.


:




:

































 

 

 

 


B.




1. long a. absence

2. forward b. permanent

3. increase . rapid

4. heavy d. short

5. slow e. lightweight

6. invisible f. complexity

7. changing g. rearward

8. with h. inward

9. simplicity i. visible

10. rise j. without

11. presence k. decrease

12. outward 1. fall

C.
.

1. launch a. study, investigation, research, -

2. promote periment, test

3. conduct b. speed, thrust, pressure, cost, drag

4. increase/lower satellite, spacecraft, space sta-

tion, rocket

d. cooperation, development, technical progress


4. .

aboard life-support key facilities assembly supply maintenance stays weightless tool

1......... systems of the ISS are expected to be the most ad
vanced, they can... cleaner air, purer water, better food, and more
sanitary toilet... than on the space shuttle. 2. Life... the station
may not be easy, but it is significantly healthier and more pleasant
than in the past, allowing astronauts to focus more on the scientific
research and station... that occupy them for about 9 hours a day.
3. Thanks to the long... on Mir station researchers learned that
bone loss did not lessen over time as previously thought. 4. In the...
environment of space, everyday activities present new challenges.
5. The Mobile Servicing System to be supplied by Canada is a
four-piece robotic... that will play a... role in... and maintenance
of the ISS.

5. . 1520 The International Space Station.

. Speak about:

Solar sail propulsion systems.


REVISION OF LESSONS 10-12

1. , , . .

1. The Internet is a great place to find and hear hit songs, movies and recorded interviews. 2. It is imperative that the experiment begin at once. 3. If I were you, I should stop the experiment. 4. He wished he were a cosmonaut. 5. A new car model was much spoken about. 6. Nobody saw the professor enter the laboratory. 7. It seems to be an interesting comparison. 8. His experience in the field of materials science can be relied upon. 9. This theory is hard to prove. 10. The new discovery was often referred to. 11. We expect this book to appear in bookshops very soon. 12. Scientists appear to know very little of this phenomenon yet. 13. The main problem is for the report to be published as soon as possible. 14. Materials to be brought back to Earth from space laboratories will have some stable properties. 15. It is unusual for a program to work correctly the first time it is tested. 16. Some experiments on the ISS could result in the development of clocks a thousand times more accurate than today's atomic clocks. 17. There are all kinds of life-supporting equipment aboard a spacecraft as it is essential that cosmonauts should feel themselves as comfortable as possible. 18. Lasers are supposed to be able to solve a number of very complicated problems connected with medicine. 19. One of the most important requirements for hypersonic craft is a sophisticated cooling system lest extreme temperatures should destroy the craft. 20. Educational system suggested by William Rodgers, the founder of MIT, proved to be very effective and to give a sound command of the basic principles of science and technology. 21. People always wished that there were a device that could vaporize the hardest and the most heat-resistant material. 22. A number of important innovations such as reducing the weight of airplanes and spacecrafts would have been impossible unless composite materials had been developed. 23. Scientists discovered superconductors to possess thermal, electric and magnetic properties quite different from the non-conducting materials. 24. The cost of electricity generation has been influenced by the development of electromagnets made with superconductors. 25. To produce the superconductive effect, a Dutch physicist cooled a mercury wire below a temperature of 269 C. 26. We know optical disks to store much more information than a plastic disk of the same size. 27. Laser was dreamt of by mankind


for centuries. 28. The applications of laser in industry and science are known to be numerous and varied. 29. The appearance of laser was followed by the fabrication of ultrathin silicon fibers capable of servicing as lightweight conductors. 30. Some metals and glasses to be cooled down to the point of solidification in space can be brought back to Earth.

2. , .

Programming Languages

The only language computers can understand directly is called machine code. It is known to consist of the Is and 0s (binary code) that are processed by the CPU. However, machine code as a means of communication is very difficult to write. That is why it is necessary to use symbolic languages that are easier to understand. Then, by using a special program, these languages can be translated into machine code.

Basic languages, in which the program is similar to the machine code version, are known as low-level languages. In these languages, each instruction is equivalent to a single machine code instruction, and the program is converted into machine code by a special program called an assembler. These languages are considered to be still quite complex and restricted to particular computers.

