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Sunday, June 10, 2018

Cyborg

From Wikipedia, the free encyclopedia

A cyborg (short for "cybernetic organism") is a being with both organic and biomechatronic body parts. The term was coined in 1960 by Manfred Clynes and Nathan S. Kline.[1]

The term cyborg is not the same thing as bionic, biorobot or android; it applies to an organism that has restored function or enhanced abilities due to the integration of some artificial component or technology that relies on some sort of feedback.[2] While cyborgs are commonly thought of as mammals, including humans, they might also conceivably be any kind of organism.

D. S. Halacy's Cyborg: Evolution of the Superman in 1965 featured an introduction which spoke of a "new frontier" that was "not merely space, but more profoundly the relationship between 'inner space' to 'outer space' – a bridge...between mind and matter."[3]

In popular culture, some cyborgs may be represented as visibly mechanical (e.g., Cyborg from DC Comics, the Cybermen in the Doctor Who franchise or The Borg from Star Trek or Darth Vader from Star Wars) or as almost indistinguishable from humans (e.g., the "Human" Cylons from the re-imagining of Battlestar Galactica, etc.). Cyborgs in fiction often play up a human contempt for over-dependence on technology, particularly when used for war, and when used in ways that seem to threaten free will.[citation needed] Cyborgs are also often portrayed with physical or mental abilities far exceeding a human counterpart (military forms may have inbuilt weapons, among other things).[citation needed]

Overview

According to some definitions of the term, the physical attachments humanity has with even the most basic technologies have already made them cyborgs.[4] In a typical example, a human with an artificial cardiac pacemaker or implantable cardioverter-defibrillator would be considered a cyborg, since these devices measure voltage potentials in the body, perform signal processing, and can deliver electrical stimuli, using this synthetic feedback mechanism to keep that person alive. Implants, especially cochlear implants, that combine mechanical modification with any kind of feedback response are also cyborg enhancements. Some theorists[who?] cite such modifications as contact lenses, hearing aids, or intraocular lenses as examples of fitting humans with technology to enhance their biological capabilities. As cyborgs currently are on the rise some theorists argue there is a need to develop new definitions of aging and for instance a bio-techno-social definition of aging has been suggested.[5]

The term is also used to address human-technology mixtures in the abstract. This includes not only commonly used pieces of technology such as phones, computers, the Internet, etc. but also artifacts that may not popularly be considered technology; for example, pen and paper, and speech and language. When augmented with these technologies and connected in communication with people in other times and places, a person becomes capable of much more than they were before. An example is a computer, which gains power by using Internet protocols to connect with other computers. Another example, which is becoming more and more relevant is a bot-assisted human or human-assisted-bot, used to target social media with likes and shares.[6] Cybernetic technologies include highways, pipes, electrical wiring, buildings, electrical plants, libraries, and other infrastructure that we hardly notice, but which are critical parts of the cybernetics that we work within.

Bruce Sterling in his universe of Shaper/Mechanist suggested an idea of alternative cyborg called Lobster, which is made not by using internal implants, but by using an external shell (e.g. a Powered Exoskeleton).[7] Unlike human cyborgs that appear human externally while being synthetic internally (e.g. the Bishop type in the Alien franchise), Lobster looks inhuman externally but contains a human internally (e.g. Elysium, RoboCop). The computer game Deus Ex: Invisible War prominently featured cyborgs called Omar, where "Omar" is a Russian translation of the word "Lobster" (since the Omar are of Russian origin in the game).

Origins

The concept of a man-machine mixture was widespread in science fiction before World War II. As early as 1843, Edgar Allan Poe described a man with extensive prostheses in the short story "The Man That Was Used Up". In 1911, Jean de la Hire introduced the Nyctalope, a science fiction hero who was perhaps the first literary cyborg, in Le Mystère des XV (later translated as The Nyctalope on Mars).[8][9][10] Edmond Hamilton presented space explorers with a mixture of organic and machine parts in his novel The Comet Doom in 1928. He later featured the talking, living brain of an old scientist, Simon Wright, floating around in a transparent case, in all the adventures of his famous hero, Captain Future. He uses the term explicitly in the 1962 short story, "After a Judgment Day," to describe the "mechanical analogs" called "Charlies," explaining that "[c]yborgs, they had been called from the first one in the 1960s...cybernetic organisms." In the short story "No Woman Born" in 1944, C. L. Moore wrote of Deirdre, a dancer, whose body was burned completely and whose brain was placed in a faceless but beautiful and supple mechanical body. Cyborgs are becoming more of a reality each day.

The term was coined by Manfred E. Clynes and Nathan S. Kline in 1960 to refer to their conception of an enhanced human being who could survive in extraterrestrial environments:


Their concept was the outcome of thinking about the need for an intimate relationship between human and machine as the new frontier of space exploration was beginning to open up. A designer of physiological instrumentation and electronic data-processing systems, Clynes was the chief research scientist in the Dynamic Simulation Laboratory at Rockland State Hospital in New York.

The term first appears in print five months earlier when The New York Times reported on the Psychophysiological Aspects of Space Flight Symposium where Clynes and Kline first presented their paper.


A book titled Cyborg: Digital Destiny and Human Possibility in the Age of the Wearable Computer was published by Doubleday in 2001.[13] Some of the ideas in the book were incorporated into the 35 mm motion picture film Cyberman.

Cyborg tissues in engineering

Cyborg tissues structured with carbon nanotubes and plant or fungal cells have been used in artificial tissue engineering to produce new materials for mechanical and electrical uses. The work was presented by Di Giacomo and Maresca at MRS 2013 Spring conference on Apr, 3rd, talk number SS4.04.[14] The cyborg obtained is inexpensive, light and has unique mechanical properties. It can also be shaped in desired forms. Cells combined with MWCNTs co-precipitated as a specific aggregate of cells and nanotubes that formed a viscous material. Likewise, dried cells still acted as a stable matrix for the MWCNT network. When observed by optical microscopy the material resembled an artificial "tissue" composed of highly packed cells. The effect of cell drying is manifested by their "ghost cell" appearance. A rather specific physical interaction between MWCNTs and cells was observed by electron microscopy suggesting that the cell wall (the most outer part of fungal and plant cells) may play a major active role in establishing a CNTs network and its stabilization. This novel material can be used in a wide range of electronic applications from heating to sensing and has the potential to open important new avenues to be exploited in electromagnetic shielding for radio frequency electronics and aerospace technology. In particular using Candida albicans cells cyborg tissue materials with temperature sensing properties have been reported.[15]

Actual cyborgization attempts


Cyborg Neil Harbisson with his antenna implant

In current prosthetic applications, the C-Leg system developed by Otto Bock HealthCare is used to replace a human leg that has been amputated because of injury or illness. The use of sensors in the artificial C-Leg aids in walking significantly by attempting to replicate the user's natural gait, as it would be prior to amputation.[16] Prostheses like the C-Leg and the more advanced iLimb are considered by some to be the first real steps towards the next generation of real-world cyborg applications.[citation needed] Additionally cochlear implants and magnetic implants which provide people with a sense that they would not otherwise have had can additionally be thought of as creating cyborgs.[citation needed]

In vision science, direct brain implants have been used to treat non-congenital (acquired) blindness. One of the first scientists to come up with a working brain interface to restore sight was private researcher William Dobelle. Dobelle's first prototype was implanted into "Jerry", a man blinded in adulthood, in 1978. A single-array BCI containing 68 electrodes was implanted onto Jerry's visual cortex and succeeded in producing phosphenes, the sensation of seeing light. The system included cameras mounted on glasses to send signals to the implant. Initially, the implant allowed Jerry to see shades of grey in a limited field of vision at a low frame-rate. This also required him to be hooked up to a two-ton mainframe, but shrinking electronics and faster computers made his artificial eye more portable and now enable him to perform simple tasks unassisted.[17]

In 1997, Philip Kennedy, a scientist and physician, created the world's first human cyborg from Johnny Ray, a Vietnam veteran who suffered a stroke. Ray's body, as doctors called it, was "locked in". Ray wanted his old life back so he agreed to Kennedy's experiment. Kennedy embedded an implant he designed (and named "neurotrophic electrode") near the part of Ray's brain so that Ray would be able to have some movement back in his body. The surgery went successfully, but in 2002, Johnny Ray died.[18]

