The Wonders of Technology

The ppl over at lifeboat foundation are totally awesome. Not only for their beautiful webdesign, but because their content is super interesting.They’ve done a list on 10 materials to watch for in the (+/-)future. Can you imagine diamonds used as building materials? How about floating cities made from a foamed-up titanium/aluminum mixture? I’d actually love to hear your imaginings of a world with diamond buildings and floating cities – leave a comment if your imagination runs wild.

Special Report

10 Futuristic Materials

by Lifeboat Foundation Scientific Advisory Board member Michael Anissimov.

1. Aerogel

Aerogel protecting crayons from a blowtorch.

This tiny block of transparent aerogel is supporting a brick weighing 2.5 kg. The aerogel’s density is 0.1 g/cm3.
Aerogel holds 15 entries in the Guinness Book of Records, more than any other material. Sometimes called “frozen smoke”, aerogel is made by the supercritical drying of liquid gels of alumina, chromia, tin oxide, or carbon. It’s 99.8% empty space, which makes it look semi-transparent. Aerogel is a fantastic insulator — if you had a shield of aerogel, you could easily defend yourself from a flamethrower. It stops cold, it stops heat. You could build a warm dome on the Moon. Aerogels have unbelievable surface area in their internal fractal structures — cubes of aerogel just an inch on a side may have an internal surface area equivalent to a football field. Despite its low density, aerogel has been looked into as a component of military armor because of its insulating properties.

2. Carbon nanotubes

Carbon nanotubes are long chains of carbon held together by the strongest bond in all chemistry, the sacred sp2 bond, even stronger than the sp3 bonds that hold together diamond. Carbon nanotubes have numerous remarkable physical properties, including ballistic electron transport (making them ideal for electronics) and so much tensile strength that they are the only substance that could be used to build a space elevator. The specific strength of carbon nanotubes is 48,000 kN·m/kg, the best of known materials, compared to high-carbon steel’s 154 kN·/kg. That’s 300 times stronger than steel. You could build towers hundreds of kilometers high with it.

3. Metamaterials

“Metamaterial” refers to any material that gains its properties from structure rather than composition. Metamaterials have been used to create microwave invisibility cloaks, 2D invisibility cloaks, and materials with other unusual optical properties. Mother-of-pearl gets its rainbow color from metamaterials of biological origin. Some metamaterials have a negative refractive index, an optical property that may be used to create “Superlenses” which resolve features smaller than the wavelength of light used to image them! This technology is called subwavelength imaging. Metamaterials would used in phased array optics, a technology that could render perfect holograms on a 2D display. These holograms would be so perfect that you could be standing 6 inches from the screen, looking into the “distance” with binoculars, and not even notice it’s a hologram.

4. Bulk diamond

We’re starting to lay down thick layers of diamond in CVD machines, hinting towards a future of bulk diamond machinery. Diamond is an ideal construction material — it’s immensely strong, light, made out of the widely available element carbon, nearly complete thermal conductivity, and has among the highest melting and boiling points of all materials. By introducing trace impurities, you can make a diamond practically any color you want. Imagine a jet, with hundreds of thousands of moving parts made of fine-tuned diamond machinery. Such a craft would be more powerful than today’s best fighter planes in the way an F-22 is better than the Red Baron’s Fokker Dr.1.

5. Bulk fullerenes

Diamonds may be strong, but aggregated diamond nanorods (what I call amorphous fullerene) are stronger. Amorphous fullerene has a isothermal bulk modulus of 491 gigapascals (GPa), compared to diamond’s 442 GPa. As we see in the image, the nanoscale structure of the fullerene gives it a beautiful iridescent appearance. Fullerenes can be made substantially stronger than diamond, but for greater energy cost. After a “Diamond Age” we may eventually transition to a “Fullerene Age” as our technology gets even more sophisticated.

6. Amorphous metal

Amorphous metals, also called metallic glasses, consist of metal with a disordered atomic structure. They can be twice as strong as steel. Because of their disordered structure, they can disperse impact energy more effectively than a metal crystal, which has points of weakness. Amorphous metals are made by quickly cooling molten metal before it has a chance to align itself in a crystal pattern. Amorphous metals may the military’s next generation of armor, before they adopt diamondoid armor in mid-century. On the green side of things, amorphous metals have electronic properties that improve the efficiency of power grids by as much as 40%, saving us thousands of tons of fossil fuel emissions.

