CN101185124A - Method and apparatus for dividing frequencyband coding of voice signal - Google Patents

Method and apparatus for dividing frequencyband coding of voice signal Download PDF

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CN101185124A
CN101185124A CNA2006800182709A CN200680018270A CN101185124A CN 101185124 A CN101185124 A CN 101185124A CN A2006800182709 A CNA2006800182709 A CN A2006800182709A CN 200680018270 A CN200680018270 A CN 200680018270A CN 101185124 A CN101185124 A CN 101185124A
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signal
frequency band
band
low
voice signal
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CN101185124B (en
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科恩·贝尔纳德·福斯
阿南塔帕德马纳卜汉·A·坎达达伊
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Qualcomm Inc
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Qualcomm Inc
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Abstract

A wideband speech encoder according to one embodiment includes a filter bank having a lowband processing path and a highband processing path. The processing paths have overlapping frequency responses. A first encoder is configured to encode a speech signal produced by the lowband processing path according to a first coding methodology. A second encoder is configured to encode a speech signal produced by the highband processing path according to a second coding methodology that is different than the first coding methodology.

Description

The method and apparatus that is used for the dividing frequencyband coding of voice signal
The application's case is advocated the rights and interests of the 60/667th, No. 901 U.S. Provisional Patent Application case that is entitled as " CODING THE HIGH-FREQUENCYBAND OF WIDEBAND SPEECH " of application on April 1st, 2005.The application's case is also advocated the rights and interests of the 60/673rd, No. 965 U.S. Provisional Patent Application case that is entitled as " PARAMETER CODING IN A HIGH-BANDSPEECH CODER " of application on April 22nd, 2005.
Technical field
The present invention relates to signal Processing.
Background technology
The bandwidth Conventional cap of the voice communication on the PSTN (PSTN) is in the frequency range of 300-3400kHz.(for example the new network of cellular phone and ip voice (Internet Protocol, VoIP)) may not have identical bandwidth constraints, and may transmit and receive the voice communication that comprises the broadband frequency range on this type of network to be used for voice communication.For instance, may need to support to extend downwardly into 50Hz and/or until 7 or the audio frequency range of 8kHz.Also may need to support to have other application of the audio speech content in traditional PSTN restriction scope in addition, for example high quality audio or audio/video conference.
The scope that speech coder is supported can be improved sharpness to the extension of upper frequency.For instance, for example distinguishing, the fricative information spinner of " s " and " f " will be in high-frequency.High frequency band extends other quality that also can improve voice, for example has rate.For instance, in addition turbid vowel also can have the spectrum energy that is higher than PSTN restriction far away.
A kind of method of wideband speech coding relates to convergent-divergent narrow-band speech coding technology (for example, be configured to encode 0-4kHz the technology of scope) with the covering wide band spectrum.For instance, voice signal can the higher rate sampling be in high-frequency component to comprise, and the narrow-band coding techniques is reconfigurable to use more filter factors to represent this broadband signal.Yet for example the narrow-band coding techniques calculated amount of CELP (code book Excited Linear Prediction) is bigger, and the broadband celp coder may consume too much cycle of treatment, to such an extent as to for many move and other Embedded Application for unrealistic.Using this technology that the entire spectrum of broadband signal is encoded to required quality also may cause bandwidth to increase greatly and make us and can't accept.Can be transferred in the system that only supports the narrow-band coding and/or before by described system decodes, will need described encoded signal is carried out code conversion in addition, even in the narrow-band of this encoded signal part.
The another kind of method of wideband speech coding relates to from encoded narrow-band spectrum envelope extrapolation high frequency band spectrum envelope.Though this method can be implemented the rough spectrum envelope or the resonance peak structure of the highband part of the voice signal that can't calculate to a nicety out usually not increasing bandwidth and do not need from the spectrum envelope of narrow-band part under the situation of code conversion.
May need to implement wideband speech coding, make the narrow-band part of encoded at least signal can pass through narrow-band channel (for example, the PSTN channel) transmission, and do not carry out code conversion or other remarkable modification.Also may need the broadband code extension efficient, so that (for example) avoids the user's that may accept to serve in the application of the broadcasting on for example wireless cellular telephony and wired and wireless channel number significantly to reduce.
Summary of the invention
In one embodiment, a kind of equipment comprises: first speech coder, its low-frequency band voice signal that is configured to encode; Second speech coder, its high frequency band voice signal that is configured to encode; And bank of filters, it has (A) low-frequency band and handles the path, described low-frequency band handle the path be configured to receive have be at least 1000 and 6000Hz between frequency content the broadband voice signal and produce described low-frequency band voice signal and (B) high frequency band handle the path, described high frequency band is handled the path and is configured to receive described broadband voice signal and produces described high frequency band voice signal.Described low-frequency band voice signal is based on the first of the frequency content of described broadband signal, described first comprise described broadband signal be in 1000 and 2000Hz between part.Described high frequency band voice signal is based on the second portion of the frequency content of described broadband signal, described second portion comprise described broadband signal be in 5000 and 6000Hz between part.Each third part of described low-frequency band voice signal and described high frequency band voice signal, described third part based on the frequency content of described broadband signal comprise described broadband signal be in 2000 and 5000Hz between have a part of the width of 250Hz at least.
In another embodiment, a kind of equipment comprises bank of filters, described bank of filters has (A) low-frequency band and handles the path, its be configured to receive the broadband voice signal and based on the low frequency of described broadband voice signal partly produce the low-frequency band voice signal and (B) high frequency band handle the path, it is configured to receive described broadband voice signal and partly produces the high frequency band voice signal based on the high-frequency of described broadband voice signal.The passband that the passband in low-frequency band processing path and high frequency band are handled the path is overlapping.Described equipment also comprises: first speech coder, and it is configured to the low-frequency band speech signal coding is at least one encoded low band excitation signal and a plurality of low band filter parameter; And second speech coder, it is configured to produce high band excitation signal based on described encoded low band excitation signal, and according to described high band excitation signal high-frequency band signals is encoded to a plurality of at least high band filter parameters.
In another embodiment, a kind of signal processing method comprises: based on have be at least 1000 and 6000Hz between the broadband voice signal of frequency content produce the low-frequency band voice signal; Coding low-frequency band voice signal; Produce the high frequency band voice signal based on the broadband voice signal; And coding high frequency band voice signal.In the method, producing the low-frequency band voice signal comprises based on following content generation low-frequency band voice signal: (A) first of the frequency content of described broadband signal, described first comprise described broadband signal be in 1000 and 2000Hz between part, (B) third part of the frequency content of described broadband signal, described third part comprise described broadband signal be in 2000 and 5000Hz between have a part of the width of 250Hz at least.In the method, producing the high frequency band voice signal comprises based on following content and produces the high frequency band voice signal: (C) second portion of the frequency content of described broadband signal, described second portion comprise described broadband signal be in 5000 and 6000Hz between the part and (D) third part of the frequency content of described broadband signal.
Description of drawings
Fig. 1 a shows the block diagram according to the wideband speech coding device A100 of an embodiment.
Fig. 1 b shows the block diagram of the embodiment A102 of wideband speech coding device A100.
Fig. 2 a shows the block diagram according to the broadband Voice decoder B100 of an embodiment.
Fig. 2 b shows the block diagram of the embodiment B102 of wideband speech coding device B100.
Fig. 3 a shows the block diagram of the embodiment A112 of bank of filters A110.
Fig. 3 b shows the block diagram of the embodiment B122 of bank of filters B120.
The bandwidth of the low and high frequency band of the example of Fig. 4 a displaying bank of filters A110 covers.
The bandwidth of the low and high frequency band of another example of Fig. 4 b displaying bank of filters A110 covers.
Fig. 4 c shows the block diagram of the embodiment A114 of bank of filters A112.
Fig. 4 d shows the block diagram of the embodiment B124 of bank of filters B122.
The example of the frequency of Fig. 5 a displaying voice signal and the curve of logarithmic amplitude.
Fig. 5 b shows the block diagram of basic linear predictive coding system.
Fig. 6 shows the block diagram of the embodiment A122 of narrowband encoder A120.
Fig. 7 shows the block diagram of the embodiment B112 of narrow-band demoder B110.
Fig. 8 a shows the example of the curve of the frequency of residual signal of turbid voice and logarithmic amplitude.
Fig. 8 b shows the example of the curve of time of residual signal of turbid voice and logarithmic amplitude.
Fig. 9 shows the block diagram also carry out long-term base of prediction linear predictive coding system.
Figure 10 shows the block diagram of the embodiment A202 of high band encoder A200.
Figure 11 shows the block diagram of the embodiment A302 of high band excitation generator A300.
Figure 12 shows the block diagram of the embodiment A402 of frequency spectrum stretcher A400.
Figure 12 a shows that frequency spectrum extends the curve of the signal spectrum at each point place in the example of operating.
Figure 12 b shows that frequency spectrum extends the curve of the signal spectrum at each point place in another example of operating.
Figure 13 shows the block diagram of the embodiment A304 of high band excitation generator A302.
Figure 14 shows the block diagram of the embodiment A306 of high band excitation generator A302.
Figure 15 shows the process flow diagram of envelope calculation task T100.
Figure 16 shows the block diagram of the embodiment 492 of combiner 490.
Figure 17 illustrates the method for the periodic measured value that calculates high-frequency band signals S30.
Figure 18 shows the block diagram of the embodiment A312 of high band excitation generator A302.
Figure 19 shows the block diagram of the embodiment A314 of high band excitation generator A302.
Figure 20 shows the block diagram of the embodiment A316 of high band excitation generator A302.
Figure 21 shows the process flow diagram of gain calculating task T200.
Figure 22 shows the process flow diagram of the embodiment T210 of gain calculating task T200.
The figure of Figure 23 a impression window function.
Figure 23 b shows the subframe that will the window function shown in Figure 23 a be applied to voice signal.
Figure 24 shows the block diagram of the embodiment B202 of high band decoder B200.
Figure 25 shows the block diagram of the embodiment AD10 of wideband speech coding device A100.
Figure 26 a shows the synoptic diagram of the embodiment D122 of lag line D120.
Figure 26 b shows the synoptic diagram of the embodiment D124 of lag line D120.
Figure 27 shows the synoptic diagram of the embodiment D130 of lag line D120.
Figure 28 shows the block diagram of the embodiment AD12 of wideband speech coding device AD10.
Figure 29 shows the process flow diagram according to the signal processing method MD100 of an embodiment.
Figure 30 shows the process flow diagram according to the method M100 of an embodiment.
Figure 31 a shows the process flow diagram according to the method M200 of an embodiment.
The process flow diagram of the embodiment M210 of Figure 31 b methods of exhibiting M200.
Figure 32 shows the process flow diagram according to the method M300 of an embodiment.
Figure 33-36b shows frequency and the impulse response for the filtering operation shown in Fig. 4 c.
Figure 37-39b shows frequency and the impulse response for the filtering operation shown in Fig. 4 d.
In each figure and the description of enclosing, same reference numerals is represented identical or similar elements or signal.
Embodiment
Embodiment described herein comprises and can be configured to provide extension to the narrow-band speech coder bandwidth only increases by about 800 to 1000bps (bps) system, method and apparatus to support transmission and/or storage broadband voice signal.The potential advantage of this type of embodiment comprise support with the compatibility of narrow band system embedded encoded, between narrow-band and high frequency band encoding channel, relatively easily distribute and reallocate, avoid the bigger broadband synthetic operation of calculated amount, and keep the low sampling rate for the treatment of by the signal of the bigger waveform coding routine processing of calculated amount.
Unless be subjected to context limited especially, otherwise this paper uses term " calculating " to represent any one of its its ordinary meaning, for example calculates, produces and select from the tabulation of value.This is described when using term " to comprise " in content and claims, does not get rid of other element or operation.Any one of its its ordinary meaning represented in use term " A is based on B ", comprises following situation: (i) " A equals B " and (ii) " A is at least based on B ".Term " Internet Protocol " comprises edition 4 and the subsequent version of describing as among IETF (the Internet engineering work group) RFC (Request for Comment) 791 (for example, version 6).
