Friday, February 25, 2011

Artificial intelligence in video games

Collin kliewe

Introduction

Technology has been improving at an alarming rate in recent years. What we take as entertainment today was sci-fi to the people of the past few generations. For example, you know those recordable birthday cards? The chip inside is more advanced then any technology in world war 2! now we have entertainment such as video games with non-player characters (npc's) that emulate humans! In this project I will be discussing the AI in video games.



Humble beginning


The first game that really “made decisions” based on player input was the classic shoot and evade game Space invaders. Space invaders is a 2D space shooter, in japan it was so popular it caused a national coin shortage! There are two reasons (the developers say) that made space invaders so appealing, one was the music, going faster and faster it was designed to make your heart beat faster and get you nervous. The other reason was its innovative enemy behavior. Space invaders was the inspiration for Galaxian (and eventually Galaga).


AI Today

Today video game AI is much more advanced, one brand of AI in particular. First person shooter (fps) AI is by far the most advanced. In the past few years developers worked day and night to get enemies not to bump into walls, forget important things (like where the player was last seen) and to act more realistic in general.

Here is a (partial) list of what developers of non-player characters have to accomplish:


  1. alertness level: is the character in a combat mindset? Are they talking to their buddy? Perhaps they are leaning against the wall outside smoking a cigarette? Are they in a warzone, or a fortress? How about Both? Are they guarding something? Do they hear gunfire? Has something suspicious happened?

  2. Goal:

      a. immediate goal: find cover. Reload. Sneak up on player. Call for backup. Etc

      b. broad goal: base infiltration. Guard duty. Sniper. Ambush. Scout out ahead. Etc

    1. combat: what adversary is the biggest threat to me? What enemy is the most vulnerable? Am I in the enemies line of sight? Do I need to change my immediate goal?

As you can see even the most basic of combat AI is highly complex. Not to mention realistic movement, believable reactions and of course the most difficult of all, human error.

Here is a flow chart of a simple capture the flag ai:

http://www.apartment167.com/overload/showcase/CTF4/CTF4_AI_Flowchart.jpg


Impact on world



video game ai has been utilized in many different platforms. Watson the ibm computer that competed on jeopardy uses a direct descendant of early video games.

Sunday, February 20, 2011

The Gyroscope: by CJ Price

I. Introduction
The gyroscope is a spinning wheel on a movable axis or axes. It was invented in 1852 by Jean Bernard Leon Foucault, a French scientist and physicist. Having normal physical properties when stationary, the gyroscope behaves interestingly when the wheel is spun. It is used for navigational purposes and has recently been incorporated into the iPhone.

Figure 1: Three Gyroscopes Balancing On Top of Each Other

II. Invention

To invent the gyroscope, Foucault took a heavy wheel, attached it to a shaft, and spun it very quickly. After experimenting with its properties, he realized that this new invention had many practical uses. For example, navigators or travelers could use a gyroscope to "detect deviations from a straight course" (http://www.madehow.com). Also, the gyroscope could be used to help stabilize machines and monitor motors. Therefore, Foucault created devices related to his gyroscope that effectively monitored engine velocity. These devices were used in big steam engines and telescope clock-drives. For demonstrations on how a gyroscope works and how it is currently used, see the links below.
Figure 2: Gyroscope Model

III. Inventor

Jean Bernard Leon Foucault was born on September 19, 1819, in Paris, France. He had a lot of success working as an experimental physicist. Foucault also shared many of the same scientific beliefs as Galileo. For example, they both believed that "experimentation and innovation were the best ways to accurately assess the properties of the natural world" (http://www.madehow.com). In 1852, Foucault invented the gyroscope, and he also invented the pendulum in 1851. He used the pendulum to prove that the earth rotates on its axis by performing a huge demonstration with a massive pendulum. Furthermore, he was the first man to photograph the surface of the sun, he proved that humans have binocular vision, and he amazingly measured the speed of light by using rotating mirrors in his laboratory. Jean Bernard Leon Foucault died on February 11, 1868, in France.

Figure 3: Jean Bernard Leon Foucault

IV. Impact on the World/Humanity

The gyroscope has had a surprisingly significant impact on the world; it is used on planes and even in iPhones. On airplanes, the gyroscope's position compared to the airplane's position tells the pilot how much the airplane is tilting. This is very valuable information when the pilot needs to make turns, allowing the plane's turns to be accurate and precise. Therefore, the gyroscope plays a vital role in the efficiency and safety of airplane flights. Also, the gyroscope is used to enhance the technology and capabilities of appliances such as the iPhone. Although this is not a necessary addition, it is still fun to play games, like Jenga, that seem even more realistic than before the gyroscope technology was added (see video).

V. Journal Article Review

In my journal article, a group of scientists were studying how to make a 30-gram aircraft that flies indoors and avoids obstacles and maintains altitude independently using technology involving a gyroscope. To start their experiment, they first used their technology on a rolling robot. It was able to move indoors for over forty-five minutes without crashing into any obstacles. Then, the scientists tested the actual 30-gram aircraft. It was able to fly for over four minutes without a collision. Although their design is not perfect, the group of scientists believe their general strategy will one day produce their desired results.

