summaryrefslogtreecommitdiff
path: root/macros/cheby2.sci
blob: d22ef866f18fbc6d0a4e1c0bea966ef1ea57ee1f (plain)
1
2
3
4
5
6
7
8
9
10
11
12
13
14
15
16
17
18
19
20
21
22
23
24
25
26
27
28
29
30
31
32
33
34
35
36
37
38
39
40
41
42
43
44
45
46
47
48
49
50
51
52
53
54
55
56
57
58
59
60
61
62
63
64
65
66
67
68
69
70
71
72
73
74
75
76
77
78
79
80
81
82
83
84
85
86
87
88
89
90
91
92
93
94
95
96
97
98
99
100
101
102
103
104
105
106
107
108
109
110
111
112
113
114
115
116
117
118
119
120
121
122
123
124
125
126
127
128
129
130
131
132
133
134
135
136
137
138
139
140
141
142
143
144
145
146
147
148
149
150
151
152
153
// Copyright (C) 2018 - IIT Bombay - FOSSEE
//
// This file must be used under the terms of the CeCILL.
// This source file is licensed as described in the file COPYING, which
// you should have received as part of this distribution.  The terms
// are also available at
// http://www.cecill.info/licences/Licence_CeCILL_V2-en.txt
// Original Source : https://octave.sourceforge.io/signal/
// Modifieded by:Sonu Sharma, RGIT Mumbai
// Organization: FOSSEE, IIT Bombay
// Email: toolbox@scilab.in

function [a, b, c, d] = cheby2 (n, rs, w, varargin)
    //Chebyshev type II filter design with rs dB of stopband attenuation.

    //Calling Sequence
    //[b, a] = cheby2 (n, rs, ws)
    //[b, a] = cheby2 (n, rs, ws, "high")
    //[b, a] = cheby2 (n, rs, [wl, wh])
    //[b, a] = cheby2 (n, rs, [wl, wh], "stop")
    //[z, p, g] = cheby2 (…)
    //[…] = cheby2 (…, "s")

    //Parameters
    //n: positive integer value (order of filter)
    //rs: non negative scalar value (stopband attenuation in dB)
    //ws: positive real value,
    //    1).Normalised digital stopband edge(s) for digital filter, in the range [0, 1] {dimensionless}
    //    2).Analog stopband edge(s) for analog filter, in the range [0, Inf] {rad/sec}

    //Description
    //This function generates a Chebyshev type II filter with rs dB of stopband attenuation.
    //The fourth parameter takes in high or low, default value is low. The cutoff is pi*Wc radians.
    //[b, a] = cheby2(n, Rp, [Wl, Wh]) indicates a band pass filter with edges pi*Wl and pi*Wh radians.
    //[b, a] = cheby2(n, Rp, [Wl, Wh], ’stop’) indicates a band reject filter with edges pi*Wl and pi*Wh radians.
    //[z, p, g] = cheby2(...) returns filter as zero-pole-gain rather than coefficients of the numerator and denominator polynomials.
    //[...] = cheby2(...,’s’) returns a Laplace space filter, w can be larger than 1.

    //Examples
    //[z, p, g]=cheby2(2,5,0.7,"high")
    //Output:
    // g  =
    //
    //    0.4752770
    // p  =
    //
    //  - 0.3938806 + 0.5313815i  - 0.3938806 - 0.5313815i
    // z  =
    //
    //  - 0.3164543 - 0.9486078i  - 0.3164543 + 0.9486078i

    funcprot(0);
    [nargout nargin] = argn();

    if (nargin > 5 | nargin < 3 | nargout > 4 | nargout < 2)
        error("cheby2: invalid number of inputs");
    end

    // interpret the input parameters
    if (~ (isscalar (n) & (n == fix (n)) & (n > 0)))
        error ("cheby2: filter order N must be a positive integer");
    end

    stop = %F;
    digital = %T;
    for i = 1:length(varargin)
        select (varargin(i))
        case "s"
            digital = %F;
        case "z"
            digital = %T;
        case "high"
            stop = %T;
        case "stop"
            stop = %T;
        case "low"
            stop = %T;
        case "pass"
            stop = %F;
        else
            error ("cheby2: expected [high|stop] or [s|z]");
        end
    end

    [rows_w columns_w] = size(w);

    if (~ ((length (w) <= 2) & (rows_w == 1 | columns_w == 1)))
        error ("cheby2: frequency must be given as WS or [WL, WH]");
    elseif ((length (w) == 2) & (w(2) <= w(1)))
        error ("cheby2: W(1) must be less than W(2)");
    end

    if (digital & ~ and ((w >= 0) & (w <= 1)))
        error ("cheby2: all elements of W must be in the range [0,1]");
    elseif (~ digital & ~ and (w >= 0))
        error ("cheby2: all elements of W must be in the range [0,inf]");
    end

    if (~ (isscalar (rs) & or(type(rs) == [1 5 8]) & (rs >= 0)))
        error ("cheby2: stopband attenuation RS must be a non-negative scalar");
    end

    // Prewarp to the band edges to s plane
    if (digital)
        T = 2;       // sampling frequency of 2 Hz
        w = 2 / T * tan (%pi * w / T);
    end

    // Generate splane poles and zeros for the Chebyshev type 2 filter
    // From: Stearns, SD; David, RA; (1988). Signal Processing Algorithms.
    //       New Jersey: Prentice-Hall.
    C = 1;  // default cutoff frequency
    lambda = 10^(rs / 20);
    phi = log (lambda + sqrt (lambda^2 - 1)) / n;
    theta = %pi * ([1:n] - 0.5) / n;
    alpha = -sinh (phi) * sin (theta);
    beta = cosh (phi) * cos (theta);
    if (modulo (n, 2))
        // drop theta==pi/2 since it results in a zero at infinity
        zero = 1*%i * C ./ cos (theta([1:(n - 1) / 2, (n + 3) / 2:n]));
    else
        zero = 1*%i * C ./ cos (theta);
    end
    pole = C ./ (alpha.^2 + beta.^2) .* (alpha - 1*%i * beta);

    // Compensate for amplitude at s=0
    // Because of the vagaries of floating point computations, the
    // prod(pole)/prod(zero) sometimes comes out as negative and
    // with a small imaginary component even though analytically
    // the gain will always be positive, hence the abs(real(...))
    gain = abs (real (prod (pole) / prod (zero)));

    // splane frequency transform
    [zero, pole, gain] = sftrans (zero, pole, gain, w, stop);

    // Use bilinear transform to convert poles to the z plane
    if (digital)
        [zero, pole, gain] = bilinear (zero, pole, gain, T);
    end

    // convert to the correct output form
    if (nargout == 2)
        [a b] = zp2tf(zero, pole, gain);
    elseif (nargout == 3)
        a = zero;
        b = pole;
        c = gain;
    else
        // output ss results
        //[a, b, c, d] = zp2ss (zero, pole, gain);
        error("cheby2: yet not implemented in state-space form OR invalid number of o/p arguments")
    end
endfunction