guise of the mark. It was no longer interpreted to be ‘just’ the bar code (see exhibit 1.4). Some of the more prominent religious web sites that discuss auto-ID and the number of the beast include: http://www.666soon.com (2003), http://www.greaterthings.com (2003), http://www.countdown.com.org (2003), http://www.raidersnewsupdate.com (2003), http://www.light1998.com (2003) and http://www.av1611.org (1996). At first the sites focused on bar code technology, now they have grown to encompass a plethora of auto-ID technologies, especially biometrics and looming chip implants. For a thorough analysis of the background, sources and interpretation of the “number of the beast” see M.G. Michael’s thesis [[cix]].

Card technology such as magnetic-stripe and smart cards became the next focus as devices that would gradually pave the way for a permanent ID for all citizens globally: “He also forced everyone, small and great, rich and poor, free and slave, to receive a mark…” (Rev 13:16). Biometrics was then introduced and immediately the association was made that the “mark” [charagma] would appear on the “right hand” (i.e. palmprint or fingerprint) or on the “forehead” (facial/ iris recognition) as was supposedly prophesied (Rev. 13:16). For the uses of charagma in early Christian literature see Arndt and Gingrich [[cx]]. Short of calling this group of people fundamentalists, as Woodward [15] refers to one prominent leader, Davies is more circumspect [[cxi]]:

“I think they’re legitimate [claims]. People have always rejected certain information practices for a variety of reasons: personal, cultural, ethical, religious and legal. And I think it has to be said that if a person feels bad for whatever reason, about the use of a body part then that’s entirely legitimate and has to be respected”.

Finally RF/ID transponders made their way into pets and livestock for identification, and that is when some Christian groups announced that the ‘authentic’ mark was now possible, and that it was only a matter of time before it would find its way into citizen applications [[cxii]]. Terry Cook [[cxiii]], for instance, an outspoken religious commentator and popular author, “worries the identification chip could be the ‘mark of the beast’, an identifying mark that all people will be forced to wear just before the end times, according to the Bible” [[cxiv]]. The description of an implant procedure for sows that Geers et al. [69] gives, especially the section about an incision being made on the skin, is what some religious advocates fear may happen to humans as well in the future.

When the thermistor was implanted the sows were restrained with a lasso. The implantation site was locally anaesthetized with a procaine (2%) injection, shaved and disinfected. After making a small incision in the skin, the thermistor was implanted subcutaneously, and the incision was closed by sewing. The position of the thermistor (accuracy 0.1C) was wire-connected to a data acquisition system linked to a personal computer.

“Religious advocates say it [i.e. transponder implants] represents ‘the mark of the Beast’, or the anti-Christ” [[cxv]]. Christians who take this mark, for whatever reason, are said to be denouncing the seal of baptism, and accepting the Antichrist in place of Christ [[cxvi], [cxvii], [cxviii]]. Horn [[cxix]] explains:

[m]any Christians believe that, before long, an antichrist system will appear. It will be a New World Order, under which national boundaries dissolve, and ethnic groups, ideologies, religions, and economics from around the world, orchestrate a single and dominant sovereignty… According to popular Biblical interpretation, a single personality will surface at the head of the utopian administration… With imperious decree the Antichrist will facilitate a one-world government, universal religion, and globally monitored socialism. Those who refuse his New World Order will inevitably be imprisoned or destroyed.

References discussing the New World Order include Barnet and Cavanagh [[cxx]], Wilshire [[cxxi]], and Smith [[cxxii]].

Exhibit 1.4     The Mark of the Beast as Shown on GreaterThings.com

Exhibit 1.4     The Mark of the Beast as Shown on GreaterThings.com

Companies that specialize in the manufacture of chip implant solutions, whether for animals or for humans, have been targeted by some religious advocates. The bad publicity has not been welcomed by these companies- some have even notably “toned down” the graphic visuals on their web sites so that they do not attract the wrong ‘type’ of web surfers. While they are trying to promote an image of safety and security, some advocates have associated company brands and products with apocalyptic labels. Some of the company and product names include: Biomark, BioWare, BRANDERS, MARC, Soul Catcher, Digital Angel and Therion Corporation. Perhaps the interesting thing to note is that religious advocates and civil libertarians agree that ultimately the chip implant technology will be used by governments to control citizens. ADSX is one of the companies that have publicly stated that they do not want adverse publicity after pouring hundreds of thousands of dollars into research and development and the multi-million dollar purchase of the Destron Fearing company. So concerned were they that they even appeared on the Christian talk show The 700 Club, emphasizing that the device would create a lot of benefits and was not meant to fulfill prophecy [60]. A spokesperson for ADSX said: “[w]e don’t want the adverse publicity. There are a number of privacy concerns and religious implications- fundamentalist Christian groups regard [i.e., implanting computer chips] as the Devil’s work” [51].  According to Gary Wohlscheid, the president of The Last Day Ministries, the VeriChip could well be the mark.  Wohlscheid believes that out of all the auto-ID technologies with the potential to be the mark, the VeriChip is the closest. About the VeriChip he says however, “[i]t’s definitely not the final product, but it’s a step toward it. Within three to four years, people will be required to use it. Those that reject it will be put to death” [56]. These are, of course, the positions of those who have entered the debate from the so-called fundamentalist literalist perspective and represent the more vocal and visible spectrum of contemporary “apocalyptic” Christianity. In this context the idea of fundamentalism seems to be a common label today, for anyone within the Christian community who questions the trajectory of technological advancement.