VI. References

Foucault -- 19th Century Physicist. (n.d.). Welcome to LoST ART. Retrieved February 20, 2011, from http://helix.gatech.edu/Classes/ME2202/2000S3/Projects/Swarner/foucault.htm

Gyroscopes - Elmer Sperry and Charles Stark Draper Gyroscopes. (n.d.). Inventors. Retrieved February 20, 2011, from http://inventors.about.com/library/inventors/blgyroscope.htm

Jean-Bernard-Léon Foucault Biography (1819-1868). (n.d.). How Products Are Made. Retrieved February 20, 2011, from http://www.madehow.com/inventorbios/39/Jean-Bernard-L-on-Foucault.html

Practical Management. (n.d.). Retrieved February 20, 2011, from http://www.practicalmanagementllc.com

Science Clarified. (n.d.). Retrieved February 20, 2011, from http://www.scienceclarified.com

YouTube - Gyroscope. (n.d.). YouTube - Broadcast Yourself. Retrieved February 20, 2011, from http://www.youtube.com/watch?v=cquvA_IpEsA

YouTube - iPhone 4's new gyroscope. (n.d.). YouTube - Broadcast Yourself. Retrieved February 20, 2011, from http://www.youtube.com/watch?v=ORcu-c-qnjg

Zufferey, J., & Floreano, D. (n.d.). Toward 30-gram Autonomous Indoor Aircraft: Vision-based Obstacle Avoidance and Altitude Control.

Progeria - Donato DiNorcia

I. Introduction
Progeria was first described in 1886 by Jonathan Hutchinson and also described independently in 1897 by Hastings Gilford. The rare condition was later named Hutchinson-Gilford Progeria syndrome (HGPS). Progeria is an extremely rare condition in which aging is accelerated. Some symptoms other than the accelerated aging include: Limited growth, alopecia, and as the child gets older, their appearance changes (they tend to have a small face and jaw, pinched nose). People usually have small and very fragile bodies, like an older person and, later in life, they develop wrinkly skin, atherosclerosis (which is a condition that an artery wall thickens as the result of a build-up of fatty materials such as cholesterol, which causes heart complications), and cardiovascular problems. Progeria is a very unfortunate disorder that affects 1 in every 4 million people. For the most part, also, you live to be approximately 13 years old (even though there have been a few exceptions to that) and, to add to the sadness, there is not treatment for progeria.

II. Causes of progeria
Progeria is caused by a mutation in the LMNA gene, replacing cytosine with thymine, which then creates an unstable form of the protein Lamin A. Lamin A is part of the building blocks of the nuclear envelope. Progeria is not caused by defective DNA repair, (like many other “age affecting” disorders) Progeria is diagnosed pretty much according to the signs and symptoms. Progeria is NOT inherited. It is considered to be an autosomal dominant condition, which means, in each cell, one copy of the mutated gene is sufficient to cause the disorder. The condition results from new mutations in the LMNA gene, and almost always occurs in people with no history of the disorder in their family.


III. Symptoms
• A pinched nose
• Cardiovascular diseases
• Tumor formation
• Small jaw
• Loss of hair (alopecia)
• Scaly skin
• Voice is high pitched
• Wide eyed
• Beak shaped nose
• Head enlargement
• Diabetic
• Generalized atherosclerosis
• Thin skin
• Short in height
• Wrinkled skin on face
• Tooth formation is delayed
• Mentally stable, but physical differences
• Motion is limited
• Osteoarthritis
• Stiff joints
• Eyelashes and eyebrows are close to absent
• Narrow face
• Growth failure usually takes place during the first year of being born
• Veins visible on scalp
• Age spots
• Ears stick out
• Cataract
*List taken from-- http://www.buzzle.com/articles/progeria-facts.html

IV. What makes progeria so… “bad”?

• The average person who has progeria usually live to the age of 13 but the life span of some can reach 20 years. In Japan though, there was one exception, a man with progeria lived to be 45, (more than double the average person diagnosed with progeria).
• A person with progeria ages 7 times faster than any other person.
• People usually start to show signs of progeria (aging) by the age of 18 months.
• It is estimated that 80% of Progeria deaths are caused by congestive heart failure or heart attacks.
• There are 45 known cases of progeria in the world.
• Most people diagnosed with progeria do not develop cancer.
• Cells that are considered “unstable” lead to progeria
• Supplements for people with progeria include: ensure, boost, enlive, pediasure.
• Most people have to go to physical therapy 2 or 3 times a week to keep in good enough shape for everyday work.
• The saddest part about progeria is that a person at the age of 10 has the mental age of a 10 year old but the body of an old person.


V. Journal Article Review - http://www.ncbi.nlm.nih.gov/books/NBK1121/
Hutchinson-Gilford Progeria Syndrome
In the article “Hutchinson-Gilford Progeria Syndrome” it is said that “Hutchinson-Gilford progeria syndrome (HGPS, progeria) is characterized by clinical features that develop in childhood and resemble some features of accelerated aging.” Most symptoms vary in age according to the person, yet, for the most part, they are very consistent. A child born with progeria usually has a normal appearance at birth. Then, in about a year, the person begins to experience extreme difficulty to thrive. Then the child’s facial features begin to change and usually by the 3rd year, they lose their hair. It also states that death is usually caused by either a heart attack or a stroke. Death occurs usually betweens the age 6 and 20 with an average of 13. (This article basically “backs up” the rest of this blog.)

