MODULATION/DEMODULATION

as the preamble. The principal function of the preamble is to alert the receiver of incoming data and provide a reference to synchronize the receiver with the transmitted signal. Following the preamble is a start code that informs the receiving equipment of the beginning of the message data. The basic format of the synchronous data message is shown in figure 1-3. The incoming bit stream is then used to synchronize the receiver or demodulator timing. A stop code follows the message data to indicate the end of transmission. MODULATION/DEMODULATION Modulation modifies a signal so it can carry data over the communications channel. The demodulator removes the data from the carrier. For most data communications applications, the carrier is a continuous sinusoidal waveform (sine wave). The frequency of the carrier varies, depending on the application. Landline transmission generally uses the audio-frequency bandwidth signals (300 to 3,000 Hz). Radio channels use audio-frequency tones as data carriers modulated to a radio-frequency signal, or they modulate the radio-frequency signal itself to convey data. The three basic modes of modulation are amplitude modulation, frequency modulation, and phase modulation. Each of these modes modifies the carrier signal in some manner to convey data. Amplitude Modulation When amplitude modulation is used for digital transmissions, the amplitude of the carrier signal represents the two discrete data states (1 or 0). The signal represents a logic 1 when the amplitude (peak-to-peak), at the same frequency, is greater at a different time, as shown in figure 1-4. The decrease in signal amplitude, below a predetermined threshold, indicates a change from a logic 1 to a logic 0. Frequency Modulation The frequency of the carrier signal or audio tones modulated to the carrier signal can be modified to indicate the two discrete states. As shown in figure Figure 1-4.—Amplitude modulation. 1-5, a selected frequency can be used to indicate the 1 state of a bit, and another selected frequency can be used to indicate the 0 state. The change in frequency, or frequency shift, indicates the same relationship as the change in amplitude did in amplitude modulation. Figure 1-5.—Frequency modulation. Shifting the frequency of the carrier signal is called frequency-shift keying (FSK) or binary frequency-shift keying (BFSK). FSK usually involves shifts to frequencies above or below a selected center frequency. Transmission of the frequency above the center frequency indicates a binary 1; the frequency below the center frequency indicates a binary 0. The center frequency is not transmitted. FSK is used in systems such as link 4A. Another method of using frequency shifts involves audio-frequency tones. Two discrete audio tones may be modulated to a constant frequency carrier signal. One of the tones is used to indicate a mark, or binary 1, the other a space, or binary 0. This method of frequency modulation is called audio-frequency tone shift (AFTS). Phase Modulation Phase modulation is modulation. It is based 1-6 a more complex mode of on the relationship of the