Teleportation requires the destruction of an object's exact atomic configuration, while simultaneously, the same atomic configuration is being created somewhere else. Physicist Charles Bennett introduced the idea of teleportation when he figured out how to do so with a single photon. Although it is possible to teleport a single photon, it is highly unlikely that it will ever be possible to teleport a living being because the atomic configuration would be too complicated to destroy and remake at the same time. Teleportation would also require a device to destroy the being in one place, and then remake it in another place.
Teleportation is common is science fiction/ fantasy movies, but unfortunately, it will never be so in real life. As a group, we originally thought teleporters could someday be possible, but after researching the topic, every source told us that humans and other living creatures will never be teleportable. All 3 of the members of our group did research and all of us worked well together.
Sunday, October 20, 2013
Holographic Projections(Post 3): Rohan Kadambi, Nick Moore, Chris Wiggins
As a quick reminder, holography is a technique for displaying three dimensional objects, in essence it is the equivalent of a three dimensional picture or movie. It is not something you can touch but rather a bunch of light that simply looks like an object. In science fiction, this technology is often used to portray a super detailed map of an area or "live stream" someones appearance and have conversations with people far away, in a similar way to skype. The level of detail in sci fi varies but often these holograms can simply be conjured by a single projector onto any surface, or moved easily, ie. they do not rely on a special screen to be functional.
In real life, we are beginning to see these technologies pop up as companies are finding small tricks to create holograms. Although none of these companies can create holograms with level of detail or mobility of science fictions, they are showing promising signs.
http://www.avconcepts.com/holographic-projection/
For example, this company uses super reflective mylar and 45-degree angles along with a static screen to create the images. This set up allows an image to be created that appears to have depth, in essence a hologram. But this technology has its limits, up close it would not look nearly as good. Also, the tech requires a rather complicated/specific set up to function. Its something that could be set up in multiple locations, but not moved quickly. Specifically, this company advertises the ability to set up 3-D tele-presences so you could have a meeting with someone who was not there, or having a person interaction on stage with someone outside of the area. Although this technology is developing it still doesn't come close the standard set by sci fi.
Another problem faced by these developing technologies is the amount of data required to store the holographic image. It is QUITE difficult to "record" or calculate the many diffraction patterns for various objects. It gets even more complicated when you start having the objects move in the image. Light Blue Optics (http://lightblueoptics.com/videos/holographic-laser-projection-technology/), another company getting into the holographic projection business has found a small trickery to deal with this. Instead of having a computer figure out exactly what the image needs to look like, and what diffraction pattern needs to be returned, it makes a few rough estimates of the image. Then it plays these estimates back in quick succession. This causes your brain to interpolate what the object is supposed to look like and put the work on your brain. This makes it easy to display more complicated images, another step in a positive direction for the development of holographic projection.
In conclusion, holographic projection is not that crazy a technology. While there are some technical limitations at the current time, its not impossible for them to be overcome (http://electronics.howstuffworks.com/gadgets/high-tech-gadgets/holographic-environment1.htm). For example, one of the biggest problems is the computing power needed to calculate what data needs to be sent to the display. But computer processors are always getting faster and more efficient (Moore's Law[not Nick, one of the co-founders of IBM] states that the number of transistors on processors doubles about every 18 months). Another thing faster computers will aid is the smoothness of images, right now, its hard for the computers to create images fast enough. This makes the image look jerky, like playing a video game where the frames per second is way too low. Another technology that needs to be developed in order to aid holographic projections is new displays. Although there are technologies being developed to display virtual reality scenes, or three-dimensional displays, its not quite enough yet. For example, Oculus Rift, is a a video game console in beta-testing that immerses the user in a 3-D environment (http://www.oculusvr.com/). Its not quite perfect, but it works. Companies are also rolling out 3-D TV's, in essence these also create holograms. This technology is pretty "meh" some still require stereoscopic technologies (the two different colored glasses) to make the image appear real.
For example, this company uses super reflective mylar and 45-degree angles along with a static screen to create the images. This set up allows an image to be created that appears to have depth, in essence a hologram. But this technology has its limits, up close it would not look nearly as good. Also, the tech requires a rather complicated/specific set up to function. Its something that could be set up in multiple locations, but not moved quickly. Specifically, this company advertises the ability to set up 3-D tele-presences so you could have a meeting with someone who was not there, or having a person interaction on stage with someone outside of the area. Although this technology is developing it still doesn't come close the standard set by sci fi.
Another problem faced by these developing technologies is the amount of data required to store the holographic image. It is QUITE difficult to "record" or calculate the many diffraction patterns for various objects. It gets even more complicated when you start having the objects move in the image. Light Blue Optics (http://lightblueoptics.com/videos/holographic-laser-projection-technology/), another company getting into the holographic projection business has found a small trickery to deal with this. Instead of having a computer figure out exactly what the image needs to look like, and what diffraction pattern needs to be returned, it makes a few rough estimates of the image. Then it plays these estimates back in quick succession. This causes your brain to interpolate what the object is supposed to look like and put the work on your brain. This makes it easy to display more complicated images, another step in a positive direction for the development of holographic projection.
In conclusion, holographic projection is not that crazy a technology. While there are some technical limitations at the current time, its not impossible for them to be overcome (http://electronics.howstuffworks.com/gadgets/high-tech-gadgets/holographic-environment1.htm). For example, one of the biggest problems is the computing power needed to calculate what data needs to be sent to the display. But computer processors are always getting faster and more efficient (Moore's Law[not Nick, one of the co-founders of IBM] states that the number of transistors on processors doubles about every 18 months). Another thing faster computers will aid is the smoothness of images, right now, its hard for the computers to create images fast enough. This makes the image look jerky, like playing a video game where the frames per second is way too low. Another technology that needs to be developed in order to aid holographic projections is new displays. Although there are technologies being developed to display virtual reality scenes, or three-dimensional displays, its not quite enough yet. For example, Oculus Rift, is a a video game console in beta-testing that immerses the user in a 3-D environment (http://www.oculusvr.com/). Its not quite perfect, but it works. Companies are also rolling out 3-D TV's, in essence these also create holograms. This technology is pretty "meh" some still require stereoscopic technologies (the two different colored glasses) to make the image appear real.
In regard to how we did this work as a group it was relatively simple. Most conversing was done over Facebook chat, sending links back and forth, having small discussions. There were drafts with bulleted points about what to say written in google docs, but I (Rohan) ended up just putting everything into sentences to make things flow better. Things sound nicer when there is one voice making it all tied together.
Wormholes Period 5 Group 3 (Jeff, Shashank, JingJing) Post # 3
Wormholes
From our research we concluded that wormholes do exist and it is possible to travel through one, but there are many many implications. As mentioned in the post before, wormholes would collapse far too quickly to used as a form of transportation. But as mentioned before, it is possible to keep a wormhole up for long enough so that travel through it is possible. In order for it to be stable, exotic matter must be introduced into it.
What is exotic matter? Well scientifically it is matter with a negative energy density. This might sound counter intuitive but it simply means matter that is more than nothing. This seems almost impossible, because the most that one could do was to remove the matter itself and be left with just a vacuum. But with quantum physics, it has been proven that it is possible than an area in space can be less than nothing, and thus have a negative energy density, or its energy per unit of volume would be negative. As quoted from an article
"The concept of negative energy is not pure fantasy; some of its effects have even been produced in the laboratory. They arise from Heisenberg's uncertainty principle, which requires that the energy density of any electric, magnetic or other field fluctuate randomly. Even when the energy density is zero on average, as in a vacuum, it fluctuates."
Heisenberg's uncertainty principle suggests that the energy density of any field that is electric of magnetic fluctuates, so that of the field as a whole has an average of zero energy density, then some parts of the field would have a positive energy density, which also supports the fact that other places must have a negative energy density to counteract this positive density. "The concept of negative energy is not pure fantasy; some of its effects have even been produced in the laboratory. They arise from Heisenberg's uncertainty principle, which requires that the energy density of any electric, magnetic or other field fluctuate randomly. Even when the energy density is zero on average, as in a vacuum, it fluctuates."
Why is this negative energy necessary?