More On Progeria:
Go to http://www.youtube.com/watch?v=xCSzysu_flY – This is an awesome video of the life of a kid with progeria!!
Sources:
“Progeria - Wikipedia, the free encyclopedia." Wikipedia, the free encyclopedia. N.p., n.d. Web. 18 Feb. 2011. .
"PubMed Health - Progeria." National Center for Biotechnology Information. N.p., n.d. Web. 18 Feb. 2011. .
"Progeria." Manbir Online ... for Health & Fitness. N.p., n.d. Web. 18 Feb. 2011. .
date., this. "Progeria : Aging starts in Childhood | Medchrome." MEDCHROME - ONLINE MEDICAL MAGAZINE. N.p., n.d. Web. 18 Feb. 2011. .
"Progeria Research Foundation | The Science behind Progeria." Progeria Research Foundation | Home. N.p., n.d. Web. 18 Feb. 2011. .
www.buzzle.com/articles/progeria-facts.html

Friday, February 18, 2011



 The Magnificent Aerosol Spray Can
By: Maury Roque

Introduction:

       How often do we use aerosol spray cans? If your answer was often, you were wrong, as it should very well be extremely often. Aerosol spray cans are used on a day to day basis, whether its in the use of bug spray when taking your daily walk into the forest, or whether it’s shaving cream for the beard that you just noticed you had grown and you really need to get rid of. These little jewels of human creativity were first made possible in as early as the 1790’s, when self-pressurized carbonated beverages we’re developed in France. Though it was an invention, it took many individual inventors to create the aerosol spray cans we have today. From Perpigna to Robert H. Abplanalps, inventors kept improving the aerosol spray can until we finally got the clog-free, pump-mechanized, water-soluble hydrocarbon-activated cans we use today.


Invention/Discovery:
      
       In 1837, a man by the name of Perpigna developed a container of soda that featured a valve. Bulky steel cans with valves were being tested, as early as 1862, but for the same bulkiness that was just mentioned, they could not be issued commercially as they weren’t the most convenient items to carry around. In 1899, a duo of brilliant scientists came up with a new way to propel fluids out of the can using methyl and ethyl chloride, and in 1927 a great engineer from Norway that went by the name of Eric Rotheim developed and patented the first aerosol can and valve that could hold and dispense products other than the reactors. During the later years of World War II, the Government of the United States funded scientific studies to develop a portable way for soldiers to deal with the elimination of malaria carrying. In 1943 Lyle Goodhue and William Sullivan, researchers of the Department of Agriculture, created a small aerosol can that was pressurized by fluorocarbon. It’s their design, in conjunction with the work of Robert Abplanalp, which makes products like Axe deodorant and hair spray possible. What Abplanalp’s work consisted of was the creation of a valve that enabled liquids to be sprayed from a can under the pressure of an inert gas, and this gas was first a fluorocarbon, but then became a water-soluble hydrocarbon after complaints that the fluorocarbons were depleting the ozone layer.



Biography:

       Robert Abplanalp (1922– 2003) was born in New York City to Swiss immigrants. He studied mechanical engineering at Villanova University in his time before joining the army in 1943 to help out with the World War going on at the time. He’s best known for pretty much creating the spray cans we use today, and at the time of his death, he held over 300 patents relating to aerosol spray cans.


Impact on the World/Humanity:

       His invention has been one of the inventions that we can imagine living without, but it does make life MUCH easier. The main uses of this invention are spray paints, a very popular choice for painting cars, instruments, city walls, and many other things, deodorant, which is heavily used by men to smell “good”, and insecticides, used to rid of those annoying bugs that bother you when out in the wilderness.

Cool video J :

please watch!!!! I love you Mrs. D'Arco!!!!!!


References:

1.http://www.museumstuff.com/learn/topics/aerosol_can::sub::History


2.http://inventors.about.com/od/astartinventions/a/aerosol.htm

free glitter text and family website at FamilyLobby.com

(Botox: A Poisonous Path to Pretty)

By Patience Elett


Cost-of-Beverly-Hills-Botox-InjectionsRed dots indicate potential sites of Botox
injection for the relief of wrinkles.



Image: Dr. Jeffrey M. Kenkel, Amy Andrade


Introduction

       Who would have thought that injecting poison into certain parts of your body could help ease the pain that comes with some disorders? Who could have assumed that doing this could alleviate muscle spasms and essentially erase wrinkles? Scientists and ophthalmologists have experimented with the botulinum toxin since the 1820s and they have found multiple uses for this toxin originally found in bad or ill-prepared food. This neurotoxin (type A) is now what we know as Botox.
History
1820s

     In the 1820s, noone really knew the biological cause for food poisoning until Dr. Justinus Kerner studied a basket of incorrectly prepared blood sausages that caused several dozen deaths in Germany. Kerner was so dedicated to his scientific career that he tested his experiments on himself, which made him sick. His experiments and studying cases of botulism outbreaks led him to a better understanding of the neurological symptoms of "food poisoning" (trouble swallowing, droopy eyelids, muscle weakness, and if untreated, respiratory failure and paralysis).  He also made suggestions for prevention and treatment of food poisoning because of his extensive research and experimenting. He also gave us a path to the therapeutic use of that toxin.