With respect to the potential of brain chips in the perceived quest for “immortality” [13, 14], many Christians across the denominational confession see this as an attempt to usurp the Eternal Life promised by God, in Jesus Christ, through the Holy Spirit. This is similar to the case of human cloning, where specialist geneticists are accused of trying to play God by usurping the Creator’s role. However, the area is notoriously grey here; when for instance, do implants for medical breakthroughs become acceptable versus those required for purposes of clear identification? In the future the technology in question could end up merging the two functions onto the single device. This is a real and very possible outcome, when all factors, both market and ethical, are taken on board by the relevant stakeholders. Ultimately, for most members of a believing religious community, this subject revolves around the most important question of individual freedom and the right to choose [[cxxiii], [cxxiv]].

8. Ethical Issues

In an attempt to make our world a safer place we have inadvertently infringed on our privacy and our freedom through the use of surveillance cameras and all other ancillary. We equip our children with mobile phones, attach tracking devices to them or make them carry them [[cxxv]] in their bags and soon we might even be implanting them with microchips [[cxxvi]]. This all comes at a price- yet it seems more and more people are willing to pay this price as heinous crimes become common events in a society that should know better. Take the example of 11-year old Danielle Duval who is about to have an active chip (i.e. containing a rechargeable battery) implanted in her. Her mother believes that it is no different to tracking a stolen car, simply that it is being used for another more important application. Mrs Duvall is considering implanting her younger daughter age 7 as well but will wait until the child is a bit older: “so that she fully understands what’s happening” [[cxxvii]]. One could be excused for asking whether Danielle at the age of 11 actually can fully comprehend the implications of the procedure she is about to undergo. It seems that the age of consent would be a more appropriate age.

Warwick has said that an urgent debate is required on this matter (i.e. whether every child should be implanted by law), and whether or not signals from the chips should be emitted on a 24x7 basis or just triggered during emergencies. Warwick holds the position that “we cannot prejudge ethics” [87]. He believes that ethics can only be debated and conclusions reached only after people become aware of the technical possibilities when they have been demonstrated. He admits that ethics may differ between countries and cultures [[cxxviii]]. The main ethical problem related to chip implants seems to be that they are under the skin [70] and cannot just be removed by the user at their convenience. In fact there is nothing to stop anyone from getting multiple implants all over their body rendering some applications useless. Tien of the Electronic Frontier Foundation (EFF) is convinced that if a technology is there to be abused, whether it is chip implants or national ID cards, then it will because that is just human nature [[cxxix]]. Similarly, Kidscape, a charity that is aimed at reducing the incidence of sexual abuse in children believe that implants will not act to curb crime. Kidscape hold the position that rather than giving children a false sense of security because they are implanted with a tracking device that could be tampered with by an offender, they should be educated on the possible dangers. Implanted tracking devices may sound entirely full-proof but deployment of emergency personnel, whether police or ambulance, cannot just magically appear at the scene of a crime in time to stop an offender from committing violence against a hostage.

8.1 The Prospect of International ID Implants

There are numerous arguments for why implanting a chip in a person is outright unconstitutional. But perhaps the under-explored area as Gellman puts it are the legal and social issues of who would have power over the chip and the information gathered by its means [49]. Gellman is correct in his summation of the problem but science has a proven way of going into uncharted territory first, then asking the questions about implications later. ADSX, for instance, have already launched the VeriChip solution. Sullivan, a spokesperson for the company told Salkowski [50]:

“I’m certainly not a believer in the abuse of power,” he offered, suggesting that Congress could always ban export of his company’s device. Of course, he admits he wouldn’t exactly lobby for that law. “I’m a businessman,” he said.

Black [53] makes the observation that the US government might well indeed place constraints on international sales of the VeriChip if it felt it could be used against them by an enemy. Consider the governance issues surrounding GPS technology that has been in operation a lot longer than human RFID implants.

“Good, neutral, or perhaps undesirable outcomes are now possible… Tension arises between some of the civil/commercial applications and the desire to preclude an adversary’s use of GPS. It is extremely difficult (technically, institutionally, politically, and economically) to combine the nonmilitary benefits of the system that require universality of access, ease of use, and low cost with military requirements for denial of the system to adversaries. Practical considerations require civil/commercial applications to have relatively easy access” [[cxxx]].

From a different angle, Rummler [[cxxxi]] points out that the monitoring and tracking of individuals raises serious legal implications regarding the individual’s capacity to maintain their right to freedom. He wrote: “[o]nce implanted with bio-implant electronic devices, humans might become highly dependent on the creators of these devices for their repair, recharge, and maintenance. It could be possible to modify the person technologically… thus placing them under the absolute control of the designers of the technology.” The Food and Drug Administration’s (FDA) Dr. David Feigal has been vocal about the need for such devices as the VeriChip not to take medical applications lightly and that companies wishing to specialize in health-related implants need to be in close consultation with the FDA [[cxxxii], [cxxxiii]]. There is also the possibility that such developments, i.e. regulating chip implants, may ultimately be used against an individual. The Freedom of Information Act for instance, already allows U.S. authorities to access automatic vehicle toll-passes to provide evidence in court [2]; there is nothing to suggest this will not happen with RFID transponder implants as well, despite the myriad of promises made by ADSX.  Professor Gray is adamant that there is no stopping technological evolution no matter how sinister some technologies may appear, and that we need to become accustomed to the fact that new technologies will continually infringe upon the constitution [49].

8.2 Beyond Chip Implants

Luggables, like mobile phones, do create a sense of attachment between the user and the device but the devices are still physically separate; they can accidentally be left behind. Wearable computers on the other hand are a part of the user, they are worn, and they “create an intimate human-computer-symbiosis in which respective strengths combine” [[cxxxiv]]. Mann calls this human-computer-symbiosis, “human interaction” (HI) as opposed to HCI (human-computer interaction).

