An encoding method includes: extracting core layer characteristic parameters and enhancement layer characteristic parameters of a background noise signal, encoding the core layer characteristic parameters and enhancement layer characteristic parameters to obtain a core layer codestream and an enhanc
An encoding method includes: extracting core layer characteristic parameters and enhancement layer characteristic parameters of a background noise signal, encoding the core layer characteristic parameters and enhancement layer characteristic parameters to obtain a core layer codestream and an enhancement layer codestream. The disclosure also provides an encoding device, a decoding device and method, an encapsulating method, a reconstructing method, an encoding-decoding system and an encoding-decoding method. By describing the background noise signal with the enhancement layer characteristic parameters, the background noise signal can be processed by using more accurate encoding and decoding method, so as to improve the quality of encoding and decoding the background noise signal.
대표청구항▼
1. An encoding method, comprising: extracting core layer characteristic parameters and enhancement layer characteristic parameters of a background noise signal;encoding the core layer characteristic parameters and enhancement layer characteristic parameters to obtain a core layer codestream and an e
1. An encoding method, comprising: extracting core layer characteristic parameters and enhancement layer characteristic parameters of a background noise signal;encoding the core layer characteristic parameters and enhancement layer characteristic parameters to obtain a core layer codestream and an enhancement layer codestream; anddividing the background noise signal into a lower band background noise signal and a higher band background noise signal;wherein extracting the core layer characteristic parameters and enhancement layer characteristic parameters of the background noise signal comprises:extracting the core layer characteristic parameters of the lower band background noise signal and extracting the higher band enhancement layer characteristic parameters of the higher band background noise signal. 2. An encoding method, comprising: extracting core layer characteristic parameters and enhancement layer characteristic parameters of a background noise signal;encoding the core layer characteristic parameters and enhancement layer characteristic parameters to obtain a core layer codestream and an enhancement layer codestream; anddividing the background noise signal into a lower band background noise signal and a higher band background noise signal;wherein extracting the core layer characteristic parameters and enhancement layer characteristic parameters of the background noise signal comprises:extracting the lower band enhancement layer characteristic parameters and core layer characteristic parameters of the lower band background noise signal; andextracting the higher band enhancement layer characteristic parameters of the higher band background noise signal. 3. A decoding method comprising: extracting a core layer codestream and an enhancement layer codestream from a Silence Insertion Descriptor (SID) frame;parsing core layer characteristic parameters from the core layer codestream;parsing enhancement layer characteristic parameters from the enhancement layer codestream; anddecoding the core layer characteristic parameters and enhancement layer characteristic parameters to obtain a reconstructed core layer background noise signal and a reconstructed enhancement layer background noise signal;wherein extracting the enhancement layer codestream from the SID frame comprises extracting a lower band enhancement layer codestream from the SID frame; andparsing the enhancement layer characteristic parameters from the enhancement layer codestream comprises parsing lower band enhancement layer characteristic parameters from the enhancement layer codestream. 4. A non-transitory computer readable media comprising computer readable instructions that when combined with a processor cause the processor to function as an encoding unit configured to perform an encoding process, wherein the encoding unit comprises: a core layer characteristic parameter encoding unit, configured to extract core layer characteristic parameters from a background noise signal received from a voice activity detector (VAD), and to transmit the core layer characteristic parameters to an encoding unit;an enhancement layer characteristic parameter encoding unit configured to extract enhancement layer characteristic parameters from the background noise signal and to transmit the enhancement layer characteristic parameters to the encoding unit; andthe encoding unit configured to encode the received core layer characteristic parameters