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authorRashpat932024-08-09 11:47:44 +0530
committerGitHub2024-08-09 11:47:44 +0530
commitaf6fe82f90dcb2314a3d37a9a1e297fb0fc447f3 (patch)
tree80effebb59b2042de6635493f4831ba215f19eee /macros/shanwavf.sci
parentb10cff2c07747b039e3c3ee83a34d437e958356b (diff)
parent2e21edde1c1a251a60739b15e1c699172401f044 (diff)
downloadFOSSEE-Signal-Processing-Toolbox-master.tar.gz
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Merge pull request #17 from avinashlalotra/masterHEADmaster
Abinash's Work
Diffstat (limited to 'macros/shanwavf.sci')
-rw-r--r--macros/shanwavf.sci65
1 files changed, 37 insertions, 28 deletions
diff --git a/macros/shanwavf.sci b/macros/shanwavf.sci
index a597214..e088f60 100644
--- a/macros/shanwavf.sci
+++ b/macros/shanwavf.sci
@@ -1,30 +1,39 @@
+/*Description
+ Compute the Complex Shannon wavelet.
+ The complex Shannon wavelet is defined by a bandwidth parameter fb, a wavelet center frequency fc, and the expression
+ psi(x) = f * b^{1/2}sinc(fb . x) e^{2 pi i f c x}
+ on an n-point regular grid in the interval of lb to ub.
+Calling Sequence
+ [psi, x]= shanwavf(lb, ub, n, fb, fc)
+Input Parameters
+ lb, ub (Real valued scalers) : Interval endpoints lb ≤ ub, specified as a pair of real-valued scalars.
+ n (Real valued integer strictly positive)` : Number of regularly spaced points in the interval [lb,ub], specified as a positive integer.
+ fb : Time-decay parameter of the wavelet (bandwidth in the frequency domain). Must be a positive scalar.
+ fc : Center frequency of the complex Shannon wavelet, specified as a positive scalar.
+Output Parameters
+ psi : Complex Shannon wavelet evaluated on the n point regular grid x in the interval [lb,ub], returned as a 1-by-n vector.
+ x : Grid where the complex Shannon wavelet is evaluated, returned as a 1-by-n vector. The sample points are evenly distributed between lb and ub.
+Examples
+ 1.[a,b]=shanwavf (2,8,3,1,6)
+ a = [-3.8982e-17 + 1.1457e-31i 3.8982e-17 - 8.4040e-31i -3.8982e-17 + 4.5829e-31i]
+ b = [2 5 8] */
function [psi,x]=shanwavf(lb,ub,n,fb,fc)
-
-// Complex Shannon Wavelet
-// Calling Sequence
-// [psi,x]=shanwavf(lb,ub,n,fb,fc)
-// Parameters
-// lb: Real or complex valued vector or matrix
-// ub: Real or complex valued vector or matrix
-// n: Real valued integer strictly positive
-// fb: Real or complex valued vector or matrix, strictly positive value for scalar input
-// fc: Real or complex valued vector or matrix, strictly positive value for scalar input
-// Description
-// This is an Octave function
-// This function implements the complex Shannon wavelet function and returns the value obtained. The complex Shannon wavelet is defined by a bandwidth parameter FB, a wavelet center frequency FC on an N point regular grid in the interval [LB,UB].
-// Examples
-// 1. [a,b]=shanwavf (2,8,3,1,6)
-// a = [-3.8982e-17 + 1.1457e-31i 3.8982e-17 - 8.4040e-31i -3.8982e-17 + 4.5829e-31i]
-// b = [2 5 8]
-// 2. [a,b]=shanwavf(1,2,1,[2,2;i,2],[-1,2;-i,i])
-// a = [-5.5128e-17 - 2.7005e-32i -5.5128e-17 + 5.4010e-32i;
-// 8.6404e+06 + 8.6404e+06i -1.9225e-22 - 0.0000e+00i]
-// b = 2
-
-funcprot(0);
-rhs=argn(2);
-if (rhs~=5) then
- error ("Wrong number of input arguments.")
-else [psi,x]=callOctave("shanwavf",lb,ub,n,fb,fc)
-end
+ funcprot(0);
+ rhs=argn(2);
+ if (rhs~=5) then
+ error ("Wrong number of input arguments.")
+ else
+ if (n <= 0 || floor(n) ~= n)
+ error("n must be an integer strictly positive");
+ elseif (fc <= 0 || fb <= 0)
+ error("fc and fb must be strictly positive");
+ end
+ x = linspace(lb,ub,n);
+ sincx=x;
+ for i=1:n
+ sincx(i)=sin(fb*x(i)*%pi)/(fb*x(i)*%pi);
+ end
+ psi = (fb.^0.5).*(sincx.*exp(2.*%i.*%pi.*fc.*x));
+ end
endfunction
+