[W]e prefer not to think of the wearer and the computer with its associated I/O apparatus as separate entities. Instead, we regard the computer as a second brain and its sensory modalities as additional senses, which synthetic synesthesia merges with the wearer’s senses. [[cxxxv]]
Exhibit 1.5     The Process of Transformation

Exhibit 1.5     The Process of Transformation

Human-computer electrification is set to make this bond irrevocable (see exhibit 1.5). Once on that path there is no turning back. If at the present all this seems impossible, a myth, unlikely, a prediction far gone, due to end-user resistance and other similar obstacles facing the industry today, history should teach us otherwise. This year alone, millions of babies will be born into a world where there are companies on the New York Stock Exchange specializing in chip implant devices for humans. “They” will grow up believing that these technologies are not only “normal” but also quite useful, just   like   other   high-tech technologies before them such as the Internet, PCs, smart cards etc. Consider the case of Cynthia Tam, aged two, who is an avid computer user:

“[i]t took a couple of days for her to understand the connection between the mouse in her hand and the cursor on the screen and then she was off… The biggest problem for Cynthia’s parents is how to get her to stop… for Cynthia, the computer is already a part of her environment… Cynthia’s generation will not think twice about buying things on the Internet, just like most people today don’t think twice when paying credit card, or using cash points for withdrawals and deposits” [[cxxxvi]].

But you do not have to be a newborn baby to adapt to technological change. Even grandmothers and grandfathers surf the web these days and send emails as a cheaper alternative to post or telephone [74]. And migrants struggling with a foreign language will even memorize key combinations to withdraw money even if they do not actually fully perceive the actions they are commanding throughout the process. Schiele [[cxxxvii]] believes that our personal habits are shaped by technological change and that over time new technologies that seem only appropriate for technophiles eventually find themselves being used by the average person. “[O]ver time our culture will adjust to incorporate the devices.” Gotterbarn is in agreement [10].

We enthusiastically adopt the latest gadget for one use, but then we start to realize that it gives us power for another use. Then there is the inevitable realization that we have overlooked the way it impacts other people, giving rise to professional and ethical issues.

What is apparent regardless of how far electrophoresis is taken is that the once irreconcilable gap between human and machine is closing (see exhibit 1.6).

Beyond chip implants for tracking there are the possibilities associated with neural prosthetics and the potential to directly link computers to humans [[cxxxviii]]. Warwick is also well aware that one of the major obstacles of cyber-humans are the associated moral issues [[cxxxix], [cxl]]- who gives anyone the right to be conducting complex procedures on a perfectly healthy person, and who will take responsibility for any complications that present themselves? Rummler [131] asks whether it is ethical to be linking computers to humans in the first place and whether or not limitations should be placed on what procedures can be conducted even if they are possible. For instance, could this be considered a violation of human rights? And more to the point what will it mean in the future to call oneself “human”. McGrath [[cxli]] asks “how human”?

As technology fills you up with synthetic parts, at what point do you cease to be fully human? One quarter? One third?... At bottom lies one critical issue for a technological age: are some kinds of knowledge so terrible they simply should not be pursued? If there can be such a thing as a philosophical crisis, this will be it. These questions, says Rushworth Kidder, president of the Institute for Global Ethics in Camden, Maine, are especially vexing because they lie at “the convergence of three domains- technology, politics and ethics- that are so far hardly on speaking terms.

At the point of becoming an electrophorus (i.e. a bearer of electricity), “[y]ou are not just a human linked with technology; you are something different and your values and judgment will change” [[cxlii]]. Some suspect that it will even become possible to alter behavior in people with brain implants [51], whether they will it or not. Maybury [101] believes that “[t]he advent of machine intelligence raises social and ethical issues that may ultimately challenge human existence on earth.”

 

Exhibit 1.6     Marketing Campaigns that Point to the Electrophorus

Exhibit 1.6     Marketing Campaigns that Point to the Electrophorus

Gotterbarn [10] argues precisely that our view of computer technologies generally progresses through several stages:

1) naïve innocence and technological wonder, 2) power and control, and 3) finally, sometimes because of disasters during the second stage, an understanding of the essential relationship between technologies and values.

Bill Joy, the chief technologist of Sun Microsystems, feels a sense of unease about such predictions made by Ray Kurzweil in The Age of Spiritual Machines [138]. Not only because Kurzweil has proven technically competent in the past but because of his ultimate vision for humanity- “a near immortality by becoming one with robotic technology” [[cxliii]]. Joy was severely criticized for being narrow-sighted, even a fundamentalist of sorts, after publishing his paper in Wired, but all he did was dare to ask the questions- ‘do we know what we are doing? Has anyone really carefully thought about this?’ Joy believes [143]:

[w]e are being propelled into this new century with no plan, no control, no brakes. Have we already gone too far down the path to alter course? I don’t believe so, but we aren’t trying yet, and the last chance to assert control- the fail-safe point- is rapidly approaching.

Surely there is a pressing need for ethical dialogue [[cxliv]] on auto-ID innovation and more generally IT&T. If there has ever been a time when engineers have had to act socially responsibly [[cxlv]], it is now as we are at defining crossroads.

