sof/tune/eq/eq_norm.m

function eq = eq_norm(eq)

%%
% 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 <seppo.ingalsuo@linux.intel.com>
%

%% Normalize loudness of EQ by computing weighted average of linear
%  response. Find scale need to make the average one.
w_lin = level_norm_fweight(eq.f);
m_lin_fir = 10.^(eq.fir_eq_db/20);
m_lin_iir = 10.^(eq.iir_eq_db/20);
i1k = find(eq.f > 1e3, 1, 'first') - 1;
m_max_fir = max(eq.fir_eq_db);
m_max_iir = max(eq.iir_eq_db);
sens_fir = sum(m_lin_fir.*w_lin)/sum(w_lin);
sens_iir = sum(m_lin_iir.*w_lin)/sum(w_lin);
g_offs = 10^(eq.norm_offs_db/20);

%% Determine scaling gain
switch lower(eq.norm_type)
        case 'loudness'
                g_fir = 1/sens_fir;
                g_iir = 1/sens_iir;
        case '1k'
                g_fir = 1/m_lin_fir(i1k);
                g_iir = 1/m_lin_iir(i1k);

        case 'peak'
                g_fir = 10^(-m_max_fir/20);
                g_iir = 10^(-m_max_iir/20);
        otherwise
                error('Requested normalization is not supported');
end

%% Adjust FIR and IIR gains if enabled
if eq.enable_fir && eq.enable_iir
        eq.b_fir = eq.b_fir * g_fir * g_offs;
        eq.b_p = eq.b_p * g_iir * g_offs;
end
if eq.enable_fir && eq.enable_iir == 0
        eq.b_fir = eq.b_fir * g_fir * g_offs;
end
if eq.enable_fir == 0 && eq.enable_iir
        eq.b_p = eq.b_p * g_iir * g_offs;
end

%% Re-compute response after adjusting gain
eq = eq_compute_tot_response(eq);

end

function m_lin = level_norm_fweight(f)

%% w_lin = level_norm_fweight(f)
%
% Provides frequency weight that is useful in normalization of
% loudness of effect like equalizers. The weight consists of pink noise
% like spectral shape that attenuates higher frequencies 3 dB per
% octave. The low frequencies are shaped by 2nd order high-pass
% response at 20 Hz and higher frequencies by 3rd order low-pass at 20
% kHz.
%
% Note: This weight may have similarity with a standard defined test signal
% characteristic for evaluating music player output levels but this is not
% an implementation of it. This weight may help in avoiding a designed EQ to
% exceed safe playback levels in othervise compliant device.
%
% Input f - frequencies vector in Hz
%
% Output w_lin  - weight curve, aligned to peak of 1.0 in the requested f
%

[z_hp, p_hp] = butter(2, 22.4,'high','s');
[z_lp, p_lp] = butter(3, 22.4e3,'s');
z_bp = conv(z_hp, z_lp);
p_bp = conv(p_hp, p_lp);
h = freqs(z_bp, p_bp, f);
m0 = 20*log10(abs(h));
noct = log(max(f)/min(f))/log(2);
att = 3*noct;
nf = length(f);
w = zeros(1,nf);
w = w - linspace(0,att,nf);
m = m0 + w;
m = m-max(m);
m_lin = 10.^(m/20);

end
SOFT: Add equalizer tuning scripts and small examples This patch adds support to SOFT to setup FIR and IIR equalizer types. The examples scripts for simple FIR loudness effect, IIR loudness effect and speaker equalization case demonstrate the usage of the tool. The output ".txt" files will be possible to apply with alsactl to setup the equalizers in SOF. Signed-off-by: Seppo Ingalsuo <seppo.ingalsuo@linux.intel.com> 2018-08-07 23:55:19 +08:00			`function eq = eq_norm(eq)`

			`%%`
			`% 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 <seppo.ingalsuo@linux.intel.com>`
			`%`