In 2002, Canadian Jens Naumann, also blinded in adulthood, became the first in a series of 16 paying patients to receive Dobelle's second generation implant, marking one of the earliest commercial uses of BCIs. The second generation device used a more sophisticated implant enabling better mapping of phosphenes into coherent vision. Phosphenes are spread out across the visual field in what researchers call the starry-night effect. Immediately after his implant, Naumann was able to use his imperfectly restored vision to drive slowly around the parking area of the research institute.[19]

In contrast to replacement technologies, in 2002, under the heading Project Cyborg, a British scientist, Kevin Warwick, had an array of 100 electrodes fired into his nervous system in order to link his nervous system into the internet to investigate enhancement possibilities. With this in place Warwick successfully carried out a series of experiments including extending his nervous system over the internet to control a robotic hand, also receiving feedback from the fingertips in order to control the hand's grip. This was a form of extended sensory input. Subsequently, he investigated ultrasonic input in order to remotely detect the distance to objects. Finally, with electrodes also implanted into his wife's nervous system, they conducted the first direct electronic communication experiment between the nervous systems of two humans.[20][21]

Since 2004, British artist Neil Harbisson has had a cyborg antenna implanted in his head that allows him to extend his perception of colors beyond the human visual spectrum through vibrations in his skull.[22] His antenna was included within his 2004 passport photograph which has been claimed to confirm his cyborg status.[23] In 2012 at TEDGlobal,[24] Harbisson explained that he started to feel cyborg when he noticed that the software and his brain had united and given him an extra sense.[24] Neil Harbisson is a co-founder of the Cyborg Foundation (2004)[25]

Furthermore many cyborgs with multifunctional microchips injected into their hand are known to exist. With the chips they are able swipe cards, open or unlock doors, operate devices such as printers or, with some using a cryptocurrency, buy products, such as drinks, with a wave of the hand.[26][27][28][29][30]

bodyNET

bodyNET is an application of human-electronic interaction currently in development by researchers from Stanford University.[31] The technology is based on stretchable semiconductor materials (Elastronic). According to their article in Nature (journal), the technology is composed of smart devices, screens, and a network of sensors that can be implanted into the body, woven into the skin or worn as clothes. It has been suggested, that this platform can potentially replace the smartphone in the future.[32]

Animal cyborgs

The US-based company Backyard Brains released what they refer to as "The world's first commercially available cyborg" called the RoboRoach. The project started as a University of Michigan biomedical engineering student senior design project in 2010[33] and was launched as an available beta product on 25 February 2011.[34] The RoboRoach was officially released into production via a TED talk at the TED Global conference,[35] and via the crowdsourcing website Kickstarter in 2013,[36] the kit allows students to use microstimulation to momentarily control the movements of a walking cockroach (left and right) using a bluetooth-enabled smartphone as the controller. Other groups have developed cyborg insects, including researchers at North Carolina State University,[37][38] UC Berkeley,[39][40] and Nanyang Technological University, Singapore,[41][42] but the RoboRoach was the first kit available to the general public and was funded by the National Institute of Mental Health as a device to serve as a teaching aid to promote an interest in neuroscience.[35] Several animal welfare organizations including the RSPCA [43] and PETA [44] have expressed concerns about the ethics and welfare of animals in this project.

Cyborg proliferation in society

In medicine

In medicine, there are two important and different types of cyborgs: the restorative and the enhanced. Restorative technologies "restore lost function, organs, and limbs".[45] The key aspect of restorative cyborgization is the repair of broken or missing processes to revert to a healthy or average level of function. There is no enhancement to the original faculties and processes that were lost.

On the contrary, the enhanced cyborg "follows a principle, and it is the principle of optimal performance: maximising output (the information or modifications obtained) and minimising input (the energy expended in the process)".[46] Thus, the enhanced cyborg intends to exceed normal processes or even gain new functions that were not originally present.

Although prostheses in general supplement lost or damaged body parts with the integration of a mechanical artifice, bionic implants in medicine allow model organs or body parts to mimic the original function more closely. Michael Chorost wrote a memoir of his experience with cochlear implants, or bionic ear, titled "Rebuilt: How Becoming Part Computer Made Me More Human."[47]  Jesse Sullivan became one of the first people to operate a fully robotic limb through a nerve-muscle graft, enabling him a complex range of motions beyond that of previous prosthetics.[48] By 2004, a fully functioning artificial heart was developed.[49] The continued technological development of bionic and nanotechnologies begins to raise the question of enhancement, and of the future possibilities for cyborgs which surpass the original functionality of the biological model. The ethics and desirability of "enhancement prosthetics" have been debated; their proponents include the transhumanist movement, with its belief that new technologies can assist the human race in developing beyond its present, normative limitations such as aging and disease, as well as other, more general incapacities, such as limitations on speed, strength, endurance, and intelligence. Opponents of the concept describe what they believe to be biases which propel the development and acceptance of such technologies; namely, a bias towards functionality and efficiency that may compel assent to a view of human people which de-emphasizes as defining characteristics actual manifestations of humanity and personhood, in favor of definition in terms of upgrades, versions, and utility.[50]

A brain-computer interface, or BCI, provides a direct path of communication from the brain to an external device, effectively creating a cyborg. Research of Invasive BCIs, which utilize electrodes implanted directly into the grey matter of the brain, has focused on restoring damaged eyesight in the blind and providing functionality to paralyzed people, most notably those with severe cases, such as Locked-In syndrome. This technology could enable people who are missing a limb or are in a wheelchair the power to control the devices that aide them through neural signals sent from the brain implants directly to computers or the devices. It is possible that this technology will also eventually be used with healthy people.[51]

Deep brain stimulation is a neurological surgical procedure used for therapeutic purposes. This process has aided in treating patients diagnosed with Parkinson's disease, Alzheimer's disease, Tourette syndrome, epilepsy, chronic headaches, and mental disorders. After the patient is unconscious, through anesthesia, brain pacemakers or electrodes, are implanted into the region of the brain where the cause of the disease is present. The region of the brain is then stimulated by bursts of electric current to disrupt the oncoming surge of seizures. Like all invasive procedures, deep brain stimulation may put the patient at a higher risk. However, there have been more improvements in recent years with deep brain stimulation than any available drug treatment.[52]

Retinal implants are another form of cyborgization in medicine. The theory behind retinal stimulation to restore vision to people suffering from retinitis pigmentosa and vision loss due to aging (conditions in which people have an abnormally low number of ganglion cells) is that the retinal implant and electrical stimulation would act as a substitute for the missing ganglion cells (cells which connect the eye to the brain.)

While work to perfect this technology is still being done, there have already been major advances in the use of electronic stimulation of the retina to allow the eye to sense patterns of light. A specialized camera is worn by the subject, such as on the frames of their glasses, which converts the image into a pattern of electrical stimulation. A chip located in the user's eye would then electrically stimulate the retina with this pattern by exciting certain nerve endings which transmit the image to the optic centers of the brain and the image would then appear to the user. If technological advances proceed as planned this technology may be used by thousands of blind people and restore vision to most of them.