The new era of biomedical and genetic research merges the worlds of engineering, computer and information technology with traditional medical research. Some of the most significant and far-reaching discoveries are being made at the interface of these disciplines. [[cxlvi]]

9. Conclusion

The principal objective of this paper was to encourage critical discussion on the exigent topic of human implants in e-business applications by documenting the central social, cultural, religious and ethical issues. The evidence provided indicates that technology-push has been the driving force behind many of the new RFID transponder implant applications instead of market-pull. What is most alarming is the rate of change in technological capabilities without the commensurate response from an informed community involvement or ethical discourse on what these changes actually “mean”, not only for the present but also for the future. It seems that the normal standard now is to introduce a technology, stand back to see its general effects on society, and then act to rectify problems as they might arise. The concluding point of this paper is that the long-term side effects of a technology should be considered at the outset and not after the event. One need only bring to mind the Atomic Bomb and the Chernobyl disaster for what is possible, if not inevitable once a technology is set on its ultimate trajectory [103]. As citizens it is our duty to remain knowledgeable about scientific developments and to discuss the possible ethical implications again and again [10]. In the end we can point the finger at the Mad Scientists [75] but we too must be socially responsible, save we become our own worst enemy [[cxlvii]]. It is certainly a case of caveat emptor, let the buyer beware.

10. References

[1] Cohen, T., The Tattoo, Savvas, Sydney (1994).

[2] Sanchez-Klein, J., “Cyberfuturist plants chip in arm to test human-computer interaction”, CNN Interactive,  http://www.cnn.com/TECH/computing/9808/28/ armchip.idg/index.html, [Accessed 28 August 1998], pp. 1-2 (1998).

[3] Jones, C., “Kevin Warwick: Saviour of humankind?”, BBC News, http://news.bbc.co.uk/2/hi/in_depth/uk/2000/newsmakers/1069029.stm, [Accessed 4 January 2003], pp. 1-4 (2000).

[4] ADSX, “Homepage”, http://www.adsx.com, Applied Digital Solutions, [Accessed 1 March 2004], p. 1 (2004).

[5] ADSX, “VeriChip Corporation”, Applied Digital Solutions, http://www.4verichip.com/, [Accessed 1 April 2004], p. 1 (2004).

[6] Warwick, K., “Professor of Cybernetics, University of Reading”, Kevin Warwick, http://www.kevinwarwick.com, [Accessed 14 November 2002], pp. 1-2 (2002).

[7] Goldman, J., “Meet ‘The Chipsons’: ID chips implanted successfully in Florida family”, ABC News: techtv, http://abcnews.go.com/sections/scitech/ TechTV/techtv_chipfamily020510.html, [Accessed 13 November 2003], pp. 1-2 (2002).

[8] Ramesh, E.M., “Time Enough: consequences of the human microchip implantation”, Franklin Pierce Law Centre, http://www.fplc.edu/risk/vol8/fall/ ramesh.htm, [Accessed 1 March 2004], pp. 1-26 (2004).

[9] Unatin, D., “Progress v. Privacy: the debate over computer chip implants”, JOLT: Notes, http://www.lawtechjournal.com/notes/2002/24_020819_ unatin. php, [Accessed 1 March 2004], pp. 1-3 (2002).

[10] Gotterbarn, D., “Injectable computers: once more into the breach! The life cycle of computer ethics awareness”, inroads- The SIGCSE Bulletin, Vol. 35, No. 4, December, pp. 10-12, (2003).

[11] Covacio, S., “Technological problems associated with the subcutaneous microchips for human identification (SMHId), InSITE-“Where Parallels Intersect, June, pp. 843-853 (2003).

[12] Warwick, K., “I, Cyborg”, 2003 Joint Lecture: The Royal Society of Edinburgh and The Royal Academy of Engineering, The Royal Society of Edinburgh, pp. 1-16 (2003).

[13] Norman, D.A., “Cyborgs”, Communications of the ACM, Vol. 44, No. 3, March, pp. 36-37 (2001).

[14] Bell, G. & Gray, J., “Futuristic forecasts of tools and technologies: digital immortality”, Communications of the ACM, March, Vol. 44, No. 3, pp. 29-31 (2001).

[15] Woodward, J.D., “Biometrics: privacy’s foe or privacy’s friend?”, Proceedings of the IEEE, Vol. 85, No. 9, pp. 1480-1492 (1997).

[16] Rosenberg, R.S., The Social Impact of Computers, Elsevier Academic Press, California (2004).

[17] Lemonick, M.D., “Future tech is now”, Time Australia, 17 July, pp. 44-79 (1995).

[18] McGinity, M., “Body of the technology: It’s just a matter of time before a chip gets under your skin”, Communications of the ACM, 43(9), September, pp. 17-19 (2000).

[19] Stephan, R., “The ultrahuman revolution”, MoneyZone.com, http://www. moneyzone.com/MTM_features3.28.cfm, [Accessed 29 November 2001], pp. 1-3 (2001).

[20] Sheridan, J.G. et al., “Spectators at a geek show: an ethnographic inquiry into wearable computing”, IEEE The Fourth International Symposium on Wearable Computers, pp. 195-196 (2000).

[21] Lukowicz, P., “The wearARM modular low-power computing core”, IEEE Micro, May-June, pp. 16-28 (2001).

[22] DeFouw, G. & Pratt, V., “The matchbox PC: a small wearable platform”, The Third International Symposium on Wearable Computers, pp. 172-175 (1999).

[23] Salonen, P. et al., “A small planar inverted-F antenna for wearable applications”, IEEE Tenth International Conference on Antennas and Propagation, Vol. 1, pp. 82-85 (1997).

[24] Mann S., “Wearable computing: a first step toward personal imaging”, IEEE Computer, February, pp. 25-32 (1997).