Fig. 1 a shows the block diagram according to the wideband speech coding device A100 of an embodiment.Bank of filters A110 is configured to broadband voice signal S10 is carried out filtering to produce narrow-band signal S20 and high-frequency band signals S30.Narrowband encoder A120 is configured to encode narrow-band signal S20 to produce narrow-band (NB) filter parameter S40 and narrow-band residual signal S50.Describe in further detail as this paper, narrowband encoder A120 is configured to as codebook index usually or takes another quantized versions and produce narrow band filter parameter S 40 and encoded narrow-band pumping signal S50.High band encoder A200 is configured to according to the coding of the information among encoded narrow-band pumping signal S50 high-frequency band signals S30 to produce high frequency band coding parameter S60.Describe in further detail as this paper, high band encoder A200 is configured to as codebook index usually or takes another quantized versions and produce high frequency band coding parameter S60.The particular instance of wideband speech coding device A100 is configured to coding broadband voice signal S10 under the speed of about 8.55kbps (kbps), wherein about 7.55kbps is used for narrow band filter parameter S 40 and encoded narrow-band pumping signal S50, and about 1kbps is used for high frequency band coding parameter S60.
May need encoded narrow-band and high-frequency band signals are combined as single bit stream.For instance, may need encoded signal multiplexed together to be used for transmission (for example, on wired, optics or wireless transmission channel) as encoded broadband voice signal or to be used for storage.Fig. 1 b shows the block diagram of the embodiment A102 of wideband speech coding device A100, wideband speech coding device A100 comprises multiplexer A130, and it is configured to narrow band filter parameter S 40, encoded narrow-band pumping signal S50 and high band filter parameter S 60 are combined as multiplex signal S70.
A kind of equipment that comprises scrambler A102 also can comprise and is configured to multiplex signal S70 is transferred to circuit in the transmission channel of for example wired, optics or wireless channel.This equipment also can be configured to signal is carried out one or more chnnel coding operations, for example error correction code (for example, the rate-compatible convolutional encoding) and/or error detection code (for example, cyclic redundancy code), and/or one or more layers procotol coding (for example, Ethernet, TCP/IP, cdma2000).
May need multiplexer A130 to be configured to embed encoded narrow-band signal (comprising narrow band filter parameter S 40 and encoded narrow-band pumping signal S50) as separable multiplex signal S70 tributary, making encoded narrow-band signal can be independent of another part of multiplex signal S70 (for example, high frequency band and/or low band signal) is resumed and decodes.For instance, multiplex signal S70 can be configured and make encoded narrow-band signal to recover by divesting high band filter parameter S 60.A potential advantage of this feature is to avoid needing described encoded broadband signal is carried out code conversion before the system of decoding of highband part encoded broadband signal being delivered to the decoding of supporting narrow-band signal but not supporting.
Fig. 2 a shows the block diagram according to the broadband Voice decoder B100 of an embodiment.Narrow-band demoder B110 is configured to decode narrow band filter parameter S 40 and encoded narrow-band pumping signal S50 to produce narrow-band signal S90.High band decoder B200 is configured to according to the high frequency band coding parameter S60 that decodes based on the narrow-band pumping signal S80 of encoded narrow-band pumping signal S50, to produce high-frequency band signals S100.In this example, narrow-band demoder B110 is configured to narrow-band pumping signal S80 is provided to high band decoder B200.Bank of filters B120 is configured to narrow-band signal S90 and high-frequency band signals S100 are made up to produce broadband voice signal S110.
Fig. 2 b is the block diagram of the embodiment B102 of broadband Voice decoder B100, and broadband Voice decoder B100 comprises demultiplexer B130, and it is configured to produce encoded signal S40, S50 and S60 from multiplex signal S70.A kind of equipment that comprises demoder B102 can comprise the circuit that is configured to receive from the transmission channel of for example wired, optics or wireless channel multiplex signal S70.This equipment also can be configured to signal is carried out one or more channel-decoding operations, for example the error correction decoding (for example, the rate-compatible convolution decoder) and/or error-detecting decoding (for example, the cyclic redundancy decoding), and/or one or more layers procotol decoding (for example, Ethernet, TCP/IP, cdma2000).
Bank of filters A110 is configured to according to division frequency band scheme input signal be carried out filtering to produce low frequency sub-band and high-frequency sub-band.Design standards on application-specific is decided, and it is overlapping or not overlapping that the output sub-band can have the bandwidth and the possibility that equate or do not wait.The bank of filters A110 configuration that produces two above sub-bands also is possible.For instance, this bank of filters can be configured to produce one or more low band signal, and described low band signal comprises the following interior component of frequency range (for example scope of 50-300Hz) of frequency range that is in narrow-band signal S20.This bank of filters also may be configured to produce one or more extra high-frequency band signals, and described extra high-frequency band signals comprises the above interior component of frequency range (for example scope of 14-20,16-20 or 16-32kHz) of frequency range that is in high-frequency band signals S30.In the case, can implement wideband speech coding device A100 with this signal of independent coding (one or more), and multiplexer A130 can be configured to extra encoded signal (one or more) is included in (for example, as removable part) among the multiplex signal S70.
Fig. 3 a shows the block diagram of the embodiment A112 of bank of filters A110, and bank of filters A110 is configured to produce two sub-frequency bands signals with the sampling rate that reduces.Bank of filters A110 is configured to receive the broadband voice signal S10 with high-frequency (or high frequency band) part and low frequency (or low-frequency band) part.Bank of filters A112 comprises the high frequency band processing path that is configured to receive broadband voice signal S10 and produces the low-frequency band processing path of narrow-band voice signal S20 and be configured to receive broadband voice signal S10 and produce high frequency band voice signal S30.110 pairs of broadband voice signals of low-pass filter S10 carries out filtering with the low frequency sub-band by selecting, and 130 pairs of broadband voice signals of Hi-pass filter S10 carries out filtering with the high-frequency sub-band by selecting.Because the bandwidth ratio broadband voice signal S10 of two sub-frequency bands signals is narrow,, its sampling rate do not have information loss so can reducing to a certain extent.Downsampled device 120 (is for example selected factor according to required, sample by removing signal and/or replace sample with mean value) reduce the sampling rate of low-pass signal, and downsampled device 140 similarly required is selected the sampling rate that factor reduces high communication number according to another.
Fig. 3 b shows the block diagram of the corresponding embodiment B122 of bank of filters B120.Upwards sampler 150 (for example, fill in and/or pass through reproduction copies by zero) increases the sampling rate of narrow-band signal S90, and 160 pairs of low-pass filters upwards sampled signal carry out filtering with only by low-frequency band part (for example, to prevent aliasing).Equally, upwards sampler 170 increases the sampling rate of high-frequency band signals S100, and 180 pairs of Hi-pass filters upwards sampled signal carry out filtering only to pass through highband part.Then, two passband signals are sued for peace to form broadband voice signal S110.In some embodiments of demoder B100, bank of filters B120 is configured to produce according to one or more flexible strategy that received and/or calculated by high band decoder B200 the weighted sum of two passband signals.Also expect the bank of filters B120 of two above passband signal combination configuration.
Each be embodied as finite impulse response (FIR) (FIR) wave filter of wave filter 110,130,160,180 or be embodied as infinite impulse response (IIR) wave filter.Encoder filters 110 and 130 frequency response can have the symmetry between stopband and the passband or the limited proportionality of dissimilar shape.Equally, demoder wave filter 160 and 180 frequency response can have the symmetry between stopband and the passband or the limited proportionality of dissimilar shape.May need (but not being that strictness is necessary) low-pass filter 110 and low-pass filter 160 to have same response, and Hi-pass filter 130 have same response with Hi-pass filter 180.In an example, two wave filters are to the 110,130 and 160, the 180th, quadrature mirror filter (QMF) group, its median filter to 110,130 and wave filter have same factor to 160,180.
In representative instance, low-pass filter 110 has the passband (for example, 0 to 4kHz frequency band) of the limited PSTN scope that comprises 300-3400Hz.The relative bandwidth of broadband voice signal S10, narrow-band signal S20 and high-frequency band signals S30 in two different embodiments of Fig. 4 a and 4b displaying.In these two particular instances, broadband voice signal S10 has the sampling rate (expression 0 is to the interior frequency component of 8kHz scope) of 16kHz, and narrow-band signal S20 has the sampling rate (frequency component that expression 0 is arrived in the 4kHz scope) of 8kHz.
In the example of Fig. 4 a, do not exist obviously overlapping between two sub-frequency bands.High-frequency band signals S30 shown in this example can obtain by the Hi-pass filter 130 that use has the passband of 4-8kHz.In the case, may need through filtering signal sampling rate to be reduced to 8kHz by being that factor is downsampled with 2.Can expect that this operation can significantly reduce the computational complexity to the further processing operation of signal, this operation will move down into the passband energy does not have information loss in 0 to the 4kHz scope.
In the alternate example of Fig. 4 b, the upper and lower sub-band has obviously overlapping, makes two sub-frequency bands signals all describe 3.5 to 4kHz zone.High-frequency band signals S30 in this example can obtain by the Hi-pass filter 130 that use has the passband of 3.5-7kHz.In the case, may need through filtering signal sampling rate to be reduced to 7kHz by being that factor is downsampled with 16/7.Can expect that this operation can significantly reduce the computational complexity to the further processing operation of signal, this operation will move down into the passband energy does not have information loss in 0 to the 3.5kHz scope.
In the call type code communication handset, the obvious response on the frequency range of one or more transducers (that is, microphone and earphone or loudspeaker) shortage 7-8kHz.In the example of Fig. 4 b, broadband voice signal S10 be in 7 and 8kHz between part be not included in the encoded signal.Other particular instance of Hi-pass filter 130 has the passband of 3.5-7.5kHz and 3.5-8kHz.
In some embodiments, as in the example of Fig. 4 b, providing overlapping permission to use low pass and/or the Hi-pass filter that on the overlay region, has level and smooth decay between the sub-band.This type of wave filter with have sharply or the wave filter of " brickwall (brick-wall) " response is compared, more easily design usually, not too complicated in the calculating, and/or the delay that causes is less.Wave filter with drastic shift district often has higher secondary lobe (this may cause aliasing) than the wave filter of the similar grade with level and smooth decay.Wave filter with drastic shift district also may have long impulse response, and this may cause the ring illusion.For bank of filters embodiment with one or more iir filters, allow the level and smooth decay on the overlay region can make it possible to use limit away from the wave filter (one or more) of unit circle, this is for guaranteeing that stable fixed point embodiment may be more important.
The overlapping permission low-frequency band of sub-band is mixed with the level and smooth of high frequency band, and this can cause the less illusion of hearing, reduces aliasing, and/or make a frequency band not too obvious to the transformation of another frequency band.In addition, the code efficiency of narrowband encoder A120 (for example, wave coder) can increase along with frequency is continuous and descend.For instance, may under low bitrate, especially there be the coding quality that reduces narrowband encoder under the situation of ground unrest.Under this type of situation, provide sub-band the overlapping quality that improves the frequency component of duplicating in the overlay region.
In addition, the overlapping permission low-frequency band of sub-band is mixed with the level and smooth of high frequency band, and it may cause the less illusion of hearing, reduces aliasing, and/or make a frequency band not too obvious to the transformation of another frequency band.This feature may especially cater to the need according to the embodiment of different coding method operation for narrowband encoder A120 and high band encoder A200.For instance, the different coding technology can produce the signal that sounds very different.Scrambler with codebook index form coding spectrum envelope can produce the signal with sound different with the scrambler that changes the coding spectral amplitude into.Time domain coding device (for example, pulse-code modulated or PCM encoder) can produce the signal with sound different with the Frequency Domain Coding device.With the scrambler of the representation coded signal of spectrum envelope and corresponding residual signal can produce have with only with the signal of the different sound of the scrambler of spectrum envelope representation coded signal.Signal encoding can be produced the output that has with from the different sound of the output of sinusoidal coder for the scrambler of the representation of its waveform.Under this type of situation, use wave filter to define in the broadband signal that non-overlapped sub-band may cause synthesizing the transformation between the sub-band more suddenly and sensuously more obvious with drastic shift district.