7. Superalloys

A superalloy is a generic term for a metal that can operate at very high temperatures, up to about 2000 °F (1100 °C). They are popular for use in the superhot turbine areas of jet engines. They are used for more advanced oxygen-breathing designs, such as the ramjet and scramjet. When we’re flying through the sky in hypersonic craft, we’ll have superalloys to thank for it.

8. Metal foam

Metal foam is what you get when you add a foaming agent, powdered titanium hydride, to molten aluminum, then let it cool. The result is a very strong substance that is relatively light, with 75–95% empty space. Because of its favorable strength-to-weight ratio, metal foams have been proposed as a construction material for space colonies. Some metal forms are so light that they float on water, which would make them excellent for building floating cities, like those analyzed by Marshall T. Savage in one of my favorite books, The Millennial Project.

9. Transparent alumina

Transparent alumina is three times stronger than steel and transparent. The number of applications for this are huge. Imagine an entire skyscraper or arcology made largely of transparent steel. The skylines of the future could look more like a series of floating black dots (opaque private rooms) rather than the monoliths of today. A huge space station made of transparent alumina could cruise in low Earth orbit without being a creepy black dot when it passes overhead. And hey… transparent swords!

10. E-textiles

If you meet up and talk to me in 2020, I’ll likely be covered in electronic textiles. Why carry some electronic gadget you can easily lose when we can just wear our computers? We’ll develop clothing that can constantly project the video of our choosing (unless it turns out being so annoying that we ban it). Imagine wearing a robe covered in a display that actually projects the night sky in realtime. Imagine talking to people over the “phone” just by making a hand gesture and activating electronics in your lapel, then merely thinking about what you want to say (thought-to-speech interfaces). The possibilities of e-textiles are limitless.

17 Definitions of the Technological Singularity

Reblog from Singularity Weblog posted by Socrates on April 18, 2012

17 Definitions of the Technological Singularity

The term singularity has many meanings.

The everyday English definition is a noun that designates the quality of being one of a kind, strange, unique, remarkable or unusual.

If we want to be even more specific, we might take the Wiktionary definition of the term, which seems to be more contemporary and easily comprehensible, as opposed to those in classic dictionaries such as the Merriam-Webster’s.

So, the Wiktionary lists the following five meanings:

singularity (plural singularities)

1. the state of being singular, distinct, peculiar, uncommon or unusual
2. a point where all parallel lines meet
3. a point where a measured variable reaches unmeasurable or infinite value
4. (mathematics) the value or range of values of a function for which a derivative does not exist
5. (physics) a point or region in spacetime in which gravitational forces cause matter to have an infinite density; associated with Black Holes

What we are most interested in, however, is the definition of singularity as a technological phenomenon — i.e. the technological singularity. Here we can find an even greater variety of subtly different interpretations and meanings. Thus it may help if we have a list of what are arguably the most relevant ones, arranged in a rough chronological order.

Seventeen Definitions of the Technological Singularity:

1. R. Thornton, editor of the Primitive Expounder

In 1847, R. Thornton wrote about the recent invention of a four function mechanical calculator:

“…such machines, by which the scholar may, by turning a crank, grind out the solution of a problem without the fatigue of mental application, would by its introduction into schools, do incalculable injury. But who knows that such machines when brought to greater perfection, may not think of a plan to remedy all their own defects and then grind out ideas beyond the ken of mortal mind!”

2. Samuel Butler

It was during the relatively low-tech mid 19th century that Samuel Butler wrote his Darwin among the Machines. In it, Butler combined his observations of the rapid technological progress of the Industrial Revolution and Charles Darwin’s theory of the evolution of the species. That synthesis led Butler to conclude that the technological evolution of the machines will continue inevitably until the point that eventually machines will replace men altogether. In Erewhon Butler argued that:

“There is no security against the ultimate development of mechanical consciousness, in the fact of machines possessing little consciousness now. A mollusc has not much consciousness. Reflect upon the extraordinary advance which machines have made during the last few hundred years, and note how slowly the animal and vegetable kingdoms are advancing. The more highly organized machines are creatures not so much of yesterday, as of the last five minutes, so to speak, in comparison with past time.”

3. Alan Turing

In his 1951 paper titled Intelligent Machinery: A Heretical Theory,  Alan Turing wrote of machines that will eventually surpass human intelligence:

“once the machine thinking method has started, it would not take long to outstrip our feeble powers. … At some stage therefore we should have to expect the machines to take control, in the way that is mentioned in Samuel Butler’s Erewhon.”