To make the program easier to write and to overcome the problem of intercommunication between different types of machines, higher-level languages were developed such as BASIC, COBOL, FORTRAN, Pascal, Ada, and others. A higher-level language is a problem oriented programming language, whereas a low-level language is machine oriented. This means that a high-level language is a convenient and simple means of describing the information structures and sequences of actions to be performed for a particular task.

A high-level language is independent of the architecture of the computer which supports it. This has two advantages. Firstly, the person writing the program does not have to know anything about the computer the program will be run on. Secondly, programs are portable, that is, the same program can (in theory) be run on different types of computer. Programs written in one of these languages should be converted by means of a compiler into a lower-level language or machine code so that the CPU could understand it.


, a high-level programming language, seems to be very popular today because it is small, so it is not too hard to learn, it is very efficient and portable so one can use it with all kinds of computers. A lot of software engineers use to write commercial applications programs for mini, micro and personal computers. There are also various versions of C++ and Objective C, which represent a new style of programming.

At present there is a tendency towards an even higher level of programming languages, which might be called specification languages, and an increasing use of software development tools.

People communicate instructions to the computer in symbolic languages and the easier this communication can be made, the wider the application of computers will be. Scientists are reported to be already working on Artificial Intelligence and the next generation of computers may be able to understand human languages.

3. . 2 .

programming compiler programmed program assembler language programmers portable low-level machine code

1. A computer... is a set of instructions that tells the computer what to do. 2. Converting an algorithm into a sequence of instructions in a programming language is called.... 3. Most computer... make a plan of the program before writing it. 4. Coding is the translation of the logical steps into a programming.... 5. In the next century computers will be... in natural languages like English or French. 6. A... is a special program that converts a program written in a high-level language into a program written in a lower level language. 7. It is difficult to use......, which is the only language understood by the processor. 8. A special program called... converts a program written in a low-level language into machine code. 9. If the same program can be used for different computers, it is called.... 10. In a... language each instruction has a corresponding machine code equivalent.

B. Speak about:

The new programming language you have heard of or read about.


SUPPLEMENTARY TEXTS

To be read after Lesson 1

Education

Most Americans start to school at the age of five when they enter kindergarten. Children do not really study at this time. They only attend for half the day and learn what school is like. Children attend elementary school for next six years. They learn to read and write and work with numbers. They also study the world and its people. After they leave elementary school, children go to junior high school for three years and senior high school for another three years. This is called secondary education. In some places the children go to elementary school for eight years and high school for four. At any rate, elementary and secondary education together take twelve years to complete excluding kindergarten.

In their secondary schooling children get more advanced knowledge and begin to concentrate on their special interests. They usually study further in history, geography, government and English language and literature.

They may choose to study foreign languages, advanced mathematics or science, such as physics or chemistry. Students who plan to go on to college or professional training must take some of these courses in order to enter college. Other students who do not intend to go on with school may take classes in accounting or typing or other subjects that will help them in the business world. Some senior high schools are vocational. Boys may learn to operate machines or do other work. Girls may learn cooking, sewing or office work. High schools have athletic teams which play against teams from other schools. Many boys enjoy playing football, basketball or baseball. These games take place after school hours. Girls are given physical education too, but they do not usually play teams from another schools.

In the most places in the US children must attend school until they are sixteen, or until they finish high school, usually at the age of seventeen or eighteen. Some children who are not good students drop out of school at the age of sixteen. This is a growing problem, for it is harder and harder for people to find work when they have not finished their high school education.

Public schools are free for all boys and girls, but some parents prefer to send their children to private schools. Some private schools are connected with churches and children receive religious


instruction as well as their regular studies. Other private schools are not religious, but have small classes and very good teachers so that the parents think their children will get a better education there than in the larger classes of the public schools. The private schools do not receive any tax money, so most of them must charge the students several hundred dollars a year to pay for the cost of the school. Boys and girls attend the public schools together, but many private schools are for girls only or for boys only.