A similar process has been created to aide people who have lost their vocal cords. This experimental device would do away with previously used robotic sounding voice simulators. The transmission of sound would start with a surgery to redirect the nerve that controls the voice and sound production to a muscle in the neck, where a nearby sensor would be able to pick up its electrical signals. The signals would then move to a processor which would control the timing and pitch of a voice simulator. That simulator would then vibrate producing a multitonal sound which could be shaped into words by the mouth.[53]

An article published in Nature Materials in 2012 reported a research on "cyborg tissues" (engineered human tissues with embedded three-dimensional mesh of nanoscale wires), with possible medical implications.[54]

In 2014, researchers from the University of Illinois at Urbana-Champaign and Washington University in St. Louis had developed a device that could keep a heart beating endlessly. By using 3D printing and computer modeling these scientist developed an electronic membrane that could successfully replace pacemakers. The device utilizes a "spider-web like network of sensors and electrodes" to monitor and maintain a normal heart-rate with electrical stimuli. Unlike traditional pacemakers that are similar from patient to patient, the elastic heart glove is made custom by using high-resolution imaging technology. The first prototype was created to fit a rabbit's heart, operating the organ in an oxygen and nutrient-rich solution. The stretchable material and circuits of the apparatus were first constructed by Professor John A. Rogers in which the electrodes are arranged in a s-shape design to allow them to expand and bend without breaking. Although the device is only currently used as a research tool to study changes in heart rate, in the future the membrane may serve as a safeguard from heart attacks.[55]

In the military

Military organizations' research has recently focused on the utilization of cyborg animals for the purposes of a supposed tactical advantage. DARPA has announced its interest in developing "cyborg insects" to transmit data from sensors implanted into the insect during the pupal stage. The insect's motion would be controlled from a Micro-Electro-Mechanical System (MEMS) and could conceivably survey an environment or detect explosives and gas.[56] Similarly, DARPA is developing a neural implant to remotely control the movement of sharks. The shark's unique senses would then be exploited to provide data feedback in relation to enemy ship movement or underwater explosives.[57]

In 2006, researchers at Cornell University invented[58] a new surgical procedure to implant artificial structures into insects during their metamorphic development.[59][60] The first insect cyborgs, moths with integrated electronics in their thorax, were demonstrated by the same researchers.[61][62] The initial success of the techniques has resulted in increased research and the creation of a program called Hybrid-Insect-MEMS, HI-MEMS. Its goal, according to DARPA's Microsystems Technology Office, is to develop "tightly coupled machine-insect interfaces by placing micro-mechanical systems inside the insects during the early stages of metamorphosis".[63]

The use of neural implants has recently been attempted, with success, on cockroaches. Surgically applied electrodes were put on the insect, which were remotely controlled by a human. The results, although sometimes different, basically showed that the cockroach could be controlled by the impulses it received through the electrodes. DARPA is now funding this research because of its obvious beneficial applications to the military and other areas[64]

In 2009 at the Institute of Electrical and Electronics Engineers (IEEE) Micro-electronic mechanical systems (MEMS) conference in Italy, researchers demonstrated the first "wireless" flying-beetle cyborg.[65] Engineers at the University of California at Berkeley have pioneered the design of a "remote controlled beetle", funded by the DARPA HI-MEMS Program. Filmed evidence of this can be viewed here.[66] This was followed later that year by the demonstration of wireless control of a "lift-assisted" moth-cyborg.[67]

Eventually researchers plan to develop HI-MEMS for dragonflies, bees, rats and pigeons.[68][69] For the HI-MEMS cybernetic bug to be considered a success, it must fly 100 metres (330 ft) from a starting point, guided via computer into a controlled landing within 5 metres (16 ft) of a specific end point. Once landed, the cybernetic bug must remain in place.[68]

In sports

In 2016 the first cyborg Olympics were celebrated in Zurich Switzerland. Cybathlon 2016 were the first Olympics for cyborgs and the first worldwide and official celebration of cyborg sports. In this event, 16 teams of people with disabilities used technological developments to turn themselves into cyborg athletes. There were six different events and its competitors used and controlled advanced technologies such as powered prosthetic legs and arms, robotic exoskeletons, bikes and motorized wheelchairs.[70]

If on one hand this was already a remarkable improvement, as it allowed disabled people to compete and showed the several technological enhancements that are already making a difference, on the other hand it showed that there is still a long way to go. For instance, the exoskeleton race still required its participants to stand up from a chair and sit down, navigate a slalom and other simple activities such as walk over stepping stones and climb up and down stairs. Despite the simplicity of these activities, 8 of the 16 teams that participated in the event drop of before the start.[71]

Nonetheless, one of the main goals of this event and such simple activities is to show how technological enhancements and advanced prosthetic can make a difference in peoples' lives. The next Cybathlon is expected to occur in 2020

In art


Cyborg artist Moon Ribas founder of the Cyborg Foundation performing with her seismic sense implant at TED (2016)

The concept of the cyborg is often associated with science fiction. However, many artists have tried to create public awareness of cybernetic organisms; these can range from paintings to installations. Some artists who create such works are Neil Harbisson, Moon Ribas, Patricia Piccinini, Steve Mann, Orlan, H. R. Giger, Lee Bul, Wafaa Bilal, Tim Hawkinson and Stelarc.

Stelarc is a performance artist who has visually probed and acoustically amplified his body. He uses medical instruments, prosthetics, robotics, virtual reality systems, the Internet and biotechnology to explore alternate, intimate and involuntary interfaces with the body. He has made three films of the inside of his body and has performed with a third hand and a virtual arm. Between 1976–1988 he completed 25 body suspension performances with hooks into the skin. For 'Third Ear' he surgically constructed an extra ear within his arm that was internet enabled, making it a publicly accessible acoustical organ for people in other places.[72] He is presently performing as his avatar from his second life site.[73]

Tim Hawkinson promotes the idea that bodies and machines are coming together as one, where human features are combined with technology to create the Cyborg. Hawkinson's piece Emoter presented how society is now dependent on technology.[74]

Wafaa Bilal is an Iraqi-American performance artist who had a small 10 megapixel digital camera surgically implanted into the back of his head, part of a project entitled 3rd I.[75] For one year, beginning 15 December 2010, an image is captured once per minute 24 hours a day and streamed live to www.3rdi.me and the Mathaf: Arab Museum of Modern Art. The site also displays Bilal's location via GPS. Bilal says that the reason why he put the camera in the back of the head was to make an "allegorical statement about the things we don't see and leave behind."[76] As a professor at NYU, this project has raised privacy issues, and so Bilal has been asked to ensure that his camera does not take photographs in NYU buildings.[76]

Machines are becoming more ubiquitous in the artistic process itself, with computerized drawing pads replacing pen and paper, and drum machines becoming nearly as popular as human drummers. This is perhaps most notable in generative art and music. Composers such as Brian Eno have developed and utilized software which can build entire musical scores from a few basic mathematical parameters.[77]

Scott Draves is a generative artist whose work is explicitly described as a "cyborg mind". His Electric Sheep project generates abstract art by combining the work of many computers and people over the internet.[78]

Artists as cyborgs

Artists have explored the term cyborg from a perspective involving imagination. Some work to make an abstract idea of technological and human-bodily union apparent to reality in an art form utilizing varying mediums, from sculptures and drawings to digital renderings. Artists that seek to make cyborg-based fantasies a reality often call themselves cyborg artists, or may consider their artwork "cyborg". How an artist or their work may be considered cyborg will vary depending upon the interpreter's flexibility with the term. Scholars that rely upon a strict, technical description of cyborg, often going by Norbert Wiener's cybernetic theory and Manfred E. Clynes and Nathan S. Kline's first use of the term, would likely argue that most cyborg artists do not qualify to be considered cyborgs.[79] Scholars considering a more flexible description of cyborgs may argue it incorporates more than cybernetics.[80] Others may speak of defining subcategories, or specialized cyborg types, that qualify different levels of cyborg at which technology influences an individual. This may range from technological instruments being external, temporary, and removable to being fully integrated and permanent.[81] Nonetheless, cyborg artists are artists. Being so, it can be expected for them to incorporate the cyborg idea rather than a strict, technical representation of the term,[82] seeing how their work will sometimes revolve around other purposes outside of cyborgism.[79]

In body modification

As medical technology becomes more advanced, some techniques and innovations are adopted by the body modification community. While not yet cyborgs in the strict definition of Manfred Clynes and Nathan Kline, technological developments like implantable silicon silk electronics,[83] augmented reality[84] and QR codes[85] are bridging the disconnect between technology and the body. Hypothetical technologies such as digital tattoo interfaces[86][87] would blend body modification aesthetics with interactivity and functionality, bringing a transhumanist way of life into present day reality.