Have the QMF bank of filters of complementary overlapping frequency response although use usually in the sub-band technology, this type of wave filter is unsuitable at least some embodiments in the broadband coding embodiment described herein.The QMF bank of filters at scrambler place is configured to produce aliasing largely, in the described corresponding QMF bank of filters that is aliasing in the demoder place by cancellation.This configuration may be unsuitable for the application that signal causes a large amount of distortions between the bank of filters, because distortion can reduce the effectiveness of aliasing cancellation property.For instance, application described herein comprises be configured to the coding embodiment of operating under low-down bit rate.Because bit rate is very low, be rendered as obvious distortion so compare with original signal probably through decoded signal, make the use of QMF bank of filters can cause the aliasing of not cancellation.Use the application of QMF bank of filters to have high bit speed (for example, surpass 12kbps, and for G.722 surpassing 64kbps) usually for AMR.
In addition, scrambler can be configured to be similar to original signal on the sensigenous but the composite signal that in fact significantly is different from original signal.For instance, the scrambler of deriving high band excitation as described herein from narrow-band is residual can produce this signal, because may not exist actual high frequency band residual fully in decoded signal.The distortion largely of in this type of is used, using the QMF bank of filters can cause the aliasing by not cancellation to cause.
If the affected children frequency band is narrower, can reduce the amount distortion that the QMF aliasing causes so, because the influence of aliasing is limited to the bandwidth that equates with the sub-band width.Yet, comprising half the example of pact of broadband bandwidth for wherein each sub-band described herein, the distortion that is caused by the aliasing of not cancellation may influence the major part of signal.The position influence of frequency band of the aliasing of not cancellation above also may being subjected to, quality of signals takes place.For instance, near the broadband voice signal center (for example, 3 and 4kHz between) distortion of producing may be much more harmful than near the distortion that (for example, more than the 6kHz) signal edge takes place.
Though the response of the wave filter of QMF bank of filters is strict relevant each other, the low-frequency band of bank of filters A110 and B120 and high frequency band path can be configured to have complete incoherent frequency spectrum except that two sub-frequency bands overlapping.We with the overlay defining of two sub-frequency bands be the frequency response of high band filter drop to-frequency response of the some tremendously low frequency band filter of 20dB drops to-distance of the point of 20dB.In the various examples of bank of filters A110 and/or B120, this overlapping scope arrives about 1kHz for about 200Hz.But about 400 to about 600Hz scope presentation code efficient and the desired trade-off between the perception smoothness.In a particular instance mentioned above, overlap near the 500Hz.
May need to implement the next operation that in some stage execution graph 4a and 4b, illustrates of bank of filters A112 and/or B122.For instance, Fig. 4 c shows the block diagram of the embodiment A114 of bank of filters A112, and embodiment A114 uses a series of interpolations, takes a sample, selects with other and operate high-pass filtering and the downsampled operation of carrying out function equivalent.This type of embodiment can more easily design and/maybe can allow to re-use the functional block of logic and/or code.For instance, can use the identical function piece carry out shown in Fig. 4 c to 14kHz select and to the operation of selecting of 7kHz.Can pass through signal and function e Jn πOr sequence (1) nMultiply each other and implement reversing spectrum operation, described sequence (1) nValue between+1 and-1 alternately.The spectrum shaping operation can be embodied as and be configured so that thereby signal shaping obtains the low-pass filter of required overall filter response.
Figure 33,34a, 34b and 35a show respectively for the low-pass filter shown in Fig. 4 c, in be inserted to 34kHz, be sampled to 28kHz and selecting again to the frequency and the impulse response of the embodiment example of 14kHz.Figure 35 b shows for the interior 34kHz of being inserted to, be sampled to 28kHz again and select to the combination frequency and the impulse response of those embodiments of 14kHz.Figure 36 a and 36b show respectively for selecting to the frequency and the impulse response of the embodiment example of 7kHz and spectrum shaping operation shown in Fig. 4 c.
Notice, since the cause of reversing spectrum operation, the reversing spectrum of high-frequency band signals S30.The correspondingly subsequent operation in configuration codes device and the respective decoder.For instance, high band excitation generator A300 described herein can be configured to produce the high band excitation signal S120 that has the reversing spectrum form equally.
Fig. 4 d shows the block diagram of the embodiment B124 of bank of filters B122, and bank of filters B122 uses a series of interpolations, sampling and other are operated upwards sampling and the high-pass filtering operation of carrying out function equivalent again.Bank of filters B124 comprises the reversing spectrum operation in the high frequency band, and it makes and the middle similar operation counter-rotating of carrying out of the bank of filters (for example, bank of filters A114) of for example scrambler.In this particular instance, bank of filters B124 also comprises the notch filter in low-frequency band and the high frequency band, and it weakens the component of signal at 7100Hz place, but this type of wave filter be choose wantonly and do not need to comprise this type of wave filter.
Figure 37 a and 37b show respectively frequency and the impulse response for the embodiment example of low-pass filter shown in Fig. 4 d and narrow-band notch filter.Figure 38 a, 38b, 39a and 39b show respectively for be inserted in shown in Fig. 4 d 14kHz, in be inserted to 28kHz, be sampled to the frequency and the impulse response of the embodiment example of 16kHz and high frequency band notch filter again.
Narrowband encoder A120 implements according to source-filter model, and it is encoded to input speech signal the pumping signal that (A) a group describes the parameter of wave filter and (B) drive the synthetic duplicate of described wave filter generation input speech signal.Fig. 5 a shows the example of the spectrum envelope of voice signal.The peak value that shows the feature of this spectrum envelope is represented the resonance of voice range and is called resonance peak.Most of speech coders to this rough spectrum structured coding of major general is one group of parameter (for example a, filter coefficient).
Fig. 5 b shows the example as the elementary sources-filter configuration of the coding of the spectrum envelope that is applied to narrow-band signal S20.Analysis module calculates one group of parameter describing corresponding to the wave filter of the speech sound in a period of time (common 20 milliseconds).Prewhitening filter (be also referred to as and analyze or prediction error filter) according to those filter parameter configurations is removed spectrum envelope signal is carried out the frequency spectrum leveling.The whitened signal of gained (being also referred to as residual) is compared with primary speech signal, has less energy and therefore change less and be easy to encode.Because the error that the residual signal coding is caused also may be dispersed on the frequency spectrum more equably.Filter parameter and residual common through quantizing to be used for effectively transmission on channel.At the demoder place, according to the composite filter of filter parameter configuration by based on residual signal excitation to produce the synthetic version of raw tone sound.Composite filter is configured to have transfer function usually, and described transfer function is the inverted versions of the transfer function of prewhitening filter.
Fig. 6 shows the block diagram of the basic embodiment A122 of narrowband encoder A120.In this example, linear predictive coding (LPC) analysis module 210 spectrum envelopes with narrow-band signal S20 are encoded to one group of linear prediction (LP) coefficient (for example, the coefficient 1/A (z) of full utmost point wave filter).Analysis module is treated to input signal a series of non-overlapped frames usually, wherein calculates one group of new coefficient for each frame.Frame period normally can expect the cycle that signal is static in this locality; A common example is 20 milliseconds (being equivalent to following 160 samples of sampling rate of 8kHz).In an example, lpc analysis module 210 is configured to calculate one group of 10 LP filter coefficient to describe the resonance peak structure of each 20 milliseconds of frame.Also may implement analysis module input signal is treated to a series of overlapping frame.
Analysis module can be configured to directly analyze the sample of each frame, perhaps can at first be weighted sample according to window function (for example, Hamming window).Also can go up execution analysis at window (for example, 30 milliseconds of windows) greater than frame.This window can symmetry (5-20-5 for example makes it comprise and then before 20 milliseconds of frames and afterwards 5 milliseconds) or asymmetric (10-20 for example makes it comprise last 10 milliseconds of previous frame).The lpc analysis module is configured to use Levinson-Durbin recursion or Leroux-Gueguen algorithm computation LP filter coefficient usually.In another embodiment, analysis module can be configured to calculate one group of cepstrum coefficient rather than one group of LP filter coefficient of each frame.
The output speed of scrambler A120 can significantly reduce by quantizing filter coefficient, and less relatively to the influence of reproduction quality.Coefficient of linear prediction wave filter is difficult to effective quantification, and is mapped as another representation usually, and for example line spectrum pair (LSP) or line spectral frequencies (LSF) quantize and/or entropy coding being used for.In the example of Fig. 6, LP filter coefficient-LSF conversion 220 is transformed to one group of corresponding LSF with described group of LP filter coefficient.Other of LP filter coefficient representation one to one comprises partial autocorrelation coefficient, log area ratio value, adpedance and composes (ISP) and adpedance spectral frequency (ISF), and it is used for GSM (global system for mobile communications) AMR-WB (the how fast broadband of self-adaptation) coder.Usually, the conversion between one group of LP filter coefficient and the one group of corresponding LSF is reversible, but embodiment also comprises can not be under the error free situation reversible scrambler A120 embodiment of conversion.
Quantizer 230 is configured to quantize described group of narrow-band LSF (or other coefficient representation), and narrowband encoder A122 is configured to export the result of this quantification as narrow band filter parameter S 40.This quantizer comprises vector quantizer usually, and it is encoded to input vector for the index of corresponding vectorial clauses and subclauses in table or the code book.
As shown in Figure 6, narrowband encoder A122 is also by making narrow-band signal S20 produce residual signal by the prewhitening filter 260 (be also referred to as and analyze or prediction error filter) according to described group of filter coefficient configuration.In this particular instance, prewhitening filter 260 is embodied as the FIR wave filter, but also can use the IIR embodiment.This residual signal will contain the sensuously more important speech frame information of not representing in the narrow band filter parameter S 40, for example relevant with tone long-term structure usually.Quantizer 270 is configured to calculate the quantization means form of this residual signal to export as encoded narrow-band pumping signal S50.This quantizer comprises vector quantizer usually, and it is encoded to input vector for the index of corresponding vectorial clauses and subclauses in table or the code book.Perhaps, this quantizer can be configured to send one or more parameters, can dynamically produce vector at the demoder place from described parameter, rather than retrieve vector as in the sparse code book method from memory storage.The method is used for the encoding scheme of algebraically CELP (code book Excited Linear Prediction) for example and the coder of for example 3GPP2 (third generation partnership relation 2) EVRC (strengthening the variable bit rate coder).
Need narrowband encoder A120 to produce encoded narrow-band pumping signal according to the same filter parameter value that will can be used for corresponding narrow-band demoder.In this way, the encoded narrow-band pumping signal of gained may be considered the undesirable property of those parameter values, for example quantization error to a certain extent.Therefore, need to use and to dispose prewhitening filter by available same tie numerical value at the demoder place.In the basic example of as shown in Figure 6 scrambler A122,240 pairs of narrow-band coding parameters of quantizer S40 de-quantization, the conversion 250 of LSF-LP filter coefficient is shone upon back one group of corresponding LP filter coefficient with income value, and this group coefficient is used to dispose prewhitening filter 260 to produce the residual signal that is quantized by quantizer 270.
Some embodiments of narrowband encoder A120 are configured to calculate encoded narrow-band pumping signal S50 by a vector that identifies with the residual signal optimum matching from one group of code book vector.Yet, notice that narrowband encoder A120 also can be through implementing in fact not produce residual signal with the quantization means form of calculating residual signal.For instance, narrowband encoder A120 can be configured to use many code book vectors (for example to produce corresponding composite signal, according to one group of current filter parameter), and in selection and the perceptual weighting territory and the code book vector that joins of institute's signal correction that produces of original narrow-band signal S20 optimum matching.
