[i]   “… will be able to “reverse engineer” the technology…”

“After joining the Army in 1942, Philip Corso served in Army Intelligence in Europe.  In 1945, Corso arranged for the safe passage of 10,000 Jewish WWII refugees out of Rome to Palestine. During the Korean War (1950-1953), Corso performed Intelligence duties under General Douglas MacArthur as Chief of the Special Projects branch of the Intelligence Division, Far East Command. One of his primary duties was to keep track of enemy prisoner of war (POW) camps in North Korea. Corso was in charge of investigating the estimated number of U.S. and other United Nations POWs held at each camp and their treatment. At later held congressional hearings of the Senate Select Committee on POW/MIA Affairs, Philip Corso would provide testimony that many hundreds of American POW’s were abandoned at these camps.

Corso was on the staff of President Eisenhower’s National Security Council for four years (1953-1957). In 1961, he became Chief of the Pentagon’s Foreign Technology desk in Army Research and Development, working under Lt. Gen. Arthur Trudeau. When he left military intelligence in 1963, Corso became a key aide to Senator Strom Thurmond. In 1964, Corso was assigned to Warren Commission member Senator Richard Russell Jr. as an investigator into the assassination of John F. Kennedy.

Philip Corso relates in his book The Day After Roswell (co-author William J. Birnes) how he stewarded extraterrestrial artifacts recovered from a crash at Roswell, New Mexico in 1947.

According to Corso, the reverse engineering of these artifacts indirectly led to the development of accelerated particle beam devices, fiber optics, lasers, integrated circuit chips and Kevlar material.

In 1947, according to Corso, a covert government group (see Majestic 12) was assembled under the leadership of the first Director of Central Intelligence , Adm. Roscoe H. Hillenkoetter. Among its tasks was to collect all information on extraterrestrial spacecraft. The US administration simultaneously discounted the existence of flying saucers in the eyes of the public, Corso says.  Corso further relates that the Strategic Defense Initiative (SDI), or Star Wars, was meant to achieve the capability of killing the electronic guidance systems of incoming enemy warheads and disabling enemy spacecraft, including those of extraterrestrial origin.”

— Reference:  Wikipedia.org

[ii]  “… attuned to the “neural network” of the craft.”

“Traditionally, the term Neural Networks had been used to refer to a network or circuit of biological neurons. The modern usage of the term often refers to artificial neural networks, which are composed of artificial neurons or nodes. Thus the term ‘Neural Network’ has two distinct usages:

1)  Biological neural networks are made up of real biological neurons that are connected or functionally-related in the peripheral nervous system or the central nervous system. In the field of neuroscience, they are often identified as groups of neurons that perform a specific physiological function in laboratory analysis.

2)  Artificial neural networks are made up of interconnecting artificial neurons (programming constructs that mimic the properties of biological neurons). Artificial neural networks may either be used to gain an understanding of biological neural networks, or for solving artificial intelligence problems without necessarily creating a model of a real biological system.”

— Reference:  Wikipedia.org

[iii]    “…microscopic wiring or fibers…”

The transistor was invented in 1947.  It was considered a revolution. Small, fast, reliable and effective, it quickly replaced the vacuum tube. Freed from the limitations of the vacuum tube, engineers finally could begin to realize the electrical constructions of their dreams.

It seems that the integrated circuit was destined to be invented. Two separate inventors, unaware of each other’s activities, invented almost identical integrated circuits or ICs at nearly the same time.

Jack Kilby, an engineer with a background in ceramic-based silk screen circuit boards and transistor-based hearing aids, started working for Texas Instruments in 1958. A year earlier, research engineer Robert Noyce had co-founded the Fairchild Semiconductor Corporation. From 1958 to 1959, both electrical engineers were working on an answer to the same dilemma: how to make more of less.

Although the first integrated circuit was pretty crude and had some problems, the idea was groundbreaking. By making all the parts out of the same block of material and adding the metal needed to connect them as a layer on top of it, there was no more need for individual discrete components. No more wires and components had to be assembled manually. The circuits could be made smaller and the manufacturing process could be automated.

Jack Kilby (Texas Instruments) is probably most famous for his invention of the integrated circuit, for which he received the Nobel Prize in Physics in the year 2000. After his success with the integrated circuit Kilby stayed with Texas Instruments and, among other things, he led the team that invented the hand-held calculator.