[25] Millanvoye, M., “Teflon under my skin”, UNESCO, http://www.unesco. org/courier/2001_07/uk/doss41.htm, [Accessed 29 November 2001], pp. 1-2 (2001).

[26] Furui, S., “Speech recognition technology in the ubiquitous/wearable computing environment”, IEEE International Conference on Acoustics, Speech, and Signal Processing, Vol. 6, pp. 3735-3738 (2000).

[27] Pickering, C., “Silicon man lives”, Forbes ASAP, http://www.cochrane.org.uk/opinion/interviews/forbes.htm, [Accessed 22 November 2001], pp. 1-2 (1999).

[28] Sydänheimo, L. et al., “Wearable and ubiquitous computer aided service, maintenance and overhaul”, IEEE International Conference on Communications, Vol. 3, pp. 2012-2017 (1999).

[29] Rhodes, B. J. et al., “Wearable computing meets ubiquitous computing: reaping the best of both worlds”, The Third International Symposium on Wearable Computers, pp. 141-149 (1999).

[30] Kaku, M., Visions: how science will revolutionize the 21st century and beyond, Oxford University Press, Oxford (1998).

[31] van Laerhoven, K. & Cakmacki, O., “What shall we teach our pants?”, IEEE The Fourth International Symposium on Wearable Computers, pp. 77-83 (2000).

[32] Kortuem, G. et al., “Context-aware, adaptive wearable computers as remote interfaces to ‘intelligent’ environments”, Second International Symposium on Wearable Computers, pp. 58-65 (1998).

[33] Starner, T., “The challenges of wearable computing: part 2”, IEEE Micro, July-August, pp. 54-67 (2001).

[34] Mills, S. (ed.), Turning Away From Technology: a new vision for the 21st century, Sierra Club Books, San Francisco (1997).

[35] Davies, S., Big Brother: Australia’s growing web of surveillance, Simon and Schuster, Sydney (1992).

[36] Davies, S., Monitor: extinguishing privacy on the information superhighway, PAN, Sydney (1996).

[37] Hibbert, C., “What to do when they ask for your social security number”, in Computerization and Controversy: value conflicts and social choices, (ed.) Rob Kling, Academic Press, New York, pp. 686-696 (1996).

[38] Kusserow, R.P., “The government needs computer matching to root out waste and fraud”, in Computerisation and Controversy: value conflicts and social choices, (ed.) Rob Kling, Academic Press, New York, part 6, section E, pp. 653f (1996).

[39] Privacy Commissioner, Selected Extracts from the Program Protocol Data-Matching Program (Assistance and Tax), Privacy Commission, Sydney (1990).

[40] Jones, D., “UK government launches smart card strategy”, Ctt, Vol. 11, No. 6, February, p. 2 (2000).

[41] Michels, S., “National ID”, Online NewsHour, http://www.pbs.org/ newshour/bb/fedagencies/jan-june02/id_2-26.html, [Accessed 2 September 2001], pp. 1-8 (2002).

[42] Rosenberg, R.S., The Social Impact of Computers, Sydney, Elsevier, pp. 339-405 (2004).

[43] Brin, D., The Transparent Society: will technology force us to choose between privacy and freedom, Perseus Books, Massachusetts (1998).

[44] Branscomb, A. W., Who Owns Information: from privacy to public access, BasicBooks, USA (1994).

[45] Rothfeder, J., “Invasion of privacy”, PC World, Vol. 13, No. 11, pp. 152-162 (1995).

[46] Newton, J. “Reducing ‘plastic’ counterfeiting”, European Convention on Security and Detection, Vol. 408, pp. 198-201 (1995).

[47] Masterson, U.O., “A day with ‘Professor Cyborg’”, MSNBC, http://www.msnbc.com/news/394441.asp, [Accessed 29 November 2001], pp. 1-6 (2000).

[48] Associated Press, “Chip in your shoulder? Family wants info device”, USA Today: Tech, http://www.usatoday.com/life/cyber/tech/2002/04/01/verichip-family.htm, [Accessed 15 October 2002], pp. 1-2 (2002).

[49] Mieszkowski, K., “Put that silicon where the sun don’t shine”, Salon.com, http://www.salon.com/tech/feature/2000/09/07/chips/, Parts 1-3, [Accessed 11 November 2001], pp. 1-3 (2000).

[50] Salkowski, J., “Go track yourself”, StarNet Dispatches, http://dispatches. azstarnet.com/joe/2000/0104-946929954.htm, [Accessed 29 November 2001], pp. 1-4 (2000).

[51] LoBaido, A.C. 2001, “Soldiers with microchips: British troops experiment with implanted, electronic dog tag”, WorldNetDaily.com, http://www.fivedoves. com/letters/oct2001/chrissa102.htm, [Accessed 20 November 2001], pp. 1-2 (2001).

[52] Swissler, M.A., “Microchips to monitor meds”, Wired, http://www.wired. com/news/technology/0,1282,39070,00.html, [Accessed 29 November 2001], pp. 1-3 (2000).

[53] Black, J., “Roll up your sleeve – for a chip implant”, Illuminati Conspiracy, http://www.conspiracyarchive.com/NWO/chip_implant.htm, [Accessed 15 October 2002], pp. 1-6 (2002).

[54] RFID, “Singapore fights SARS with RFID”, RFID Journal, http://216.121.131.129/article/articleprint/446/-1/1/, [Accessed 1 May 2004], pp. 1-2 (2003).

[55] RFID, “Taiwan uses RFID to combat SARS”, RFID Journal, http://216.121.131.129/article/articleprint/520/-1/1/, [Accessed 1 May 2004], pp. 1-2 (2003).

