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Frequency Modulation ReviewFrequency Modulation (FM) results in an identical signal to phase modulation, however the terminology is different. For an ideal oscillator s(t) = A sin(wct) .. (1.5) the phase at any time is given by wct, note that it changes steadily with time with slope wc. This leads to the definition of the instantaneous frequency as the rate of change of the phase of the signal with time. So for the phase modulated signal s(t) = A sin(wct + qpk sin(wmt)) .. (1.6) the phase at any time is wct + qpksin(wmt), and differentiating (1.6) leads to instantaneous frequency = wc + qpk wm cos(wmt) Thus the carrier frequency wc is sinusoidally modulated with peak frequency deviation wpk given by wpk = qpk wm define b = qpk = wpk / wm = fpk / fm .. (1.7) where b is the Modulation Index. Notice that the modulation index is the ratio of the peak frequency deviation to the modulating frequency, and that this can be calculated using both frequencies as radian frequencies, or both in Hz. The Modulation Index also represents the peak phase deviation in radians. The frequency modulated signal becomes s(t) = A sin(wct + b cos(wmt)) .. (1.8) Thus we can repeat the spectra shown on the previous page for PM, but in this case simply change the labels from phase deviation to modulation index. So for a 0dBm carrier at 100MHz, being frequency modulated by a 100kHz sine wave with various values of the modulation index, the spectra are shown in the following table:
As it is equivalent to Phase Modulation, Frequency Modulation is also non-linear modulation.
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