Digital Signal Processing
Covers the analysis and representation of discrete-time signals and systems, including discrete-time convolution, difference equations, the z-transform, and the discrete-time Fourier transform. Emphasis is placed on the similarities and distinctions between discrete-time and continuous-time signals and systems. Also covers digital network structures for implementation fo both recursive (infinite impulse response) and nonrecursive (finite impulse response) digital filters with four videocassettes devoted to digital filter design for recursive and nonrecursive filters. Concludes with a discussion of the fast Fourier transform algorithm for computation of the discrete Fourier transform.
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DISCRETETIME SIGNALS AND SYSTEMS
FLOW GRAPH AND MATRIX REPRESENTA
DIGITAL FILTER DESIGN TECHNIQUES
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analog filter applied approximation arithmetic assume autocorrelation autocovariance causal cepstrum chapter circular convolution coefficients complex cepstrum complex logarithm computation consider continuous-time corresponding defined denote depicted in Fig derived determine difference equation digital filter digital signal processing discrete Fourier transform discussed error example expressed FFT algorithm finite finite-duration sequence FIR filter FIR system first-order fixed-point floating-point frequency response H(eia Hilbert transform implementation impulse response integral inverse length linear phase linear shift-invariant system linear system lowpass filter magnitude minimum phase minimum-phase multiplication node noise sources noise-to-signal ratio obtain output noise parameters passband periodic sequence periodogram poles and zeros polynomial power spectrum Problem properties quantization random process random variables realization region of convergence representation represented result samples second-order sequence x(n Show shown in Fig spectrum estimate stopband system function techniques theorem truncation two-dimensional unit circle unit-sample response variance z-plane z-transform