In addition, it is quite plausible for anxiety expression to manifest. Individuals may experience pre-implantation feelings of fear and nervousness. To this end, individuals may also embody feelings of uneasiness, particularly in a socialized setting, due to their post-operative, technologically augmented bodies, and mutual unfamiliarity with the mechanical insertion. Anxieties may be linked to notions of otherness or a cyborged identity.[88]

In popular culture

Cyborgs have become a well-known part of science fiction literature and other media. Although many of these characters may be technically androids, they are often referred to as cyborgs. Well-known examples from film and television include RoboCop, The Terminator, Evangelion, United States Air Force Colonel Steve Austin in both Cyborg and, as acted out by Lee Majors, The Six Million Dollar Man, Replicants from Blade Runner, Daleks and Cybermen from Doctor Who, the Borg from Star Trek, Darth Vader and General Grievous from Star Wars, Inspector Gadget, and Cylons from the 2004 Battlestar Galactica series. From comics, manga and anime are characters such as 8 Man (the inspiration for RoboCop), Kamen Rider, Ghost in the Shell's Motoko Kusanagi, as well as characters from western comic books like Tony Stark (after his Extremis and Bleeding Edge armor) and Victor "Cyborg" Stone. The Deus Ex videogame series deals extensively with the near-future rise of cyborgs and their corporate ownership, as does the Syndicate series. William Gibson's Neuromancer features one of the first female cyborgs, a "Razorgirl" named Molly Millions, who has extensive cybernetic modifications and is one of the most prolific cyberpunk characters in the science fiction canon.[89]

In space

Sending humans to space is a dangerous task in which the implementation of various cyborg technologies could be used in the future for risk mitigation.[90] Stephen Hawking, a renowned physicist, stated "Life on Earth is at the ever-increasing risk of being wiped out by a disaster such as sudden global warming, nuclear war... I think the human race has no future if it doesn't go into space." The difficulties associated with space travel could mean it might be centuries before humans ever become a multi-planet species.[citation needed] There are many effect of spaceflight on the human body. One major issue of space exploration is the biological need for oxygen. If this necessity was taken out of the equation, space exploration would be revolutionized. A theory proposed by Manfred E. Clynes and Nathan S. Kline is aimed at tackling this problem. The two scientists theorized that the use of an inverse fuel cell that is "capable of reducing CO2 to its components with removal of the carbon and re-circulation of the oxygen..."[91] could make breathing unnecessary. Another prominent issue is radiation exposure. Yearly, the average human on earth is exposed to approximately 0.30 rem of radiation, while an astronaut aboard the International Space Station for 90 days is exposed to 9 rem.[92] To tackle the issue, Clynes and Kline theorized a cyborg containing a sensor that would detect radiation levels and a Rose osmotic pump "which would automatically inject protective pharmaceuticals in appropriate doses." Experiments injecting these protective pharmaceuticals into monkeys have shown positive results in increasing radiation resistance.[91]

Although the effects of spaceflight on our body is an important issue, the advancement of propulsion technology is just as important. With our current technology, it would take us about 260 days to get to Mars.[93] A study backed by NASA proposes an interesting way to tackle this issue through deep sleep, or torpor. With this technique, it would "reduce astronauts' metabolic functions with existing medical procedures".[94] So far experiments have only resulted in patients being in torpor state for one week. Advancements to allow for longer states of deep sleep would lower the cost of the trip to mars as a result of reduced astronaut resource consumption.

In cognitive science

Theorists such as Andy Clark suggest that interactions between humans and technology result in the creation of a cyborg system. In this model "cyborg" is defined as a part biological, part mechanical system which results in the augmentation of the biological component and the creation of a more complex whole. Clark argues that this broadened definition is necessary to an understanding of human cognition. He suggests that any tool which is used to offload part of a cognitive process may be considered the mechanical component of a cyborg system. Examples of this human and technology cyborg system can be very low tech and simplistic, such as using a calculator to perform basic mathematical operations or pen and paper to make notes, or as high tech as using a personal computer or phone. According to Clark, these interactions between a person and a form of technology integrate that technology into the cognitive process in a way which is analogous to the way that a technology which would fit the traditional concept a cyborg augmentation becomes integrated with its biological host. Because all humans in some way use technology to augment their cognitive processes, Clark comes to the conclusion that we are "natural-born cyborgs".[95]

Cyborg Foundation

In 2010, the Cyborg Foundation became the world's first international organization dedicated to help humans become cyborgs.[96] The foundation was created by cyborg Neil Harbisson and Moon Ribas as a response to the growing number of letters and emails received from people around the world interested in becoming a cyborg.[97] The foundation's main aims are to extend human senses and abilities by creating and applying cybernetic extensions to the body,[98] to promote the use of cybernetics in cultural events and to defend cyborg rights.[99] In 2010, the foundation, based in Mataró (Barcelona), was the overall winner of the Cre@tic Awards, organized by Tecnocampus Mataró.[100]

In 2012, Spanish film director Rafel Duran Torrent, created a short film about the Cyborg Foundation. In 2013, the film won the Grand Jury Prize at the Sundance Film Festival's Focus Forward Filmmakers Competition and was awarded with $100,000 USD.[101]

The Future Scope and Regulation of Implantable Technologies

Given the technical scope of current and future implantable sensory/telemetric devices, these devices will be greatly proliferated, and will have connections to commercial, medical, and governmental networks. For example, in the medical sector, patients will be able to login to their home computer, and thus visit virtual doctor’s offices, medical databases, and receive medical prognoses from the comfort of their own home from the data collected through their implanted telemetric devices.[102] However, this online network presents huge security concerns because it has been proven by several U.S. universities that hackers could get onto these networks and shut down peoples’ electronic prosthetics.[102] These sorts of technologies are already present in the U.S. workforce as a firm in River Falls, Wisconsin called Three Square Market partnered with a Swedish firm called Biohacks Technology to implant RFID microchips in the hands of its employees (which are about the size of a grain of rice) that allow employees to access offices, computers, and even vending machines. More than 50 of the firms 85 employees were chipped. It was confirmed that the U.S. Food and Drug Administration approved of these implantations.[103] If these devices are to be proliferated within society, then the question that begs to be answered is what regulatory agency will oversee the operations, monitoring, and security of these devices? According to this case study of Three Square Market, it seems that the FDA is assuming the role in regulating and monitoring these devices.

Saturday, June 9, 2018

Telepresence

From Wikipedia, the free encyclopedia

A telepresence videoconferencing system in 2007

Telepresence refers to a set of technologies which allow a person to feel as if they were present, to give the appearance of being present, or to have an effect, via telerobotics, at a place other than their true location.

Telepresence requires that the users' senses be provided with such stimuli as to give the feeling of being in that other location. Additionally, users may be given the ability to affect the remote location. In this case, the user's position, movements, actions, voice, etc. may be sensed, transmitted and duplicated in the remote location to bring about this effect. Therefore information may be traveling in both directions between the user and the remote location.

A popular application is found in telepresence videoconferencing, the highest possible level of videotelephony. Telepresence via video deploys greater technical sophistication and improved fidelity of both sight and sound than in traditional videoconferencing. Technical advancements in mobile collaboration have also extended the capabilities of videoconferencing beyond the boardroom for use with hand-held mobile devices, enabling collaboration independent of location.

History

In a pioneering paper, the U.S. cognitive scientist Marvin Minsky attributed the development of the idea of telepresence to science fiction author Robert A. Heinlein: "My first vision of a remote-controlled economy came from Robert A. Heinlein's prophetic 1948 [sic] novel, Waldo," wrote Minsky. In his science fiction short story "Waldo" (1942), Heinlein first proposed a primitive telepresence master-slave manipulator system.

The Brother Assassin, written by Fred Saberhagen in 1969, introduced the complete concept for a telepresence master-slave humanoid system. In the novel, the concept is described as follows: "And a moment later it seemed to all his senses that he had been transported from the master down into the body of the slave-unit standing beneath it on the floor. As the control of its movements passed over to him, the slave started gradually to lean to one side, and he moved its foot to maintain balance as naturally as he moved his own. Tilting back his head, he could look up through the slave's eyes to see the master-unit, with himself inside, maintaining the same attitude on its complex suspension."