Fig. 7 shows the block diagram of the embodiment B112 of narrow-band demoder B110.310 pairs of narrow band filter parameter S 40 de-quantizations of quantizer (in the case, de-quantization is one group of LSF), and the conversion 320 of LSF-LP filter coefficient is transformed to one group of filter coefficient (for example, describing with reference to quantizer 240 and the conversion 250 of narrowband encoder A122 as mentioned) with LSF.340 pairs of narrow-band residual signals of quantizer S40 de-quantization is to produce narrow-band pumping signal S80.Based on filter coefficient and narrow-band pumping signal S80, narrow-band composite filter 330 synthesis of narrow band signal S90.In other words, narrow-band composite filter 330 is configured to according to the de-quantization filter coefficient narrow-band pumping signal S80 be carried out spectrum shaping, to produce narrow-band signal S90.Narrow-band demoder B112 also is provided to high band encoder A200 with narrow-band pumping signal S80, and high band encoder A200 uses narrow-band pumping signal S80 to derive high band excitation signal S120, as described herein.In some embodiments of Miao Shuing, narrow-band demoder B110 can be configured to the extraneous information relevant with narrow-band signal (for example, spectral tilt, pitch gain and hysteresis, and speech pattern) is provided to high band decoder B200 hereinafter.
The system of narrowband encoder A122 and narrow-band demoder B112 is the basic example of synthesis analysis speech coder and decoder device.Code book Excited Linear Prediction (CELP) coding is the general series of of synthesis analysis coding, and the embodiment of this type of scrambler can be carried out residual waveform coding, wherein comprises for example selector bar purpose operation from fixing and self-adaptation code book, error minimize operation and/or perceptual weighting operation.Other embodiment of synthesis analysis coding comprises MELP (Mixed Excitation Linear Prediction) (MELP), algebraically CELP (ACELP), lax CELP (RCELP), Regular-Pulse Excitation (RPE), multiple-pulse CELP (MPE) and vector sum Excited Linear Prediction (VSELP) coding.The correlative coding method comprises multi-band excitation (MBE) and prototype waveform interpolation (PWI) coding.The example of standard synthesis analysis speech coder and decoder device comprises ETSI (ETSI) the GSM full rate coder (GSM06.10) that uses residual excited linear predictive (RELP), GSM EFR coder (ETSI-GSM 06.60), ITU (International Telecommunications Union (ITU)) standard the 11.8kb/s G.729 IS of Annex E scrambler, IS-136 (interim standard) 641 coders (time division multiple access (TDMA) scheme), GSM adaptive multi-rate (GSM-AMR) coder, and 4GV TM(the 4th generation Vocoder TM) coder (Qualcomm of California Diego California (QUALCOMM Incorporated, San Diego, CA)).Narrowband encoder A120 and corresponding demoder B110 can implement according to any one or any other speech coding technology in these technology (known or leaved for development), and described speech coding technology is expressed as voice signal the pumping signal that (A) a group describes the parameter of wave filter and (B) be used to drive described wave filter reproduction speech signal.
Even prewhitening filter is removed rough spectrum envelope from narrow-band signal S20 after, also may keep quite a large amount of meticulous harmonic structure (especially for turbid voice).The spectrum curve of an example of the residual signal (as producing) of Fig. 8 a displaying voiced sound signal (for example, vowel) by prewhitening filter.Visible periodic structure is relevant with tone in this example, and the different voiced sounds that send of same speaker may have different resonance peak structure but have similar tone structure.Fig. 8 b shows the time-domain curve of the example of this residual signal, and it shows the time series of tone pulses.
Can increase code efficiency and/or voice quality by the characteristic of using one or more parameter value coding tone structures.The frequency (being also referred to as fundamental frequency) that a key property of tone structure is a first harmonic, it arrives in the 400Hz scope 60 usually.This characteristic is encoded to the inverted versions of fundamental frequency usually, is also referred to as pitch lag (pitch lag).The number of sample in pitch period of pitch lag indication, and may be encoded as one or more codebook index.Voice signal from male speaker often recently has bigger pitch lag from women speaker's voice signal.
Another characteristics of signals relevant with the tone structure is periodically, the intensity of its indication harmonic structure, or in other words, signal is harmonic wave or non-harmonic degree.Periodic two typical designators are zero crossing and normalized autocorrelation function (NACF).Periodically also can be indicated by pitch gain, described pitch gain is encoded to code book gain (for example, quantizing the gain of self-adaptation code book) usually.
Narrowband encoder A120 can comprise one or more modules of the long-term harmonic structure of the narrow-band signal S20 that is configured to encode.As shown in Figure 9, a spendable typical CELP example comprises open loop lpc analysis module, and its coding short-term characteristic or rough spectrum envelope are the closed type loop long-term forecasting analysis phase afterwards, described stage coding fine pitch or harmonic structure.Short-term characteristic is encoded to filter coefficient, and long-time quality is encoded to for example value of the parameter of pitch lag and pitch gain.For instance, narrowband encoder A120 can be configured so that export encoded narrow-band pumping signal S50 with the form that comprises one or more codebook index (for example, this index of fixed password and self-adaptation codebook index) and corresponding yield value.The calculating of this quantization means form of narrow-band residual signal (for example, by quantizer 270) can comprise to be selected these index and calculates these values.The coding of tone structure also can comprise interpolation pitch prototype waveform, and described operation can comprise calculates poor between the continuous tone pulse.Can be at the modeling of forbidding long-term structure corresponding to the frame of clear voice (it is similar to noise and not systematization usually).
Embodiment according to the narrow-band demoder B110 of example shown in Figure 9 can be configured to after long-term structure (tone or harmonic structure) has been recovered narrow-band pumping signal S80 be outputed to high band decoder B200.For instance, this demoder can be configured to export the de-quantization version of narrow-band pumping signal S80 as encoded narrow-band pumping signal S50.Certainly, also may implement narrow-band demoder B110, make high band decoder B200 carry out the de-quantization of encoded narrow-band pumping signal S50 to obtain narrow-band pumping signal S80.
In the embodiment according to the wideband speech coding device A100 of example shown in Figure 9, high band encoder A200 can be configured to receive the narrow-band pumping signal that is produced by short run analysis or prewhitening filter.In other words, narrowband encoder A120 can be configured to before the long-term structure of coding the narrow-band pumping signal be outputed to high band encoder A200.Yet high band encoder A200 need receive from narrow-band channel will be by the same-code information of high band decoder B200 reception, and the coding parameter that makes high band encoder A200 produce may be considered the undesirable property of described information to a certain extent.Therefore, may be preferably, high band encoder A200 is from treating the identical parametersization of being exported by wideband speech coding device A100 and/or quantizing to rebuild the encoded narrow-band pumping signal S50 narrow-band pumping signal S80.A potential advantage of the method is to calculate high frequency band gain factor S60b described below more exactly.
Except the parameter of the short-term of describing narrow-band signal S20 and/or long-term structure, narrowband encoder A120 also can produce the parameter value relevant with other characteristic of narrow-band signal S20.These values (it may quantize to be exported by wideband speech coding device A100 through suitable) can be included in the narrow band filter parameter S 40 or output separately.High band encoder A200 also can be configured to calculate high frequency band coding parameter S60 according to one or more (for example, after the de-quantization) in these additional parameter.At broadband Voice decoder B100 place, high band decoder B200 can be configured to receive parameter value via narrow-band demoder B110 (for example, after the de-quantization).Perhaps, high band decoder B200 can be configured to direct reception (and may be used for de-quantization) parameter value.
In an example of additional narrow frequencyband coding parameter, narrowband encoder A120 produces the spectral tilt of each frame and the value of speech pattern parameter.The shape of spectrum envelope is relevant on spectral tilt and the passband, and represents by quantizing first reflection coefficient usually.For most of voiced sounds, spectrum energy reduces along with the continuous increase of frequency, makes the reflection coefficient of winning for negative and can approaching-1.Most of voicelesss sound have smooth frequency spectrum, thereby make the reflection coefficient of winning near zero, perhaps have more energy under high-frequency, thereby make the reflection coefficient of winning for just and can approaching+1.
Speech pattern (being also referred to as the sounding pattern) indication present frame represents that turbid voice still are clear voice.This parameter can have binary value, and it is based on the voice activity (for example, the relation between this measured value and the threshold value) of periodic one or more measured values (for example, zero crossing, NACF, pitch gain) and/or frame.In other embodiments, the speech pattern parameter has one or more other states to indicate the pattern of the transformation between for example noiseless or ground unrest or the noiseless and turbid voice.
High band encoder A200 is configured to according to source-filter model high-frequency band signals S30 that encodes, and wherein the excitation of this wave filter is based on encoded narrow-band pumping signal.Figure 10 shows the block diagram of the embodiment A202 of high band encoder A200, and high band encoder A200 is configured to produce the high frequency band coding parameter S60 stream that comprises high band filter parameter S 60a and high frequency band gain factor S60b.High band excitation generator A300 derives high band excitation signal S120 from encoded narrow-band pumping signal S50.Analysis module A210 produces one group of parameter value of the spectrum envelope of describing high-frequency band signals S30.In this particular instance, analysis module A210 is configured to carry out lpc analysis so that produce one group of LP filter coefficient for each frame of high-frequency band signals S30.Coefficient of linear prediction wave filter-LSF conversion 410 is transformed to one group of corresponding LSF with described group of LP filter coefficient.Described with reference to analysis module 210 and conversion 220 as mentioned, analysis module A210 and/or conversion 410 can be configured to use other coefficient sets (for example, cepstrum coefficient) and/or the coefficient representation (for example, ISP).
Quantizer 420 is configured to quantize described group of high frequency band LSF (or other coefficient representation, for example ISP), and high band encoder A202 is configured to export the result of this quantification as high band filter parameter S 60a.This quantizer comprises vector quantizer usually, and it is encoded to input vector for the index of corresponding vectorial clauses and subclauses in table or the code book.
High band encoder A202 also comprises composite filter A220, and its high band excitation signal S120 and encoded spectrum envelope (for example, described group of LP filter coefficient) that is configured to produce according to analysis module A210 produces synthetic high-frequency band signals S130.Composite filter A220 is embodied as iir filter usually, but also can use the FIR embodiment.In particular instance, composite filter A220 is embodied as the sextic autoregressive filter.
It is poor that high frequency band gain factor counter A230 calculates between the level of original high-frequency band signals S30 and synthetic high-frequency band signals S130 one or more, with the gain envelope of designated frame.Quantizer 430 can be embodied as input vector is encoded to the vector quantizer of index for the corresponding vectorial clauses and subclauses in table or the code book, it quantizes to specify the value (one or more) of gain envelope, and high band encoder A202 is configured to export the result of this quantification as high frequency band gain factor S60b.
In embodiment as shown in figure 10, composite filter A220 is configured to from analysis module A210 receiving filter coefficient.The alternate embodiment of high band encoder A202 comprises quantizer and inverse transform, it is configured to decoding filter coefficient from high band filter parameter S 60a, and composite filter A220 is configured to change into reception through the decoding filter coefficient in the case.This alternative arrangements can be supported the calculated gains envelope more exactly by high frequency band gain calculator A230.
In a particular instance, the respectively every frame output hexad LSF of analysis module A210 and high frequency band gain calculator A230 and one group of five yield value, the feasible broadband extension that can only realize narrow-band signal S20 with 11 bonus values of every frame.Ear is often more insensitive for the frequency error under the high-frequency, thereby the high frequency band of low LPC level coding can produce the signal with the perceived quality that can compare with the narrow-band coding of higher LPC level.The typical embodiments of high band encoder A200 can be configured to 8 to 12 high-quality that are used for spectrum envelope of every frame output and rebuild, and every frame is exported other 8 to 12 high-quality reconstructions that are used for temporal envelope.In another particular instance, the every frame of analysis module A210 is exported one group of eight LSF.
Some embodiments of high band encoder A200 are configured to produce high band excitation signal S120 in the following manner: produce the random noise signal with high-band frequency component, and according to the temporal envelope of narrow-band signal S20, narrow-band pumping signal S80 or high-frequency band signals S30 noise signal is carried out Modulation and Amplitude Modulation.Though this method based on noise can produce suitable result for voiceless sound, yet it may be undesirable for voiced sound, and the residual of voiced sound is generally harmonic wave and therefore has certain periodic structure.