To be read after Lesson 2

The Trees Fell So Did the People

Early civilisations may have killed themselves off by plundering ( ) local plants and animals. New archeo-logical findings suggest that far from living in perfect harmony with nature, prehistoric civilisation dealt major and sometimes fatal blow to natural surroundings. Many investigators now question the idea that environmental problems began only with the industrial revolution in the 19th century.

Long before the appearance of industrial civilization prehistoric societies were destroying () forests, plants, animals and farmland. Such destruction sometimes destroyed them in turn.

The mysterious disappearance of Anasasi Indians may be a dramatic example of this. In territories that are now New Mexico and Arizona the Indians built a complex of roads, irrigation systems and giant houses with 800 rooms and more. All were abruptly left by them around A.D. 1200. Until now, the majority of archeologists have believed that the reason was a prolonged drought (), but by using an electron microscope to analyze the tree rings American scientists found that over two centuries or so the Indians were systematically deforesting the canyon where they lived until the forests' ability to replenish itself was destroyed.

Some Words About Words

With about 200,000 words in current usage English is generally regarded as the richest of the world's languages. Few other languages can match this word power. Chinese comes close. German has a vocabulary of only 184,000 words, and French has fewer than 100,000 words.

English owes its exceptionally large vocabulary to its ability to borrow and absorb words from outside. Atomic, jeans, khaki, sput-


nik, perestroika, glasnost are just a few of the many words that have come into use during this century. They have been taken or adopted from Italian, Hindi, Creek and Russian. The process of borrowing words from other languages has been going on for more than 1,000 years. When the Normans crossed over from France to conquer England in 1066, most of the English spoke old English or Anglo-Saxon a language of about 30,000 words. The Normans spoke a language which was a mixture of Latin and French. It took about three centuries for the language to become one that is the ancestor of the English they speak today. The Normans gave us words such as city, and palace. The Anglo-Saxon gave us ring and town.

Latin and Greek have been a fruitful source of vocabulary since the 16th century. The Latin word mini, its opposite maxi and the Greek word micro have become popular adjectives to describe everything from bikes to fashion.

To be read after Lesson 3

Nuclear Power? Well, Yes

Although nuclear reactors have generated electricity commercially for more than 40 years and nearly 400 now in operation, two major accidents in the US in 1979 and Chernobyl in the USSR in 1986 have put the industry under a radioactive cloud. In the popular imagination, reactors are nuclear bombs; even if they don't explode, they go on accumulating waste that will finally cause a global catastrophe.

As a result, an energy source once considered as the fuel of the future became questionable. But not everywhere. Nuclear power provides nearly a quarter of the electricity generated in the industrialized Western world by the 24-member countries of the Organization for Economic Cooperation and Development. In France more than 76 % of electric power is nuclear-generated, in Belgium 62 %, Sweden 50 %, Germany, Switzerland, Spain and Finland come in at one third, Japan a little less; Britain, the US and Canada under 20 %. Some countries have no nuclear power plants at all and don't want any.

Not only the strong emotions of fear have worked against nuclear power. Energy demand grew more slowly than expected in the past decade. Prices of oil and coal have reduced. However, energy prices can rise. Moreover, supplies of fossil fuel are limited, while


energy needs and tide () can't meet the increasing requirements. Besides, nuclear power doesn't add to global warming.

All this causes the people to believe that the world can't live and work without nuclear power.

To be read after Lesson 4

Telecommunication

A group of people enter a room, the lights go down, the screens come... the videoconference is under way.

Tomorrow's scientific fiction has become today's new technology -a daily reality for global companies who recognise the importance of regular communication between groups of people in different locations around the world.

Essentially the videoconference room resembles a usual conference room. Delegates sit along one side of a table facing their colleagues on screen on the other side. They can see, hear and talk to each other simultaneously and can present slides of diagrams, even pieces of equipment. The technology is relatively simple. A device called videocodec takes the picture, digitalizes it for transmission over a special network and reforms the picture at the other end.

The problem today is to manufacture codec to the new international standard and to improve picture quality through faster transmission speeds. Research and development is also focusing on mobile videoconferencing with broadcast quality pictures which enable to have instant communication with colleagues around the world.

There is no doubt about the effectiveness of videoconferencing, as the videoconference eliminates the working time lost through travel.