[56] Scheeres, J. “They want their id chips now”, Wired News, http://www.wired.com/news/privacy/0,1848,50187,00.html, [Accessed 15 October 2002], pp. 1-2 (2002).

[57] Wherify, “Frequently Asked Questions”, Wherify Wireless, http://www.wherifywireless.com/faq.asp, [Accessed 15 April 2004], pp. 1-7 (2004).

[58] Scheeres, J., “Kidnapped? GPS to the rescue”, Wired News, http://www.wired.com/news/business/0,1367,50004,00.html, [Accessed 15 October 2002], pp. 1-2 (2002).

[59] McClimans, F., ‘Is that a chip in your shoulder, or are you just happy to see me?’, CNN.com, http://www.cnn.com/TECH/computing/9809/02/chippotent. idg/index.html, [Accessed 22 November 2001], pp. 1-4 (1998).

[60] Scheeres, J., “Politician wants to ‘get chipped’”, Wired News, http://www.wired.com/news/technology/0,1282,50435,00.html, [Accessed 15 October 2002], pp. 1-2 (2002).

[61] Horn, T., “Opinionet contributed commentary”, Opinionet, http://www. opinionet.com/commentary/contributors/ccth/ccth13.htm, [Accessed 29 November 2001], pp. 1-4 (2000).

[62] Levi, P., The Drowned and the Saved, trans. Raymond Rosenthal, Summit Books, London (1988).

[63] Lifton, R.J., The Nazi Doctors: medical killing and the psychology of genocide, Basic Books, New York (1986).

[64] McMurchie, L., “Identifying risks in biometric use”, Computing Canada, Vol. 25, No. 6, p. 11, (1999).

[65] Nairne, D., “Building better people with chips and sensors”, scmp.com, http://special.scmp.com/mobilecomputing/article/FullText_asp_ArticleID-20001009174, [Accessed 29 November 2001], pp. 1-2 (2000).

[66] National Radiological Protection Board, “Understanding radiation: ionizing radiation and how we are exposed to it”, NRPB, http://www.nrpb.org/radiation_ topics/risks/index.htm, [Accessed 1 May 2004], pp. 1-2 (2004).

[67] Australian Communications Authority, Human exposure to radiofrequency electromagnetic energy: information for manufacturers, importers, agents, licensees or operators of radio communications transmitters, Australian regulations, Melbourne (2000).

[68] Salonen, P. et al., “A small planar inverted-F antenna for wearable applications”, IEEE Tenth International Conference on Antennas and Propagation, Vol. 1, pp. 82-85 (1997).

[69] Geers, R. et al., Electronic Identification, Monitoring and Tracking of Animals, CAN International, New York (1997).

[70] Trull, D., “Simple Cyborg”, Parascope, http://www.parascope.com/ articles/slips/fs29_2.htm, [Accessed 20 November 2001], pp. 1-4 (1998).

[71] Witt, S., “Professor Warwick chips in”, Computerworld, 11 January, p. 89 (1999).

[72] Martin, C.D., “The myth of the awesome thinking machine”, Communications of the ACM, 36(4), pp. 120-133 (1993).

[73] Michael, K., “The automatic identification trajectory: from the ENIAC to chip implants”, in Internet Commerce: digital models for business, E. Lawrence et al., John Wiley and Sons, Queensland, pp. 131-134, 136 (2002).

[74] Tapscott, D., Growing up digital: the rise of the net generation, McGraw- Hill, New York (1998).

[75] Walker, I., “Cyborg dreams: Beyond Human”, Background Briefing ABC Radio National, 4 November, pp. 1-15 (2001)

[76] Anonymous, “Will a chip every day keep the doctor away?”, PhysicsWeb, http://physicsweb.org/article/world/14/7/11, [Accessed 29 November 2001], pp. 1-2 (2001).

[77] Goldberg, H., “Building a better mMode”, http://www.mmodemagazine. com/features/bettermmode.asp, mMode Magazine, [Accessed 1 April 2004), pp. 1-4 (2004).

[78] Wilmington, M., “Movie review, ‘Metropolis (Re-release)’”, Metromix.com, http://metromix.chicagotribune.com/search/mmx-17922_lgcy. story, [Accessed 3 May 2004], pp. 1-3 (2004).

[79] McRoy, J., “Science fiction studies”, DePauw University, Vol. 28, No. 3, http://www.depauw.edu/sfs/birs/bir85b.htm, [Accessed 3 May 2004], pp. 1-3 (2001).

[80] Anonymous, “The NET”, MovieWeb, http://movieweb.com/movie/thenet/ index.html, [Accessed 3 May 2004], pp. 1-5 (2001).

[81] King, B., “Robots: It’s an art thing” http://www.wired.com/news/print/ 0,1294,48253,00.html, [Accessed 4 January 2003], pp. 1-2 (2001).

[82] Branwyn, G., “The desire to be wired”, Wired, September/October (1993).

[83] Schirato, T. & Yell, S. Communication & Cultural Literacy: an introduction, Allen and Unwin, NSW (1996).

[84] Dery, M., Escape Velocity: cyberculture at the end of the century, Hodder and Stoughton, London (1996).

[85] Scheeres, J., “New body art: Chip implants”, Wired News, http://www. wired.com/news/culture/0,1284,50769,00.html, [Accessed 15 October 2002], pp. 1-2 (2002).

[86] Tysome, T., “Dance of a cyborg”, The Australian, p. 35 (2001).