Early system for immersive telepresence (USAF, 1992 - Virtual Fixtures)

The term telepresence was coined in a 1980 article by Minsky, who outlined his vision for an adapted version of the older concept of teleoperation that focused on giving a remote participant a feeling of actually being present at a different location.[1] One of the first systems to create a fully immersive illusion of presence in a remote location was the Virtual Fixtures platform developed in 1992 at the U.S. Air Force, Armstrong Labs by inventor Louis Rosenberg. The system included stereoscopic image display from the remote environment as well as immersive touch feedback using a full upper-body exoskeleton.[2][3][4]

The first commercially successful telepresence company, Teleport (which was later renamed TeleSuite), was founded in 1993 by David Allen and Herold Williams.[5] Before TeleSuite, they ran a resort business from which the original concept emerged, because they often found businesspeople would have to cut their stays short to participate in important meetings. Their idea was to develop a technology that would allow businesspeople to attend their meetings without leaving the resorts so that they could lengthen their hotel stays.

A Tandberg E20 high resolution videoconferencing phone meant to replace conventional desktop phones

Hilton Hotels had originally licensed to install them in their hotels throughout the United States and other countries, but use was low. The idea lost momentum, with Hilton eventually backing out. TeleSuite later began to focus less on the hospitality industry and more on business-oriented telepresence systems. Shareholders eventually held enough stock to replace the company's original leadership, which ultimately led to its collapse.[citation needed] David Allen purchased all of the assets of TeleSuite and appointed Scott Allen as president [6] of the new company called Destiny Conferencing.

Destiny Conferencing licensed its patent portfolio to HP which became the first large company to join the telepresence industry, soon followed by others such as Cisco and Polycom.[7] After forming a distribution agreement with Pleasanton-based Polycom, Destiny Conferencing sold on January 5, 2007 to Polycom for $60 million.

An important research project in telepresence began in 1990. Located at the University of Toronto, the Ontario Telepresence Project (OTP) was an interdisciplinary effort involving social sciences and engineering. Its final report stated that it "...was a three year, $4.8 million pre-competitive research project whose mandate was to design and field trial advanced media space systems in a variety of workplaces in order to gain insights into key sociological and engineering issues. The OTP, which ended in December 1994, was part of the International Telepresence Project which linked Ontario researchers to their counterparts in four European nations. The Project’s major sponsor was the Province of Ontario, through two of its Centres of Excellence—the Information Technology Research Centre (ITRC) and the Telecommunications Research Institute of Ontario (TRIO)." [8]

Benefits


A modular telepresence system

An industry expert described some benefits of telepresence: "There were four drivers for our decision to do more business over video and telepresence. We wanted to reduce our travel spend, reduce our carbon footprint and environmental impact, improve our employees' work/life balance, and improve employee productivity.".[9]


American exile Edward Snowden participates in a TED talk in Texas from Russia via telepresence robot, March 2014

Rather than traveling great distances in order to have a face-face meeting, it is now commonplace to instead use a telepresence system, which uses a multiple codec video system (which is what the word "telepresence" most currently represents). Each member/party of the meeting uses a telepresence room to "dial in" and can see/talk to every other member on a screen/screens as if they were in the same room. This brings enormous time and cost benefits. It is also superior to phone conferencing (except in cost), as the visual aspect greatly enhances communications, allowing for perceptions of facial expressions and other body language.

Mobile collaboration systems combine the use of video, audio and on-screen drawing capabilities using newest generation hand-held mobile devices to enable multi-party conferencing in real-time, independent of location. Benefits include cost-efficiencies resulting from accelerated problem resolution, reductions in downtimes and travel, improvements in customer service and increased productivity.[10]

Implementation

Telepresence has been described as the human experience of being fully present at a live real-world location remote from one's own physical location. Someone experiencing video telepresence would therefore be able to behave, and receive stimuli, as though part of a meeting at the remote site. The aforementioned would result in interactive participation of group activities that would bring benefits to a wide range of users.[11]

Implementation of human sensory elements

To provide a telepresence experience, technologies are required that implement the human sensory elements of vision, sound, and manipulation.

Vision and sound

A minimum system usually includes visual feedback. Ideally, the entire field of view of the user is filled with a view of the remote location, and the viewpoint corresponds to the movement and orientation of the user's head. In this way, it differs from television or cinema, where the viewpoint is out of the control of the viewer.

In order to achieve this, the user may be provided with either a very large (or wraparound) screen, or small displays mounted directly in front of the eyes. The latter provides a particularly convincing 3D sensation. The movements of the user's head must be sensed, and the camera must mimic those movements accurately and in real time. This is important to prevent unintended motion sickness.

Another source of future improvement to telepresence displays, compared by some to holograms, is a projected display technology featuring life-sized imagery.[12]

Sound is generally the easiest sensation to implement with high fidelity, based on the foundational telephone technology dating back more than 130 years. Very high-fidelity sound equipment has also been available for a considerable period of time, with stereophonic sound being more convincing than monaural sound.

Manipulation


Monty, a telemanipulation prototype from Anybots

The ability to manipulate a remote object or environment is an important aspect for some telepresence users, and can be implemented in large number of ways depending on the needs of the user. Typically, the movements of the user's hands (position in space, and posture of the fingers) are sensed by wired gloves, inertial sensors, or absolute spatial position sensors. A robot in the remote location then copies those movements as closely as possible. This ability is also known as teleoperation.

The more closely the robot re-creates the form factor of the human hand, the greater the sense of telepresence. Complexity of robotic effectors varies greatly, from simple one axis grippers, to fully anthropomorphic robot hands.

Haptic teleoperation refers to a system that provides some sort of tactile force feedback to the user, so the user feels some approximation of the weight, firmness, size, and/or texture of the remote objects manipulated by the robot.

Freedom of movement


iRobot Ava 500, an autonomous roaming telepresence robot.

The prevalence of high quality video conferencing using mobile devices, tablets and portable computers has enabled a drastic growth in telepresence robots to help give a better sense of remote physical presence for communication and collaboration in the office, home or school when one cannot be there in person. The robot avatar can move or look around at the command of the remote person. Drivable telepresence robots – typically contain a display (integrated or separate phone or tablet) mounted on a roaming base. Some examples of roaming telepresence robots include Beam by Suitable Technologies, Double by Double Robotics, RP-Vita by iRobot, Anybots, Vgo, TeleMe by Mantarobot, and Romo by Romotive.[13]

More modern roaming telepresence robots may include an ability to operate autonomously. The robots can map out the space and be able to avoid obstacles while driving themselves between rooms and their docking stations.[14]

Effectiveness

Telepresence's effectiveness varies by degree of fidelity. Research has noted that telepresence solutions differ in degree of implementation, from "immersive" through "adaptive" to "lite" solutions.[15] At the top are immersive solutions where the environments at both ends are highly controlled (and often the same) with respect to lighting, acoustics, decor and furniture, thereby giving all the participants the impression they are together at the same table in the same room, thus engendering the "immersive" label.

Adaptive telepresence solutions may use the same technology, but the environments at both ends are not highly controlled and hence often differ. Adaptive solutions differ from telepresence lite solutions not in terms of control of environments, but in terms of integration of technology. Adaptive solutions use a managed service, whereas telepresence lite solutions use components that someone must integrate.

Transparency of implementation


A telepresence conference between participants in Ghana and Newark, New Jersey in 2012

A good telepresence strategy puts the human factors first, focusing on visual collaboration configurations that closely replicate the brain's innate preferences for interpersonal communications, separating from the unnatural "talking heads" experience of traditional videoconferencing. These cues include life–size participants, fluid motion, accurate flesh tones and the appearance of true eye contact.[16] This is already a well-established technology, used by many businesses today. The chief executive officer of Cisco Systems, John Chambers in June 2006 at the Networkers Conference compared telepresence to teleporting from Star Trek, and said that he saw the technology as a potential billion dollar market for Cisco.[17]

Rarely will a telepresence system provide such a transparent implementation with such comprehensive and convincing stimuli that the user perceives no differences from actual presence. But the user may set aside such differences, depending on the application.

The fairly simple telephone achieves a limited form of telepresence using just the human sensory element of hearing, in that users consider themselves to be talking to each other rather than talking to the telephone itself.

Watching television, for example, although it stimulates our primary senses of vision and hearing, rarely gives the impression that the watcher is no longer at home. However, television sometimes engages the senses sufficiently to trigger emotional responses from viewers somewhat like those experienced by people who directly witness or experience events. Televised depictions of sports events, or disasters such as the September 11 terrorist attacks, can elicit strong emotions from viewers.