1890s

       Dr. Emile Pierre van Ermengem of Belgium was asked to investigate an outbreak of food poisoning at a funeral. Ironically, three people died, while 23 were paralyzed because of the bad ham someone brought. Van Ermengem was able to make a connection between botlism and a spore forming bacterium he had named Bacillus botulinus; later re-named Clostidium botulinum. Later studies revealed seven strains of the toxin (A-G). A, B, E, and F cause illness in humans.

1940s

       When the U.S. got involved in WWII, the military started researching biological weapons, including the toxin that causes botulism.  It's considered the deadliest substance in the world. One plan was to use Chinese prostitutes to put small toxic pills into the food and drinks of the superior Japanese officers. A batch of botulinum toxin filled gelatin capsules were made, but the plan was abandoned before poisoning the Japanese.
1950-60s

       When WWII ended, researchers focused on the beneficial aspects of the botulinum toxin, especially after Dr. Edward J. Schantz and his colleagues purified botulinum toxin type A into crystalline form. In 1953 , Dr. Vernon Brooks, a physiologist, found that injecting tiny amounts of the now scientifically "famous" toxin into a hyperactive muscle blocks the release of acetylcholine from motor nerve endings. This caused temporary "relaxation". In the 60s, ophthalmologist Dr. Alan B. Scott began injecting BTTA (botulinum toxin type A) into monkeys, with a theory that its muscle relaxing effects could help treat crossed eyes (strabismus). Soon after, BTTA became the go-to toxin in researching labs worldwide.
1970-80s

       In 1978, Scott gained approval from the FDA to inject human volunteers with tiny amounts of BTTA for experimentation. More research showed that the drug's benefits reached far beyond ophthalmology. It gave temporary relief from facial, neck, vocal cord, and shoulder spasms as well. In 1988, the drugmaker Allergan bought the rights to sell Dr. Scott's batch of BTTA, and in the following year, the FDA approved BTTA for the treatment of eyelid spasms and strabismus. Shortly after the approval, Allergan bought Scott's company and changed the name of the drug to what we know it as today: Botox.

1990s

        As research continued, other uses for BTTA were discovered. Scientists found that bladder spasms, cerebral palsy in kids, excessive sweating, and writers cramp could all be temporarily alleviated by injecting miniscule amounts of this neurotoxin. The discovery that most impacted what we think of when Botox comes up was made when Dr. Jean Carruthers realized that her blepharospasm patients were losing their wrinkles in their face. In 1992, both her and her husband published a paper which stated that, "treatment with C. botulinum-A exotoxin is a simple safe procedure" for the treatment of brow wrinkles. Dermatologists instantly took advantage of this "off label" use. By 1997, the demand for Botox spiked so dramatically that the U.S.'s supply ran out, causing panic among those who used it and the NY Times's headline to read "Drought Over, Botox Is Back" once a new batch of BTTA recieved approval from the FDA.

2000s

       In 2000, Botox recieved the FDA's go-ahead for the treatment of cervical dystonia. In 2002, Botox Cosmetic (the brand of Botox that fixes wrinkles and lines) got its first government approval, which allowed Allergan to start a multi-million-dollar marketing campaign to raise the already prosperous Botox sales, which had reached $310 million at the end of 2001. Only one year later, Botox had been featured in almost 14,000 TV and stories in hte U.S. alone. At the end of the same year, sales had reached nearly $440 million, and Allergan declared Botox Cosmetic one of the most successful pharmaceutical brand launches in the company's 53 year history. In 2004, Allergan recieved an FDA approval for the use of BTTA to stop excessive underarm sweating. Botox started showing up everywhere. It even became an acceptable gift to friends and family, especially new moms! Doctors pay $400 for one vial of Botox Cosmetic. For each injection, the patient must pay $200. To noone's surprise, the intense popularity and large price tag inspired alot of knockoffs and "bargain basement" treatments by scam artists. By December 2006, Botox sales had gone through the roof with $1 billion in sales. Cosmetic uses accounted for about half of the income. Botox is the #1 non-surgical cosmetic treatment in the U.S.. As this method for removing wrinkles becomes more popular, there are more signs of possible outrages. The Botox Cosmetic has been shown as a method of torture in the TV show Nip/Tuck and the weapon of choice for a murder in  the TV show Law and Order. It has been the subject of at least one addiction study, and misuse has brought new meaning to the expression "poker face". People are also more concerned about the credibility of who is performing the injection.

Journal Article

             Unfortunately, during my research I did not come upon a single journal article.

References
Mapes, D. (Producer). (2007). Frozen in time: botox over the years. [Web]. Retrieved from http://www.msnbc.msn.com/id/21369061/ns/health-skin_and_beauty

Pearce, J. (2005, May 04). Edward j. schantz. Retrieved from www.nytimes.com/2005/05/04/national/04schantz.html

Genetically Modified Foods by Arni Savoretti

I.                   Introduction: Genetically Modified Foods (GMF)

Pictures pending!