High band excitation generator A300 is configured to extend to by the frequency spectrum with narrow-band pumping signal S80 and produces high band excitation signal S120 in the high-band frequency range.Figure 11 shows the block diagram of the embodiment A302 of high band excitation generator A300.Quantizer 450 is configured to the encoded narrow-band pumping signal of de-quantization S50 to produce narrow-band pumping signal S80.Frequency spectrum stretcher A400 is configured to produce harmonic wave based on narrow-band pumping signal S80 and extends signal S160.Combiner 470 is configured to the temporal envelope of the random noise signal of noise generator 480 generations and 460 calculating of envelope counter is made up to produce through zoop signal S170.Combiner 490 is configured to harmonic wave is extended signal S60 and mixes through zoop signal S170 to produce high band excitation signal S120.
In an example, frequency spectrum stretcher A400 is configured to narrow-band pumping signal S80 is carried out spectrum folding operation (being also referred to as mirror) to produce harmonic wave extension signal S160.Spectrum folding can be filled in pumping signal S80 execution and then use Hi-pass filter and keep false signal by zero.In another example, frequency spectrum stretcher A400 is configured to produce harmonic wave extension signal S160 by narrow-band pumping signal S80 frequency spectrum being translated to (for example, via upwards sampling, multiply each other with the constant frequency cosine signal afterwards) in the high frequency band.
Spectrum folding and translation method can produce harmonic structure and extend signal with the discontinuous frequency spectrum of the original harmonic structure of narrow-band pumping signal S80 on phase place and/or frequency.For instance, these class methods can produce the signal of the peak value with the multiple place that is not positioned at fundamental frequency usually, and this may cause the illusion of microphonia in the voice signal of rebuilding.These methods produce toward contact has the unnatural high-frequency harmonic wave of transferring characteristic than forte.Yet, bandwidth is restricted to and is not more than 3400Hz because the PSTN signal can be taken a sample under 8kHz, so the top frequency spectrum of narrow-band pumping signal S80 may contain seldom or not contain energy, make that translating extension signal that operation produces according to spectrum folding or frequency spectrum can have spectral hole more than the 3400Hz.
Other method that produces harmonic wave extension signal S160 comprises one or more fundamental frequencies of identification narrow-band pumping signal S80 and produces homophonic according to described information.For instance, the harmonic structure of pumping signal can be described with amplitude and phase information by fundamental frequency.Another embodiment of high band excitation generator A300 produces harmonic wave extension signal S160 based on fundamental frequency and amplitude (for example, as being indicated by pitch lag and pitch gain).Yet it is relevant on phase place to remove anharmonic wave extension signal and narrow-band pumping signal S80, otherwise the quality through decoded speech of gained may be unacceptable.
Can use nonlinear function produce with the narrow-band excitation phase on mutually dry doubling keep harmonic structure and do not have the high band excitation signal of phase discontinuity.Nonlinear function also can provide the noise level of the increase between the high-frequency harmonic wave, and it often sounds more natural than the tone high-frequency harmonic wave that the method for translating by for example spectrum folding and frequency spectrum produces.Can comprise ABS function (being also referred to as full-wave rectification), half-wave rectification, square, cube and slicing by the typical memoryless nonlinear function that the various embodiments of frequency spectrum stretcher A400 are used.Other embodiment of frequency spectrum stretcher A400 can be configured to use the nonlinear function with memory.
Figure 12 is the block diagram of the embodiment A402 of frequency spectrum stretcher A400, and frequency spectrum stretcher A400 is configured to use the frequency spectrum that nonlinear function extends narrow-band pumping signal S80.Upwards sampler 510 is configured to the sampling that makes progress to narrow-band pumping signal S80.May need signal is carried out fully upwards sampling so that the aliasing when using nonlinear function minimizes.In a particular instance, upwards sampler 510 is a factor to the signal sampling that makes progress with 8.Upwards sampler 510 can be configured to fill in and the result is carried out low-pass filtering carry out upwards sampling operation by input signal being carried out zero.Nonlinear function counter 520 is configured to nonlinear function is applied to through the sampled signal that makes progress.Extend (for example, square) for frequency spectrum, ABS function is not need energy scaleization with respect to a potential advantage of other nonlinear function.In some embodiments, can use ABS function effectively by the sign bit of peeling off or remove each sample.Nonlinear function counter 520 also can be configured to carry out through upwards sampling or frequency spectrum extend the amplitude excursion of signal.
Downsampled device 530 is configured to that the frequency spectrum of using nonlinear function is extended the result and carries out downsampled.Downsampled device 530 may need to carry out the bandpass filtering operation to select frequency spectrum to extend the required frequency band of signal before reducing sampling rate (for example, so that reduce or avoid because aliasing or the error that unnecessary image causes).Downsampled device 530 may also need reduce sampling rate an above stage.
Figure 12 a shows that frequency spectrum extends the figure of the signal spectrum at each point place in the example of operating, and wherein frequency scaling is identical on each curve.Curve (a) is showed the frequency spectrum of the example of narrow-band pumping signal S80.Curve (b) shows that signal S80 is a upwards sampling frequency spectrum afterwards of factor with 8.Curve (c) is showed the example of using nonlinear function extension frequency spectrum afterwards.Curve (d) is showed the frequency spectrum after the low-pass filtering.In this example, passband extends to the upper frequency limit (for example, 7kHz or 8kHz) of high-frequency band signals S30.
Frequency spectrum after curve (e) is showed the downsampled phase one, wherein making sampling rate is that factor reduces to obtain broadband signal with 4.Curve (f) displaying carrying out high-pass filtering is operated with the frequency spectrum after the highband part of selecting the extension signal, and the downsampled subordinate phase frequency spectrum afterwards of curve (g) displaying, and wherein making sampling rate is that factor reduces with 2.In a particular instance, downsampled device 530 is carried out high-pass filtering and downsampled subordinate phase by the Hi-pass filter 130 and the downsampled device 140 that make broadband signal pass through bank of filters A112 (or other structure or routine with same response), has the frequency spectrum extension signal of frequency range and the sampling rate of high-frequency band signals S30 with generation.
As in the curve (g) as seen, downsampled its reversing spectrum that impels of the high communication number shown in the curve (f).In this example, downsampled device 530 also is configured to signal is carried out the spectrum inversion operation.Curve (h) is showed the result who uses the spectrum inversion operation, and described spectrum inversion operation can be passed through signal and function e Jn πOr sequence (1) nMultiply each other and carry out, described sequence (1) nValue between+1 and-1 alternately.This operation is equivalent in frequency domain the digital spectrum translocation distance π with signal.Notice, also can obtain identical result by use downsampled the operation with different order with spectrum inversion.Upwards sampling and/or downsampled operation also can be configured to comprise sampling rate (for example, frequency spectrum extension signal 7kHz) that sampling again obtains to have high-frequency band signals S30.
Notice as mentioned, bank of filters A110 and B120 can be through implementing to make the one or both among narrow-band and high-frequency band signals S20, the S30 have the reversing spectrum form in output place of bank of filters A110, be encoded and decode with the reversing spectrum form, and in broadband voice signal S110 before the output at bank of filters B120 place reversing spectrum once more.Certainly, in the case, with the spectrum inversion operation that does not need as shown in Figure 12 a, because high band excitation signal S120 will also need to have the reversing spectrum form.
The upwards sampling of the frequency spectrum extension operation that frequency spectrum stretcher A402 carries out and each downsampled task can many different modes configurations and arrangements.For instance, Figure 12 b shows that frequency spectrum extends the figure of the signal spectrum at each point place in another example of operating, and wherein frequency scaling is identical on each curve.Curve (a) is showed the frequency spectrum of the example of narrow-band pumping signal S80.Curve (b) shows that signal S80 is a upwards sampling frequency spectrum afterwards of factor with 2.Curve (c) is showed the example of using nonlinear function extension frequency spectrum afterwards.In the case, accept contingent aliasing in the upper frequency.
Curve (d) is showed the frequency spectrum after the reversing spectrum operation.Frequency spectrum after curve (e) is showed the downsampled single stage, wherein making sampling rate is that factor reduces to extend signal to obtain required frequency spectrum with 2.In this example, described signal is taked the reversing spectrum form, and can be used for handling in the embodiment of high band encoder A200 of the high-frequency band signals S30 that takes this form.
The frequency spectrum that nonlinear function counter 520 produces extends signal, and amplitude obviously reduces along with the frequency increase probably.Frequency spectrum stretcher A402 comprises frequency spectrum tenderizer 540, and it is configured to operating through the albefaction of sampled signal execution downwards.Frequency spectrum tenderizer 540 can be configured to carry out fixedly albefaction operation or carry out the adaptive whitening operation.In the particular instance of adaptive whitening, frequency spectrum tenderizer 540 comprises: the lpc analysis module, and it is configured to according to calculating one group of four filter coefficient through downward sampled signal; And four analysis filters, it is configured to according to those coefficients signal be carried out albefaction.Other embodiment of frequency spectrum stretcher A400 comprises frequency spectrum tenderizer 540 extended signal operation to frequency spectrum before downsampled device 530 configuration.
Can implement high band excitation generator A300 and extend signal S160 as high band excitation signal S120 with output harmonic wave.Yet, in some cases, only use harmonic wave extension signal may cause the illusion that can hear as high band excitation.The harmonic structure of voice is not so good as in the low-frequency band obvious in high frequency band usually, and uses too much harmonic structure may cause buzz in high band excitation signal.This illusion may be especially obvious in from women speaker's voice signal.
Embodiment comprises the embodiment that is configured to harmonic wave is extended the high band excitation generator A300 that signal S160 mixes with noise signal.As shown in figure 11, high band excitation generator A302 comprises noise generator 480, and it is configured to produce random noise signal.In an example, noise generator 480 is configured to produce unit variance white pseudo-random noise signal, but in other embodiments, noise signal do not need for white and can have power density along with frequency change.Noise generator 480 may need to be configured to the output noise signal as the determinacy function so that can duplicate its state at the demoder place.For instance, noise generator 480 can be configured to the output noise signal conduct determinacy function of information encoded (for example, narrow band filter parameter S 40 and/or encoded narrow-band pumping signal S50) in same number of frames previously.
Extending before signal S160 mixes with harmonic wave, the random noise signal that noise generator 480 produces can be through the temporal envelope of Modulation and Amplitude Modulation with energy distribution in time with approximate narrow-band signal S20, high-frequency band signals S30, narrow-band pumping signal S80 or harmonic wave extension signal S160.As shown in figure 11, high band excitation generator A302 comprises combiner 470, and its temporal envelope that is configured to calculate according to envelope counter 460 carries out Modulation and Amplitude Modulation to the noise signal that noise generator 480 produces.For instance, combiner 470 can be embodied as multiplier, and it is configured to come the output of convergent-divergent noise generator 480 to produce through zoop signal S170 according to the temporal envelope that envelope counter 460 calculates.
Shown in the block diagram of Figure 13, in the embodiment A304 of high band excitation generator A302, envelope counter 460 is configured to calculate the envelope that harmonic wave extends signal S160.Shown in the block diagram of Figure 14, in the embodiment A306 of high band excitation generator A302, envelope counter 460 is configured to calculate the envelope of narrow-band pumping signal S80.The other embodiments of high band excitation generator A302 can otherwise be configured in time to extend signal S160 to harmonic wave according to the position of narrow-band tone pulses and add noise.
Envelope counter 460 can be configured to comprise the task of a series of subtasks and carry out envelope and calculate as one.Figure 15 shows the process flow diagram of the example T100 of this task.Subtask T110 calculate envelope treat the signal of modeling (for example, narrow-band pumping signal S80 or harmonic wave extend signal S160) frame each sample square to produce the square value sequence.Subtask T120 carries out smooth operation to the square value sequence.In an example, subtask T120 uses an IIR low-pass filter according to following formula to sequence:
y(n)=ax(n)+(1-a)y(n-1), (1)
Wherein x is the wave filter input, and y is wave filter output, Domain Index when n is, and a is the smoothing factor with the value between 0.5 and 1.The value of smoothing factor a can be fixing, perhaps in alternate embodiment, can be according to the indication of noise in the input signal and self-adaptation, and make under muting situation a near 1, and exist under the situation of noise near 0.5.Subtask T130 is applied to through each sample of level and smooth sequence square root function to produce temporal envelope.
This embodiment of envelope counter 460 can be configured to according to execute the task each subtask of T100 of serial and/or parallel mode.In the other embodiments of task T100, can the logical operation of band before the T110 of subtask, the required frequency part of the signal that it is configured to select envelope to treat modeling, for example 3-4kHz scope.
Combiner 490 is configured to harmonic wave is extended signal S160 and mixes through zoop signal S170 to produce high band excitation signal S120.The embodiment of combiner 490 can be configured (for example) with high band excitation signal S120 is calculated as harmonic wave extend signal S160 with through zoop signal S170's and.This embodiment of combiner 490 can be configured to by extending signal S160 and/or to using weighting factor through zoop signal S170 to harmonic wave before summation, and high band excitation signal S120 is calculated as weighted sum.Can calculate each this type of weighting factor according to one or more standards, and described weighting factor can be fixed value, perhaps frame by frame or by the adaptation value that calculates on the sub-frame basis.
Figure 16 shows the block diagram of the embodiment 492 of combiner 490, and described embodiment 492 is configured to that high band excitation signal S120 is calculated as harmonic wave and extends signal S160 and weighted sum through zoop signal S170.Combiner 492 is configured to extend signal S160 according to harmonic wave weighting factor S180 weighting harmonic wave, and through zoop signal S170, and output high band excitation signal S120 is as the summation that is weighted signal according to noise weighting factor S190 weighting.In this example, combiner 492 comprises weighting factor counter 550, and it is configured to calculate harmonic wave weighting factor S180 and noise weighting factor S190.
Weighting factor counter 550 can be configured to calculate weighting factor S180 and S190 according to the required ratio of harmonic content and noise content among the high band excitation signal S120.For instance, combiner 492 may need to produce high band excitation signal S120 with have with the harmonic energy of high-frequency band signals S30 and noise energy than similar harmonic energy and noise energy ratio.In some embodiments of weighting factor counter 550, calculate weighting factor S180, S190 according to one or more parameters relevant (for example, pitch gain and/or speech pattern) with the periodicity of narrow-band signal S20 or narrow-band residual signal.This embodiment of weighting factor counter 550 can be configured to assign (for example) and the proportional value of pitch gain to harmonic wave weighting factor S180, and/or be compared to turbid voice signal for clear voice signal and assign higher value to noise weighting factor S190.
In other embodiments, weighting factor counter 550 is configured to calculate according to the periodic measured value of high-frequency band signals S30 the value of harmonic wave weighting factor S180 and/or noise weighting factor S190.In this type of example, the maximal value of the present frame of the high-frequency band signals S30 that weighting factor counter 550 is calculated as harmonic wave weighting factor S180 or the coefficient of autocorrelation of subframe is wherein in the delay that comprises a pitch lag and do not comprise on the hunting zone of delay of zero sample and carry out auto-correlation.Figure 17 is illustrated in that length placed in the middle and that have a width that is not more than a pitch lag is the example of this hunting zone of n sample near the delay of a pitch lag.
Figure 17 also shows the example of weighting factor counter 550 in the other method of the periodic measured value of some stages calculating high-frequency band signals S30.In the phase one, present frame is divided into many subframes, and discerns the delay of coefficient of autocorrelation when maximum separately at each subframe.As mentioned above, in the delay that comprises a pitch lag and do not comprise on the hunting zone of delay of zero sample and carry out auto-correlation.
In subordinate phase, be applied to each subframe by delay with corresponding identification, the subframe that connects gained to be setting up the optimal delay frame, and harmonic wave weighting factor S180 is calculated as related coefficient between primitive frame and the optimal delay frame, sets up deferred frame.In another alternate embodiment, weighting factor counter 550 is calculated as harmonic wave weighting factor S180 the mean value of the maximum coefficient of autocorrelation that obtains at each subframe in the phase one.The embodiment of weighting factor counter 550 also can be configured to the convergent-divergent related coefficient, and/or itself and another value is made up, to calculate the value of harmonic wave weighting factor S180.
Weighting factor counter 550 may need only otherwise indicating frame to have the periodic measured value that calculates high-frequency band signals S30 under the periodic situation.For instance, weighting factor counter 550 can be configured to the periodic measured value that calculates high-frequency band signals S30 according to periodic another designator (for example, pitch gain) and the relation between the threshold value of present frame.In an example, weighting factor counter 550 value that only is configured to the pitch gain (for example, the residual self-adaptation code book gain of narrow-band) when frame is just carried out auto-correlation computation to high-frequency band signals S30 during greater than 0.5 (perhaps, at least 0.5).In another example, weighting factor counter 550 is configured to only at the frame with special sound mode state (for example, only at the voiced sound signal) high-frequency band signals S30 be carried out auto-correlation computation.Under this type of situation, weighting factor counter 550 can be configured to assign the default weighting factor at the frame with other speech pattern state and/or less pitch gain value.
Embodiment comprises and is configured to according to being different from periodically or removing the other embodiments that characteristic the periodicity is calculated the weighting factor counter 550 of weighting factor.For instance, this embodiment can be configured at the voice signal with big pitch lag than assigning bigger value at the voice signal with little pitch lag to noise gain factor S190.This type of embodiment of another of weighting factor counter 550 is configured to signal energy according to the multiple place that is in fundamental frequency with respect to the measured value of the signal energy that is in other frequency component place, determines the measured value of the humorous degree of broadband voice signal S10 or high-frequency band signals S30.
Some embodiments of wideband speech coding device A100 are configured to another measured value based on pitch gain described herein and/or periodicity or humorous degree, export periodically or the indication of humorous degree (for example, the indication frame is that harmonic wave still is non-harmonic 1 flag).In an example, corresponding broadband Voice decoder B100 uses this to indicate and disposes for example operation of weighting factor calculating.In another example, this indication is used for the value that scrambler and/or demoder place come the computing voice mode parameter.
May need high band excitation generator A302 to produce high band excitation signal S120, make the energy of pumping signal roughly not be subjected to the influence of the particular value of weighting factor S180 and S190.In the case, weighting factor counter 550 can be configured to calculate the value (or receive this value from another element of memory storage or high band encoder A200) of harmonic wave weighting factor S180 or noise weighting factor S190, and derives the value of another weighting factor according to for example following formula:
(W Harmonic wave) 2+ (W Noise) 2=1, (2)
W wherein Harmonic waveExpression harmonic wave weighting factor S180, and W NoiseExpression noise weighting factor S190.Perhaps, weighting factor counter 550 can be configured to according to the value of the periodic measurement of present frame or subframe from how corresponding one to selecting weighting factor S180, the S190, and is wherein said to through calculating to satisfy for example constant energy ratio of expression formula (2) in advance.For the embodiment of the weighting factor counter 550 of following expression formula (2), the representative value of harmonic wave weighting factor S180 arrives in about 1.0 scopes about 0.7, and the representative value of noise weighting factor S190 arrives in about 0.7 scope about 0.1.Other embodiment of weighting factor counter 550 can be configured to extend expression formula (2) pattern that signal S160 and the required baseline between zoop signal S170 add weight update according to the foundation harmonic wave and operate.
When using sparse code book (the most of code book of clauses and subclauses) when calculating residual quantization means form, in the synthetic speech signal illusion may take place as null value.Especially when with low bitrate coding narrow-band signal, it is sparse code book to take place.The sparse illusion that causes of code book is quasi periodic usually in time, and mainly takes place more than 3kHz.Because people's ear has time resolution preferably under upper frequency, so these illusions may be more obvious in high frequency band.
Embodiment comprises the embodiment of the high band excitation generator A300 that is configured to carry out anti-sparseness filtering.Figure 18 shows the block diagram of the embodiment A312 of high band excitation generator A302, and described embodiment A312 comprises anti-sparseness filtering device 600, and it is configured to carry out filtering to what quantizer 450 produced through de-quantization narrow-band pumping signal.Figure 19 shows the block diagram of the embodiment A314 of high band excitation generator A302, and described embodiment A314 comprises anti-sparseness filtering device 600, and its frequency spectrum that is configured to that frequency spectrum stretcher A400 is produced extends signal and carries out filtering.Figure 20 shows the block diagram of the embodiment A316 of high band excitation generator A302, and described embodiment A316 comprises anti-sparseness filtering device 600, and it is configured to the output of combiner 490 is carried out filtering to produce high band excitation signal S120.Certainly, expection and this disclose clearly with embodiment A304 and A306 any one feature and any one the embodiment of high band excitation generator A300 of characteristics combination of embodiment A312, A314 and A316.Anti-sparseness filtering device 600 is also configurable in frequency spectrum stretcher A400: for example the element in frequency spectrum stretcher A402 510,520,530 and 540 any one after.Pay particular attention to, anti-sparseness filtering device 600 also can be used for the embodiment that execution spectrum folding, frequency spectrum are translated or harmonic wave extends of frequency spectrum stretcher A400.
Anti-sparseness filtering device 600 can be configured to change its phase of input signals.For instance, anti-sparseness filtering device 600 may need to be configured and to arrange, and makes the phase place of high band excitation signal S120 along with time randomization or alternate manner distribute more equably.The response that may also need anti-sparseness filtering device 600 is the frequency spectrum leveling, and feasible amplitude frequency spectrum through filtering signal does not have sizable change.In an example, anti-sparseness filtering device 600 is embodied as the all-pass filter with transfer function according to following formula:
H ( z ) = - 0.7 + z - 4 1 - 0.7 z - 4 · 0.6 + z - 6 1 + 0.6 z - 6 . - - - ( 3 )
An effect of this wave filter can be the energy dissipation of input signal to be opened make it no longer only concentrate in several samples.
The sparse illusion that causes of code book is more obvious for the signal of the residual similar noise that comprises less tone information wherein usually, and also more obvious for the voice in the ground unrest.Usually cause less illusion under the sparse situation that has long-term structure in excitation, and in fact phase modification can cause noise in the voiced sound signal.Therefore, may need to dispose anti-sparseness filtering device 600 the voiceless sound signal is carried out filtering and at least some voiced sound signals are passed through.The voiceless sound signal (for example is characterised in that the low pitch gain, quantize the gain of narrow-band self-adaptation code book) and near zero or be positive spectral tilt (for example, quantize first reflection coefficient), thus indication leveling or acclivitous spectrum envelope along with the continuous increase of frequency.The typical embodiments of anti-sparseness filtering device 600 to voiceless sound (for example is configured to, value as spectral tilt is indicated) carry out filtering, when pitch gain is lower than threshold value (perhaps, being not more than threshold value), voiced sound is carried out filtering, and otherwise under the situation of not making change, signal is passed through.
The other embodiments of anti-sparseness filtering device 600 comprise two or more wave filters, and it is configured to have different maximum phases and revises angle (for example, up to 180 degree).In the case, anti-sparseness filtering device 600 according to pitch gain (for example can be configured to, quantize self-adaptation code book or LTP gain) value form in wave filters at these and select be used to have frame so that maximum phase that will be bigger is revised the angle than the low pitch yield value.The embodiment of anti-sparseness filtering device 600 also can comprise different composition wave filters, it is configured to revise phase place on the part more or less of frequency spectrum, is used to have frame than the low pitch yield value so that will be configured on the wider frequency range of input signal to revise the wave filter of phase place.
In order to duplicate encoded voice signal exactly, may need to make the high frequency band of synthetic broadband voice signal S100 and ratio between the narrow-band level partly to be similar to described ratio among the original broadband voice signal S10.Except the spectrum envelope that high frequency band coding parameter S60a represents, high band encoder A200 also can be configured to represent by fixed time or gain envelope the feature of high-frequency band signals S30.As shown in figure 10, high band encoder A202 comprises high frequency band gain factor counter A230, it is configured and arranges to calculate one or more gain factors according to the relation between high-frequency band signals S30 and the synthetic high-frequency band signals S130 (for example, the difference or the ratio of described two signals between the energy on frame or its certain part).In other embodiment of high band encoder A202, high frequency band gain calculator A230 can similarly dispose but change into through arranging to come the calculated gains envelope according to this time-varying relationship between high-frequency band signals S30 and narrow-band pumping signal S80 or the high band excitation signal S120.
The temporal envelope of narrow-band pumping signal S80 and high-frequency band signals S30 is similar probably.Therefore, coding usually will be only more effective based on the gain envelope of high-frequency band signals S30 than coding based on the gain envelope of the relation between high-frequency band signals S30 and the narrow-band pumping signal S80 (or the signal of therefrom deriving, for example high band excitation signal S120 or synthetic high-frequency band signals S130).In typical embodiments, high band encoder A202 is configured to be output as 8 to 12 the quantization index that each frame is specified 5 gain factors.
High frequency band gain factor counter A230 can be configured to comprise the task of one or more serial subtasks and carry out gain factor and calculate as one.Figure 21 shows that the relative energy according to high-frequency band signals S30 and synthetic high-frequency band signals S130 calculates the process flow diagram of example T200 of task of the yield value of corresponding subframe.Task 220a and 220b calculate the energy of the corresponding subframe of each signal.For instance, task 220a and 220b can be configured to energy be calculated as each subframe sample square and.Task T230 is calculated as the gain factor of subframe the square root of the ratio of those energy.In this example, task T230 is calculated as gain factor the square root of ratio of the energy of the energy of high-frequency band signals S30 on the subframe and synthetic high-frequency band signals S130.
High frequency band gain factor counter A230 may need to be configured to calculate subframe energy according to window function.Figure 22 shows the process flow diagram of this embodiment T210 of gain factor calculation task T200.Task T215a is applied to high-frequency band signals S30 with window function, and task T215b is applied to synthetic high-frequency band signals S130 with the uniform window function.The embodiment 222a of task 220a and 220b and 222b calculate the energy of window separately, and task T230 is calculated as the gain factor of subframe the square root of the ratio of energy.
May need to use the window function overlapping with adjacent sub-frames.For instance, can be overlapping-window function of the generation gain factor that the phase add mode is used can help to reduce or avoid uncontinuity between the subframe.In an example, high frequency band gain factor counter A230 is configured to use the trapezoidal window function shown in Figure 23 a, and wherein each of window and two adjacent sub-frames is overlapping one millisecond.Figure 23 b shows each of five subframes that this window function is applied to 20 milliseconds of frames.Other embodiment of high frequency band gain factor counter A230 can be configured to use and have negative lap cycle not and/or different windows shape (for example, rectangle, Hamming) window function of (its can symmetry or asymmetric).The embodiment of high frequency band gain factor counter A230 may be configured to that also the different windows function is applied to the different subframes in the frame and/or comprise the frame of the subframe with different length.
The example of following value (without limits) as particular is provided.At the frame of one 20 milliseconds of these situation supposition, but can use any other duration.For the high-frequency band signals with the 7kHz sampling, each frame has 140 samples.If this frame is divided into five subframes with equal length, each subframe will have 28 samples so, and the window shown in Figure 23 a will be wide for 42 samples.For the high-frequency band signals with the 8kHz sampling, each frame has 160 samples.If this frame is divided into five subframes with equal length, each subframe will have 32 samples so, and the window shown in Figure 23 a will be wide for 48 samples.In other embodiments, can use subframe, and even may make the embodiment of high frequency band gain calculator A230 be configured to produce different gain factors at each sample of frame with any width.
Figure 24 shows the block diagram of the embodiment B202 of high band decoder B200.High band decoder B202 comprises high band excitation generator B300, and it is configured to produce high band excitation signal S120 based on narrow-band pumping signal S80.Select to decide on particular system design, can implement high band excitation generator B300 according to any one of the embodiment of high band excitation generator A300 described herein.Usually, high band excitation generator B300 need be embodied as the identical response of high band excitation generator that has with the high band encoder of specific coding system.Yet, because narrow-band demoder B110 will carry out the de-quantization of encoded narrow-band pumping signal S50 usually, so in most of the cases, high band excitation generator B300 can be through implementing receiving narrow-band pumping signal S80 from narrow-band demoder B110, and do not need to comprise the quantizer that is configured to encoded narrow-band pumping signal S50 de-quantization.Narrow-band demoder B110 also may be through implementing comprising the example of anti-sparseness filtering device 600, and it carried out filtering to described signal before arranging with the narrow-band composite filter that will be input to wave filter 330 for example through the narrow-band pumping signal of de-quantization.
Quantizer 560 is configured to the de-quantization to high band filter parameter S 60a (being one group of LSF in this example), and LSF-LP filter coefficient conversion 570 is configured to LSF is transformed to one group of filter coefficient (for example, describing with reference to quantizer 240 and the conversion 250 of narrowband encoder A122 as mentioned).In other embodiments, as mentioned above, can use different coefficient sets (for example, cepstrum coefficient) and/or the coefficient representation (for example, ISP).High frequency band composite filter B200 is configured to produce synthetic high-frequency band signals according to high band excitation signal S120 and described group of filter coefficient.The system that comprises composite filter for high band encoder wherein (for example, in the example as above-mentioned scrambler A202), may need high frequency band composite filter B200 is embodied as and have the response identical (for example, identical transfer function) with described composite filter.
High band decoder B202 also comprises the quantizer 580 that is configured to high frequency band gain factor S60b de-quantization, with be configured and arrange will be applied to synthetic high-frequency band signals through the gain factor of de-quantization to produce the gain control element 590 (for example, multiplier or amplifier) of high-frequency band signals S100.For the gain envelope of frame wherein situation by an above gain factor appointment, gain control element 590 can comprise the logic that is configured to gain factor to be applied to according to window function each subframe, described window function can be identical or different with the window function of being used by the gain calculator (for example, high frequency band gain calculator A230) of corresponding high band encoder.In other embodiment of high band decoder B202, gain control element 590 is applied to the gain factor through de-quantization narrow-band pumping signal S80 or is applied to high band excitation signal S120 to change into through configuration similarly but through arranging.
As mentioned above, may in high band encoder and high band decoder, obtain equal state (for example, by using through the de-quantization value during encoding).Therefore, may guarantee in coded system that the corresponding noise generator among high band excitation generator A300 and the B300 has equal state according to this embodiment.For instance, the high band excitation generator A300 of this embodiment and B300 can be configured and make that the state of noise generator is that information encoded has been (for example in the same number of frames, narrow band filter parameter S 40 or its part, and/or encoded narrow-band pumping signal S50 or its part) the determinacy function.
One or more (for example, quantizer 230,420 or 430) in the quantizer of element described herein can be configured to carry out class vector and quantize.For instance, this quantizer can be configured to based in the narrow-band channel and/or in the same number of frames in the high frequency band channel information encoded from one group of code book, select a code book.This technology is the code efficiency that cost provides increase to store extra code book usually.
Referring to for example Fig. 8 and 9 argumentations, remove rough spectrum envelope from narrow-band voice signal S20 after, quite a large amount of periodic structures may be retained in the residual signal as mentioned.For instance, residual signal can contain rough recurrent pulses or spiking sequence in time.This structure (relevant with tone usually) especially might occur in the voiced speech signal.The calculating of the quantization means form of narrow-band residual signal can comprise according to the model of the long term periodicities of being represented by (for example) one or more code books this tone structure of encoding.
The tone structure of actual residual signals may not mated with periodic model fully.For instance, residual signal may comprise the less shake of the location rule of tone pulses, makes in the frame distance between the continuous tone pulse not exclusively equate and described structure is not suitable rule.These scramblings tend to reduce code efficiency.
Some embodiments of narrowband encoder A120 be configured to by before quantizing or during be applied to the auto-adaptive time deviation residual, or, carry out the regularization of tone structure by otherwise in encoded pumping signal, comprising the auto-adaptive time deviation.For instance, this scrambler can be configured to select or otherwise computing time deviation degree (for example, according to one or more perceptual weightings and/or error minimize standard), make the pumping signal of gained and model the best of long term periodicities fit.The regularization of tone structure is carried out by the celp coder group that is called lax code exciting lnear predict (RCELP) scrambler.
The RCELP scrambler is configured to the execution time deviation usually and is offset as auto-adaptive time.This time skew can be negative several milliseconds and arrives the just delay of several milliseconds of scopes, and it changes the uncontinuity that can hear to avoid usually smoothly.In some embodiments, this scrambler is configured to the segmented mode application ruleization, the wherein corresponding set time skew of each frame or subframe deviation.In other embodiments, scrambler is configured to application rule and turns into and be continuous departure function, makes frame or subframe according to tone contour (being also referred to as the tone track) and deviation.In some cases (for example, described in No. 2004/0098255 U.S. Patent Application Publication case), scrambler is configured to by offset applications is comprised time deviation in being used for calculating the perceptual weighting input signal of encoded pumping signal in encoded pumping signal.
The encoded pumping signal of scrambler computation ruleization and quantification, and demoder is used for synthetic pumping signal through decodeing speech signal to encoded pumping signal de-quantization with acquisition.Therefore show the delay of the variation identical through decoded output signal be included in delay in the encoded pumping signal by regularization.Usually, not with the information transmission of any specified rule amount to demoder.
Regularization often makes residual signal more easily encode, and this has improved from the coding gain of long-term predictor and has therefore advanced overall code efficiency, and can not produce illusion usually.May need only to the unvoiced frame executing ruleization.For instance, narrowband encoder A124 can be configured to only be offset frame or the subframe that those have long-term structure (for example, voiced sound signal).Even may need only to comprising the subframe executing ruleization of tone pulses energy.The various embodiments of RCELP coding have been described in the 5th, 704, No. 003 United States Patent (USP) people such as () Kleijn and the 6th, 879, No. 955 United States Patent (USP)s (Rao) and No. 2004/0098255 U.S. Patent Application Publication case people such as () Kovesi.The existing embodiment of RCELP scrambler comprises as enhancing variable bit rate coder (EVRC) and third generation partnership relation plan 2 (3GPP2) alternative mode vocoder (SMV) described in the IS-127 of telecommunications industry association (TIA).
Unfortunately, regularization may cause some problems for the wideband speech coding device (system that for example, comprises wideband speech coding device A100 and broadband Voice decoder B100) of wherein deriving high band excitation from encoded narrow-band pumping signal.Because high band excitation signal is with respect to the deflection of time deviation signal, so high band excitation signal will have the timetable different with the timetable of original high frequency band voice signal usually.In other words, high band excitation signal will be no longer synchronous with original high frequency band voice signal.
Temporal misalignment between deviation high band excitation signal and the original high frequency band voice signal may cause some problems.For instance, the deviation high band excitation signal may no longer provide suitable source forcing for the composite filter according to the filter parameter configuration of extracting from original high frequency band voice signal.Therefore, synthetic high-frequency band signals can contain the illusion of hearing that reduces through the perceived quality of decoding broadband voice signal.
Temporal misalignment also may cause the poor efficiency of gain envelope coding.As mentioned above, exist probably between the temporal envelope of narrow-band pumping signal S80 and high-frequency band signals S30 relevant.By gain envelope, compare the raising that can realize code efficiency with direct coding gain envelope according to the coding of the relation between these two temporal envelope high-frequency band signals.Yet, when encoded narrow-band pumping signal regularization, this relevant may weakening.Temporal misalignment between narrow-band pumping signal S80 and the high-frequency band signals S30 can cause occurring fluctuation among the high frequency band gain factor S60b, and code efficiency may reduce.
Embodiment comprises according to the wideband speech coding method of the time deviation that comprises in the corresponding encoded narrow-band pumping signal to high frequency band voice signal execution time deviation.The potential advantage of these class methods comprises improvement through the quality of decoding broadband voice signal and/or the efficient of improvement coding high frequency band gain envelope.