Through our research, we came across many physics topics that are still very complicated and hard to explain, but can be somewhat understandable. It is understood, through the work of Stephen Hawkings, that black holes radiate energy. Remember that wormholes consist of two black holes as mouths.
But how can a black hole radiate energy if not even light can escape it?
This comes into conflict with some laws of thermodynamics which state that energy is conserved. Because at a black holes horizon, the point "of no return" where not even light can escape, energy is only going in. In order to counteract this, because energy is always at a thermodynamic equilibrium, negative energy is being sucked in, which maintains the thermodynamic equilibrium. Therefore this negative energy, or exotic matter plays an important role in black holes.
Another way to think about it is because exotic matter has a negative energy, it would have a repulsive gravitational force, since the force of gravity is determined by the mass of the corresponding object. In simple terms it will be able to hold open the wormhole, in simple terms.
Simply put, it is possible to travel through wormholes, provided there is some way to pump in exotic energy.
But many other implications are still present. Where would we get the amount of energy needed to create a black hole, the amount of energy equal to a super nova? If negative energy were to be introduced into the black hole, then the ship traveling within it would have to have protection against this strong force of gravity. Also the fact that as gravity increases, time dilates, or slows down.
There are not many solutions to these other implications, but some solutions are to gather the amount of energy that is required, it can be harvested from an isolated reaction between matter and antimatter. One solution to the force of gravity that would affect the ship would be for the ship to have a gravitational barrier, which would keep the passengers safe. An example of this is the earths gravity field prevents anyone on earth from feeling the pull of the sun.
So conclusively, the ability to travel through wormholes is absolutely possible theoretically, but we are no where near being able to. Another, more closer idea that would allow travel at speeds faster than light is traveling through hyperspace. This idea is similar to wormholes, but not the same concept at all. Hyperspace involves traveling at speeds faster than light by traveling through a space-time bubble. The ship would be traveling in a bubble that contracts space time in front of the ship, while riding the wave of the expansion of this compression.
While all these technologies are far beyond our reach, that does not stop us from dreaming. The idea of being able to step through a tunnel on earth and end up in another galaxy within seconds is very science fictional indeed, but the fact that it has been proven through science and studied for decades gives us hope that one day this scientific idea will become reality.
Works Cited
HyperSpace and Wormholes for total idiots. Relicnews forums. Relicnews. 2 July 2004. Web. 19 October 2013.
Lawrence H. Ford and Thomas A. Roman. Negative Energy - Wormholes and Warpdrive-. Biblioteca PLeyades. Scientific America. January 2000. Web. 15 october 2013.
Nola Taylor Redd. What is a Wormhole? Space.com. 29 April 2013. Web. October 10 2013.
http://www.space.com/20881-wormholes.html
http://forums.relicnews.com/showthread.php?28599-Hyperspace-and-Wormholes-for-total-idiots
http://www.bibliotecapleyades.net/ciencia/negativeenergy/negativeenergy.htm
Period 1-Group 7 (Sarah Bien and Amanda Li): Post 3 on Artificial Intelligence
Through our research, our group concluded that AI is indeed a practical form of technology. Since we have become more aware of AI, it is clear that countless forms of AI already exist. As technology becomes increasingly advanced, AI at the same time becomes increasingly relevant in our daily lives. As for robots, however, there is currently much ongoing research and debate surrounding the ethical issues behind making robots more like humans.
For many people, the first thought that comes to mind when one thinks of AI is robots, and that a human-like robot - and therefore the entire concept of AI - is somewhat of a futuristic idea. While robots do comprise a large portion of current AI research, based on our definition of AI from our first post, it is the “ability of technology to perform tasks that would have previously required human intelligence.” Basically, anything that is programmed would be considered as AI. As mentioned in our first post, AI can be found everywhere in our daily lives. The recommendation programs on sites like Youtube and Pandora are examples of AI. In addition, video games, voice-recognition software, and credit card transactions are all controlled by AI. Companies and advertisements also use AI to maximize their sales. For instance, according to Will Browne, University of Reading, “AI is used in supermarkets to work out what products should be placed with other products, the colour and price the product should be compared to other products, and whether certain products should be stacked vertically or horizontally” (Hilpern) He says that companies invest large amounts of money in these kinds of technology to help them increase their profits.
