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annotate gen_ddm_3.m @ 4:72c011ed1977 tip

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more elaborate example with non-stat. estimate explanation
author smusevic
date Tue, 30 Jul 2013 09:56:27 +0100
parents a4a7e3405062
children
rev   line source
dan@0 1 % distribution derivative method:
dan@0 2 % 3rd degree system solver is used, make sure the data provided corresponds to that
dan@0 3 function dg3 = gen_ddm_3(krnls, krlns_ders, mf_ders, sig, N)
dan@0 4 % multi-frequency distribution derivative based non-stationary sinusoidal estimator
dan@0 5 % can estimate only 1 sinusoid at the once
dan@0 6 %
dan@0 7 %
dan@0 8 % [1] Michael Betser: Sinusoidal Polynomial Estimation Using The Distribution
dan@0 9 % Derivative, in IEEE Transactions on Signal Processing, Vol.57, Nr. 12,
dan@0 10 % December 2009
dan@0 11 %
dan@0 12 % krnls: matrix of all the kernels... N x R x K, where R is the number of
dan@0 13 % non-static parameters to estimate and at the same time, the number
dan@0 14 % of kernels for each sinusoid, K
dan@0 15 %
dan@0 16 % krlns_ders: matrix of all the kernel time derivatives... N x R x K , where R
dan@0 17 % is the number of non-static parameters to estimate and at the same
dan@0 18 % time, the number of kernels
dan@0 19 %
dan@0 20 % mf_ders: matrix of all the model function time derivatives... N x Q , where Q
dan@0 21 % is the number of model functions
dan@0 22 %
dan@0 23 %
dan@0 24 % sig: vector - signal, N x 1 (CAUTION: MUST be column vector!!!)
dan@0 25 %
dan@0 26 % N: odd integer - signal buffer length, ...
dan@0 27 %
dan@0 28 % K: number of sinusoids to estimate - NOT OVERLAPPING!!!
dan@0 29 %
dan@0 30 % For any reasonable use, Q equals R, otherwise it makes little sense.
dan@0 31 % Kernels must include the window function...
dan@0 32
dan@0 33 % 3rd degree system solver is used, make sure the data provided corresponds
dan@0 34 % to that
dan@0 35 R = size(krnls,2);
dan@0 36 assert(R == 3);
dan@0 37 assert(R == size(krlns_ders,2) );
dan@0 38 assert(R == size(mf_ders,2) );
dan@0 39
dan@0 40 [A, b] = ddm_lin_sys(krnls, krlns_ders, mf_ders, sig, N); % generate the linear system of eqs (slow)
dan@0 41 dg2 = lin_solve_dgr_3(A,b,1); %hardcoded degree 2 solver (fast)
dan@0 42
dan@0 43