4. John von Neumann

In 1958 Stanislaw Ulam wrote about a conversation with John von Neumann who said that: ”the ever accelerating progress of technology … gives the appearance of approaching some essential singularity in the history of the race beyond which human affairs, as we know them, could not continue.” Neumann’s alleged definition of the singularity was that it is the moment beyond which “technological progress will become incomprehensibly rapid and complicated.”

5. I.J. Good, who greatly influenced Vernor Vinge, never used the term singularity itself. However, what Vinge later called singularity Good called intelligence explosion. By that I. J. meant a positive feedback cycle within which minds will make technology to improve on minds which once started will rapidly surge upwards and create super-intelligence:

“Let an ultraintelligent machine be defined as a machine that can far surpass all the intellectual activities of any man however clever. Since the design of machines is one of these intellectual activities, an ultraintelligent machine could design even better machines; there would then unquestionably be an “intelligence explosion,” and the intelligence of man would be left far behind. Thus the first ultraintelligent machine is the last invention that man need ever make.”

6. Vernor Vinge introduced the term technological singularity in the January 1983 issue of Omni magazine in a way that was specifically tied to the creation of intelligent machines:

“We will soon create intelligences greater than our own. When this happens, human history will have reached a kind of singularity, an intellectual transition as impenetrable as the knotted space-time at the center of a black hole, and the world will pass far beyond our understanding. This singularity, I believe, already haunts a number of science-fiction writers. It makes realistic extrapolation to an interstellar future impossible. To write a story set more than a century hence, one needs a nuclear war in between … so that the world remains intelligible.”

He later developed further the concept in his essay the Coming Technological Singularity (1993):

“Within thirty years, we will have the technological means to create superhuman intelligence. Shortly after, the human era will be ended. […] I think it’s fair to call this event a singularity. It is a point where our models must be discarded and a new reality rules. As we move closer and closer to this point, it will loom vaster and vaster over human affairs till the notion becomes a commonplace. Yet when it finally happens it may still be a great surprise and a greater unknown.”

It is important to stress that for Vinge the singularity could occur in four ways: 1. The development of computers that are “awake” and superhumanly intelligent. 2. Large computer networks (and their associated users) may “wake up” as a superhumanly intelligent entity. 3. Computer/human interfaces may become so intimate that users may reasonably be considered superhumanly intelligent. 4. Biological science may find ways to improve upon the natural human intellect.

7. Hans Moravec: 

In his 1988 book Mind Children, computer scientist and futurist Hans Moravec generalizes Moore’s Law to make predictions about the future of artificial life. Hans argues that starting around 2030 or 2040, robots will evolve into a new series of artificial species, eventually succeeding homo sapiens. In his 1993 paper The Age of Robots Moravek writes:

“Our artifacts are getting smarter, and a loose parallel with the evolution of animal intelligence suggests one future course for them. Computerless industrial machinery exhibits the behavioral flexibility of single-celled organisms. Today’s best computer-controlled robots are like the simpler invertebrates. A thousand-fold increase in computer power in this decade should make possible machines with reptile-like sensory and motor competence. Properly configured, such robots could do in the physical world what personal computers now do in the world of data–act on our behalf as literal-minded slaves. Growing computer power over the next half-century will allow this reptile stage will be surpassed, in stages producing robots that learn like mammals, model their world like primates and eventually reason like humans. Depending on your point of view, humanity will then have produced a worthy successor, or transcended inherited limitations and transformed itself into something quite new. No longer limited by the slow pace of human learning and even slower biological evolution, intelligent machinery will conduct its affairs on an ever faster, ever smaller scale, until coarse physical nature has been converted to fine-grained purposeful thought.”

8. Ted Kaczynski

In Industrial Society and Its Future (aka the “Unabomber Manifesto”) Ted Kaczynski tried to explain, justify and popularize his militant resistance to technological progress:

“… the human race might easily permit itself to drift into a position of such dependence on the machines that it would have no practical choice but to accept all of the machines decisions. As society and the problems that face it become more and more complex and machines become more and more intelligent, people will let machines make more of their decision for them, simply because machine-made decisions will bring better result than man-made ones. Eventually a stage may be reached at which the decisions necessary to keep the system running will be so complex that human beings will be incapable of making them intelligently. At that stage the machines will be in effective control. People won’t be able to just turn the machines off, because they will be so dependent on them that turning them off would amount to suicide.”

