function iir_resp = eq_iir_blob_quant(eq_z, eq_p, eq_k) %% Convert IIR coefficients to 2nd order sections and quantize % % iir_resp = eq_iir_blob_quant(z, p, k) % % z - zeros % p - poles % k - gain % % iir_resp - vector to setup an IIR equalizer with number of sections, shifts, % and quantized coefficients % %% % Copyright (c) 2016, Intel Corporation % All rights reserved. % % Redistribution and use in source and binary forms, with or without % modification, are permitted provided that the following conditions are met: % * Redistributions of source code must retain the above copyright % notice, this list of conditions and the following disclaimer. % * Redistributions in binary form must reproduce the above copyright % notice, this list of conditions and the following disclaimer in the % documentation and/or other materials provided with the distribution. % * Neither the name of the Intel Corporation nor the % names of its contributors may be used to endorse or promote products % derived from this software without specific prior written permission. % % THIS SOFTWARE IS PROVIDED BY THE COPYRIGHT HOLDERS AND CONTRIBUTORS "AS IS" % AND ANY EXPRESS OR IMPLIED WARRANTIES, INCLUDING, BUT NOT LIMITED TO, THE % IMPLIED WARRANTIES OF MERCHANTABILITY AND FITNESS FOR A PARTICULAR PURPOSE % ARE DISCLAIMED. IN NO EVENT SHALL THE COPYRIGHT OWNER OR CONTRIBUTORS BE % LIABLE FOR ANY DIRECT, INDIRECT, INCIDENTAL, SPECIAL, EXEMPLARY, OR % CONSEQUENTIAL DAMAGES (INCLUDING, BUT NOT LIMITED TO, PROCUREMENT OF % SUBSTITUTE GOODS OR SERVICES; LOSS OF USE, DATA, OR PROFITS; OR BUSINESS % INTERRUPTION) HOWEVER CAUSED AND ON ANY THEORY OF LIABILITY, WHETHER IN % CONTRACT, STRICT LIABILITY, OR TORT (INCLUDING NEGLIGENCE OR OTHERWISE) % ARISING IN ANY WAY OUT OF THE USE OF THIS SOFTWARE, EVEN IF ADVISED OF THE % POSSIBILITY OF SUCH DAMAGE. % % Author: Seppo Ingalsuo % %% Settings bits_iir = 32; % Q2.30 qf_iir = 30; bits_gain = 16; % Q2.14 qf_gain = 14; scale_max = -6; % dB, scale biquads peak gain to this plot_pz = 0; plot_fr = 0; %% Convert IIR to 2nd order sections % This a simple implementation of zp2sos() function. It is not used here due % to utilization of rather strong scaling and resulting low SNR with the % available word length in EQ in SOF. This poles and zeros allocation to % biquads is base only in ascending sort of angular frequency. sz = length(eq_z); sp = length(eq_p); sk = length(eq_k); nb = max(sz, sp)/2; az = angle(eq_z); ap = angle(eq_p); [~, iz] = sort(abs(az)); [~, ip] = sort(abs(ap)); eq_z = eq_z(iz); eq_p = eq_p(ip); sos = zeros(nb, 6); for i = 1:nb j = 2*(i-1)+1; if i == 1 [b, a] = zp2tf(eq_z(j:j+1), eq_p(j:j+1), eq_k); else [b, a] = zp2tf(eq_z(j:j+1), eq_p(j:j+1), 1); end sos(i,1:3) = b; sos(i,4:6) = a; end gain = 1; %% Convert 2nd order sections to SOF parameters format and scale the biquads % with criteria below (Gain max -6 dB at any frequency). Then calculate % scaling shifts and finally gain multiplier for output. sz = size(sos); nbr_sections = sz(1); n_section_header = 2; n_section = 7; iir_resp = int32(zeros(1,n_section_header+nbr_sections*n_section)); iir_resp(1) = nbr_sections; iir_resp(2) = nbr_sections; % Note: All sections in series scale_max_lin = 10^(scale_max/20); for n=1:nbr_sections b = sos(n,1:3); a = sos(n,4:6); if plot_pz figure zplane(b,a); tstr = sprintf('SOS %d poles and zeros', n); title(tstr); end np = 1024; [h, w] = freqz(b, a, np); hm = max(abs(h)); scale = scale_max_lin/hm; gain_remain = 1/scale; gain = gain*gain_remain; b = b * scale; ma = max(abs(a)); mb = max(abs(b)); if plot_fr figure [h, w] = freqz(b, a, np); plot(w, 20*log10(abs(h))); grid on; xlabel('Frequency (w)'); ylabel('Magnitude (dB)'); tstr = sprintf('SOS %d frequency response', n); title(tstr); end %% Apply remaining gain at last section output if n == nbr_sections section_shift = -fix(log(gain)/log(2)); section_gain= gain/2^(-section_shift); else section_shift = 0; section_gain = 1; end %% Note: Invert sign of a! %% Note: a(1) is omitted, it's always 1 m = n_section_header+(n-1)*n_section+1; iir_resp(m:m+1) = eq_coef_quant(-a(3:-1:2), bits_iir, qf_iir); iir_resp(m+2:m+4) = eq_coef_quant( b(3:-1:1), bits_iir, qf_iir); iir_resp(m+5) = section_shift; iir_resp(m+6) = eq_coef_quant( section_gain, bits_gain, qf_gain); %fprintf('sec=%d, shift=%d, gain=%f\n', n, section_shift, section_gain); end end