The First Travelling Post Office

The first travelling post office in the United States was Abraham Lincoln's hat. That was a strange place, indeed, for mail; but that is where it was kept. Lincoln was appointed postmaster of New Salem, a small Western town, about the year 1833. The postman visited the place once a week and brought the mail a dozen letters, perhaps, and two or three newspapers in his saddle () bags. He was always met by Postmaster Lincoln who put the letters into his hat for safekeeping. Lincoln was also the clerk in the country store, so he had a good opportunity to distribute the mail. But if


people did not come for it, he put on his hat and delivered it. So New Salem was the first town in the US to have rural free delivery, even though the postmaster received very small pay for his work. At that time, stamps and envelopes were not used. When the sender of a letter paid the postal charges, the postmaster wrote PAID in the large letters on the face of the letter. But the postal rates were so high that the sender seldom paid them. Thus, the mailing charges were usually collected from the person who received the mail. The postmaster always held his postal receipts until a government representative came for them.

The Internet

The Internet is a magnificent global network with millions and millions of computers and people connected to one another where each day people worldwide exchange an immeasurable amount of information, electronic mail, news, resources and, more important, ideas.

It has grown at a surprising rate. Almost everyone has heard about it and an increasing number of people use it regularly. The current estimate is that over 70 million people are connected, in some way, to the Internet whether they know it or not.

With a few touches at a keyboard a person can get access to materials in almost everywhere. One can have access to full-text newspapers, magazines, journals, reference works, and even books. The Web is one of the best resources for up-to-date information. It is a hypertext-based system by which you can navigate through the Internet. Hypertext is the text that contains links to other documents. A special program known as browser can help you find news, pictures, virtual museums, electronic magazines, etc. and print Web pages. You can also click on keywords or buttons that take you to other pages or other Web sites. This is possible because browsers understand hypertext markup language or code, a set of commands to indicate how a Web page is formatted and displayed.

Internet Video conferencing programs enable users to talk to and see each other, exchange textual and graphical information, and collaborate.

Internet TV sets allow you to surf the Web and have e-mail while you are watching TV, or vice versa. Imagine watching a film on TV and simultaneously accessing a Web site where you get information on the actors of the film. The next generation of Internet-enabled televisions will incorporate a smart-card for


home shopping, banking and other interactive services. Internet-enabled TV means a TV set used as an Internet device.

The Internet is a good example of a wide area network (WAN). For long-distance or worldwide communications, computers are usually connected into a wide area network to form a single integrated network. Networks can be linked together by telephone lines or fibre-optic cables. Modern telecommunication systems use fibre-optic cables because they offer considerable advantages. The cables require little physical space, they are safe as they don't carry electricity, and they avoid electromagnetic interference.

Networks on different continents can also be connected via satellites. Computers are connected by means of a modem to ordinary telephone lines or fibre-optic cables, which are linked to a dish aerial. Communication satellites receive and send signals on a transcontinental scale.

To be read after Lesson 5

Harnessing () the Speed of Light

When American engineer Alan Huang revealed his plans to build an optical computer, most scientists considered this idea as hopeless. It was impractical, if not possible, they said, to create a general-purpose computer that could use pulses of light rather than electrical signals to process data. During one of the scientist's lectures on the subject, a third of the audience walked out. At another one, some of the scientists laughed, calling the researcher a dreamer.

That was several years ago. Now the scientist demonstrated his experimental computing machine based on optics. It took him five years to develop it. The device a collection of lasers, lenses and prisms can serve as the basis for future optical computers 100 to 1,000 times as powerful as today's most advanced supercomputers. The potential applications are remarkable: robots that can see, computers that can design aircraft, processors that can convert spoken words into written text and vice versa. Such practical optical computers are still years away some would say light-years.

Yet many scientists are predicting that the device will have an impact similar to that of the integrated circuit which made small personal computers possible.

Photons, the basic unit of light beams, can in theory be much better than electrons for moving signals through a computer. First of all, photons can travel about the times as fast as electrons. And


while electrons react with one another, beams of photons, which have no mass or charge, can cross through one another without interference. Thus, photons can move in free space. This could open the door to radically new and different computer designs, including so-called parallel processors that could work on more than one problem at a time instead of one after another, as today's new generation computers do.

How Transistors Work

Microprocessors are essential to many of the products we use every day such as TVs, cars, radios, home appliances and of course, computers. Transistors are the main components of microprocessors. At their most basic level, transistors may seem simple. But their development actually required many years of thorough research. Before transistors, computers relied on slow, inefficient vacuum tubes and mechanical switches to process information. In 1958, engineers put two transistors onto a silicon crystal and created the first integrated circuit that led to the microprocessor. Here on a tiny silicon chip there are millions of switches and pathways that help computers make important decisions and perform helpful tasks.

Transistors are miniature electronic switches. They are the building blocks of the microprocessor which is the brain of the computer. Similar to a basic light switch, transistors have two operating positions, on and off. This on/off function enables the processing of information in a computer.

The only information computers understand are electrical signals that are switched on and off. To understand how transistors work, it is necessary to have an understanding of how a switched electronic circuit works. Switched electronic circuits consist of several parts. One is the circuit pathway where the electrical current flows typically through a wire. Another is the switch, a device that starts and stops the flow of electrical current by either completing or breaking the circuit's pathway. Transistors have no moving parts and are turned on and off by electrical signals. The on/off switching of transistors facilitates the work performed by microprocessors.

Something that has only two states, like a transistor, can be referred to as binary. The transistor's on state is represented by a 1 and the off state is represented by a 0. Specific sequences and patterns of Ps and 0's generated by multiple transistors can represent letters, numbers, colours and graphics. This is known as binary notation.


More complex information can be created such as graphics, audio and video using the binary, or on/off action of transistors.

Many materials, such as most metals, allow electrical current to flow through them. These are known as conductors. Materials that do not allow electrical current to flow through them are called insulators. Pure silicon, the base material of most transistors, is considered a semiconductor because its conductivity can be modulated by the introduction of impurities.

Adding certain types of impurities () to the silicon in a transistor changes its crystalline structure and improves its ability to conduct electricity.

The binary function of transistors gives microprocessors the ability to perform many tasks; from simple word processing to video editing. Microprocessors have developed to a point where transistors can carry out hundreds of millions of instructions per second on a single chip. Automobiles, medical devices, televisions, computers and even the Space Shuttle use microprocessors. They all rely on the flow of binary information made possible by the transistor.

To be read after Lesson

Ceramic Application

The application which has captured the imagination of engineers, as well as the general public, is certainly the ceramic engine, that is the adiabatic turbo-diesel engine and the ceramic turbine for automotive use. There are some successful phototypes on the road, however, applications on a large scale have been held back by problems of cost and reliability. Steady progress is being made in the increase of the reliability of ceramics. But the cost factor is likely to remain a problem for some time.

One should mention here that the long-term reliability in service still needs to be defined for those applications where the material must withstand very high temperatures and dynamically changing mechanical and thermal loads in a chemically aggressive environment.

Ceramic engines and turbines are but the top of the pyramid with respect to applications. At lower levels of performance there are numerous other applications, in which the operating conditions are less severe, for example, ceramic heat exchangers for chemical plants. Ceramics finds application in bearings and engine parts because of its high hardness and high abrasion resistance.


There are three main materials used in making pipes: metal, rubber and plastic.

Metal is stronger than rubber and plastic. It is also heavier and more rigid than rubber and plastic. Metal is the strongest material, but it is also the heaviest, and the most rigid. It is also the most expensive of the three materials.

Rubber is weaker than metal or plastic. It is also more flexible than the other two materials. Rubber is the most flexible of the three materials, but it is the weakest.

Plastic is lighter than metal. It is also less expensive than steel or rubber. Plastic is the lightest material. It is also the least expensive of the three materials.

Glass is used for making windows because you can see through it, and it is very hard and therefore cannot be cut easily. But at the same time it is very brittle and therefore it can break easily.

Wood is soft and therefore it can be cut easily. It can be used in fires because it is combustible.

Car tyres are made of rubber because rubber is flexible.

A car panel is made by three methods. First, sheet steel is made. This is done by pushing a piece of steel between two rollers, which squeeze the metal and make it longer and thinner. This method is called rolling. Not all metals can be rolled. For example, iron cannot be rolled because it is too brittle. But steel can be rolled because it is tough and malleable () enough.