and enhancement layer characteristic parameters to obtain a core layer codestream and an enhancement layer codestream;wherein the enhancement layer characteristic parameter encoding unit comprises at least one of a lower band enhancement layer characteristic parameter encoding unit and a higher band enhancement layer characteristic parameter encoding unit;wherein the lower band enhancement layer characteristic parameter encoding unit is configured to extract lower band enhancement layer characteristic parameters from the background noise signal and to transmit the lower band enhancement layer characteristic parameters to the encoding unit;wherein the higher band enhancement layer characteristic parameter encoding unit is configured to extract higher band enhancement layer characteristic parameters from the background noise signal and to transmit the higher band enhancement layer characteristic parameters to the encoding unit; andwherein the encoding unit is configured to encode the received lower band enhancement layer characteristic parameters and higher band enhancement layer characteristic parameters to obtain the core layer codestream and enhancement layer codestream. 5. A non-transitory computer readable media comprising computer readable instructions that when combined with a processor cause the processor to function as a decoding unit configured to perform a decoding process, the decoding unit comprising: a SID frame parsing unit, configured to receive a SID frame of a background noise signal received from a discontinuous transmission (DTX) unit to extract a core layer codestream and an enhancement layer codestream; to transmit the core layer codestream to a core layer characteristic parameter decoding unit; and to transmit the enhancement layer codestream to an enhancement layer characteristic parameter decoding unit;the core layer characteristic parameter decoding unit, configured to extract core layer characteristic parameters from the core layer codestream and to decode the core layer characteristic parameters to obtain a reconstructed core layer background noise signal; andthe enhancement layer characteristic parameter decoding unit configured to extract enhancement layer characteristic parameters from the enhancement layer codestream and to decode the enhancement layer characteristic parameters to obtain a reconstructed enhancement layer background noise signal;wherein the enhancement layer characteristic parameter decoding unit comprises at least one of a lower band enhancement layer characteristic parameter decoding unit and a higher band enhancement layer characteristic parameter decoding unit;wherein the lower band enhancement layer characteristic parameter decoding unit is configured to extract lower band enhancement layer characteristic parameters from the enhancement layer codestream, and to decode the lower band enhancement layer characteristic parameters to obtain the reconstructed enhancement layer background noise signal; andwherein the higher band enhancement layer characteristic parameter decoding unit is configured to extract higher band enhancement layer characteristic parameters from the enhancement layer codestream, and to decode the higher band enhancement layer characteristic parameters to obtain the reconstructed enhancement layer background noise signal. 6. The-non-transitory computer readable media of claim 5, wherein the lower band enhancement layer characteristic parameter decoding unit comprises: a lower band enhancement layer characteristic parameter parsing unit, configured to extract the lower band enhancement layer characteristic parameters from the received enhancement layer codestream, and to transmit the lower band enhancement layer characteristic parameters to a lower band enhancing unit; andthe lower band enhancing unit, configured to decode the lower band enhancement layer characteristic parameters to obtain a reconstructed enhancement layer background noise signal. 7. The non-transitory computer readable media of claim 5, wherein the higher band enhancement layer characteristic parameter decoding unit comprises: a higher band enhancement layer characteristic parameter parsing unit, configured to extract the higher band enhancement layer characteristic parameters from the received enhancement layer codestream and to transmit the higher band enhancement layer characteristic parameters to a higher band enhancing unit; andthe higher band enhancing unit, configured to decode the higher band enhancement layer characteristic parameters to obtain a reconstructed enhancement layer background noise signal. 