[87] Warwick, K., “Frequently asked questions”, Professor Kevin Warwick, http://www2.cyber.rdg.ac.uk/kevinwarwick/FAQ.html, [Accessed 20 November 2001], pp. 1-4 (2001).

[88] Sacleman, H. Computers, System Science, And Evolving Society: the challenge of man-machine digital systems, Wiley, New York (1967).

[89] McLuhan, M., Understanding Media: the extensions of man, The MIT Press, England (1999).

[90] McLuhan, M. & Powers, B.R., The Global Village: transformations in world life and media in the 21st century, Oxford University Press, New York (1989).

[91] McLuhan, E. & Zingrone, F., Essential McLuhan, BasicBooks, USA (1995).

[92] Ellul, J., The Technological Society, Vintage Books, New York (1964).

[93] Toffler, A., Future Shock, Bantam Books, New York (1970).

[94] Gates, B., The Road Ahead, The Penguin Group, New York (1995).

[95] Negroponte, N., Being Digital, Hodder and Stoughton, Australia (1995).

[96] Moravec, H., Mind Children: the future of robot and human intelligence, Harvard University Press, Cambridge (1988).

[97] Moravec, H., Robot: mere machine to transcendent mind, Oxford University Press, Oxford (1999).

[98] Paul, G.S. & Cox, E.D. Beyond Humanity: cyberevolution and future minds, Charles River Media, Massachusetts (1996).

[99] Sorkin, D.L. & McClanahan, J. “Cochlear implant reimbursement cause for concern”, HealthyHearing, http://www.healthyhearing.com/healthyhearing/ newroot/articles/arc_disp.asp?id=147&catid=1055, [Accessed 3 May 2004], pp. 1-4 (2004).

[100] Weber, D.O., “Me, myself, my implants, my micro-processors and I”, Software Development Magazine, http://www.sdmagazine.com/print/ documentID=11149, [Accessed 29 November 2001], pp. 1-6 (2000).

[101] Maybury, M.T., “The mind matters: artificial intelligence and its societal implications”, IEEE Technology and Society Magazine, June/July, pp. 7-15 (1990).

[102] Bijker, W.E. & Law, J. (eds), Shaping Technology/Building Society: studies in sociotechnical change, The MIT Press, Massachusetts (1992).

[103] Pool, R. Beyond Engineering: how society shapes technology, Oxford University Press, New York (1997).

[104] Hristodoulou, M. Hieromonk, “In the last days”, in Geron Paisios, Mount Athos, Greece, (in Greek), pp. 181-192 (1994).

[105] Relfe, M.S., The New Money System, Ministries Inc., Alabama (1982).

[106] Relfe, M.S., When Your Money Fails, League of Prayer, Alabama (1981).

[107] Barker, K. et al. (eds), The NIV Study Bible, Zondervan Publishing House, Michigan, pp. 1939-1940 (1995).

[108] Watkins, T., “WARNING: 666 IS COMING!”, Dial-the-Truth Ministries,  http://www.secis.com/truth [Accessed 1 August 1996], now http://www.av1611. org, pp. 1-6 (1996).

[109] Michael, M.G., The Number of the Beast, 666 (Revelation 13:16-18): Background, Sources and Interpretation, Macquarie University, MA (Hons) Thesis, Sydney, Australia (1998).

[110] Arndt, W.F. & Gingrich, F.W., A Greek-English Lexicon of the New Testament and Other Early Christian Literature, The University of Chicago Press, Chicago, p. 876 (1979).

[111] Roethenbaugh, G., “Simon Davies- Is this the most dangerous man in Europe?”, Biometrics in Human Services, Vol. 2, No. 5, pp. 2-5 (1998).

[112] Decker, S., “Technology raises concerns: Pros and cons of scientific advances weighed as Christians discuss issue”, The Falcon Online Edition,  http://www.thefalcononline.com//story/2270, [Accessed 1 April 2003], pp. 1-3 (2002).

[113] Cook, T.L. The Mark of the New World Order, ASIN, USA (1999).

[114] Newton, C., “U.S. to weigh computer chip implant”, Netscape: Daily News, http://dailynews.netscape.com/mynsnews/story.tmpl?table=n&cat=51180 &id= 200202261956000188605, [Accessed 15 October 2002], pp. 1-2 (2002).

[115] Associated Press, “Chip in your shoulder? Family wants info device”, USA Today: Tech, http://www.usatoday.com/life/cyber/tech/2002/04/01/ verichip-family.htm, [Accessed 15 October 2002], pp. 1-2 (2002).

[116] Michael, M.G., “For it is the number of a man”, Bulletin of Biblical Studies, Vol. 19, January-June, pp. 79-89 (2000).

[117] Michael, M.G., “666 or 616 (Rev 13:18): Arguments for the authentic reading of the Seer's conundrum”, Bulletin of Biblical Studies, Vol. 19, July-December, pp. 77-83 (2000).

[118] Bauckham, R., The Climax of Prophecy: Studies on the Book of Revelation, T & T Clark: Edinburgh, pp. 384-452 (1993).

[119] Horn, T., “Opinionet contributed commentary”, Opinionet, http://www.opinionet.com/commentary/contributors/ccth/ccth13.htm, [Accessed 29 November 2001], pp. 1-4 (2000).

[120] Barnet, R.J. & Cavanagh, J., Global Dreams: imperial corporations and the new world order, Simon and Schuster, New York (1994).

[121] Wilshire, B., The Fine Print, Brian Wilshire, Australia (1992).

[122] Smith, B., Warning, Smith Family Evangelism, New Zealand (1980).

[123] Stahl, W.A., God and the Chip: religion and the culture of technology, EDSR, Canada (1999).