Naturally, AI also includes the field of robotics. Robots have actually been around for a long time. For example, this video describes the abilities of Shakey in 1969, the very first mobile robot that could reason about its surroundings. http://www.youtube.com/watch?v=RhrLHkVuerc
Robotics are also employed extensively in manufacturing to increase production output, minimize mistakes, and decrease expenses. They are also used to “construct our cars, clean our floors and even perform delicate microsurgery on us“ (Hilpern). AI applications are increasing in the military, agricultural, and healthcare fields (Hilpern). More recent developments in robotics deal with, as mentioned in our second post, making robots more like humans. Researchers are looking into the inner workings of the brain, and, through brain emulation, trying to recreate the human brain through technology. Essentially, they are teaching robots how to learn and giving them emotions so that they can think and feel like humans. Also gaining attention is the creation of autonomous machines such as driverless cars, pilotless planes, and military drones. Driverless trains and military drones are already in use, and driverless cars are being announced in the market. In these cases, AI is operating vehicles and drones and replacing humans’ roles where they were once needed.
Of course, many ethical issues arise when discussing the humanization of robots and autonomous machines. Many people fear the domination of the world of a robot species if technology frees itself from human control. However, military expert Robert Finkelstein assures the public that this will never happen because robots have neither a survival instinct nor the ability to reproduce without human help (Turner). The mechanization of everything due to advancements in technology causes unemployment because workers are continually replaced by machines. What happens if a robot has emotions and a human wants to turn the robot off when the robot doesn’t want to be turned off (“The Rise”)? What are the ethical implications of having a robot as a sexual partner or as a slave (“Robot Ethics”)? Should robots be considered as individuals and be given the rights of an individual? As for autonomous vehicles, even though they are theoretically safer than human operators, “should a driverless car swerve to avoid pedestrians if that means hitting other vehicles or endangering its occupants?” (“Morals and the Machine”). Much of the debate surrounding robot ethics has culminated in a field called machine ethics, which aims to teach machines how to make moral decisions. However, the author of “Morals and the Machine” suggests collaboration from lawyers, engineers, policymakers, and ethicists to reach standards for the field of robotics.
AI is a rapidly developing field, and its implications for the future of humankind are tremendous. Its applications are both feasible and practical, as demonstrated by our research. In the future, researchers and engineers believe they will be able not only to create a humanoid robot species, but also control the weather, explore the universe, and cure diseases with artificially intelligent medicine. Even though AI and technology in general seems to be extremely beneficial to the human race, scientists and the public alike should always be aware of the ethical issues behind tampering with humanity.
An Interesting Podcast on the Ethics of Robots: http://www.robotspodcast.com/podcast/mp3/robots-20130419-episode128.mp3
Works Cited:
Hilpern, Kate. “Artificial Intelligence: Transforming the World We Live In.” The Independent. The Independent. 26 Oct. 2007. Web. 19 Oct. 2013.
Turner, Bambi. “10 Ways Artificial Intelligence Will Affect Our Lives.” Discovery. Discovery Communications, LLC. 2013. Web. 19 Oct. 2013.
“Morals and the Machine.” The Economist. The Economist Newspaper Limited. 2 June 2012. Web. 19 Oct. 2013.
Lin, Patrick, Keith Abney, and George Bekey. “Robot Ethics: The Ethical and Social Implications of Robotics.” The MIT Press. MIT. 2013. Web. 19 Oct. 2013.
Group Evaluation:
Between Amanda and I, we were able to work together on our posts by using google documents in order to ensure that we all had equal portions of work for each post. We also discovered that our topic was much more elaborate than we expected and found interesting research such as videos and articles to add to our posts. Unfortunately, our work was only between two members, and the other member did not contribute in any of the posts. Even with consistent emails, communication in class, and reminders, the other member was not able to add anything to the work.