            In the 1990’s technology evolved to a level where food could be genetically altered to produce larger quantities. Originally intended to feed more people around the world and address the world’s hungry and ever-growing population, scientists began to use organisms to genetically modify foods. Through mutagenesis, or organisms that have been exposed to radiation or chemicals in order to change their DNA or genetic composition, foods like corn and soybeans could be produced in larger quantities. GM foods are highly controversial as the long term effects of these genetic mutations when consumed by humans, has not fully been studied even though 88% of the world’s market of maize, soybean, and cotton is genetically modified (GMO Compass 2009).

II.                Discovery: Mutating DNA

      According to Campden and Chorleywood Food Research Association (CCFRA),
“genes change every day by natural mutation and recombination creating new biological combinations” (CCFRA 2010). DNA is not, nor ever will be, “static”. As long as we can modify it, genetic alterations, mutations, and recombinations will occur. In the case of GM foods, rather than change occurring naturally, it is forced to alter through controlled and deliberate means usually through chemical changes or via radiation. Characteristics and elements that seem to yield beneficial results such as chymosin of bovines can be transferred to industrial microorganisms and produced commercially as yeast rather than yeast obtained from the remnants of animal carcasses once used in cheese production.
     
III.             Benefits/Consequences

      The idea of GMF was to increase food supplies to the world through food production. GM techniques make crops pest and disease resistant, expanding the shelf life of fruits and vegetables so they do not spoil as quickly, the elimination of toxicants, increase food production in previously inhospitable environments, and increase in high value drugs to meet the needs of diseased individuals, to assist in the development of environmentally safe products such as using starches to make plastics or create more sustainable crops. According to the British Medical Journal (BMJ) all of these elements make the system of food production better and ease world hunger. However, there are consequences to GM foods. In a journal article by the American Chemical Society (ACS), these consequences can result in significant problems the least of which is antibiotic resistance in humans (Engel 1995). Other issues presented by the European Union include: the effects of GM potatoes on the intestines (Ewen 1999), increases in allergies, increase in disease due to cross breeding and contamination, long-term effects, and loss of valuable nutrients. According to The Global Healing Center’s website, one of the top processed and genetically altered products on the market today is baby formula.

IV.              Impact on the World/Humanity

      There is no doubt that GMF are here to stay, Supermarket shelves are full of processed and altered foods catering to nearly every segment of the population. Although they have been subjected to rigorous safety assessments, there needs to obviously be more since these altered foods are playing with our chemically and genetic compositions.
      Some will continue to argue that it is easy to forget that DNA is, and always has been, part of our daily diet and that it naturally changes every day. Daily, each of us consumes millions of copies of many thousands of genes, most of whom we do not know what they do to our bodies. Seriously, how many people stop to think about the genes of tomato, cucumber, and lettuce in a salad, the bovine genes in a beef steak, the fragmented DNA in many processed foods, and the genes of the many micro-organisms that we breathe and swallow? Answer? Not many. When chomping on that cheeseburger, does anyone think about how it might make them insulin resistant or make the usual antibiotics unable to fight infectious viruses like MRSA?
      At the end of the day GM has improved the quality of life and food for the world. Between 1998 and 2001, GM silkworms and cottonseeds changed India’s ability to produce fabrics by 60%. If we could apply these principles of GM to bio-plastics and bio-fuels, the world would benefit tremendously (Bourzac 2010).


V.                 Journal Article Review

                        Genetically Modified Foods as published in The Science Journal and posted to Penn State’s Eberly School of Science website, was written by Dr. Nina Federoff and suggests that one of the primary benefits of GMF is that fewer people need to farm and more people can pursue their passions because they are not tied to the responsibilities of food production. She claims, that in fact, our society as a whole is richer because we use GMFs. Federoff further suggests that it is within our natures to alter nature; to preserve and adapt plant material for survival.  
            Having worked with such scientists as the Nobel Laureate Barbara McClintock of “transposons”  or “jumping genes”, Federoff was able to map and analyze the gene recognizing the moveable quality of genes to chromosomes. As somewhat of a pioneer in the field of corn transposons, Federoff was instrumental in developing the first few waves of GM maize. She contends that since man has been monkeying with evolution since the dawn of man walking upright, that GM is a natural extension of man’s tendency to develop better methods of feeding and that many of the foods we have come to love have been the product of crossbreeding or GM. As author of the book, Mendel in the Kitchen: A Scientist’s View of Genetically Modified Food, she shares her concern about industry standards and governmental regulations only focusing on plants that have undergone molecular modifications (sugar for example) as opposed to examining all lab manufactured products.
            She also highlights how other important contributions to the world of feeding an ever-growing population by suggesting that the “Haber-Bosch process for converting the gaseous nitrogen in the air to a form that plants can use as nitrogen fertilizer. Second was the observation of George Harrison Shull that intercrossing inbred corn varieties produces robust and productive offspring. This is the scientific underpinning of the entire hybrid corn industry” (Federoff 2007). Continued work in the field, especially with regard to radiation and chemical alterations is necessary if politics and economics cannot resolve the issues with food deployment.

Works Cited
Bourzac, Katherine. "Transgenic Worms Make Tough Fibers - Technology Review." Technology         Review: The Authority on the Future of Technology. MIT, 27 Oct. 2010. Web. 13 Feb.   2011. <http://www.technologyreview.com/biomedicine/26623/>.

