Latest Digital Camera

digital camera is a camera that stores the pictures and video it takes in electronic format instead of to film. The picture is of a Casio QV-R62, a 6.0 Mega Pixel digital camera and example of a typical digital camera.
Note: A camera that is always connected to your computer with no storage could also be referred to as a digital camera. However, it is more appropriate to refer to this camera as a webcam.
Digital camera advantages

Below are key advantages that make digital cameras a popular choice when compared to film cameras.
LCD screen
The LCD screen can show photos and videos after they have been taken, which allows you to delete the photo if you do not like the results or show other people.
Storage
A digital camera can store hundreds of pictures instead of only up to 36 pictures.
Picture development
Digital camera pictures can be developed, but you can pick and choose what pictures to develop instead of having to develop a full role of film with pictures you don't want.
Size
Because a digital camera does not need a place for film a digital camera (not an SLR) is much smaller and can easily be carried in your pocket or purse.

Definition of Satellite:

Definition of Satellite:

It is an object that orbits about some body (i.e planet, dwarf planet, asteroid, or star of a larger size.) capable of exerting a gravitational force. 

ADVANTAGES:

1) Used in long distance communications such as in television,fax,internet etc
2) Used in television and radio broadcasting etc
3) Weather for casting (i.e) in prediction of rainfall, snowfall, storm etc
4) Agricultural monitoring (i.e) crop disease, crop failure.
5) Collecting information about other planets, stars and other celestial bodies

Generally, a satellite has been classified in following classes:

(i) Natural Satellites

A natural satellite is a celestial body that orbits a planet or other body larger than itself. The term is normally used to identify non-artificial satellites of planets, dwarf planets, or minor planets. Such objects are often called moons. There are upto 240 known moons within the solar system, including 163 orbiting the planets, four orbiting dwarf planets.
Earth's Moon is the most obvious example and was the only one known until the discovery of the Jupiter in 1610. All the solar system's planets except Mercury and Venus have moons, which vary greatly in size, composition (from rock to mostly ice), and activity (from cold and inert to volcanic). Some asteroids are also known to have their own moons.
The orbital properties and compositions of natural satellites provides us with important information on the origin and evolution of the satellite system. Especially a system of natural satellites orbiting around a gas giant can be regarded as a miniature solar system that contains precious clues for studying the formation of solar systems.
Irregular vs Regular Satellites

Natural satellites have been further divided in two classes:

(a) Regular satellite is a natural satellite following a relatively close and generally prograde orbit with little orbital inclination or eccentricity. They are believed to have formed in orbit about their primary, as opposed to irregular moons, which were captured. The regular satellites are two of Mars, inner five of Jupiter, inner seven of Saturn etc.
(b) Irregular satellite is a natural satellite following a distant, inclined, and often eccentric and retrograde orbit. They are believed to have been captured by their parent planet, unlike regular satellites, which form in situ.

(ii) Artificial Satellites:

Artificial satellite is a man-made device placed in orbit around the earth, moon, or another planet used for communication and transmitting scientific information to earth.

The electrical power required by satellite is provided by panels of solar cells and small nuclear reactors. Satellites are kept in the correct position by small rocket motors called thrusters. They orbit with their disc aerials pointing to Earth. When the thrusters run out of fuel, the satellite eventually drifts out of position and becomes unusable. Satellites are equipped with radio transmitters, radio receivers and electronic circuits for storing data.

The first artificial satellite, Sputnik I, was launched by the USSR on October 4, 1957 into orbit around Earth. Since then, thousands have been sent into orbit around Earth as well as the Moon, Venus, Mars, Jupiter, and other bodies. 







Artificial satellites have many uses, including relaying communication signals, making accurate surveys and inventories of the earth's surface and weather patterns, and carrying out scientific experiments.

Functions and Types of Satellites:

Satellites can be divided into six principal types based on their functions i.e.
(i) Research
(ii) Communications
(iii) Weather
(iv) Navigation
(v) Applications and
(vi) Military satellites

(I) Research satellites:
These measure fundamental properties of outer space, e.g., magnetic fields, the flux of cosmic rays and micrometeorites, and properties of celestial objects that are difficult or impossible to observe from the earth. Early research satellites included a series of orbiting observatories designed to study radiation from the sun, light and radio emissions from distant stars, and the earth's atmosphere. Notable research satellites have included the Hubble Space Telescope , the Compton Gamma-Ray Observatory, the Infrared Space Observatory, and the Solar and Heliospheric Observatory.


