- •Contents
- •Radio Engineering Text 1. Electronics
- •Text 2. Electron Emission
- •Text 3. The Elements of a System of Radio Communication
- •Text 4. Propagation of Radio Waves of Different Frequencies
- •Text 5. Reception of Radio Signals
- •Text 6. Radio Receivers (I)
- •Text 8. Oscillators
- •Text 9. Radio-Frequency Amplifiers
- •Text 11. Detection
- •Text 13. Functions of Vacuum Tubes
- •Text 14. Basic Tube Types
- •Vacuum Diode
- •Vacuum Triode
- •Text 20. Fundamentals of Radar
- •Text 22. Bearing
- •Text 23. Transistors, the Basic Mechanism
- •Text 24. Radio Transmitters
- •Text 25. Transistor Radio Frequency Amplifiers
- •Computing Technique Text 1. The Computer
- •Text 2. Using the Computer
- •Text 3. Peripheral Equipment
- •Text 4. Computers on Wheels
- •Text 5. Programming a Computer
- •Text 6. The Robot’s Nervous System
- •Text 7. Menu System
- •Text 8. Input, Process, Store, Output
- •In addition
- •Text 9. Input-Output System
- •Text 10. Memory
- •Text 11. Automatic Translator
- •Text 12. Universal Electronic Computer
- •Text 13. What Is a Digital Computer?
- •Text 14. Digital Computers
- •Text 15. Analog Versus Digital Computers
- •Text 16. Age of Thinking Machines
- •Text 17. General- and Special-Purpose Computers
- •Text 18. Programming
- •Text 19. Types of Instructions
- •Text 20. Simple Hardware, Complicated Logic
- •Text 22. Video Terminals
- •In a pictorial form [pik'torrial] — у вигляд зображення
Text 4. Propagation of Radio Waves of Different Frequencies
As radio waves travel away from their point of origin, they become attenuated or weakened. This is due in part to the fact that the waves spread out.
In addition, however, energy may be absorbed from the waves by the ground or by ionized regions in the upper atmosphere, and the waves may also be reflected or refracted by the earth, by ionized regions in the upper atmosphere, or by conditions within the lower atmosphere. The resulting situation is quite complex and differs greatly for radio waves of different frequencies.
Radiation of Electrical Energy
Every electrical circuit carrying alternating current radiates a certain amount of electrical energy in the form of electromagnetic waves, but the amount of energy thus radiated is extremely small unless all the dimensions of the circuit approach the order of magnitude of a wave length. Thus, a power line carrying 60-cycle current with a 20-ft. spacing between conductors will radiate practically no energy because a wave length at 60 cycles is more than 3 000 miles, and 20 ft. is negligible in comparison.
On the other hand, a coil 20 ft. in diameter and carrying a 2 000-kc current will radiate a considerable amount of energy because 20 ft. is comparable with the 150-meter wave length of the radio wave.
From these considerations it is apparent that the size of radiator required is inversely proportional to the frequency.
High-frequency waves can therefore be produced by a small radiator, while low-frequency waves require a large antenna system for effective radiation.
Every radiator has directional characteristics as a result of which it sends out stronger waves in certain directions than in others.
Directional characteristics of antennas are used to concentrate the radiation toward the point to which it is desired to transmit, or to favor reception of energy arriving from a particular direction.
Generation and Control of Radio-Frequency Power
The radio-frequency power required by a radio transmitter is practically always obtained from a vacuum-tube, oscillator or amplifier.
Vacuum tubes can convert direct-current power into alternating-cur- rent energy, for all frequencies from the very lowest up to 30 000 me, or even greater.
Under most conditions the efficiency with which this transformation takes place is in the neighbourhood of 50 percent or higher. At frequencies up to well over 1,000 me, the amount of power that can be generated continuously by vacuum tubes is of the order of kilowatts.
Notes
to attenuate [a'tenjueit] |
— виснажувати |
to absorb [ab'soib] |
— вбирати; поглинати |
magnitude ['maegnitjuid] |
— величина |
negligible ['neglidjsbl] |
— незначний |
oscillator [^si'leita] |
— вібратор |
Text 5. Reception of Radio Signals
In the reception of radio signals it is first necessary to abstract energy from the radio waves passing the receiving point.
After this has been done, the radio receiver must next separate the desired signal from other signals that may be present, and then reproduce the original intelligence from the radio waves. In addition, arrangements are ordinarily provided for amplification of the received energy so that the output of the radio receiver can be greater than the energy abstracted from the wave.
Any antenna system capable of radiating electrical energy is also able to abstract energy from a passing radio wave, because the electromagnetic flux of the wave in cutting across the antenna conductors induces a voltage that varies with time in exactly the same wave as the current flowing in the antenna radiating the wave.
The energy represented by the current flowing in the receiving antenna system is abstracted from the passing wave and will be greatest when the reactance of the antenna system has been reduced to a minimum by making the antenna circuit resonant to the frequency of the wave to be received.
Since every wave passing the receiving antenna induces its own voltage in the antenna conductor, it is necessary that the receiving equipment be capable of separating the desired signal from the unwanted signals that are also inducing voltages in the antenna.
This separation is made on the basis of the difference in frequency between transmitting stations and is carried out by the use of resonant circuits which can be made to discriminate very strongly in favour of a particular frequency.
It has already been pointed out that, by making the antenna circuit resonant to a particular frequency, the energy abstracted from radio waves of that frequency will be much greater than the energy from waves of other frequencies; this alone gives a certain amount of separation between signals.
Still greater selective action can be obtained by the use of additional suitably adjusted resonant circuits located somewhere in the receiver in such a way as to reject all but the desired signals.
The ability to discriminate between radio waves of different frequencies is called selectivity and the process of adjusting circuits to resonance with the frequency of a desired signal is spoken of as tuning.
Although intelligible radio signals have been received from stations thousands of miles distant, using only the energy abstracted from the radio wave by the receiving antenna, much more satisfactory reception can be obtained if the received energy is amplified.
This amplification may be applied to the radio-frequency currents before detection, in which case it is called radio-frequency amplification; or it may be applied to the rectified currents after detection, which is called audio-frequency amplification.
The use of amplification makes possible the satisfactory reception of signals from waves that would otherwise be too weak to give an audible response. The only satisfactory method of amplifying radio signals that has been discovered is the use of vacuum tubes. Before such tubes were discovered, radio reception had available only the energy abstracted from the radio wave by the receiving antenna.
Notes
to receive [nfeiiv] |
— сприймати, приймати |
resonant [tezansnt] |
— який звучить |
conductor [ksn'dAkta] |
— провідник |
frequency ['friikwsnsi] |
— частота; частотність |
to reject [ri^ekt] |
— відхиляти |
to tune [tju:n] |
—настроювати |
to amplify [ismplifai] |
— посилювати |
amplification [jaemplififei/n] |
— збільшення, поширення, посилення |
reactance [ri;laektans] |
— реактивний опір |
voltage [ivoultidj] |
— напруга |
to detect [ditakt] |
— випрамляти |
audible [bidabl] |
— чутний |