AM SUPERHETERODYNE RECEIVER

and tuned. Measurement of selectivity is usually done by taking a series of sensitivity readings in which the input signal is stepped along a band of frequencies above and below resonance of the receiver’s circuits. As the frequency to which the receiver is tuned is ap- proached, the input level required to maintain a given output will fall. As the tuned frequency is passed, the input level will rise. Input levels are then plotted against frequency. The steepness of the curve at the tuned frequency indicates the selectivity of the re- ceiver. Fidelity Fidelity is a receiver’s ability to reproduce the in- put signal accurately. Generally, the broader the bandpass, the greater the fidelity. Measurement is taken by modulating an input frequency with a series of audio frequencies and then plotting the output measurements at each step against the audio input. The curve will show the limits of reproduction. Good selectivity requires a narrow bandpass. Good fidelity requires a wider bandpass to amplify the outer- most frequencies of the sidebands. Knowing this, you can see that most receivers are a compromise between good selectivity and high fidelity. AM SUPERHETERODYNE RECEIVER The superheterodyne receiver was developed to overcome the disadvantages of earlier receivers. A block diagram of a representative superheterodyne re- ceiver is shown in figure 1-7. Superheterodyne receiv- ers may have more than one frequency-converting stage and as many amplifiers as needed to attain the de- sired power output. FM SUPERHETERODYNE RECEIVER Fundamentally, FM and AM receivers function similarly. However, there are important differences in component construction and circuit design because of differences in the modulating techniques. Comparison of block diagrams (figures 1-7 and 1-8) shows that electrically there are two sections of the FM receiver that differ from the AM receiver: the discriminator (de- tector) and the accompanying limiter. FM receivers have some advantages over AM re- ceivers. During normal reception, FM signals are static- free, while AM is subject to cracking noise and whistles. Also, FM provides a much more realistic reproduction of sound because of the increased number of sidebands. Figure 1-8.—FM superheterodyne receiver and waveforms. 1-9