(ii) Communications satellites:
These provide a worldwide linkup of radio, telephone, and television. The first communications satellite was Echo 1, launched in 1960. Relay 1 and Tel star 1, both launched in 1962, were the first active communications satellites; Tel-star 1 relayed the first live television broadcast across the Atlantic Ocean. In principle, these can provide complete coverage of the earth's surface, instantaneous communications throughout the world and a variety of telecommunications tasks.

(iii) Weather satellites or meteorological satellites:

These provide continuous, up-to-date information about large-scale atmospheric conditions such as cloud cover and temperature profiles. Trios 1, the first such satellite, was launched in 1960; it transmitted infrared television pictures of the earth's cloud cover and was able to detect the development of hurricanes and to chart their paths. Current weather satellites can transmit visible or infrared photos, focus on a narrow or wide area, and maneuver in space to obtain maximum coverage.

(iv) Navigation satellites:

These were developed primarily to satisfy the need for a navigation system that nuclear submarines could use to update their inertial navigation system. This led the U.S. navy to establish the Transit program in 1958. Transit satellites provided a constant signal by which aircraft and ships could determine their positions with great accuracy. It provides greater accuracy in a shorter time; users can obtain information 24 hours a day. These satellites were of enormous help to transportation companies, especially transportation over water and through the air.Navigation satellites are also used for distance measurements for instance between buildings.

(v) Applications satellites:

These are designed to test ways of improving satellite technology itself. Areas of concern include structure, instrumentation, controls, power supplies, and telemetry for future communications, meteorological, and navigation satellites.

(vi) Military Satellites
Satellites also have been used for a number of military purposes, including infrared sensors that track missile launches; electronic sensors that eavesdrop on classified conversations; and optical and other sensors that aid military surveillance. These are Very similar to weather satellites but generally with higher resolution cameras and instead of normal communications equipment, they use encryption as well.

Stay in the Heart of Bangkok

                                    

The Tara Place is less than a 10-minute walk from Khaosan Road and nightlife options. It features non-smoking rooms with a cable flat-screen TV and an on-site restaurant. Free Wi-Fi is available throughout the property. The Thammasat University is a 10-minute walk from Tara Place. The Grand Palace and Emerald Buddha Temple are a 10-minute walk away. The residence is a 45-minute ride from Suvarnabhumi International Airport. The air-conditioned rooms all have a sitting area, a minibar and a fridge. Free toiletries are included in the private bathrooms. For convenience, there is a 24-hour front desk front desk. Guests may arrange day trips at the tour desk. For meals, sample the delicious international cuisine served at De O’Sha Restaurant.

Outdoors
Grounds
Food & Drink
Bar, Restaurant with Dining Menu, Snack Bar
Internet
Free! WiFi is available in all areas and is free of charge.
Parking
No parking available.
Services
24-Hour Front Desk, Tour Desk, Baggage Storage, ATM on site, Hair/Beauty Salon
General
Safe, Non-smoking Rooms, Family Rooms, Elevator, All Spaces Non-Smoking (public and private), Air Conditioning, Designated Smoking Area
Languages spoken
Thai, English
Children and Extra Beds
All children are welcome.
Free! One child under 6 years stays free of charge when using existing beds.
There is no capacity for extra beds in the room.
Pets
Pets are not allowed.

Category: Thailand Amazing Hotels

Discovery Of Electricity

Here is some information on the book, Electrical History by Tom Henry. This book was written in appreciation of the more than 15 million men and women that work in the electrical industry to keep the lights burning every second, every minute, 24 hours a day, everyday.
Did Edison invent the light bulb, Marconi the radio, Bell the telephone, Morse the telegraph? The answers are no. They didn't invent the wheel. They were instrumental in making it better and, in some cases, obtaining the patent.

Electrical history goes back before Christ and brings us to the computer age. Along this journey you will discover it took several people, along the way, to make the light bulb glow.

The journey won't end with this book, as we are constantly discovering new inventions that will someday even take us to the stars.


Benjamin Franklin (1706-1790)

His kite experiment demonstrated that lightning is electricity. He was the first to use the terms positive and negative charge.