			`%% Normalize loudness of EQ by computing weighted average of linear`
			`% response. Find scale need to make the average one.`
			`w_lin = level_norm_fweight(eq.f);`
			`m_lin_fir = 10.^(eq.fir_eq_db/20);`
			`m_lin_iir = 10.^(eq.iir_eq_db/20);`
			`i1k = find(eq.f > 1e3, 1, 'first') - 1;`
			`m_max_fir = max(eq.fir_eq_db);`
			`m_max_iir = max(eq.iir_eq_db);`
			`sens_fir = sum(m_lin_fir.*w_lin)/sum(w_lin);`
EQ: Improve Matlab compatibility of equalizer filter design plus cleanup This patch adds checks into places where Octave and Matlab handle the used functions differently. In previous version the difference in bilinear transform caused IIR designs to fail totally in Matlab. There remains an issue with IIR EQs design with Matlab. In that case a warning text is printed since the problem with tf2sos() does not happen with all designs (example_spk_eq is impacted). It will be investigated and fixed later. The problem does not happen with Octave. Equalizer defaults had accidentally by default boost of one dB compared to desired filter scaling. the offset (norm_offs_db) is now restored to 0. In parametric equalizers design renamed BW to Q for the correct purpose (peaking filter Q-value). Fixed bug in filters normalization where loudness based scaling of IIR filters was using calculated value for the FIR part. Also cleaned up lot commented out lines and simplified some functions parameters usage. Signed-off-by: Seppo Ingalsuo <seppo.ingalsuo@linux.intel.com> 2018-08-09 22:00:19 +08:00			`sens_iir = sum(m_lin_iir.*w_lin)/sum(w_lin);`
SOFT: Add equalizer tuning scripts and small examples This patch adds support to SOFT to setup FIR and IIR equalizer types. The examples scripts for simple FIR loudness effect, IIR loudness effect and speaker equalization case demonstrate the usage of the tool. The output ".txt" files will be possible to apply with alsactl to setup the equalizers in SOF. Signed-off-by: Seppo Ingalsuo <seppo.ingalsuo@linux.intel.com> 2018-08-07 23:55:19 +08:00			`g_offs = 10^(eq.norm_offs_db/20);`

			`%% Determine scaling gain`
			`switch lower(eq.norm_type)`
			`case 'loudness'`
			`g_fir = 1/sens_fir;`
			`g_iir = 1/sens_iir;`
			`case '1k'`
			`g_fir = 1/m_lin_fir(i1k);`
			`g_iir = 1/m_lin_iir(i1k);`

			`case 'peak'`
			`g_fir = 10^(-m_max_fir/20);`
			`g_iir = 10^(-m_max_iir/20);`
			`otherwise`
			`error('Requested normalization is not supported');`
			`end`

			`%% Adjust FIR and IIR gains if enabled`
			`if eq.enable_fir && eq.enable_iir`
			`eq.b_fir = eq.b_fir * g_fir * g_offs;`
			`eq.b_p = eq.b_p * g_iir * g_offs;`
			`end`
			`if eq.enable_fir && eq.enable_iir == 0`
			`eq.b_fir = eq.b_fir * g_fir * g_offs;`
			`end`
			`if eq.enable_fir == 0 && eq.enable_iir`
			`eq.b_p = eq.b_p * g_iir * g_offs;`
			`end`

			`%% Re-compute response after adjusting gain`
			`eq = eq_compute_tot_response(eq);`

			`end`

			`function m_lin = level_norm_fweight(f)`

			`%% w_lin = level_norm_fweight(f)`
			`%`
			`% Provides frequency weight that is useful in normalization of`
			`% loudness of effect like equalizers. The weight consists of pink noise`
			`% like spectral shape that attenuates higher frequencies 3 dB per`
			`% octave. The low frequencies are shaped by 2nd order high-pass`
			`% response at 20 Hz and higher frequencies by 3rd order low-pass at 20`
			`% kHz.`
			`%`
			`% Note: This weight may have similarity with a standard defined test signal`
			`% characteristic for evaluating music player output levels but this is not`
			`% an implementation of it. This weight may help in avoiding a designed EQ to`
			`% exceed safe playback levels in othervise compliant device.`
			`%`
			`% Input f - frequencies vector in Hz`
			`%`
			`% Output w_lin - weight curve, aligned to peak of 1.0 in the requested f`
			`%`

			`[z_hp, p_hp] = butter(2, 22.4,'high','s');`
			`[z_lp, p_lp] = butter(3, 22.4e3,'s');`
			`z_bp = conv(z_hp, z_lp);`
			`p_bp = conv(p_hp, p_lp);`
			`h = freqs(z_bp, p_bp, f);`
			`m0 = 20*log10(abs(h));`
			`noct = log(max(f)/min(f))/log(2);`
			`att = 3*noct;`
			`nf = length(f);`
			`w = zeros(1,nf);`
			`w = w - linspace(0,att,nf);`
			`m = m0 + w;`
			`m = m-max(m);`
			`m_lin = 10.^(m/20);`

			`end`