8. An encoding method, comprising: extracting core layer characteristic parameters and enhancement layer characteristic parameters of a background noise signal;encoding the core layer characteristic parameters and enhancement layer characteristic parameters to obtain a core layer codestream and an enhancement layer codestream; anddividing the background noise signal into a lower band background noise signal and a higher band background noise signal;wherein extracting the core layer characteristic parameters and enhancement layer characteristic parameters of the background noise signal comprises:extracting the core layer characteristic parameters of the lower band background noise signal and extracting the higher band enhancement layer characteristic parameters of the higher band background noise signal; andwherein the higher band enhancement layer characteristic parameters comprise at least one of time-domain envelopes and frequency-domain envelopes. 9. The method of claim 8, wherein the time-domain envelopes comprise time-domain envelope mean values, a time domain envelope quantized vector, and frequency-domain envelopes comprises a frequency domain envelope quantized vector; wherein the time-domain envelope mean value is calculated through: MT=116∑i=015Tenv(i),where, the MT is the time-domain envelope mean value of 16 time-domain envelope parameters, the 16 time-domain envelope parameters are calculated through Tenv(i)=12log2(∑n=09sHB2(n+i·10)),i=0,…,15, the Tenv(i) is i-th time-domain envelope parameter, and the sHB(n) is the input voice superframe signal; the time domain envelope quantized vector is calculated through: Tenv,1=(TenvM(0),TenvM(1)1, . . . ,TenvM(7)) and Tenv,2=(TenvM(8),TenvM(9), . . . ,TenvM(15));where, the Tenv,1 and Tenv,2 are calculated through TenvM(i)=Tenv(i)−{circumflex over (M)}T, i=0, . . . , 15, and the {circumflex over (M)}T equals to MT;the frequency domain envelope quantized vector is calculated through: {Fenv,1=(FenvM(0),FenvM(1)1,FenvM(2),FenvM(3))Fenv,2=(FenvM(4),FenvM(5)1,FenvM(6),FenvM(7))Fenv,3=(FenvM(8),FenvM(9)1,FenvM(10),FenvM(11))where, the Fenv,1, Fenv,2, and Fenv,3 are calculated through FenvM(j)i=Fenv(j)−{circumflex over (M)}T, j=0, . . . , 11, the FenvM(j)i is the difference between the 12 frequency envelope parameters and the time envelope mean, the Fenv(j) is calculated through Fenv(j)=12log2(∑k=2j2(j+1)WF(k-2j)·SHBfft(k)2),j=0,…,11, the SHBfft(k)=FFT64(sHBw(n)+sHBw(n+64)), k=0, . . . , 63, n=−31, . . . , 32, and the wF(n)={12(1-cos(2πn143)),12(1-cos(2π(n-16))111)),n=0,…,71n=72,…,127. 10. The method of claim 9, wherein extracting the core layer characteristic parameters and enhancement layer characteristic parameters of the background noise signal comprises: extracting the core layer characteristic parameters and the lower band enhancement layer characteristic parameters of the background noise signal. 11. The method of claim 10, wherein extracting the lower band enhancement layer characteristic parameters comprises: computing the lower band enhancement layer characteristic parameters according to the core layer characteristic parameter and the background noise signal. 12. The method of claim 9, further comprising: encapsulating the obtained core layer codestream and enhancement layer codestream into a Silence Insertion Descriptor (SID) frame. 13. The method of claim 12, wherein encapsulating the core layer codestream and enhancement layer codestream into a SID frame comprises: forming the SID frame by placing the enhancement layer codestream before or after the core layer codestream. 14. A decoding method, comprising: extracting a core layer codestream and an enhancement layer codestream from a Silence Insertion Descriptor (SID) frame;parsing core layer characteristic parameters from the core layer codestream;parsing enhancement layer characteristic parameters from the enhancement layer codestream; anddecoding the core layer characteristic parameters and enhancement layer characteristic parameters to obtain a reconstructed core layer background noise signal and a reconstructed enhancement layer background noise signal;wherein the extracting the enhancement layer codestream from the SID frame comprises extracting a higher band enhancement layer codestream from the SID frame;wherein parsing the enhancement layer characteristic parameters from the enhancement layer codestream comprises paring higher band enhancement layer characteristic parameters from the enhancement layer codestream; andwherein the higher band enhancement layer characteristic parameters comprise at least one of time-domain envelopes and frequency-domain envelopes. 