As the screen size increases, so does the sense of immersion, as well as the range of subjective mental experiences available to viewers. Some viewers have reported a sensation of genuine vertigo or motion sickness while watching IMAX movies of flying or outdoor sequences.

Because most currently feasible telepresence gear leaves something to be desired; the user must suspend disbelief to some degree, and choose to act in a natural way, appropriate to the remote location, perhaps using some skill to operate the equipment. In contrast, a telephone user does not see herself as "operating" the telephone, but merely talking to another person with it.

Related technologies

Virtual presence (virtual reality)


An Online Video Web Conference in an office

Telepresence refers to a user interacting with another live, real place, and is distinct from virtual presence, where the user is given the impression of being in a simulated environment. Telepresence and virtual presence rely on similar user-interface equipment, and they share the common feature that the relevant portions of the user's experience at some point in the process will be transmitted in an abstract (usually digital) representation. The main functional difference is the entity on the other end: a real environment in the case of telepresence, vs. a computer in the case of immersive virtual reality.

Applications

Application examples could be cited within emergency management and security services, B&I, and the entertainment and education industries.[11]

Connecting communities

Telepresence can be used to establish a sense of shared presence or shared space among geographically separated members of a group.[citation needed]

Hazardous environments



Many other applications in situations where humans are exposed to hazardous situations are readily recognised as suitable candidates for telepresence. Mining, bomb disposal, military operations, rescue of victims from fire, toxic atmospheres, deep sea exploration, or even hostage situations, are some examples. Telepresence also plays a critical role in the exploration of other worlds, such as with the Mars Exploration Rovers, which are teleoperated from Earth.

Pipeline inspection

Small diameter pipes otherwise inaccessible for examination can now be viewed using pipeline video inspection.

Remote surgery

The possibility of being able to project the knowledge and the physical skill of a surgeon over long distances has many attractions. Thus, again there is considerable research underway in the subject. (Locally controlled robots are currently being used for joint replacement surgery as they are more precise in milling bone to receive the joints.) The armed forces have an obvious interest since the combination of telepresence, teleoperation, and telerobotics can potentially save the lives of battle casualties by allowing them prompt attention in mobile operating theatres by remote surgeons.

Recently, teleconferencing has been used in medicine (telemedicine or telematics), mainly employing audio-visual exchange, for the performance of real time remote surgical operations – as demonstrated in Regensburg, Germany in 2002.[18] In addition to audio-visual data, the transfer of haptic (tactile) information has also been demonstrated in telemedicine.[19]

Education


A professional development expert in Denver uses telepresence to coach a teacher in Utah during the initial research of Project ThereNow.

Research has been conducted on the use of telepresence to provide professional development to teachers. Research has shown that one of the most effective forms of teacher professional development is coaching, or cognitive apprenticeship. The application of telepresence shows promise for making this approach to teacher professional development practical.[20]

The benefits of enabling schoolchildren to take an active part in exploration have also been shown by the JASON and the NASA Ames Research Center programs. The ability of a pupil, student, or researcher to explore an otherwise inaccessible location is a very attractive proposition; For example, locations where the passage of too many people is harming the immediate environment or the artifacts themselves, e.g. undersea exploration of coral reefs, ancient Egyptian tombs, and more recent works of art.

Another application is for remote classroom which allows a professor to interact with students in multiple campuses to teach the same class simultaneously. An example of this application is in classrooms of the law schools of Rutgers University. Two identical rooms are located in two metropolitan areas. Each classroom is equipped with studio lighting, audio, and video conference equipment connected to a 200-inch monitor on the wall that students face to give an impression that they are all in the same classroom. This allows professors to be on either campus and facilitates the interaction among students in both campuses during the classes.[21]

Telepresence art

True telepresence is a multidisciplinary art and science that foundationally integrates engineering, psychology, and the art of television broadcast.

In 1998, Diller and Scofidio created the "Refresh", an Internet-based art installation that juxtaposed a live web camera with recorded videos staged by professional actors. Each image was accompanied with a fictional narrative which made it difficult to distinguish which was the live web camera.


A soap opera for iMacs

In 1993, Eduardo Kac and Ed Bennett created a telepresence installation "Ornitorrinco on the Moon", for the international telecommunication arts festival "Blurred Boundaries" (Entgrenzte Grenzen II). It was coordinated by Kulturdata, in Graz, Austria, and was connected around the world.

From 1997 to the present Ghislaine Boddington of shinkansen and body>data>space has explored, in a collaboration process she has called The Weave[22] using performing arts techniques, the extended use of telepresence into festivals, arts centres and clubs and has directed numerous workshops leading to exploration of telepresence by many artists worldwide. This methodology has been used extensively to develop skills in tele-intuition for young people in preparation for the future world of work through the body>data>space / NESTA project "Robots and Avatars" an innovative project explores how young people will work and play with new representational forms of themselves and others in virtual and physical life in the next 10–15 years.

An overview of tele-presence in dance and theatre through the last 20 years is given in Excited Atoms[23] a research document by Judith Staines (2009) which one can download from the On The Move website

Artificial intelligence

Marvin Minsky was one of the pioneers of intelligence-based mechanical robotics and telepresence. He designed and built some of the first mechanical hands with tactile sensors, visual scanners, and their software and computer interfaces. He also influenced many robotic projects outside of MIT, and designed and built the first LOGO "turtle."

Popular culture

Telepresence is represented in media and entertainment.

Literature

  • The Naked Sun (1957) – a novel mostly occurring on Solaria, a planet with an extremely low population where all personal contact is considered obscene, and all communication occurs through holographic telepresence.

Television

Film

Video games

Comics

  • Lamar Waldron's "M.I.C.R.A. Mind Controlled Remote Automaton" (1987), related the story of a college female paralyzed by a neck injury, who volunteered to be the remote pilot of an android body created by one of her professors.

Virtual reality communities

Cyberspace

From Wikipedia, the free encyclopedia

Cyberspace is interconnected technology. The term entered the popular culture from science fiction and the arts but is now used by technology strategists, security professionals, government, military and industry leaders and entrepreneurs to describe the domain of the global technology environment. Others consider cyberspace to be just a notional environment in which communication over computer networks occurs.[1] The word became popular in the 1990s when the uses of the Internet, networking, and digital communication were all growing dramatically and the term "cyberspace" was able to represent the many new ideas and phenomena that were emerging.[2] It has been called the largest unregulated and uncontrolled domain in the history of mankind,[3] and is also unique because it is a domain created by people vice the traditional physical domains.

The parent term of cyberspace is "cybernetics", derived from the Ancient Greek κυβερνήτης (kybernētēs, steersman, governor, pilot, or rudder), a word introduced by Norbert Wiener for his pioneering work in electronic communication and control science. This word cyberspace first appeared in the art installation of the same name by danish artist Susanne Ussing, 1968).[4]

As a social experience, individuals can interact, exchange ideas, share information, provide social support, conduct business, direct actions, create artistic media, play games, engage in political discussion, and so on, using this global network. They are sometimes referred to as cybernauts. The term cyberspace has become a conventional means to describe anything associated with the Internet and the diverse Internet culture. The United States government recognizes the interconnected information technology and the interdependent network of information technology infrastructures operating across this medium as part of the US national critical infrastructure. Amongst individuals on cyberspace, there is believed to be a code of shared rules and ethics mutually beneficial for all to follow, referred to as cyberethics. Many view the right to privacy as most important to a functional code of cyberethics.[5] Such moral responsibilities go hand in hand when working online with global networks, specifically, when opinions are involved with online social experiences.[6]

According to Chip Morningstar and F. Randall Farmer, cyberspace is defined more by the social interactions involved rather than its technical implementation.[7] In their view, the computational medium in cyberspace is an augmentation of the communication channel between real people; the core characteristic of cyberspace is that it offers an environment that consists of many participants with the ability to affect and influence each other. They derive this concept from the observation that people seek richness, complexity, and depth within a virtual world.

