Semester assignment for the course "Multimedia systems and virtual reality" of THMMY in AUTH university.
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6 years ago
function [S, sfc, G] = AACquantizer(frameF, frameType, SMR)
%Implementation of Quantizer
% Usage [S, sfc, G] = AACquantizer(frameF, frameType, SMR), where:
% Inputs
% - frameF is the frame in the frequency domain, in MDCT coefficients
% representation containing only one of the audio channels stored in
% a vector of length 1024
% - frameType is the type of the current frame in string
% representation, can be one of "OLS" (ONLY_LONG_SEQUENCE), "LSS"
% (LONG_START_SEQUENCE), "ESH" (EIGHT_SHORT_SEQUENCE), "LPS"
% (LONG_STOP_SEQUENCE)
% - SMR is the signal to mask ratio array of dimensions 42X8 for
% EIGHT_SHORT_SEQUENCE frames and 69X1 otherwise
%
% Output
% - S are the MDCT quantization symbols of one audio channel stored
% in a vector of length 1024
% - sfc are the scalefactors per band stored in an array of
% dimensions NBX8 for EIGHT_SHORT_SEQUENCE frames and NBX1
% otherwise, where NB is the number of bands
% - G is the global gain stored in an array of dimensions 1X8 for
% EIGHT_SHORT_SEQUENCE frames and a single value otherwise
% Declares constant numbers of bands for long and short windows
LONG_WINDOW_NUMBER_OF_BANDS = 69;
SHORT_WINDOW_NUMBER_OF_BANDS = 42;
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% Declares persistent variable holding the TNS tables and initializes if empty
persistent TNSTables;
if isempty(TNSTables)
TNSTables = load('TableB219.mat');
end
if ~strcmp(frameType, 'ESH')
T(LONG_WINDOW_NUMBER_OF_BANDS, 1) = 0;
quantCoeff(LONG_WINDOW_NUMBER_OF_BANDS, 1) = 0;
sfc(LONG_WINDOW_NUMBER_OF_BANDS, 1) = 0;
initialQuantCoeff = 16 * log2(max(frameF) ^ (3 / 4) / 8191) / 3;
for band = 1:LONG_WINDOW_NUMBER_OF_BANDS
frameWlow = TNSTables.B219a(band, 2) + 1;
frameWhigh = TNSTables.B219a(band, 3) + 1;
subFrameF = frameF(frameWlow:frameWhigh);
T(band) = sumsqr(subFrameF) ./ SMR(band);
% Calculates an initial quantization coefficient and attempts
% quantization
quantCoeff(band) = initialQuantCoeff;
S(frameWlow:frameWhigh, 1) = sign(subFrameF) .* floor(( ...
abs(subFrameF) .* 2 ^ (-quantCoeff(band) / 4)) ...
.^ (3 / 4) + 0.4054);
% Calculates dequantized frame samples
frameFDequant = sign(S(frameWlow:frameWhigh, 1)) .* ...
abs(S(frameWlow:frameWhigh, 1)) .^ ...
(4 / 3) .* 2 ^ (quantCoeff(band) / 4);
% Calculates current quantization error
quantErr = sumsqr(subFrameF - frameFDequant);
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% Gradually increases the quantization coefficient
while quantErr < T(band) && (band < 2 || ...
(quantCoeff(band) - quantCoeff(band - 1) + 1) <= 60)
quantCoeff(band) = quantCoeff(band) + 1;
S(frameWlow:frameWhigh) = sign(subFrameF) .* round(( ...
abs(subFrameF) .* 2 ^ (-quantCoeff(band) / 4)) ...
.^ (3 / 4) + 0.4054);
frameFDequant = sign(S(frameWlow:frameWhigh, 1)) .* ...
abs(S(frameWlow:frameWhigh, 1)) .^ ...