Group Evaluation:
Between Amanda and I, we were able to work together on our posts by using google documents in order to ensure that we all had equal portions of work for each post. We also discovered that our topic was much more elaborate than we expected and found interesting research such as videos and articles to add to our posts. Unfortunately, our work was only between two members, and the other member did not contribute in any of the posts. Even with consistent emails, communication in class, and reminders, the other member was not able to add anything to the work.
Genetics Post #3 Kat, Raisa, Anni
Katie, Raisa, Anni
Through research, we have found that it is in fact possible to use cross species genetics. Not only is this possible, but it is also a very helpful field of science that can help cure diseases and figure out the evolution of traits among organisms. This understanding also leads to the ability to alter genes, such as in the GMOs as discussed in post 2. Genetically modified organisms can have very desired benefits, including resisting insects, viruses, and tolerate herbicides (GMO Facts). Another important advancement is curing diseases. Not only Parkinsons can be better understood, but so can many other issues, like bipolar disorder and Alzheimer's (Cell Press and Magnus)
The concept Dr. Connors and Peter Parker explore in The Amazing Spiderman reaches validity with the scientific research of the mouse and human homologous chromosomes. Research has shown that the neurobehavioral traits of mice and humans are very similar, thus the genes can be overlapping with the same neurobiological mechanisms that deal with bipolar. Rudolf Magnus, of the University of Medical Center Utretcht, Netherlands, explores how mouse chromosome 15 is homologous with the human gene region 8q24 and chromosome 19 with region 10q23-24 (Magnus). With Alzheimer’s, scientists have found that the fruit fly and humans share a similarity. Philip L. De Jager, of Brigham and Women’s Hospital, says that this is an important pathway of the future (Cell Press).
This group project went without any major hassles. There was a collaborative group effort. I do think that there was a lack of communication among group members. In the end, the work was divided up equally.
Works Consulted
Cell Press. "Cross-species strategy might be a powerful tool for studying human disease."ScienceDaily,
Feb. 2011. Web. 20 Oct. 2013.
“GMO Facts.” Non GMO Project. N.p. Non-GMO Project. Web. 20 October 2013.
Magnus, Rudolf. “Cross-species genetics converge to TLL2 for mouse avoidance behavior and human
bipolar disease.” US National Library of Medicine. 12 August 2013. National Center for
Biotechnology Information. Web. 20 October 2013.Saturday, October 19, 2013
Lightsabers Derek/Carter Episode III: Revenge of the Critics
In order to wield a lightsaber, one
of the most dangerous weapons in the universe, one can simply go to their local
supermarket and buy a light-up child’s toy (and batteries) that would visually amuse
him/her for days. Or you could do what Harvard and MIT scientists did and accidentally
create one. Well, actually, what they created was not exactly a Jedi’s weapon
of choice, but instead a photon beam that acted as one. The article we talked
about in post 2 proved that photons can in fact interact with each other. But this
does not make lightsabers feasible, unless you consider majoring in physics at
Harvard or MIT “Jedi Training”. 
Only highly trained scientists can operate this
kind of energy at this point; and besides, part of the whole allure of a
lightsaber is the hilt. Watching the colorful beam of light slowly rise out of
the handle is as much a part of a lightsaber as any. And at this point in time
in science, getting a controlled photon
beam into a hilt is just not feasible.
This site
brings up a lot of problems with the idea of infusing the photon beam with a
handle such as creating a short enough blade, controlling the size, and perhaps
most importantly, powering the beam. Unlike the toy replica, batteries would
not be enough to power a real life lightsaber (this is really the only
difference between the two). The only possible way to generate enough energy to
power this weapon would be to plug it in to the mains socket. But I assume
saber battles would be much less intense if you could not do all the cool
jumping and dodging that Jedi do, and instead had to settle with standing right
next to each other while you were charging your weapons. You could try
unplugging the sabers and fighting with them after they are fully charged, but
since photon lasers would burn through energy so quickly, it could turn into 20
second fight sessions, with constant hour-long recharge timeouts. And sizing
issues will be a problem. How will these photon beams end. They are not like a
stick or anything solid for that matter. They are simply just light beams. The
beams used for lightsabers must have a set length created for the saber to
actually be weapon and not just a glorified flashlight.