9. Nick Bostrom

In 1997 Nick Bostrom – a world-renowned philosopher and futurist, wrote How Long Before Superintelligence. In it Bostrom seems to embrace I.J. Good’s intelligence explosion thesis with his notion of superintelligence:

“By a “superintelligence” we mean an intellect that is much smarter than the best human brains in practically every field, including scientific creativity, general wisdom and social skills. This definition leaves open how the superintelligence is implemented: it could be a digital computer, an ensemble of networked computers, cultured cortical tissue or what have you. It also leaves open whether the superintelligence is conscious and has subjective experiences.”

10. Ray Kurzweil

Ray Kurzweil is easily the most popular singularitarian. He embraced Vernor Vinge’s term and brought it into the mainstream. Yet Ray’s definition is not entirely consistent with Vinge’s original. In his seminal book The Singularity Is Near Kurzweil defines the technological singularity as:

“… a future period during which the pace of technological change will be so rapid, its impact so deep, that human life will be irreversibly transformed. Although neither utopian nor dystopian, this epoch will transform the concepts that we rely on to give meaning to our lifes, from our business models to the cycle of human life, including death itself.”

11. Kevin Kelly, senior maverick and co-founder of Wired Magazine

Singularity is the point at which “all the change in the last million years will be superseded by the change in the next five minutes.”

12. Eliezer Yudkowsky

In 2007 Eliezer Yudkowsky pointed out that singularity definitions fall within three major schools: Accelerating Change, the Event Horizon, and the Intelligence Explosion. He also argued that many of the different definitions assigned to the term singularity are mutually incompatible rather than mutually supporting.  For example, Kurzweil extrapolates current technological trajectories past the arrival of self-improving AI or superhuman intelligence, which Yudkowsky argues represents a tension with both I. J. Good’s proposed discontinuous upswing in intelligence and Vinge’s thesis on unpredictability. Interestingly, Yudkowsky places Vinge’s original definition within the event horizon camp while placing his own self within the Intelligence Explosion school. (In my opinion Vinge is equally within the Intelligence Explosion and Event Horizon ones.)

13. Michael Anissimov

In Why Confuse or Dilute a Perfectly Good Concept Michael writes:

“The original definition of the Singularity centers on the idea of a greater-than-human intelligence accelerating progress. No life extension. No biotechnology in general. No nanotechnology in general. No human-driven progress. No flying cars and other generalized future hype…”

According to the above definition, and in contrast to his SIAI colleague Eliezer Yudkowsky, it would seem that Michael falls both within the Intelligence Explosion and Accelerating Change schools. (In an earlier article, Anissimov defines the singularity as transhuman intelligence.)

14. John Smart

On his Acceleration Watch website John Smart writes:

“Some 20 to 140 years from now—depending on which evolutionary theorist, systems theorist, computer scientist, technology studies scholar, or futurist you happen to agree with—the ever-increasing rate of technological change in our local environment is expected to undergo a permanent and irreversible developmentalphase change, or technological “singularity,” becoming either:

A. fully autonomous in its self-development,
B. human-surpassing in its mental complexity, or
C. effectively instantaneous in self-improvement (from our perspective),

or if only one of these at first, soon after all of the above. It has been postulated by some that local environmental events after this point must also be “future-incomprehensible” to existing humanity, though we disagree.”

15. James Martin

James Martin – a world-renowned futurist, computer scientist, author, lecturer and, among many other things, the largest donor in the history of Oxford University – the Oxford Martin School, defines the singularity as follows:

Singularity “is a break in human evolution that will be caused by the staggering speed of technological evolution.”

16. Sean Arnott: “The technological singularity is when our creations surpass us in our understanding of them vs their understanding of us, rendering us obsolete in the process.”

17. Qwiki: Definition of the Technological Singularity


As we can see there is a large variety of flavors when it comes to defining the technological singularity. I personally tend to favor what I would call the original Vingean definition, as inspired by I.J. Good’s intelligence explosion because it stresses both the crucial importance of self-improving super-intelligence as well as its event horizon-type of discontinuity and uniqueness. (I also sometimes define the technological singularity as the event, or sequence of events, likely to occur right at or shortly after the birth of strong artificial intelligence.)

At the same time, after all of the above definitions it has to be clear that we really do not know what the singularity is (or will be). Thus we are just using the term to show (or hide) our own ignorance.

But tell me – what is your own favorite definition of the technological singularity?

15 Futuristic Terms of Endearment

There are certain things that when traveling into the realm of future-speak, you simply must know. Here are some highlights of concepts and philosophies that are mucking about in the current-future spheres. Advance thanks to wikipedia, a wonderful compendium of information which has allowed me to create these definitions quickly and painlessly. Ah, cut and paste.