Next, the steel is cut into a flat shape. This is done by placing the sheet onto a die, and then cutting a hole in it with a punch. The method is called punching. The steel can be cut easily because it is now very thin.

Finally, the sheet steel is bent and pressed into a rounded shape. This is done by putting the sheet onto a die and then bending the sheet around the die with a press. This method is called pressing. It is not difficult to press sheet steel because it is thin and malleable.

To be read after Lesson 7

Electric Car

The electric car is not a new idea. It had success with American women in the early 1900s. Women liked electric cars because they were quiet and, what was more important, they did not pollute the


air. Electric cars were also easier to start than gasoline-powered ones. But the latter was faster, and in the 1920s they became much more popular.

The electric car was not used until the 1970s, when there were serious problems with the availability of oil. The General Motors Co. had plans to develop an electric car by 1980. However, soon oil became available again, and this car was never produced.

Today there is a new interest in the electric car. The Toyota Co. recently decided to spend $800 million a year on the development of new car technology. Many engineers believe that the electric car will lead to other forms of technology being used for transportation.

Car companies are working at developing a supercar. A super-efficient car will have an electric motor. Four possible power sources are being investigated. The simple one is batteries. Another possibility is fuel cells, which combine oxygen from air with hydrogen to make electricity. Yet another approach would be a flywheel (), an electric generator consisting of free-spinning wheels with magnets in the rims that can produce a current. A fourth possible power source for the super-car would be a small turbine engine, running on a clean fuel like natural gas. It would run at a constant speed, generating electricity for driving vehicles or for feeding a bank of batteries, storing energy for later use.

Engines

Do you know what the first engine was like? It was called the water wheel. This was an ordinary wheel with blades fixed to it, and the current of a river turned it. These first engines were used for irrigating fields.

Then a wind-powered engine was invented. This was a wheel, but a very small one. Long wide wooden blades were attached to it. The new engine was driven by the wind. Some of these ones can still be seen in the country.

Both of these, the water- and wind-operated engines are very economical. They do not need fuel in order to function. But they are dependent on the weather.

Many years passed and people invented a new engine, one operated by steam. In a steam engine, there is a furnace and a boiler. The furnace is filled with wood or coal and then lit. The fire heats the water in the boiler and when it boils, it turns into steam which does some useful work.


The more coal is put in the furnace, the stronger the fire is burning. The more steam there is, the faster a train or a boat is moving.

The steam engine drove all sorts of machines, for example, steam ships and steam locomotives. Indeed, the very first aeroplane built by A.F. Mozhaisky also had a steam engine. However, the steam engine had its disadvantages. It was too large and heavy, and needed too much fuel.

The imperfections of the steam engine led to the design of a new type. It was called the internal combustion engine, because its fuel ignites and burns inside the engine itself and not in a furnace. It is smaller and lighter than a steam engine because it does not have a boiler. It is also more powerful, as it uses better-quality fuel: petrol or kerosene.

The internal combustion engine is now used in cars, diesel locomotives and motor ships. But to enable aeroplanes to fly faster than the speed of sound another, more powerful engine was needed. Eventually, one was invented and it was given the name jet engine. The gases in it reach the temperature of over a thousand degrees. It is made of a very resistant metal so that it will not melt.

To be read after Lesson 8

The Driving Lesson

Miss Green: Good afternoon. My name is Miss Green and I'm your driving instructor. Is this your first lesson?

Simon: It is my first lesson at this driving school.

M. G.: Oh, you've been to another one?

S.: Yes. The Greenwich school of driving. But I stopped

going there.

M. G.: Why? Weren't the lessons good enough?

S.: They were good but my instructor left.

M. G.: Really? Well, let's see what you can do. I want you to

drive down this road and turn left at the end.

S.: Yes, all right.

M. G.: You drive very well! I'm sure you'll pass your test. All

my pupils pass their tests. Oh, look out! That lorry!

S.: You said turn left at the end.

M. G.: When you want to turn a corner, slow down and look

first. You nearly hit that lorry. Please, be careful. Now turn right at the traffic lights... Right, not left!