Engel, Karl, Gary R. Takeoka, and Roy Teranishi. Genetically modified foods: safety issues :            developed from a symposium sponsored by the Division of Agricultural and Food       Chemistry at the 208th National Meeting of the American Chemical Society, Washington,      DC, August 21-25, 1994. Washington, DC: American Chemical Society, 1995. Print.

Ewen, Dr Stanley W B . "Effect of diets containing genetically modified potatoes expressing       Galanthus nivalis lectin on rat small intestine." Vivat Academia 354.9187 (199): 100-112.            Print.

Federoff, Nina. "Genetically Modified Foods." Science Journal 26 (2007): 1-5. Print.

Jones, Leighton. "Genetically Modified Foods." British Medical Journal 318.7183 (1999): 611-          613. Print.

"USA: Cultivation of GM plants, 2009." GMO COMPASS - Information on genetically modified       organisms. N.p., n.d. Web. 13 Feb. 2011. <http://www.gmo-            compass.org/eng/agri_biotechnology/gmo_planting/506.usa_cultivation_gm_plants.



Alea DelleCave's Work on the True Color of Dinosaur's...check out link!!!!!

                                                     http://blockdbiology.blogspot.com/

Thursday, February 17, 2011

THE CAMERA!!! - BY: CARTER


The Camera!!!

- BY: Carter Moore

Introduction
The camera is one of the most popular and widely used pieces of technology that we use today. A camera works by taking the light that is reflected off of an object and taking it through the lens of the camera and projecting it onto the film as shown in this very informative picture below!
History
The first photograph was taken by Joseph Niepce, taken by coating a pewter plate with bitumen and exposing the plate to light in France in 1827. Louis Daguerre invented the first practical method of photography, he coated a copper plate with silver and then treated it with iodine vapor to make it sensitive to light. Then Richard Maddox invented the gelatin dry plate that rivaled the usual wet plate in speed and quality. In 1885 photographic film was invented by George Eastman. Eastman went on to create the Kodak camera, he invented the Kodak brownie which was a cheap portable camera that everyone could afford, it was very popular. Then in 1928 the first practical modern portable camera was made, and in 1948 Edwin land made the first instant-picture camera that revolutionized the camera world!

Biography
Louis Daguerre was born on November 18, 1787 in France and died on July 10, 1851 at the age of 63. Daguerre apprenticed in architecture, theater design, and panoramic painting. In July 1822 Daguerre invented the diorama. And in 1839 invented the Daguerreotype, but in august of that same year the French government acquired the patent and announced that his invention was a gift ‘free to the world.'

Journal Article

http://www.opticsinfobase.org/ocisdirectory/220_3620.cfm

This journal article is explaining the research about the flooded mask that can be put on cameras to allow them to take clear pictures underwater and above-water.


Impact on the world

Photography and the camera is undoubtedly one of the most important inventions in history, it has transformed how people view the world. Now we can "see" all sorts of things that are actually many miles and years away. Photography lets us capture moments in time and preserve them for years to come.

Bibliography
Louis Daguerre - Wikipedia, the free encyclopedia. (n.d.). Wikipedia, the free encyclopedia. Retrieved February 5, 2011, from http://en.wikipedia.org/wiki/Louis_Daguerre


How the camera works. (n.d.). How the camera works. Retrieved February 3, 2011, from www.islandnet.com/~yesmag/how_work/camera.html


D'Silva, R. (n.d.). History of the Camera. Buzzle Web Portal: Intelligent Life on the Web. Retrieved February 14, 2011, from http://www.buzzle.com/articles/history-of-the-camera.html


History of the camera - Wikipedia, the free encyclopedia. (n.d.). Wikipedia, the free encyclopedia. Retrieved February 9, 2011, from http://en.wikipedia.org/wiki/History_of_the_camera


Figure 1: http://www.artlex.com/ArtLex/Pin.html

String Theory: by Jennifer Grigsby

String Theory

By Jennifer Grigsby

I. Introduction

String theory was developed in hopes of being a theory of everything. If it’s right, it could potentially answer all questions about the universe. Gabriele Vineziano laid the basis for the idea of string theory was laid in 1968. From that point on, physicists made discoveries that all converged into this one theory. String theory, if correct, perfectly unifies general relativity and quantum mechanics.

Video 1: a brief summary of string theory

http://www.youtube.com/watch?v=_B0Kaf7xYMk

II. Laying Foundations

In the late 1600’s, Isaac Newton unified the solar systems and the earth by discovering gravity. He figured out that the same force that held together the planets was also responsible for making apples fall to the ground. Albert Einstein proved Newton wrong. Newton thought that the sun (the center of our solar system) reaches out and grabs planets with its gravitational pull, keeping them in orbital. Contradicting Newton’s theories, Einstein said that time and space are bound together (spacetime). The planets follow curves in spatial “fabric” created by the sun. If a cosmic catastrophe were to occur (where the sun disappears/vaporizes), Newton believed that the planets would instantaneously shoot off across the universe because the sun was no longer keeping them in line; whereas Einstein believed that the curve in spacetime fabric would disappear, and would make a ripple in the fabric. In Einstein’s scenario, the Earth wouldn’t feel the effect of the sun’s disappearance until the ripple reached it. By solving numerous mathematical equations, he concluded that light and gravity take the same amount of time to travel from the sun to the earth. So basically, he corrected Newton’s concept of gravity and made his own new version of it. This new picture of gravity (which included other examples) was called general relativity.