In computing, an avatar is the graphical representation of the user or the user’s alter ego or character. It may take either a three-dimensional form, as in games or virtual worlds, or a two-dimensional form as an icon in Internet forums and other online communities.It is an object representing the user.

Artificial Intelligence

Artificial intelligence (AI) is the intelligence of machines and the branch of computer science that aims to create it. AI textbooks define the field as “the study and design of intelligent agents” where an intelligent agent is a system that perceives its environment and takes actions that maximize its chances of success. John McCarthy, who coined the term in 1956, defines it as “the science and engineering of making intelligent machines.” Artifical intelligence takes the intelligence of humans, such as perception, natural language processing, problem solving and planning, learning and adaptation, and acting on the environment and applies them with machines, systems, and virtual objects.

The field was founded on the claim that a central property of humans, intelligence—the sapience of Homo sapiens—can be so precisely described that it can be simulated by a machine.This raises philosophical issues about the nature of the mind and the ethics of creating artificial beings, issues which have been addressed by myth, fiction and philosophy since antiquity. Artificial intelligence has been the subject of optimism, but has also suffered setbacks and, today, has become an essential part of the technology industry, providing the heavy lifting for many of the most difficult problems in computer science.

AI research is highly technical and specialized, deeply divided into subfields that often fail in the task of communicating with each other. Subfields have grown up around particular institutions, the work of individual researchers, and the solution of specific problems, resulting in longstanding differences of opinion about how AI should be done and the application of widely differing tools. The central problems of AI include such traits as reasoning, knowledge, planning, learning, communication, perception and the ability to move and manipulate objects.General intelligence (or “strong AI“) is still among the field’s long term goals.

Augmented Reality

Augmented reality (AR) is a live, direct or indirect, view of a physical, real-world environment whose elements are augmented by computer-generated sensory input such as sound, video, graphics or GPS data. It is related to a more general concept called mediated reality, in which a view of reality is modified (possibly even diminished rather than augmented) by a computer. As a result, the technology functions by enhancing one’s current perception of reality. By contrast, virtual reality replaces the real world with a simulated one.

Computer Simulation

A computer simulation, a computer model, or a computational model is a computer program, or network of computers, that attempts to simulate an abstract model of a particular system. Computer simulations have become a useful part of mathematical modeling of many natural systems in physics (computational physics), astrophysics, chemistry and biology, human systems in economics, psychology, social science, and engineering. Simulation of a system is represented as the running of the system’s model. It can be used to explore and gain new insights into new technology, and to estimate the performance of systems too complex for analytical solutions.


Consciousness is a term that refers to the relationship between the mind and the world with which it interacts. It has been defined as: subjectivity, awareness, the ability to experience or to feel, wakefulness, having a sense of selfhood, and the executive control system of the mind.


Cyberspace is the electronic medium of computer networks, in which online communication takes place. The term “cyberspace” was first used by the cyberpunk science fiction author William Gibson.

Now ubiquitous, in current usage the term “cyberspace” stands for the global network of interdependent information technology infrastructures, telecommunications networks and computer processing systems. 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. The term 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.


A cyborg, short for “cybernetic organism”, is a being with both biological and artificial (e.g. electronic, mechanical or robotic) parts.

The term cyborg is often applied to an organism that has enhanced abilities due to technology,though this perhaps oversimplifies the necessity of feedback for regulating the subsystem. The more strict definition of Cyborg is almost always considered as increasing or enhancing normal capabilities. While cyborgs are commonly thought of as mammals, they might also conceivably be any kind of organism and the term “Cybernetic organism” has been applied to networks, such as road systems, corporations and governments, which have been classed as such. The term can also apply to micro-organisms which are modified to perform at higher levels than their unmodified counterparts.

Fictional cyborgs are portrayed as a synthesis of organic and synthetic parts, and frequently pose the question of difference between human and machine as one concerned with morality, free will, and empathy.

Cyborg Manifesto

Cyborg theory was created by Donna Haraway in order to criticize traditional notions of feminism—particularly its strong emphasis on identity, rather than affinity. She uses the metaphor of a cyborg in order to construct a feminism that moves beyond dualisms and moves beyond the limitations of traditional gender, feminism, and politics. Marisa Olson‘s take on Haraway’s thoughts is a belief that there were no separations between bodies and objects; that our life force flows through us and out into the objects we make; thus there ought to be no distinction between the so-called real or natural organisms that nature produces and the artificial machines that humans make. Haraway’s conclusion: We are all cyborgs.