15. The method of claim 14, wherein the time-domain envelopes comprise time-domain envelope mean values, a time domain envelope quantized vector, and frequency-domain envelopes comprises a frequency domain envelope quantized vector; the time-domain envelope mean value is calculated at coding end by: MT=116∑i=015Tenv(i),where, the MT is the time-domain envelope mean value of 16 time-domain envelope parameters, the 16 time-domain envelope parameters are calculated through Tenv(i)=12log2(∑n=09sHB2(n+i·10)),i=0,…,15, the Tenv(i) is i-th time-domain envelope parameter, and the sHB(n) is the input voice superframe signal; the time domain envelope quantized vector is calculated at coding end by: Tenv,1=(TenvM(0),TenvM(1)1, . . . ,TenvM(7)) and Tenv,2=(TenvM(8),TenvM(9), . . . ,TenvM(15))where, the Tenv,1 and Tenv,2 are calculated through TenvM(i)=Tenv(i)−{circumflex over (M)}T, i=0, . . . , 15, and the {circumflex over (M)}T equals to MT;the frequency domain envelope quantized vector is calculated at coding end by: {Fenv,1=(FenvM(0),FenvM(1)1,FenvM(2),FenvM(3))Fenv,2=(FenvM(4),FenvM(5)1,FenvM(6),FenvM(7))Fenv,3=(FenvM(8),FenvM(9)1,FenvM(10),FenvM(11))where, the Fenv,1, Fenv,2, and Fenv,3 are calculated through FenvM(j)i=Fenv(j)−{circumflex over (M)}T, j=0, . . . , 11, the FenvM(j)i is the difference between the 12 frequency envelope parameters and the time envelope mean, the Fenv(j) is calculated through Fenv(j)=12log2(∑k=2j2(j+1)WF(k-2j)·SHBfft(k)2),j=0,…,11, the SHBfft(k)=FFT64(sHBw(n)+sHBw(n+64)), k=0, . . . , 63, n=−31, . . . , 32, and the wF(n)={12(1-cos(2πn143)),12(1-cos(2π(n-16))111)),n=0,…,71n=72,…,127. 16. The method of claim 15, wherein extracting the enhancement layer codestream from the SID frame comprises extracting a lower band enhancement layer codestream from the SID frame; andparsing the enhancement layer characteristic parameters from the enhancement layer codestream comprises parsing lower band enhancement layer characteristic parameters from the enhancement layer codestream. 17. The method of claim 15, wherein the reconstructed enhancement layer background noise signal comprises reconstructed lower band enhanced layer background noise signal and reconstructed higher band enhancement layer background noise signal; wherein the reconstructed lower band enhanced layer background noise signal is obtained through: s^enh(n)=uenh(n)-∑i=110α^is^enh(n-i)where, âi is the interpolation coefficient of the linear prediction (LP) synthesis filter Â(z) of the current frame; uenh(n)=u(n)ĝenh×c′(n) is the signal obtained by combining the lower band excitation signal u(n) and the lower band enhancement fixed-codebook excitation signal ĝenh×c′(n), n=0, . . . , 39, the lower band enhancement fixed-codebook excitation signal ĝenh×c′(n) is obtained by synthesizing fixed codebook index, fixed codebook sign and fixed codebook gain of low band enhanced layer;wherein the reconstructed higher band enhancement layer background noise signal is obtained through:in time domain, the time domain envelope parameter {circumflex over (T)}env(i) obtained through the decoding is used to compute the gain function gT(n), which is then multiplied with the excitation signal sHBexc(n) to obtain ŝHBT(n), ŝHBT(n)=gT(n)·sHBexc(n), n=0, . . . , 159;in frequency domain, the correction gain of two sub-frames are computed using {circumflex over (F)}env(j)={circumflex over (F)}envM(j)+{circumflex over (M)}T, j=0, . . . , 11:GF,1(j)2{circumflex over (F)}env,int(j)−{tilde over (F)}env,1(j) and GF,2(i)=2Fenv(j)−Fenv,2(j), j=0, . . . , 11, and two linear phase finite impulse response (FIR) filters are constructed for each super-frame: hF,l(n)=∑i=011GF,l(i)·hF(i)(n)+0.1·hHP(n),n=0,…,32,l=1,2; the two FIR correcting filters are applied to the signal ŝHBT(n) to generate the reconstructed higher band enhancement layer background noise signal: ŝHBT(n) s^HBF(n)={∑m=032s^HBT(n-m)hF,1(m),n=0,…,79∑m=032s^HBT(n-m)hF,2(m),n=80,…,159. 18. The method of claim 15, further comprising: combining the reconstructed core layer background noise signal and reconstructed enhancement layer background noise signal to obtain a reconstructed background noise signal. 19. A non-transitory computer readable media comprising computer readable instructions that when combined with a processor cause the processor to function as an encoding-unit configured to perform an encoding process the encoding unit comprising: a core layer characteristic parameter encoding unit, configured to extract core layer characteristic parameters from a background noise signal received from a voice activity detector (VAD), and to transmit the core layer characteristic parameters to an encoding unit;an enhancement layer characteristic parameter encoding unit, configured to extract enhancement layer characteristic parameters from the background noise signal, and to transmit the enhancement layer characteristic parameters to the encoding unit; andthe encoding unit, configured to encode the received core layer characteristic parameters and enhancement layer characteristic parameters to obtain a core layer codestream and an enhancement layer codestream;wherein the enhancement layer characteristic parameter encoding unit comprises at least one of a lower band