Earlier, James Clerk Maxwell had unified electricity with magnetism which resulted in a force called electromagnetism. Einstein wanted to unify general relativity with electromagnetism to form a master equation that could describe everything, but he didn’t know how he could because there was a huge difference in strength: electromagnetism is way stronger than general relativity.

A new group of young scientists came into the picture and made Einstein’s and Maxwell’s work seem useless. These physicists made the theory of quantum mechanics: described how subatomic particles interacted. Quantum mechanics was a radical theory that crushed all previous ways of looking at the universe. The laws of the quantum world are way different than what we know and live daily. There’s never certainty. This new theory explained the 3 forces in the microscopic realm: electromagnetism, the strong nuclear force, and the weak nuclear force. But no one could figure out how the 4th major force, gravity (and Einstein’s theory of general relativity) fit in with it. Essentially, no one could figure out how to put quantum mechanics (little) and general relativity (big) together, but they all knew somehow they had to fit because they all exist in the same universe.

Through Schwarzschild discovery of black holes, scientists began to find the key to a theory of everything. At the center of a black hole is an entire star crushed into a tiny speck. Does that mean it’s big, falling under the theory of general relativity, or does that mean it’s small, falling under the theory of quantum mechanics? Both theories have to work, which means there must be something that unifies these two separate parts of the laws of the universe. But the problem was, nobody could figure out how these two related, because they each came up with separate answers and wouldn’t mesh.

III. Development of the “Theory of Everything”

String theory states that every particle (of matter, force, etc.) is made up of tiny vibrating strands of energy, called strings. These strings “wiggle” and vibrate in different ways which determine the particle’s properties, such as mass and charge.

Figure 1: What strings are supposed to look like. Top left corner = the 4 main forces: gravity, electromagnetism, the strong nuclear force, and the weak nuclear force.









In 1968, a young Italian physicist named Gabriele Vineziano accidently found 200-year-old equations written by Leonard Boyler that described the strong nuclear force. Leonard Susskind, and American physicist, took those equations and manipulated them. He ended up noticing something peculiar within his math, and he developed the initial concept of the “string” and string theory.

String theory was, at this point, rather confusing and unexplained. It required 10 dimensions, which was inconceivable. In 1973, John Schwarz decided that strings unite the theories of general relativity and quantum mechanics, but his work had anomalies (mathematical inconsistencies). In 1984, he and Michael B. Green continued the search for the possibility of a theory of everything, and realized that their theory was free of anomalies and could encompass all four forces (gravity, electromagnetism, strong nuclear force, and weak nuclear force). This discovery fulfilled Einstein’s dream.

There were 5 different string theories, which was kind of embarrassing for string theorists. But Ed Whitten solved this problem. He discovered that these 5 different theories were really just 5 different ways of looking at the same thing, and thus he created M theory (nobody knows what the M stands for, he says it can be magic, mystery, matrix, or even murky). Now there must be 11 dimensions.

Figure 2: String theory demands 11 dimensions; 6 of the ones we can’t see are supposedly curled up into something that looks like this. (4 of the other dimensions we know: 1 in time, and 3 in space. The 11th dimension was conjured up by Whitten in his M theory, after this image was accepted by string theorists.)








String theory has an inability to experiment and make observations upon, so as far as we know, it can’t be proven. However, it remains permanently safe because it can’t be proven wrong.

IV. Impact on the World/Humanity

“The discovery of the T.O.E. [theory of everything]—the ultimate explanation of the universe at its most microscopic level, a theory that does not rely on any deeper explanation—would provide the firmest foundation on which to build our understanding of the world. Its discovery would mark a beginning, not an end. The ultimate theory would provide an unshakable pillar of coherence forever assuring us that the universe is a comprehensible place.” (Greene, 2003)

String theory could be the foundation of many scientific breakthroughs to come. With the knowledge it could potentially provide, we could make advances in technology and virtually anything else. After all, it explains the basis of everything.

V. Journal Article Review

Unifying general relativity with quantum mechanics into a theory of quantum gravity has been the challenge of many scientists over the years, and string theory is the closest they've gotten. General relativity was thought to have covered all there was to know about gravity, but it was flawed because it didn't apply to the quantum level, and so was the problem with quantum mechanics alone. Black holes were the key to the creation of string theory. At the center of a black hole is an entire star crushed into a tiny speck. Nothing, not even light, can escape a black hole. So since at the time there were 2 separate theories of the universe, which one would black holes be classified as? There couldn't be 2 separate universes, because black holes unified everything into one, as well as they unified the quantum world with the idea of general relativity - both applied.