Origins of the term

The term “cyberspace” first appeared in the visual arts in the late 1960s, when Danish artist Susanne Ussing (1940-1998) and her partner architect Carsten Hoff (b. 1934) constituted themselves as Atelier Cyberspace. Under this name the two made a series of installations and images entitled “sensory spaces” that were based on the principle of open systems adaptable to various influences, such as human movement and the behaviour of new materials.[8]

Atelier Cyberspace worked at a time when the Internet did not exist and computers were more or less off-limit to artists and creative engagement. In a 2015-interview with Scandinavian art magazine Kunstkritikk, Carsten Hoff recollects, that although Atelier Cyberspace did try to implement computers, they had no interest in the virtual space as such:[8]
To us, "cyberspace" was simply about managing spaces. There was nothing esoteric about it. Nothing digital, either. It was just a tool. The space was concrete, physical.
And in the same interview Hoff continues:
Our shared point of departure was that we were working with physical settings, and we were both frustrated and displeased with the architecture from the period, particularly when it came to spaces for living. We felt that there was a need to loosen up the rigid confines of urban planning, giving back the gift of creativity to individual human beings and allowing them to shape and design their houses or dwellings themselves – instead of having some clever architect pop up, telling you how you should live. We were thinking in terms of open-ended systems where things could grow and evolve as required.
For instance, we imagined a kind of mobile production unit, but unfortunately the drawings have been lost. It was a kind of truck with a nozzle at the back. Like a bee building its hive. The nozzle would emit and apply material that grew to form amorphous mushrooms or whatever you might imagine. It was supposed to be computer-controlled, allowing you to create interesting shapes and sequences of spaces. It was a merging of organic and technological systems, a new way of structuring the world. And a response that counteracted industrial uniformity. We had this idea that sophisticated software might enable us to mimic the way in which nature creates products – where things that belong to the same family can take different forms. All oak trees are oak trees, but no two oak trees are exactly alike. And then a whole new material – polystyrene foam – arrived on the scene. It behaved like nature in the sense that it grew when its two component parts were mixed. Almost like a fungal growth. This made it an obvious choice for our work in Atelier Cyberspace.
The works of Atelier Cyberspace were originally shown at a number of Copenhagen venues and have later been exhibited at The National Gallery of Denmark in Copenhagen as part of the exhibition “What’s Happening?”[9]

The term "cyberspace" first appeared in fiction in the 1980s in the work of cyberpunk science fiction author William Gibson, first in his 1982 short story "Burning Chrome" and later in his 1984 novel Neuromancer.[10] In the next few years, the word became prominently identified with online computer networks. The portion of Neuromancer cited in this respect is usually the following:[11]
Cyberspace. A consensual hallucination experienced daily by billions of legitimate operators, in every nation, by children being taught mathematical concepts... A graphic representation of data abstracted from the banks of every computer in the human system. Unthinkable complexity. Lines of light ranged in the nonspace of the mind, clusters and constellations of data. Like city lights, receding.
Now widely used, the term has since been criticized by Gibson, who commented on the origin of the term in the 2000 documentary No Maps for These Territories:
All I knew about the word "cyberspace" when I coined it, was that it seemed like an effective buzzword. It seemed evocative and essentially meaningless. It was suggestive of something, but had no real semantic meaning, even for me, as I saw it emerge on the page.

Metaphorical

Don Slater uses a metaphor to define cyberspace, describing the "sense of a social setting that exists purely within a space of representation and communication ... it exists entirely within a computer space, distributed across increasingly complex and fluid networks." The term "Cyberspace" started to become a de facto synonym for the Internet, and later the World Wide Web, during the 1990s, especially in academic circles[12] and activist communities. Author Bruce Sterling, who popularized this meaning,[13] credits John Perry Barlow as the first to use it to refer to "the present-day nexus of computer and telecommunications networks". Barlow describes it thus in his essay to announce the formation of the Electronic Frontier Foundation (note the spatial metaphor) in June 1990:[14]
In this silent world, all conversation is typed. To enter it, one forsakes both body and place and becomes a thing of words alone. You can see what your neighbors are saying (or recently said), but not what either they or their physical surroundings look like. Town meetings are continuous and discussions rage on everything from sexual kinks to depreciation schedules. Whether by one telephonic tendril or millions, they are all connected to one another. Collectively, they form what their inhabitants call the Net. It extends across that immense region of electron states, microwaves, magnetic fields, light pulses and thought which sci-fi writer William Gibson named Cyberspace.
— John Perry Barlow, "Crime and Puzzlement", 1990-06-08
As Barlow, and the EFF, continued public education efforts to promote the idea of "digital rights", the term was increasingly used during the Internet boom of the late 1990s.

Virtual environments

Although the present-day, loose use of the term "cyberspace" no longer implies or suggests immersion in a virtual reality, current technology allows the integration of a number of capabilities (sensors, signals, connections, transmissions, processors, and controllers) sufficient to generate a virtual interactive experience that is accessible regardless of a geographic location. It is for these reasons cyberspace has been described as the ultimate tax haven.[15]

In 1989, Autodesk, an American multinational corporation that focuses on 2D and 3D design software, developed a virtual design system called Cyberspace.[16]

Recent definitions of Cyberspace

Although several definitions of cyberspace can be found both in scientific literature and in official governmental sources, there is no fully agreed official definition yet. According to F. D. Kramer there are 28 different definitions of the term cyberspace. See in particular the following links: "Cyberpower and National Security: Policy Recommendations for a Strategic Framework," in Cyberpower and National Security, FD Kramer, S. Starr, L.K. Wentz (ed.), National Defense University Press, Washington (DC) 2009; see also Mayer, M., Chiarugi, I., De Scalzi, N., https://www.academia.edu/14336129/International_Politics_in_the_Digital_Age.

The most recent draft definition is the following:
Cyberspace is a global and dynamic domain (subject to constant change) characterized by the combined use of electrons and electromagnetic spectrum, whose purpose is to create, store, modify, exchange, share and extract, use, eliminate information and disrupt physical resources. Cyberspace includes: a) physical infrastructures and telecommunications devices that allow for the connection of technological and communication system networks, understood in the broadest sense (SCADA devices, smartphones/tablets, computers, servers, etc.); b) computer systems (see point a) and the related (sometimes embedded) software that guarantee the domain's basic operational functioning and connectivity; c) networks between computer systems; d) networks of networks that connect computer systems (the distinction between networks and networks of networks is mainly organizational); e) the access nodes of users and intermediaries routing nodes; f) constituent data (or resident data). Often, in common parlance (and sometimes in commercial language), networks of networks are called Internet (with a lowercase i), while networks between computers are called intranet. Internet (with a capital I, in journalistic language sometimes called the Net) can be considered a part of the system a). A distinctive and constitutive feature of cyberspace is that no central entity exercises control over all the networks that make up this new domain.[17] Just as in the real world there is no world government, cyberspace lacks an institutionally predefined hierarchical center. To cyberspace, a domain without a hierarchical ordering principle, we can therefore extend the definition of international politics coined by Kenneth Waltz: as being "with no system of law enforceable." This does not mean that the dimension of power in cyberspace is absent, nor that power is dispersed and scattered into a thousand invisible streams, nor that it is evenly spread across myriad people and organizations, as some scholars had predicted. On the contrary, cyberspace is characterized by a precise structuring of hierarchies of power.[18]
The Joint Chiefs of Staff of the United States Department of Defense define cyberspace as one of five interdependent domains, the remaining four being land, air, maritime, and space.[19] See United States Cyber Command

Cyberspace as an Internet metaphor

While cyberspace should not be confused with the Internet, the term is often used to refer to objects and identities that exist largely within the communication network itself, so that a website, for example, might be metaphorically said to "exist in cyberspace".[20] According to this interpretation, events taking place on the Internet are not happening in the locations where participants or servers are physically located, but "in cyberspace". The philosopher Michel Foucault used the term heterotopias, to describe such spaces which are simultaneously physical and mental.