From the article Cyborgs:

Cyborgs not only disrupt orderly power structures and fixed interests but also signify a challenge to settled politics, which assumes that binary oppositions or identities are natural distinctions. Actually those oppositions are cultural constructions. Haraway underlines the critical function of the cyborg concept, especially for feminist politics. The current dualistic thinking involves a “logic of dominance” because the parts of the dualisms are not equivalent. Thus, the logic produces hierarchies that legitimize men dominating women, whites dominating blacks, and humans dominating animals. Instead, Haraway suggests that people should undermine these hierarchies by actively exploring and mobilizing the blurring of borders.

In the Cyborg Manifesto, she writes: “The cyborg does not dream of community on the model of the organic family, this time without the oedipal project. The cyborg would not recognize the Garden of Eden; it is not made of mud and cannot dream of returning to dust.”


I think google should be included here. And I think you should get to know about google, as they will surely be behind some developments in the future. But rather than give you a definition, I suggest: google it. It took me two tries to find their info. How long will it take you?


Nanotechnology (sometimes shortened to “nanotech“) is the study of manipulating matter on an atomic and molecular scale. Generally, nanotechnology deals with developing materials, devices, or other structures possessing at least one dimension sized from 1 to 100 nanometres. Quantum mechanical effects are important at this quantum-realm scale.

Nanotechnology is very diverse, ranging from extensions of conventional device physics to completely new approaches based upon molecular self-assembly, from developing new materials with dimensions on the nanoscale to direct control of matter on the atomic scale. Nanotechnology entails the application of fields of science as diverse as surface science, organic chemistry, molecular biology, semiconductor physics, microfabrication, etc.


A posthuman or post-human is a concept originating notably in the fields of science fiction, futurology, contemporary art, and philosophy. A posthuman would no longer be a human being, having been so significantly altered as to no longer represent the human species. Underlying this worldview is a core belief that the human species in its current form does not represent the end of our development, but rather its beginning. – Nick Bostrum, 1999

The Singularity

The Singularity Is Near: When Humans Transcend Biology is a 2005 update of Raymond Kurzweil‘s 1999 book, The Age of Spiritual Machines and his 1990 book The Age of Intelligent Machines. In it, as in the two previous versions, Kurzweil attempts to give a glimpse of what awaits us in the near future. He proposes a coming technological singularity, and how we would thus be able to augment our bodies and minds with technology. He describes the singularity as resulting from a combination of three important technologies of the 21st century: genetics, nanotechnology, and robotics (including artificial intelligence).

Technological singularity refers to the hypothetical future emergence of greater-than-human intelligence through technological means. Since the capabilities of such intelligence would be difficult for an unaided human mind to comprehend, the occurrence of a technological singularity is seen as an intellectual event horizon, beyond which events cannot be predicted or understood. Proponents of the singularity typically state that an “intelligence explosion” is a key factor of the Singularity where superintelligences design successive generations of increasingly powerful minds.


Technology is the making, usage, and knowledge of tools, machines, techniques, crafts, systems or methods of organization in order to solve a problem or perform a specific function. It can also refer to the collection of such tools, machinery, and procedures. Technologies significantly affect human as well as other animal species’ ability to control and adapt to their natural environments.


Transhuman or trans-human is a term that has been defined and redefined many times in history. In its contemporary usage, “transhuman” refers to an intermediary form between the human and the hypothetical posthuman.

It is a commitment to overcoming human limits in all their forms including extending lifespan, augmenting intelligence, perpetually increasing knowledge, achieving complete control over our personalities and identities and gaining the ability to leave the planet. Transhumanists seek to achieve these goals through reason, science and technology. – Vita More

Virtual Reality

Virtual reality (VR),is a term that applies to computer-simulated environments that can simulate physical presence in places in the real world, as well as in imaginary worlds. Most current virtual reality environments are primarily visual experiences, displayed either on a computer screen or through special stereoscopic displays, but some simulations include additional sensory information, such as sound through speakers or headphones. Some advanced, haptic systems now include tactile information, generally known as force feedback, in medical and gaming applications. Furthermore, virtual reality covers remote communication environments which provide virtual presence of users with the concepts of telepresence and telexistence or a virtual artifact (VA) either through the use of standard input devices such as a keyboard and mouse, or through multimodal devices such as a wired glove, the Polhemus, and omnidirectional treadmills.