Jack Kilby now holds patents on over sixty inventions and is also well known as the inventor of the portable calculator (1967). In 1970 he was awarded the National Medal of Science. Robert Noyce, with sixteen patents to his name, founded Intel, the company responsible for the invention of the microprocessor, in 1968. But for both men the invention of the integrated circuit stands historically as one of the most important innovations of mankind. Almost all modern products use chip technology.

— Reference:  Wikipedia.org

[iv] “…wiring is used for light, sub-light and ultra-light spectrum detection and vision.”

An optical fiber is a glass or plastic fiber designed to guide light along its length. Fiber optics is the overlap of applied science and engineering concerned with the design and application of optical fibers. Optical fibers are widely used in fiber-optic communication, which permits transmission over longer distances and at higher data rates than other forms of communications. Fibers are used instead of metal wires because signals travel along them with less loss, and they are immune to electromagnetic interference. Optical fibers are also used to form sensors, and in a variety of other applications.

In 1952, physicist Narinder Singh Kapany conducted experiments that led to the invention of optical fiber, based on Tyndall’s earlier studies; modern optical fibers, where the glass fiber is coated with a transparent cladding to offer a more suitable refractive index, appeared later in the decade.

In 1991, the emerging field of photonic crystals led to the development of photonic crystal fiber (Science (2003), vol 299, page 358), which guides light by means of diffraction from a periodic structure, rather than total internal reflection. The first photonic crystal fibers became commercially available in 1996. Photonic crystal fibers can be designed to carry higher power than conventional fiber, and their wavelength dependent properties can be manipulated to improve their performance in certain applications.”

— Reference:  Wikipedia.org

[v]   “… fabrics of the interior of the craft…”  

“Technical textiles is the term given to textile products manufactured for non aesthetic purposes, where function is the primary criterion.  This is a large and growing sector and supports a vast array of other industries.

It has been heard that soon textiles will be merged with electronics in all areas. In future wearable computers would be launched, these will not be like advance wrist watches etc, they will contain IC s in fabric to develop fabric keyboards and other wearable computer devices. These types of products are known as Interactive electronic textiles (IET).  Research to support IET development is being conducted in many universities. Growing consumer interest in mobile, electronic devises will initiate the demand for IET products.

Technical textiles include textile structures for autmotive applications, medical textiles (e.g. implants), geotextiles (reinforcement of embankments), agrotextiles (textiles for crop protection), protective clothing (e.g. against heat and radiation for fire figther clothing, against molten metals for welders, stab protection and bulletproof vests), spacesuits (astronauts).”

Biotextiles are structures composed of textile fibers designed for use in specific biological environments where their performance depends on biocompatibility and biostability with cells and biological fluids. Biotextiles include implantible devices such as surgical sutures, hernia repair fabrics, arterial grafts, artificial skin and parts of artificial hearts. They were first created 30 years ago (1978) by Dr. Martin W. King, a professor in North Carolina State University’s College of Textiles.

Medical textiles are a broader group which also includes bandages, wound dressings, hospital linen, preventive clothing etc. Antiseptic biotextiles are textiles used in fighting against cutaneous bacterial proliferation. Zeolite and triclosan are at the present time the most used molecules. This original property allows to inhibits the development of odors or bacterial proliferation in the diabetic foot.”

— Reference:  Wikipedia.org

[vi]  “… mechanisms for creating,  amplifying and channeling light particles or waves as a form of energy.”

In 1947, Willis E. Lamb and R. C. Retherford found apparent stimulated emission in hydrogen spectra and made the first demonstration of stimulated emission.  In 1950, Alfred Kastler (Nobel Prize for Physics 1966) proposed the method of optical pumping.

The work of Schawlow and Townes, however, can be traced back to the 1940sand early 50s* and their interest in the field of microwave spectroscopy, which had emerged as a powerful tool for puzzling out the characteristics of a wide variety of molecules.

The invention of the laser, which stands for light amplification by stimulated emission of radiation, can be dated to 1958 with the publication of the scientific paper, Infrared and Optical Masers, by Arthur L. Schawlow, then a Bell Labs researcher, and Charles H. Townes, a consultant to Bell Labs. That paper, published in Physical Review, the journal of the American Physical Society, launched a new scientific field and opened the door to a multibillion-dollar industry.

Many different materials can be used as lasers. Some, like the ruby laser, emit short pulses of laser light. Others, like helium-neon gas lasers or liquid dye lasers emit a continuous beam of light.

*NOTE:  According to the book, “The Day After Roswell”, reports about microwave and light projecting components from the Roswell “flying disc”, technology were “leaked” to Bell Laboratories through the Pentagon.

— Reference:  Wikipedia.org