S.: Sorry it was too late. I've turned left now.

M. G.: Didn't you see the No Entry sign? This is a one-way

street.
S.: Why are those drivers shouting?

M. G.: Because you're driving the wrong way down a one-way

street. Stop the car, please, and turn it round.
S.: I'm not very good at that.

M. G.: Mind that red car!

S.: Madman! He nearly hit me!

M. G.: He was right and you were wrong. Why didn't you

wait? Now you are blocking the road. You want reverse gear. Turn the wheel... more... more... Not too

fast! Oh, what have you done now?
S.: It is all right. I went into the lamp-post but it is still

standing. I didn't knock it down.
M.G.: Oh, but look at the back of the car.

S.: Sorry, but you said reverse.

M.G.: I didn't say drive into the lamp-post. Well, you've

turned the car round now, so drive back to the traffic

lights and go straight across.
S.: Are we going to the park?

M.G.: The roads are quiter near the park. Oh, not too fast!

S.: The lights are green.

M.G.: Slow down! The lights are changing!

S.: I can't slow down. There! We are across.

M.G.: The lights were red!

S.: It's all right. There were no policemen.

M.G.: I know why your last instructor left. He wanted to stay

alive.
S.: That's not a very nice thing to say. And it's not true.

He left because he wasn't very well.
M.G.: Stop the car, please. Oh, gently!

S.: Sorry. Did you hit your head on the roof?

M.G.: No. Luckily I was wearing the seat belt. Now I want

you to practise driving backwards. Reverse the park

gates. Look first, than reverse in.
S.: Right.

M.G.: Oh, you've hit the gate!... Now you are driving on the

grass!
S.: I'm going backwards down the hill and I can't stop!

Help me!
M.G.: Use the brakes! Don't drive into the lake!


S.: Too late.

M.G.: Look what you've done. You reversed into a lamp

post. You hit the park gate. Now you've driven into the lake. Oh, why didn't you stay with the other driving school?

S.: They had no more cars left.

Heavy-Lift Dirigible

Unlike other new dirigible projects the giant CargoLifter CL 160 (Germany) is aimed at heavy-lift cargo applications, not at tourism or advertising. It will be the beginning of a new era in freight transport.

The 260-meter-long, 65-meter-diameter semi-rigid airship will be capable of transporting 160 ton loads-equivalent to 36 standard 40-ft containers to out-of-the-way (remote) construction sites 10,000 km away. With a cruise speed of just 80-120 km/hr the CL 160 would not get the load to its destination nearby as fast as a heavier-than-air craft such as Antonov An-124, but it would also not require the landing facilities needed for the unusually large aircraft.

Moored () above the delivery site, the airship will lower loads using an onboard crane without actually having to touch down. A crew of five, including navigator and two cargo-masters ( ) would man the ship.

In fact, the CargoLifter project was born of a logistics need expressed by manufacturers of electric generators, turbines and other outsized (i.e., larger than the usual size) machinery.

Rolls-Royce-Turbomeca turboshaft engines are to be used for maneuvering the big airship, cruise being provided by diesel power-plants.

What Is GPS?

The Global Positioning System (GPS) is a satellite-based navigation system made up of a network of 24 satellites. GPS was originally intended for military applications, but now the systems is available for civilian use. GPS works in any weather conditions, anywhere in the world, 24 hours a day.

GPS satellites circle the earth twice a day in a very precise orbit and transmit signal information to Earth. GPS receivers take this information and use triangulation to calculate the user's exact location. Essentially, the GPS receiver compares the time a signal


was transmitted by a satellite with the time it was received. The time difference tells the GPS receiver how far away the satellite is. Now, with distance measurements from a few more satellites, the receiver can determine the user's position and display it on the unit's electronic map.

A GPS receiver must be locked on to the signal of at least three satellites to calculate a 2D position (latitude and longitude) and track () movement. With four or more satellites in view, the receiver can determine the user's 3D position (latitude, longitude and altitude). Once the user's position has been determined, the GPS unit can calculate other information, such as speed, bearing (), track, trip distance, distance to destination, sunrise and sunset time and more.