(4 / 3) .* 2 ^ (quantCoeff(band) / 4);
quantErr = sumsqr(subFrameF - frameFDequant);
end
% Undoes the last incrementation
if quantCoeff(band) ~= initialQuantCoeff
quantCoeff(band) = quantCoeff(band) - 1;
S(frameWlow:frameWhigh) = sign(subFrameF) .* round(( ...
abs(subFrameF) .* 2 ^ (-quantCoeff(band) / 4)) ...
.^ (3 / 4) + 0.4054);
end
if band == 1
sfc(band) = quantCoeff(band);
else
sfc(band) = quantCoeff(band) - quantCoeff(band - 1);
end
end
G = quantCoeff(1);
else
T(SHORT_WINDOW_NUMBER_OF_BANDS, 1) = 0;
quantCoeff(SHORT_WINDOW_NUMBER_OF_BANDS, 1) = 0;
sfc(SHORT_WINDOW_NUMBER_OF_BANDS, 8) = 0;
G(1, 8) = 0;
for subFrameIndex = 1:8
currFrameStart = (subFrameIndex - 1) * 128 + 1;
currFrameStop = currFrameStart + 127;
subFrame = frameF(currFrameStart:currFrameStop);
initialQuantCoeff = 16 * log2(max(subFrame) ^ (3 / 4) / 8191) / 3;
for band = 1:SHORT_WINDOW_NUMBER_OF_BANDS
frameWlow = TNSTables.B219b(band, 2);
frameWhigh = TNSTables.B219b(band, 3);
subFrameF = subFrame(frameWlow + 1:frameWhigh + 1);
T(band) = sumsqr(subFrameF) ./ SMR(band);
% Calculates an initial quantization coefficient and attempts
% quantization
quantCoeff(band) = initialQuantCoeff;
S(currFrameStart + frameWlow:currFrameStart + frameWhigh, 1) = sign(subFrameF) .* floor(( ...
abs(subFrameF) .* 2 ^ (-quantCoeff(band) / 4)) ...
.^ (3 / 4) + 0.4054);
% Calculates dequantized frame samples
frameFDequant = sign(S(currFrameStart + frameWlow: ...
currFrameStart + frameWhigh, 1)) .* abs(S( ...
currFrameStart + frameWlow:currFrameStart + frameWhigh, 1) ...
) .^ (4 / 3) .* 2 ^ (quantCoeff(band) / 4);
% Calculates current quantization error
quantErr = sumsqr(subFrameF - frameFDequant);
% Gradually increases the quantization coefficient
while quantErr < T(band) && (band < 2 || ...
(quantCoeff(band) - quantCoeff(band - 1) + 1) <= 60)
quantCoeff(band) = quantCoeff(band) + 1;
S(currFrameStart + frameWlow:currFrameStart + frameWhigh) = sign(subFrameF) .* round(( ...
abs(subFrameF) .* 2 ^ (-quantCoeff(band) / 4)) ...
.^ (3 / 4) + 0.4054);
frameFDequant = sign(S(currFrameStart + frameWlow: ...
currFrameStart + frameWhigh, 1)) .* abs(S( ...
currFrameStart + frameWlow:currFrameStart + frameWhigh, 1) ...
) .^ (4 / 3) .* 2 ^ (quantCoeff(band) / 4);
quantErr = sumsqr(subFrameF - frameFDequant);
end
% Undoes the last incrementation
if quantCoeff(band) ~= initialQuantCoeff
quantCoeff(band) = quantCoeff(band) - 1;
S(currFrameStart + frameWlow:currFrameStart + frameWhigh) = sign(subFrameF) .* round(( ...
abs(subFrameF) .* 2 ^ (-quantCoeff(band) / 4)) ...
.^ (3 / 4) + 0.4054);
end
if band == 1
sfc(band, subFrameIndex) = quantCoeff(band);
else
sfc(band, subFrameIndex) = quantCoeff(band) - quantCoeff(band - 1);
end
end
G(1, subFrameIndex) = quantCoeff(1);
end
end
end