enhancement layer characteristic parameter encoding unit and a higher band enhancement layer characteristic parameter encoding unit;wherein the lower band enhancement layer characteristic parameter encoding unit is configured to extract lower band enhancement layer characteristic parameters from the background noise signal and to transmit the lower band enhancement layer characteristic parameters to the encoding unit;wherein the higher band enhancement layer characteristic parameter encoding unit is configured to extract higher band enhancement layer characteristic parameters from the background noise signal and to transmit the higher band enhancement layer characteristic parameters to the encoding unit, wherein the higher band enhancement layer characteristic parameters comprise at least one of time-domain envelopes and frequency-domain envelopes; andwherein the encoding unit is configured to encode the received lower band enhancement layer characteristic parameters and higher band enhancement layer characteristic parameters to obtain the core layer codestream and enhancement layer codestream. 20. The non-transitory computer readable media of claim 19, wherein, the time-domain envelope mean value is calculated by the higher band enhancement layer characteristic parameter encoding unit through: MT=116∑i=015Tenv(i),where, the MT is the time-domain envelope mean value of 16 time-domain envelope parameters, the 16 time-domain envelope parameters are calculated through Tenv(i)=12log2(∑n=09sHB2(n+i·10)),i=0,…,15, the Tenv(i) is i-th time-domain envelope parameter, and the sHB(n) is the input voice superframe signal; the time domain envelope quantized vector is calculated by the higher band enhancement layer characteristic parameter encoding unit through: Tenv,1=(TenvM(0),TenvM(1)1, . . . ,TenvM(7)) and Tenv,2=(TenvM(8),TenvM(9), . . . ,TenvM(15));where, the Tenv,1 and Tenv,2 are calculated through TenvM(i)=Tenv(i)−{circumflex over (M)}T, i=0, . . . , 15, and the {circumflex over (M)}T equals to MT;the frequency domain envelope quantized vector is calculated by the higher band enhancement layer characteristic parameter encoding unit through: {Fenv,1=(FenvM(0),FenvM(1)1,FenvM(2),FenvM(3))Fenv,2=(FenvM(4),FenvM(5)1,FenvM(6),FenvM(7))Fenv,3=(FenvM(8),FenvM(9)1,FenvM(10),FenvM(11))where, the Fenv,1, Fenv,2, and Fenv,3 are calculated through FenvM(j)i=Fenv(j)−{circumflex over (M)}T, j=0, . . . , 11, the FenvM(j)i is the difference between the 12 frequency envelope parameters and the time envelope mean, the Fenv(j) is calculated through Fenv(j)=12log2(∑k=2j2(j+1)WF(k-2j)·SHBfft(k)2),j=0,…,11, the SHBfft(k)=FFT64(sHBw(n)+sHBw(n+64)), k=0, . . . , 63, n=−31, . . . , 32, and the wF(n)={12(1-cos(2πn143)),n=0,…,7112(1-cos(2π(n-16))111)),n=72,…,127. 21. The non-transitory computer readable media of claim 20, wherein the encoding unit further comprises: a Silence Insertion Descriptor (SID) frame encapsulation unit, configured to encapsulate the core layer codestream and enhancement layer codestream into a SID frame. 22. A non-transitory computer readable media comprising computer readable instructions that when combined with a processor cause the processor to function as a decoding unit configured to perform a decoding process the decoding unit comprising: a SID frame parsing unit, configured to receive a SID frame of a background noise signal received from a discontinuous transmission (DTX) unit, to extract a core layer codestream and an enhancement layer codestream; to transmit the core layer codestream to a core layer characteristic parameter decoding unit; and to transmit the enhancement layer codestream to an enhancement layer characteristic parameter decoding unit;the core layer characteristic parameter decoding unit, configured to extract core layer characteristic parameters from the core layer codestream and to decode the core layer characteristic parameters to obtain a reconstructed core layer background noise signal; andthe enhancement layer characteristic parameter decoding unit, configured to extract enhancement layer characteristic parameters from the enhancement layer codestream and to decode the enhancement layer characteristic parameters to obtain a reconstructed enhancement layer background noise signal;wherein the enhancement layer characteristic parameter decoding unit comprises at least one of a lower band enhancement layer characteristic parameter decoding unit and a higher band enhancement layer characteristic parameter decoding unit;wherein the lower band enhancement layer characteristic parameter decoding unit is configured to extract lower band enhancement layer characteristic parameters from the enhancement layer codestream, and to decode the lower band enhancement layer characteristic parameters to obtain the reconstructed enhancement layer background noise signal;wherein the higher band enhancement layer characteristic parameter decoding unit is configured to extract higher band enhancement layer characteristic parameters from the enhancement layer codestream, and to decode the higher band enhancement layer characteristic parameters to obtain the reconstructed enhancement layer background noise signal; andwherein the higher band enhancement layer characteristic parameters comprise at least one of time-domain envelopes and frequency-domain envelopes. 