There is
another problem that Carter and I thought of that has to do less with feasibility
and more with affectivity. In the movies, the Jedi and their lightsabers
dominate their gun-wielding foes. One Jedi can take out 100 gunmen (or
gunwomen) just like that. But even if this weapon was created, in modern
warfare it would not be effective. 
The quote “never bring a knife to a gunfight”
fits perfectly with this situation. In the battlefield a Jedi would not stand a
chance against highly trained soldiers. The only way a Jedi could beat a
soldier in combat was if the soldier was this guy:
The quote “never bring a knife to a gunfight”
fits perfectly with this situation. In the battlefield a Jedi would not stand a
chance against highly trained soldiers. The only way a Jedi could beat a
soldier in combat was if the soldier was this guy:
The only difference would be that saying “your stepfather
was slain by a Jedi” would sound a lot cooler than “your stepfather was run
over by a steamroller”. But in all seriousness, hand to hand combat would always
be trumped by gun fighting. The irony is when we were kids we thought lightsabers
were so futuristic and high-tech, but on the battlefield they have the same
qualities as swords: outdated and ineffective.
In the movies, George Lucas did not
have to think about all these flaws in lightsabers, because he could just use “the
force” as the excuse for everything. I mean, how could a 900 year old creature
move like this?
The force. That’s how.
But Carter and I sought deeper for the truth, so we went to
the most reliable place in the world to research our topic: The internet. We
used multiple sites and conversed with each other what argument each site
brought up and whether we agreed with it or not. Our initial thoughts were
actually pretty accurate: Lightsabers may soon be feasible, but they are not
yet.
Time Travel Pt 3 (Alec, Jack, Robert, Max)
After much debate and discussion on many theories and possibilities, our group has determined that the technology of time travel is completely unfeasible. Time travel is defined as “the hypothetical process of moving between past and future”; now depending how you interpret that definition, you may disagree with my earlier statement. As Robert previously posted, time travel at its most basic occurs every day. The clock transitioning from 12:00 to 12:01 could constitute as time travel. However, it’s the virtual definition that comes to mind when we think of time travel. While a one minute change may seem normal, the clock going from 12:00 to 12:02 is a completely different concept. That is just a small magnitude of how we perceive time travel.
Despite many theories and claims, time travel is not possible for one reason. Given the resources and technology we have in 2013, how come it has never happened? Better yet, if time travel is possible how come no one from the year 2034 has travelled back in time to 2013? Time travel is not possible because it goes against the law of physics.
Moving forward to a more factual standpoint, there is an overwhelming amount of evidence that proves time travel is not possible. First, the most well-known data against time travel is an equation. E=MC^2, Energy equals mass times the speed of light squared, an equation that Albert Einstein created to show that nothing can be faster than the speed of light. Physicists in Hong Kong proved that a single proton obeyed this theory, proving that time travel is completely unfeasible. The article goes on to state that “By showing that single photons cannot travel faster than the speed of light, our results bring a closure to the debate on the true speed of information carried by a single photon.” What this means is that these scientists tested the lowest common denominator. They tested the one thing that could of had a chance of actually being faster than the speed of light, since nothing is more pure than a proton. In order for time travel to occur, you must be able to move faster than the speed of light. Since nothing else on this earth can do that, time travel is not possible.
On the contrary, with the constantly changing field of physics and development of technology, who knows what could happen in the future. We most likely won’t be alive to see it, but if technology evolves enough, then time travel may just be a possibility. Although it may not necessarily lead to time travel, one possibility is solving the mystery of how certain particles “communicate with each other instantaneously with each other faster than the speed of light.” This could lead to a development in time travel.
Works Cited:
Howell, Elizabeth. "Time Travel: Theories, Paradoxes & Possibilities." Space.com. N.p., 21 June
2013. Web. 19 Oct. 2013.
AFP. "Discovery News." DNews. N.p., 24 July 2011. Web. 19 Oct. 2013.
Porter, Kevin. "Why Time Travel Is Impossible." HubPages. N.p., n.d. Web. 19 Oct. 2013.
"Einstein's Theory of General Relativity." Space.com. N.p., n.d. Web. 19 Oct. 2013.
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