[124] Noble, D.F., The Religion of Technology: the divinity of man and the spirit of invention, Penguin Books, England (1999).

[125] Sensormatic, “SafeKids™”, Sensormatic, http://www.sensormatic.com/ html/safekids/index.htm, [Accessed 3 June 1999], pp. 1-2 (1999).

[126] Raimundo, N., ‘Digital angel or big brother?’, SCU, http://cseserv.engr. scu.edu/StudentWebPages/NRaimundo/ResearchPaper.htm [Accessed 15th December 2002], (2002).

[127] Wilson, J., “Girl to get tracker implant to ease parents’ fears”, The Guardian, http://www.guardian.co.uk/Print/0,3858,4493297,00.html, [Accessed 15 October 2002], pp. 1-2 (2002).

[128] Ermann, M.D. et al. (eds), Computers, Ethics, and Society, Oxford University Press, New York (1997).

[129] Eng, P., “I, Chip? Technology to meld chips into humans draws closer”, ABCNEWS.com, http://abcnews.go.com/sections/scitech/DailyNews/  chipimplant020225.html, [Accessed 15 October 2002], pp. 1-3 (2002).

[130] Pace, S. et al. (eds), The Global Positioning System: assessing national policies, Rand Corporation, New York (1996).

[131] Rummler, D.M., “Societal issues in engineering”, ENGR 300, pp. 1-3 (2001).

[132] Associated Press, “Company gets okay to sell ID-only computer chip implant”, The Detroit News, http://www.detnews.com/2002/technology/0204/ 05/technology-457686.htm, [Accessed 15 October 2002] (2002).

[133] Associated Press, “ID chip ready for implant”, USA Today: Tech, http:// www.usatoday.com/life/cyber/tech/2002/04/04/implant-chip.htm, [Accessed 15 October 2002], pp. 1-2.

[134] Billinghurst, M. & Starner T., “Wearable devices: new ways to manage information”, IEEE Computer, January, Vol. 32, No. 1, pp. 57-64 (1999).

[135] Mann, S., “Wearable computing: toward humanistic intelligence”, IEEE Intelligent Systems, May/June, pp. 10-15 (2001).

[136] Chan, T., “Welcome to the Internet, baby!”, Telecom Asia, p. 38 (2001).

[137] Schiele, B. et al., “Sensory-augmented computing: wearing the museum’s guide”, IEEE Micro, pp. 44-52.

[138] Kurzweil, R., The Age of Spiritual Machines: when computers exceed human intelligence, Penguin Books, New York (1999).

[139] Irwin, A., “Brain implant lets man control computer by thought”, Telegraph.co.uk, 1238, http://www.telegraph.co.uk/et?ac=000118613908976, [Accessed 22 November 2001], pp. 1-3 (1998).

[140] Warwick, K., “Are chip implants getting under your skin?”, Compiler, http://www.synopsys.com/news/pubs/compiler/art3_chipimplan-mar03.html, [Accessed 1 March 2004], pp. 1-5 (2003).

[141] McGrath, P., “Technology: Building better humans”, Newsweek, http:// egweb.mines.edu/eggn482/admin/Technology.htm, [Accessed 29 November], pp. 1-3 (2001).

[142] Anonymous, “Professor Cyborg”, Salon.com, http://www.salon.com/tech/ feature/1999/10/20/cyborg/index1.html, 3 parts, [Accessed 29 November 2001], pp. 1-3 (1999).

[143] Joy, B. “Why the future doesn’t need us”, Wired, 8.04, http://www.wired. com/wired/archive/8.04/joy_pr.html, [Accessed 4 January 2003], pp. 1-19 (2000).

[144] Masey, S. “Can we talk? The need for ethical dialogue”, The IEE, p. 4/1, (1998).

[145] Wenk, E., “The design of technological megasystems: new social responsibilities for engineers”, IEEE, pp. 47-61 (1990).

[146] Boehringer, B., “Benefits of the OHSU/OGI merger”, The Oregon Opportunity: A New Era of Medical Breakthroughs, http://www.ohsu.edu/ about/opportunity/ohsu_ogi.htm, [Accessed 20 November 2001], pp. 1-2 (2001).

[147] Ebert, R., “Enemy of the State”, Ebert on Movies, http://www.suntimes. com/ebert/ebert_reviews/1998/11/112006.html, pp. 1-3 (2001).

 

Biographical Note

Dr Katina Michael is a lecturer in Information Technology at the University of Wollongong in Australia. In 1996 she completed her Bachelor of Information Technology degree with a co-operative scholarship from the University of Technology, Sydney (UTS) and in 2003 she was awarded her Doctor of Philosophy with the thesis “The Auto-ID Trajectory” from the University of Wollongong. She has an industrial background in telecommunications and has held positions as a systems analyst with United Technologies and Andersen Consulting. Most of her work experience was acquired as a senior network and business planner with Nortel Networks (1996-2001). In this capacity she consulted for Asia’s largest telecommunication operators and service providers. Katina now teaches and researches in eBusiness and her main academic interests are in the areas of automatic identification devices, third generation wireless applications, geographic information systems, and technology forecasting.

Dr M.G. Michael is a church historian and New Testament scholar. He has spoken at numerous international conferences and has written two highly regarded dissertations on the Book of Revelation. His specialist interests are in apocalypticism, millennial studies, and Orthodox mysticism. He has completed a Doctor of Philosophy at the Australian Catholic University, a Master of Arts (Honours) at Macquarie University, a Master of Theology and Bachelor of Arts at Sydney University and a Bachelor of Theology at the Sydney College of Divinity.