Firstly, cyberspace describes the flow of digital data through the network of interconnected computers: it is at once not "real", since one could not spatially locate it as a tangible object, and clearly "real" in its effects. Secondly, cyberspace is the site of computer-mediated communication (CMC), in which online relationships and alternative forms of online identity were enacted, raising important questions about the social psychology of Internet use, the relationship between "online" and "offline" forms of life and interaction, and the relationship between the "real" and the virtual. Cyberspace draws attention to remediation of culture through new media technologies: it is not just a communication tool but a social destination, and is culturally significant in its own right. Finally, cyberspace can be seen as providing new opportunities to reshape society and culture through "hidden" identities, or it can be seen as borderless communication and culture.[21]
Cyberspace is the "place" where a telephone conversation appears to occur. Not inside your actual phone, the plastic device on your desk. Not inside the other person's phone, in some other city. The place between the phones. [...] in the past twenty years, this electrical "space," which was once thin and dark and one-dimensional—little more than a narrow speaking-tube, stretching from phone to phone—has flung itself open like a gigantic jack-in-the-box. Light has flooded upon it, the eerie light of the glowing computer screen. This dark electric netherworld has become a vast flowering electronic landscape. Since the 1960s, the world of the telephone has cross-bred itself with computers and television, and though there is still no substance to cyberspace, nothing you can handle, it has a strange kind of physicality now. It makes good sense today to talk of cyberspace as a place all its own.
— Bruce Sterling, Introduction to The Hacker Crackdown
The "space" in cyberspace has more in common with the abstract, mathematical meanings of the term (see space) than physical space. It does not have the duality of positive and negative volume (while in physical space for example a room has the negative volume of usable space delineated by positive volume of walls, Internet users cannot enter the screen and explore the unknown part of the Internet as an extension of the space they are in), but spatial meaning can be attributed to the relationship between different pages (of books as well as web servers), considering the unturned pages to be somewhere "out there." The concept of cyberspace therefore refers not to the content being presented to the surfer, but rather to the possibility of surfing among different sites, with feedback loops between the user and the rest of the system creating the potential to always encounter something unknown or unexpected.

Video games differ from text-based communication in that on-screen images are meant to be figures that actually occupy a space and the animation shows the movement of those figures. Images are supposed to form the positive volume that delineates the empty space. A game adopts the cyberspace metaphor by engaging more players in the game, and then figuratively representing them on the screen as avatars. Games do not have to stop at the avatar-player level, but current implementations aiming for more immersive playing space (i.e. Laser tag) take the form of augmented reality rather than cyberspace, fully immersive virtual realities remaining impractical.

Although the more radical consequences of the global communication network predicted by some cyberspace proponents (i.e. the diminishing of state influence envisioned by John Perry Barlow[22]) failed to materialize and the word lost some of its novelty appeal, it remains current as of 2006.[6][23]
Some virtual communities explicitly refer to the concept of cyberspace, for example Linden Lab calling their customers "Residents" of Second Life, while all such communities can be positioned "in cyberspace" for explanatory and comparative purposes (as did Sterling in The Hacker Crackdown, followed by many journalists), integrating the metaphor into a wider cyber-culture.

The metaphor has been useful in helping a new generation of thought leaders to reason through new military strategies around the world, led largely by the US Department of Defense (DoD).[24] The use of cyberspace as a metaphor has had its limits, however, especially in areas where the metaphor becomes confused with physical infrastructure. It has also been critiqued as being unhelpful for falsely employing a spatial metaphor to describe what is inherently a network.[20]

Alternate realities in philosophy and art

Predating computers

A forerunner of the modern ideas of cyberspace is the Cartesian notion that people might be deceived by an evil demon that feeds them a false reality. This argument is the direct predecessor of modern ideas of a brain in a vat and many popular conceptions of cyberspace take Descartes's ideas as their starting point.

Visual arts have a tradition, stretching back to antiquity, of artifacts meant to fool the eye and be mistaken for reality. This questioning of reality occasionally led some philosophers and especially theologians[citation needed] to distrust art as deceiving people into entering a world which was not real (see Aniconism). The artistic challenge was resurrected with increasing ambition as art became more and more realistic with the invention of photography, film (see Arrival of a Train at La Ciotat), and immersive computer simulations.

Influenced by computers

Philosophy

American counterculture exponents like William S. Burroughs (whose literary influence on Gibson and cyberpunk in general is widely acknowledged[25][26]) and Timothy Leary[27] were among the first to extol the potential of computers and computer networks for individual empowerment.[28]

Some contemporary philosophers and scientists (e.g. David Deutsch in The Fabric of Reality) employ virtual reality in various thought experiments. For example, Philip Zhai in Get Real: A Philosophical Adventure in Virtual Reality connects cyberspace to the platonic tradition:
Let us imagine a nation in which everyone is hooked up to a network of VR infrastructure. They have been so hooked up since they left their mother's wombs. Immersed in cyberspace and maintaining their life by teleoperation, they have never imagined that life could be any different from that. The first person that thinks of the possibility of an alternative world like ours would be ridiculed by the majority of these citizens, just like the few enlightened ones in Plato's allegory of the cave.
Note that this brain-in-a-vat argument conflates cyberspace with reality, while the more common descriptions of cyberspace contrast it with the "real world".

A New Communication Model

The technological convergence of the mass media is the result of a long adaptation process of their communicative resources to the evolutionary changes of each historical moment. Thus, the new media became (plurally) an extension of the traditional media on the cyberspace, allowing to the public access information in a wide range of digital devices.[29] In other words, it is a cultural virtualization of human reality as a result of the migration from physical to virtual space (mediated by the ICTs), ruled by codes, signs and particular social relationships. Forwards, arise instant ways of communication, interaction and possible quick access to information, in which we are no longer mere senders, but also producers, reproducers, co-workers and providers. New technologies also help to “connect” people from different cultures outside the virtual space, what was unthinkable fifty years ago. In this giant relationships web, we mutually absorb each other’s beliefs, customs, values, laws and habits, cultural legacies perpetuated by a physical-virtual dynamics in constant metamorphosis (ibidem). In this sense, Professor Doctor Marcelo Mendonça Teixeira created, in 2013, a new model of communication to the virtual universe, based in Claude Elwood Shannon (1948) article "A Mathematical Theory of Communication".

Art

Having originated among writers, the concept of cyberspace remains most popular in literature and film. Although artists working with other media have expressed interest in the concept, such as Roy Ascott, "cyberspace" in digital art is mostly used as a synonym for immersive virtual reality and remains more discussed than enacted.[30]

Computer crime

Cyberspace also brings together every service and facility imaginable to expedite money laundering. One can purchase anonymous credit cards, bank accounts, encrypted global mobile telephones, and false passports. From there one can pay professional advisors to set up IBCs (International Business Corporations, or corporations with anonymous ownership) or similar structures in OFCs (Offshore Financial Centers). Such advisors are loath to ask any penetrating questions about the wealth and activities of their clients, since the average fees criminals pay them to launder their money can be as much as 20 percent.[31]

5-level model

In 2010, a five-level model was designed in France. According to this model, cyberspace is composed of five layers based on information discoveries: language, writing, printing, Internet, etc. This original model links the world of information to telecommunication technologies.

Popular culture examples

  • The anime Digimon is set in a variant of the cyberspace concept called the "Digital World". The Digital World is a parallel universe made up of data from the Internet. Similar to cyberspace, except that people could physically enter this world instead of merely using a computer.
  • The anime Ghost in the Shell is set in the future where cyberization of humanity is commonplace and the world is connected by a vast electronic network.
  • The CGI series, ReBoot, takes place entirely inside cyberspace, which is composed of two worlds: the Net and the Web.
  • In the film Tron, a programmer was physically transferred to the program world, where programs were personalities, resembling the forms of their creators.
  • In the film Virtuosity a program encapsulating a super-criminal within a virtual world simulation escapes into the "real world".
  • In the novel Simulacron-3 the author Daniel F. Galouye explores multiple levels of "reality" represented by the multiple levels of computer simulation involved.
  • The idea of "the matrix" in the film The Matrix resembles a complex form of cyberspace where people are "jacked in" from birth and do not know that the reality they experience is virtual.
  • In the televised remote controlled robot competition series Robot Wars, the Megahurtz and subsequently Terrorhurtz team and their robot were introduced as being "from Cyberspace", a nod to their online collaborative formation.
  • In the 1984 novel Neuromancer the author William Gibson introduces the idea of a virtual reality data space called "the Matrix".
  • The British 1960s spy/fantasy TV show The Avengers used antagonists called Cybernauts. Their nature, however, was merely that of murderous remote-controlled humanoid robots.

Inequality (mathematics)

From Wikipedia, the free encyclopedia https://en.wikipedia.org/wiki/Inequality...