23. The non-transitory computer readable media of claim 22, wherein the time-domain envelopes comprise time-domain envelope mean values, a time domain envelope quantized vector, and frequency-domain envelopes comprises a frequency domain envelope quantized vector; the time-domain envelope mean value is calculated at coding end by: MT=116∑i=015Tenv(i),where, the MT is the time-domain envelope mean value of 16 time-domain envelope parameters, the 16 time-domain envelope parameters are calculated through Tenv(i)=12log2(∑n=09sHB2(n+i·10)),i=0,…,15, the Tenv(i) is i-th time-domain envelope parameter, and the sHB(n) is the input voice superframe signal; the time domain envelope quantized vector is calculated at coding end by: Tenv,1=(TenvM(0),TenvM(1)1, . . . ,TenvM(7)) and Tenv,2=(TenvM(8),TenvM(9), . . . ,TenvM(15));where, the Tenv,1 and Tenv,2 are calculated through TenvM(i)=Tenv(i)−{circumflex over (M)}T, i=0, . . . , 15, and the {circumflex over (M)}T equals to MT;the frequency domain envelope quantized vector is calculated through: {Fenv,1=(FenvM(0),FenvM(1)1,FenvM(2),FenvM(3))Fenv,2=(FenvM(4),FenvM(5)1,FenvM(6),FenvM(7))Fenv,3=(FenvM(8),FenvM(9)1,FenvM(10),FenvM(11))where, the Fenv,1, Fenv,2, and Fenv,3 are calculated through FenvM(j)i=Fenv(j)−{circumflex over (M)}T, j=0, . . . , 11, the FenvM(j)i is the difference between the 12 frequency envelope parameters and the time envelope mean, the Fenv(j) is calculated through Fenv(j)=12log2(∑k=2j2(j+1)WF(k-2j)·SHBfft(k)2),j=0,…,11, the SHBfft(k)=FFT64(sHBw(n)+sHBw(n+64)), k=0, . . . , 63, n=−31, . . . , 32, and the wF(n)={12(1-cos(2πn143)),n=0,…,7112(1-cos(2π(n-16))111)),n=72,…,127. 24. The non-transitory computer readable media of claim 23, wherein the lower band enhancement layer characteristic parameter decoding unit comprises: a lower band enhancement layer characteristic parameter parsing unit, configured to extract the lower band enhancement layer characteristic parameters from the received enhancement layer codestream, and to transmit the lower band enhancement layer characteristic parameters to a lower band enhancing unit; andthe lower band enhancing unit, configured to decode the lower band enhancement layer characteristic parameters to obtain a reconstructed enhancement layer background noise signal. 25. The non-transitory computer readable media of claim 23, wherein the reconstructed enhancement layer background noise signal comprises reconstructed lower band enhanced layer background noise signal and reconstructed higher band enhancement layer background noise signal; wherein the reconstructed lower band enhanced layer background noise signal is obtained through: s^enh(n)=uenh(n)-∑i=110a^is^enh(n-i)where, âi is the interpolation coefficient of the linear prediction (LP) synthesis filter Â(z) of the current frame; uenh(n)=u(n)+ĝenh×c′(n) is the signal obtained by combining the lower band excitation signal u(n) and the lower band enhancement fixed-codebook excitation signal ĝenh×c′(n), n 0, . . . , 39, the lower band enhancement fixed-codebook excitation signal ĝenh×c′(n) is obtained by synthesizing fixed codebook index, fixed codebook sign and fixed codebook gain of low band enhanced layer;wherein the reconstructed higher band enhancement layer background noise signal is obtained through:in time domain, the time domain envelope parameter {circumflex over (T)}env(i) obtained through the decoding is used to compute the gain function gT(n), which is then multiplied with the excitation signal sHBexc(n) to obtain ŝHBT(n), ŝHBT(n)=gT(n)·sHBexc(n), n=0, . . . , 159;in frequency domain, the correction gain of two sub-frames are computed using {circumflex over (F)}env(j)={circumflex over (F)}envM(j)+{circumflex over (M)}T, j=0, . . . , 11:GF,1(j)=2{circumflex over (F)}env,int(j)−{tilde over (F)}env,1(j) and GF,2(i)=2{circumflex over (F)}env(j)−{tilde over (F)}env,2(j), j=0, . . . , 11, and two linear phase finite impulse response (FIR) filters are constructed for each super-frame: hF,l(n)=∑i=011GF,l(i)·hF(i)(n)+0.1·hHP(n),n=0,…,32,l=1,2;the two FIR correcting filters are applied to the signal ŝHBT(n) to generate the reconstructed higher band enhancement layer background noise signal: ŝHBF(n) s^HBF(n)={∑m=032s^HBT(n-m)hF,1(m),n=0,…,79∑m=032s^HBT(n-m)hF,2(m),n=80,…,159.
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