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6.3.7 Single-Sideband Suppressed-Carrier AM

Although there is no carrier and the transmitter power is now devoted solely to the sidebands, DSB is also still inefficient because the transmission bandwidth must still be twice that of the message bandwidth due to the transmission of two sidebands, both of which contain identical information. When only one sideband is transmitted, the transmission is called single-sideband suppressed carrier (SSBSC), or more commonly, SSB. Generally, the term used refers to the particular sideband transmitted and the transmission is called upper side band (USB) or lower sideband (LSB). SSB reduces the transmission bandwidth to approximately the baseband bandwidth and is power-efficient since all of the transmitted power goes toward transmitting the baseband information. Figure 6.12 shows the frequency spectrum of an LSB waveform.

Figure 6.12. Frequency spectrum of an LSB waveform for baseband frequencies between f1 and fn.

SSB modulation. The most straightforward method of generating SSB is to generate DSB and to filter out the redundant sideband. As shown in Figure 6.13, however, an ideal cut-off characteristic is required for the sideband filter to ensure that the modulator neither attenuates a portion of the desired pass band nor passes a portion of the undesired sideband. Fortunately, this problem is most difficult when the baseband signal comprises frequencies from zero upwards. If the baseband signal is audio, for example, the frequencies will extend from approximately 300–3,400 Hz giving sufficient margin at the lower end of the sideband to accommodate the inefficiencies of the cut-off filter. SSB can also be generated by the phase-shift method that removes the need for sideband filters. However, the design of the phase-shift circuitry is not straightforward and distortion of low-frequency components means that the system still only operates best with baseband signals that have small low-frequency content.

Figure 6.13. (a) Ideal sideband filter, and a practical sideband filter that (b) attenuates a portion of the desired sideband, or (c) passes a portion of the undesired sideband.

SSB reception. In SSB systems, the suppressed carrier frequency lies at one edge of the transmitted spectrum. As illustrated in Figure 6.14 for USB, early analog SSB receivers often appeared to require tuning approximately 1.5–2 kHz away from the center of the transmitted sideband because the receiver display referred to the suppressed carrier frequency rather than the spectral center of the transmitted signal. Modern synthesized and DSP-based receivers automatically generate the required carrier insertion frequency internally, so operators simply tune to the assigned channel frequency. To assist the receiver, as illustrated in Figure 6.15 for LSB, the transmitter can also insert a pilot (or reduced carrier) which uses a little additional power but aids the receiver in synchronizing to the carrier.

Figure 6.14. Illustration of offset tuning for an SSB receiver
Figure 6.15. Frequency spectrum of an LSB waveform for baseband frequencies between f1 and fn.

SSB applications. Analog SSB has numerous applications, even in a digital world:

SSB demodulation. As with DSB, the complexity and hence the cost of the SSB receiver is increased by the need for the carrier to be re-inserted extremely accurately to avoid distortion of the demodulated signal. In modern receivers a frequency synthesizer can be used to generate a very stable carrier. In older radios, a low-amplitude pilot carrier is transmitted in addition to the sideband. The pilot carrier is used by automatic frequency control (AFC) circuitry in the receiver to maintain the frequency of the re-inserted carrier within the prescribed limits.

Advantages of single-sideband operation. SSB is the preferred modulation for HF radio communications since it occupies minimum bandwidth. SSB operation of a radio system has a number of advantages over AM and DSB:

Disadvantages of single-sideband operation. Although SSB is more bandwidth- and power-efficient than AM and DSB, it has a number of disadvantages: