Figure 1.3 Periodic sound signal.
Figure 1.4 Frequency spectrum of the periodic signal of Figure 1.3.
1.3.2 Nonperiodic Functions and the Fourier Spectrum
Equation (1.1) is known as a Fourier series and can only be applied to periodic signals. Very often a sound signal is not a pure or a complex tone but is impulsive in time. Such a signal might be caused in practice by an impact, explosion, sonic boom, or the damped vibration of a mass‐spring system (see Chapter 2 of this book) as shown in Figure 1.2c. Although we cannot find a Fourier series representation of the wave in Figure 1.2c because it is nonperiodic (it does not repeat itself), we can find a Fourier spectrum representation since it is a deterministic signal (i.e. it can be predicted in time). The mathematical arguments become more complicated [1, 7, 9] and will be omitted here. Briefly, the Fourier spectrum may be obtained by assuming that the period of the motion, T, becomes infinite. Then since f = ω/2π = 1/T, the fundamental frequency approaches zero and Eq. (1.2) passes from a summation of harmonics to an integral:
Just as Cn was complex in Eq. (1.2), X(ω) is complex in Eq. (1.5), having both a magnitude and a phase. The Fourier spectrum (magnitude), ∣ X(ω)∣, of the wave in Figure 1.2c is plotted to the right of Figure 1.2c. ∣ X(ω)∣may be thought of as the amplitude of the time signal at each value of frequency ω.
1.3.3 Random Noise
So far we have discussed periodic and nonperiodic signals. In many practical cases the sound or vibration signal is not deterministic (i.e. it cannot be predicted) and it is random in time (see Figure 1.5). For a random signal, x(t), mathematical descriptions become difficult since we have to use statistical theory [1, 7, 9]. Theoretically, for random signals the Fourier transform X(ω) does not exist unless we consider only a finite sample length of the random signal, for example, of duration τ in the range 0 < t < τ. Then the Fourier transform is
where X(ω,τ) is the finite Fourier transform of x(t). Note that X(ω) is defined for both positive and negative frequencies. In the real world x(t) must be a real function, which implies that the complex conjugate of X must satisfy X(−ω) = X*(ω); i.e. X(ω) exhibits conjugate symmetry. Finite Fourier transforms can easily be calculated with special analog‐to‐digital computers (see Section 1.5).
Figure 1.5 Random noise signal.
Example 1.2
An R–C (resistance–capacitance) series circuit is a classic first‐order low‐pass filter (see Section 1.4). Transient response describes how energy that is contained in a circuit will become dissipated when no input signal is applied. The transient response of an R–C series circuit (for t > 0) is given by
Find the Fourier spectrum representation of this transient response.
Solution
Substituting x(t) into Eq. (1.6) we obtain
Therefore,
The transient response and its Fourier spectrum are shown in Figure 1.6.
Figure 1.6 Time and frequency domain representations of the transient response of an R–C series circuit.
Example 1.3
The impulse response of a dynamic system is its output in response to a brief input pulse signal, called an impulse. The impulse response of the damped vibration of a one‐degree‐of‐freedom mass‐spring system of mass M,