Franklin was one of seventeen children. He quit school at age ten to become a printer. His life is the classic story of a self-made man achieving wealth and fame through determination and intelligence.

James Watt (1736-1819) was born in Scotland. Although he conducted no electrical experiments, he must not be overlooked. He was an instrument maker by trade and set up a repair shop in Glasgow in 1757. Watt thought that the steam engine would replace animal power, where the number of horses replaced seemed an obvious way to measure the charge for performance. Interestingly, Watt measured the rate of work exerted by a horse drawing rubbish up an old mine shaft and found it amounted to about 22,000 ft-lbs per minute. He added a margin of 50% arriving at 33,000 ft-lbs.

William Thomson, Lord Kelvin (1824-1907) was best known in his invention of a new temperature scale based on the concept of an absolute zero of temperature at -273°C (-460°F). To the end of his life, Thomson maintained fierce opposition to the idea that energy emitted by radioactivity came from within the atom. One of the greatest scientific discoveries of the 19th century, Thomson died opposing one of the most vital innovations in the history of science.

Thomas Seebeck (1770-1831) a German physicist was the discoverer of the "Seebeck effect".

He twisted two wires made of different metals and heated a junction where the two wires met. He produced a small current. The current is the result of a flow of heat from the hot to the cold junction. This is called thermo electricity. Thermo is a Greek word meaning heat.

Michael Faraday (1791-1867) an Englishman, made one of the most significant discoveries in the history of electricity: Electromagnetic induction. His pioneering work dealt with how electric currents work. Many inventions would come from his experiments, but they would come fifty to one hundred years later.

Failures never discouraged Faraday. He would say; "the failures are just as important as the successes." He felt failures also teach. The farad, the unit of capacitance is named in the honor of Michael Faraday.

James Maxwell (1831-1879) a Scottish mathematician translated Faraday's theories into mathematical expressions. Maxwell was one of the finest mathematicians in history. A max well is the electromagnetic unit of magnetic flux, named in his honor.
Today he is widely regarded as secondary only to Isaac Newton and Albert Einstein in the world of science.

Thomas Alva Edison (1847-1931) was one of the most well known inventors of all time with 1093 patents. Self-educated, Edison was interested in chemistry and electronics.During the whole of his life, Edison received only three months of formal schooling, and was dismissed from school as being retarded, though in fact a childhood attack of scarlet fever had left him partially deaf.

Nikola Tesla was born of Serbian parents July 10, 1856 and died a broke and lonely man in New York City January 7, 1943. He envisioned a world without poles and power lines. Referred to as the greatest inventive genius of all time. Tesla's system triumphed to make possible the first large-scale harnessing of Niagara Falls with the first hydroelectric plant in the United States in 1886.

October 1893 George Westinghouse (1846-1914)was awarded the contract to build the first generators at Niagara Falls. He used his money to buy up patents in the electric field. One of the inventions he bought was the transformer from William Stanley. Westinghouse invented the air brake system to stop trains, the first of more than one hundred patents he would receive in this area alone. He soon founded the Westinghouse Air Brake Company in 1869.

Alexander Graham Bell (1847-1922) born in Scotland, was raised in a family that was interested and involved in the science of sound. Bell's father and grandfather both taught speech to the deaf. A unit of sound level is called a bel in his honor. Sound levels are measured in tenths of a bel, or decibels. The abbreviation for decibel is dB.

Heinrich Hertz (1857-1894) a German physicist, laid the ground work for the vacuum tube. He laid the foundation for the future development of radio, telephone, telegraph, and even television. He was one of the first people to demonstrate the existence of electric waves. Hertz was convinced that there were electromagnetic waves in space.

Otto Hahn (1879-1968), a German chemist and physicist, made the vital discovery which led to the first nuclear reactor. He uncovered the process of nuclear fission by which nuclei of atoms of heavy elements can break into smaller nuclei, in the process releasing large quantities of energy. Hahn was awarded the Nobel prize for chemistry in 1944.

Albert Einstein (1879-1955). Einstein's formula proved that one gram of mass can be converted into a torrential amount of energy. To do this, the activity of the atoms has to occur in the nucleus. E = energy, M = mass, and C = the speed of light which is 186,000 miles per second. When you square 186,000 you can see it would only take a small amount of mass to produce a huge amount of energy.