(translation), modulation, and othe

(translation), modulation, and others are necessary. This unit will provide the background material helpful to understanding these concepts.
If you were asked to define communication, you would probably say that it had to do with the exchange of information. This is essentially what communication is, and it is for this purpose that communications systems exist. A more precise definition of communication would be that it is the transfer of information from one place, or person, to another. A block diagram representation of a basic communications system is shown in Figure 1.

Figure 1. A basic communication system.
The essential parts of the system as shown are the sender or transmitter, the transmission line, and the receiver. The direction of information flow is from sender to receiver, which indicates why the terms transmitter and receiver are used. This system, however, is unidirectional. For a complete communications system to exist, we must have the same equipment operating in the opposite direction. Otherwise, the one who receives the information cannot make his response known to the sender. This is generally taken for granted in the study of communications systems, and not often mentioned.
Now that the concept of a communications system has been defined, let us define electronic communications. It is based on the use of electrical energy to transmit information. Since electrical energy can travel nearly as fast as light, communication is almost instantaneous. The original form of the information (sounds, images) must be converted to electrical signals, which are then transmitted directly over wires, or radiated through the air as electromagnetic radio waves. These signals are picked up by the receiver and reconverted to their original form so that the information can be understood.
In order to transmit information using radio waves, a way must be found to add the information to the radio signal. This process is called modulation, and the three principal forms of modulation found in analog communications are amplitude modulation, frequency modulation, and phase modulation. It is either the amplitude, the frequency, or the phase of the radio signal that is made to change in accordance with the amplitude of the information signal. The information signal is generally a low frequency audio signal in the case of AM. In this manual, the information signal will be referred to as the message, which is usually a low frequency audio signal in the 20 Hz to 20 kHz range. The radio frequency (RF) signal is known as the carrier, and the frequencies of the message and the RF carrier are symbolized by fm and fC respectively.
In amplitude modulation, the amplitude of the carrier wave is made to vary in accordance with the message signal. The waveform of a typical AM signal is shown in Figure 2. It represents a high frequency carrier modulated by a sine wave. Notice the dashed curve drawn through the peaks and valleys of the AM waveform. This is called the envelope and it is identical to the waveform of the message signal.

Figure 2. A typical AM signal
When the RF carrier wave is amplitude modulated, sidebands (or sideband frequencies) are produced. For a 2-kHz tone that modulates a 1000 kHz (1 MHz) carrier, the sideband frequencies are fC + fm = 1 002 000 Hz, and fC - fm = 998 000 Hz. Figure 3 shows the frequency components of the AM signal.

Figure 3. Frequency components of an AM signal.
If the transmitted message signal is the human voice, which contains frequencies between 200 Hz and 3 kHz, the sidebands generated on each side of the carrier occupy a range of frequencies equal to the one occupied by the message signal. In this particular case, each sideband is 3000 - 200 = 2800 Hz wide. The sidebands are known as the upper sideband and the lower sideband (USB and LSB respectively). For a 1000 kHz carrier, the LSB ranges from 997 000 to 999 800 Hz, and the USB ranges from 1 000 200 to 1 003 000 Hz. Figure 4 shows the sidebands generated in AM voice communications.

Figure 4. AM sidebands generated in voice communications.
If you have already seen telecommunication installations, you will have noticed that there are many kinds of antenna structures. They vary in size from small to very large and yet, they are all used to perform the same function - communication using radio frequency signals. To be effective, the size of an antenna should be at least one-half the wavelength of the radio frequency. This means that a 1000 Hz signal having a wavelength of 300 km, would require an antenna 150 km long - not a very practical size. One way of avoiding this problem is to move (translate) the frequency contents of the message to a higher place in the frequency spectrum. Thus, a 1000-Hz signal that is converted to 1000 kHz before transmission only requires an antenna 150 meters long. As a general rule, the higher the radio frequency, the smaller the antenna.
A mixer (multiplier) (Figure 5 (a))