Today's GPS receivers are extremely accurate within an average of three to five meters thanks to their parallel multi-channel design.

The 24 satellites that make up the GPS space segment are orbiting the earth about 12,000 miles above us. They are constantly moving, making two complete orbits in less than 24 hours. These satellites are travelling at speeds of roughly 7,000 miles an hour.

GPS satellites are powered by solar energy. They have backup batteries onboard to keep them running in the event of a solar eclipse (), when there's no solar power. Small rocket boosters on each satellite keep them flying in the correct path.

Here are some other interesting facts about the GPS satellites:

1. The first GPS satellite was launched in 1978.

2. A full constellation () of 24 satellites was achieved in 1994.

3. Each satellite is built to last about 10 years. Replacements are constantly being built and launched into orbit.

4. A GPS satellite weighs approximately 2,000 pounds and is about 17 feet across with the solar panels extended.

5. Transmitter power is only 50 watts or less.

GPS satellites transmit two low power radio signals. The signals travel by line of sight, meaning they will pass through clouds, glass and plastic but will not go through most solid objects such as buildings and mountains.

A GPS signal contains three different bits of information a pseudorandom code, ephemeris data and almanac data.

Some factors that can degrade the GPS signal and thus affect accuracy include the following:

1. The satellite signal slows as it passes through the atmosphere.


2. The GPS signal is reflected off objects such as tall buildings or large rock surfaces before it reaches the receiver. This increases the travel time of the signal, thereby causing errors.

3. A receiver's built-in clock is not as accurate as the atomic clocks onboard the GPS satellites. Therefore, it may have very slight timing errors.

4. The more satellites a GPS receiver can see, the better the accuracy. Buildings, terrain, electronic interference, or sometimes even dense foliage () can block signal reception, causing position errors or possibly no position reading at all. GPS units typically will not work indoors, underwater or underground.

To be read after Lesson 9

Getting into Deep Water

The dark depths of the Gulf of Mexico, once frequented by only the sea creatures, are now alive with human activity. Miniature submarines and robot-like vehicles move around the ocean bottom while divers make their way around incredible underwater structures taller than New York City skyscrapers, but almost totally beneath the surface of the waves. Modern-day explorers are using technology worth of Jules Verne and Jacques Cousteau to find fresh supplies of oil and natural gas.

Until recently, drilling in the Gulf was concentrated close to shore in water as deep as 9 m. But now the scientists are looking to hundreds of meters deep and 160 km and more from land.

The deep water research began in 1984. Since then many American companies have built the world's deepest production platforms of more than 100 storeys high. Finding gas and oil deposits at large depth is not an easy technological task.

Voyage to the Bottom of the Sea

There is an American project of one-person submarine, which will fly to the bottom on inverted wings rather than simply sinking under its own weight as the bathyscaphes did. This design is more like an aeroplane than a balloon. It could one day make exploring the ocean depth as easy as flying a plane is today.

The most difficult problem is to find a material that is also light enough to allow the craft to float back to the surface if there is a loss of power or some other emergency. Alumina, a hard ceramic, was chosen for the vessel.


The pilot's capsule is about a meter in diameter, 5 centimeters thick and about 2 meters long. It is capped at one end with a ceramic hemisphere and at the other with a glass viewing dome. The rest of the craft, including the wings on either side and the casing at the rear for the motors, are made of a lightweight composite material.

In addition to the pilot, the pressure vessel houses the controls and instrument panel, the life-support system and a 24-volt power supply. The pilot effectively operates the craft by radio control.

The batteries feed a pair of electric motors that can drive the craft at up to 14 knots (25 kilometers per hour). The craft could dive vertically but this would be uncomfortable for the pilot who lies face downwards in the cylindrical chamber. So it descends at an angle of up to 45. Deep Flight is designed to be as streamlined as possible. This means making the submarine's cross section as small as possible and providing as little equipment as possible on the hull.

At a cruising speed of 10 knots Deep Flight will descend at a rate of 200 meters per minute and reach 11,000 meters in about an hour in the Mariana Trench ( ), the deepest site on Earth. The weight of the craft is 2.5 tonnes, which is about the same as a large car. This will allow it to be launched from any vessel.





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