References:

Greene, B. (n.d.). NOVA | The Elegant Universe | A Theory of Everything? | PBS. PBS: Public Broadcasting Service. Retrieved February 13, 2011, from http://www.pbs.org/wgbh/nova/elegant/everything.html

Maldacena, J. (1996, August 20). Black Holes in String Theory. arxiv.org. Retrieved February 18, 2011, from arxiv.org/PS_cache/hep-th/pdf/9607/9607235v2.pdf

Mcmaster, J. (Director). (2003). NOVA - The Elegant Universe [Motion picture]. US: PBS.

String Theory - (2 Minutes). (2007, March 13). YouTube. Retrieved February 17, 2011, from http://www.youtube.com/watch?v=_B0Kaf7xYMk

Pictures:

Kadimi, A. (2010, March 25). The impossible says i'm possible. Blogger. Retrieved February 17, 2011, from http://travelthroughtime-possible.blogspot.com/

Testing String Theory? How Real Science Progresses « The Skeptical Teacher. (2010, September 16). The Skeptical Teacher. Retrieved February 17, 2011, from http://skepticalteacher.wordpress.com/2010/09/16/testing-string-theory-how-real-science-progresses/

MSG & Umami- by Ali Hunt


















Figure 1- The Umami Taste Bud


Introduction:

Monosodium Glutamate (MSG) is an amino acid. It is a sodium salt of a glutamic acid. It is marketed as a food additive and flavoring enhancer, commonly found in processed foods such as potato chips, dry soups, spice mixes, and Chinese restaurants. MSG has a meaty, “broth-y” like taste that is different from any other food group. MSG enhances the flavors of the foods that it is commonly added to. MSG is one of the most commonly known food items in the umami food groups.



Umami:

Humans have five categories of taste: bitter, salty, sweet, sour... and umami? Umami (savory flavor) was founded in 1908 by Japanese scientist Kikinadue Ikeda. Ikeda was tasting his native seaweed dish, kombu. He noticed that the kombu had a different, distinct taste that wasn’t salty, sweet, sour, or bitter. In 1913, Shintaro Kodama, found that dried bonito flakes also had the “umami” flavor. In 1957, scientist Akira Kuninaka discovered that

the ribonucleotide GMP (found in shiitake mushrooms) also had the umami flavoring. But where was this mysterious taste coming from? Kuninaka kept researching and found that the umami taste was present when items with gluatamate were combined with items containing ribonucleotides (for example: parmesan cheese and tomato sauce combined).



MSG & Health:

There is speculation about the use of MSG. M

SG is a nuerotoxin, which has an effect on the brain and nervous system from it’s first entry. It leaves us filling hungry and empty within an hour of consuming it (hence why many people full hungry shorty after eating Chinese food- one of MSG’s greatest known victims). MSG (and umami in general)increases salivation, which means it can seem “addictive” to some people. In addition to that, one’s first encounter with the umami substance is during th

e breastfeeding stage (umami is found breast milk- another “addictive” characteristic.)


Impact on World:

MSG is said to be slowly poisoning America. MSG is added to almost every food (kraft, top ramen, lays, doritos, hostess, and especially low fat, low card, or low sugar items because it is a flavor additive!). MSG was tested on lab rats, and it tripled the amount of insulin that the rat’s took in- significantly increasing the risk for diabetes and obesity. MSG’s addictive “umami” qualities make it literally “nicotine for food”. A chemical in MSG, Adrenalectomy stops serotonin production in brain, so the signal that you are full isn’t sent. There is also no FDA limit on how much MSG can be added to food.


Journal Article:

Andrew Weil, M.D.

http://www.drweil.com/drw/u/QAA400377/Umami-Whats-That-Great-Taste.html


Figure 2- MSG

Chemically, umami differs in structure from other foods because it has a type of amino acid called a gluamate. Anchovies, tomato paste, mushrooms, and asparagus have the umami quality in addition to MSG. These food items bring a savory taste to each dish. Although adding MSG for flavor can decrease salt and sugar content, the MSG has a bad rep for causing headaches and stomachaches. Eating MSG on an empty stomach can cause numbness, dizziness, rapid heartbeat, drowsiness, and weakness. Some people even have allergic reactions to MSG in food.





Bibliography



Moss, M. (2007, November 12). Monosodium glutamate (msg) - The Addiction You Never Knew You Had. Retrieved from http://www.associatedcontent.com/article/442155/monosodium_glutamate_msg_the_addiction.htm


MSG - Slowly Poisoning America. (n.d.). Retrieved from http://www.rense.com/general52/msg.htm


(n.d.). Retrieved from http://www.msreversed.com/picts/MSG_2.jpg (Figure 2)


(n.d.). Retrieved from https://blogger.googleusercontent.com/img/b/R29vZ2xl/AVvXsEgeyhWu_ZDUnyC3Jd2mOXsq1ZGLYYzabKGF_tvE4pYgddfxwLcHSG-waufzEVJcMcBfmcq3Wz5lbPUtw7pRq2Acne8msaUzG35zStoDglBpQHXPrb0lX_hu8it1y0Icwsd7sBdrU1G0pKcw/s1600/nature05401-f1.2.jp (Figure 1)


The Truth About MSG. (n.d.). Retrieved from http://www.truthinlabeling.org/


Weil, A. (2008, March 27). Umami- Whats That Great Taste? . Retrieved from http://www.drweil.com/drw/u/QAA400377/Umami-Whats- That-Great-Taste.html