Figure 25 shows the block diagram of the embodiment AD10 of wideband speech coding device A100.Scrambler AD10 comprises the embodiment A124 of narrowband encoder A120, and described embodiment A124 is configured to executing ruleization during calculating encoded narrow-band pumping signal S50.For instance, narrowband encoder A124 can be according to the one or more configurations in the RCELP embodiment discussed above.
Narrowband encoder A124 also is configured to export the regularization data-signal SD10 of the degree of specifying applied time deviation.Be configured to the various situations of set time offset applications for narrowband encoder A124 in each frame or subframe, regularization data-signal SD10 can comprise a series of values, and it is that unit is designated as integer or non integer value with each time offset with sample, millisecond or a certain increment At All Other Times.The time scale that is configured to otherwise to revise frame or other sample sequence for narrowband encoder A124 (for example, by compressing a part and expanding another part) situation, regularization information signal SD10 can comprise the corresponding description of revising, for example one group of function parameter.In a particular instance, narrowband encoder A124 is configured to that frame is divided into three subframes and calculates the set time skew of each subframe, makes regularization data-signal SD10 indicate three time offset of each regularization frame of encoded narrow-band signal.
Wideband speech coding device AD10 comprises lag line D120, and it is configured to advance or block according to the retardation by the input signal indication several portions of high frequency band voice signal S30, thus generation time deviation high frequency band voice signal S30a.In example shown in Figure 25, lag line D120 is configured to according to coming the execution time deviation to high frequency band voice signal S30 by the deviation of regularization data-signal SD10 indication.In this way, the identical time deviation amount that comprises among the encoded narrow-band pumping signal S50 also was applied to the appropriate section of high frequency band voice signal S30 before analyzing.Although this example is shown as the individual component of high band encoder A200 with lag line D120, in other embodiments, lag line D120 is configured to the part of high band encoder.
The other embodiments of high band encoder A200 can be configured to carry out the not spectrum analysis of deviation high frequency band voice signal S30 (for example, lpc analysis), and carry out the time deviation of high frequency band voice signal S30 before calculating high frequency band gain parameter S60b.This scrambler can be including (for example) the embodiment of the lag line D120 that is configured to the execution time deviation.Yet, under this type of situation, spectrum envelope with high band excitation signal S120 misalignment in time can be described based on high band filter parameter S 60a to the not analysis of deviation signal S30.
Lag line D120 can be according to being suitable for that the required time biased operation is applied to the logic element of high frequency band voice signal S30 and any combination of memory element is disposed.For instance, lag line D120 can be configured to read high frequency band voice signal S30 according to required time migration from impact damper.Figure 26 a shows the synoptic diagram of this embodiment D122 of lag line D120, and described lag line D120 comprises shift register SR1.Shift register SR1 is the impact damper with about length m that is configured to receive and store m the most recent sample of high frequency band voice signal S30.Value m equals just (or " propellings ") and the summation of bearing (or " retardance ") time migration of maximum that will support at least.Value m equals the length of the frame of high-frequency band signals S30 or subframe may be more convenient.
Lag line D122 is configured to the deviation post OL output time deviation high-frequency band signals S30a from shift register SR1.The location of deviation post OL is according to being changed near reference position (zero time offset) by the current time skew of for example regularization data-signal SD10 indication.Lag line D122 can be configured to support that the propelling and the retardance that equate limit, and perhaps a restriction limits greater than another, and making can be in one direction than carry out bigger skew on other direction.Figure 26 a shows that the positive time of supporting is offset the particular instance greater than negative time offset.Lag line D122 can be configured to once export one or more samples (for example deciding on the output bus width).
Have regularization time migration greater than several milliseconds value and can cause the illusion of hearing in decoded signal.Usually, the value of the regularization time migration of being carried out by narrowband encoder A124 will be no more than several milliseconds, make time migration by regularization data-signal SD10 indication with limited.Yet, may need lag line D122 to be configured under this type of situation to align and/or negative direction on time migration force maximum constraints (for example, to follow the more strict restriction of restriction of forcing) than narrowband encoder.
Figure 26 b shows the synoptic diagram of the embodiment D124 of lag line D122, and lag line D122 comprises offset window SW.In this example, the location of deviation post OL is limited by offset window SW.Although Figure 26 b shows the situation of buffer length m greater than the width of offset window SW, lag line D124 also can be through implementing to make the width of offset window SW equal m.
In other embodiments, lag line D120 is configured to according to required time skew high frequency band voice signal S30 is written to impact damper.Figure 27 shows the synoptic diagram of the embodiment D130 of lag line D120, and described embodiment D130 comprises two shift register SR2 and the SR3 that is configured to receive and store high frequency band voice signal S30.Lag line D130 is configured to according to for example being written to shift register SR3 from frame or the subframe of shift register SR2 by the time migration of regularization data-signal SD10 indication.Shift register SR3 is configured to fifo buffer, and it is configured to output time deviation high-frequency band signals S30.
In particular instance shown in Figure 27, shift register SR2 comprises frame buffer part FB1 and delay buffer part DB, and shift register SR3 comprises frame buffer part FB2, advances bumper portion AB and retardance bumper portion RB.Advance the length of impact damper AB and retardance impact damper RB to equate, perhaps wherein one can be greater than another person, make skew on the direction of being supported greater than the skew on the other direction of being supported.Delay buffer DB and retardance bumper portion RB can be configured to have equal length.Perhaps, the comparable retardance impact damper of delay buffer DB RB is short to transfer to the shift register SR3 required time interval with sample from frame buffer FB1 to consider, described transfer can comprise other processing operation that for example made sample bias before storing shift register SR3 into earlier.
In the example of Figure 27, frame buffer FB1 is configured to have the length with the equal in length of the frame of high-frequency band signals S30.In another example, frame buffer FB1 is configured to have the length with the equal in length of the subframe of high-frequency band signals S30.In the case, lag line D130 can be configured to comprise and be used for identical (for example, average) delay is applied to the logic of all subframes of frame to be offset.Lag line D130 also can comprise the value and the logic that blocks impact damper RB or advance impact damper AB value to be rewritten to average that is used for from frame buffer FB1.In another example, shift register SR3 can be configured to only receive via frame buffer FB1 the value of high-frequency band signals S30, and in the case, lag line D130 can comprise the logic that is used for carrying out interpolation on the gap between successive frame that is written to shift register SR3 or the subframe.In other embodiments, lag line D130 can be configured to before will being written to shift register SR3 from the sample of frame buffer FB1 described sample be carried out biased operation (for example, according to the function of being described by regularization data-signal SD10).
Lag line D120 may need to use based on but be not equal to time deviation by the deviation of regularization data-signal SD10 appointment.Figure 28 shows the block diagram of the embodiment AD12 of wideband speech coding device AD10, and wideband speech coding device AD10 comprises length of delay mapper D110.Length of delay mapper D110 is configured to the deviation by regularization data-signal SD10 indication is mapped as through mapping length of delay SD10a.Lag line D120 is configured to according to coming generation time deviation high frequency band voice signal S30a by the deviation of indicating through mapping length of delay SD10a.
Can expect that the time migration that narrowband encoder is used makes progress in time smoothly.Therefore, usually computing voice is applied to the average narrow-band time migration of subframe image duration and is offset the respective frame of high frequency band voice signal S30 according to this mean value enough.In this type of example, length of delay mapper D110 is configured to calculate the mean value of the subframe delay value of each frame, and the lag line D120 mean value that is configured to calculate is applied to the respective frame of high-frequency band signals S30.In other example, can calculate and use than the mean value in short period (for example, two subframes, or half frame) or the longer cycle (for example, two frames).Be that length of delay mapper D110 can be configured to before described value is outputed to lag line D120 described value is rounded to the integer number of sample under the situation of non integer value of sample at mean value.
Narrowband encoder A124 can be configured to comprise the regularization time migration of the sample of non-integer number in encoded narrow-band pumping signal.In the case, length of delay mapper D110 may need to be configured to the narrow-band time migration is rounded to the integer number of sample, and lag line D120 may need the time migration through rounding up is applied to high frequency band voice signal S30.
In some embodiments of wideband speech coding device AD10, narrow-band voice signal S20 is different with the sampling rate possibility of high frequency band voice signal S30.Under this type of situation, length of delay mapper D110 can be configured to regulate the time offset of indicating among the regularization data-signal SD10, with the difference between the sampling rate of considering narrow-band voice signal S20 (or narrow-band pumping signal S80) and high frequency band voice signal S30.For instance, length of delay mapper D110 can be configured to the ratio convergent-divergent time offset according to sampling rate.In a particular instance mentioned above, with 8kHz narrow-band voice signal S20 is taken a sample, and high frequency band voice signal S30 is taken a sample with 7kHz.In the case, length of delay mapper D110 is configured to each side-play amount be multiply by 7/8.The embodiment of length of delay mapper D110 also can be configured to carry out this convergent-divergent computing and integer described herein rounds up and/or the time migration average calculating operation.
In other embodiments, lag line D120 is configured to otherwise revise the time scale (for example, by compressing a part and expanding another part) of frame or other sample sequence.For instance, narrowband encoder A124 can be configured to come executing ruleization according to the function of for example tone contour or track.In the case, regularization data-signal SD10 can comprise the corresponding description (for example one group of parameter) to described function, and lag line D120 can comprise the logic that is configured to according to described function the frame of high frequency band voice signal S30 or subframe be carried out deviation.In other embodiments, length of delay mapper D110 be configured to before described function is applied to high frequency band voice signal S30 by lag line D120 to described function average, convergent-divergent and/or round up.For instance, length of delay mapper D110 can be configured to according to one or more length of delays of described function calculation, each length of delay indication number of samples, it is then used with one or more respective frame or subframe execution time deviation to high frequency band voice signal S30 by lag line D120.
Figure 29 shows according to the process flow diagram of the time deviation that comprises in the corresponding encoded narrow-band pumping signal to the method MD100 of high frequency band voice signal execution time deviation.Task TD100 handles the broadband voice signal to obtain narrow-band voice signal and high frequency band voice signal.For instance, task TD100 can be configured to use the bank of filters (for example embodiment of bank of filters A110) with low-pass filter and Hi-pass filter that the broadband voice signal is carried out filtering.Task TD200 is encoded to encoded narrow-band pumping signal and a plurality of narrow band filter parameter at least with the narrow-band voice signal.Described encoded narrow-band pumping signal and/or filter parameter can quantize, and encoded narrow-band pumping signal also can comprise for example other parameter of speech pattern parameter.Task TD200 also comprises the time deviation in the encoded narrow-band pumping signal.
Task TD300 produces high band excitation signal based on the narrow-band pumping signal.In the case, the narrow-band pumping signal is based on encoded narrow-band pumping signal.Task TD400 is encoded to a plurality of high band filter parameters according to described at least high band excitation signal at least with the high frequency band voice signal.For instance, can be configured to the high frequency band speech signal coding be a plurality of quantification LSF to task TD400.Task TD500 is applied to the high frequency band voice signal with time migration, described time migration based on encoded narrow-band pumping signal in the relevant information of time deviation that comprises.
Task TD400 can be configured to the high frequency band voice signal is carried out spectrum analysis (for example, lpc analysis), and/or calculate the gain envelope of high frequency band voice signal.Under this type of situation, task TD500 can be configured to before described analysis and/or the calculating of gain envelope time migration is applied to the high frequency band voice signal.
Other embodiment of wideband speech coding device A100 is configured to the time deviation counter-rotating of the high band excitation signal S120 that will be caused by the time deviation that comprises in the encoded narrow-band pumping signal.For instance, high band excitation generator A300 can be through implementing to comprise the embodiment of lag line D120, the described embodiment of lag line D120 is configured to receive regularization data-signal SD10 or through mapping length of delay SD10a, and with corresponding reversing time offset applications in narrow-band pumping signal S80, and/or be applied to signal subsequently (for example, harmonic wave extends signal S160 or high band excitation signal S120) based on described narrow-band pumping signal S80.
Other wideband speech coding device embodiment can be configured to independently of one another narrow-band voice signal S20 and high frequency band voice signal S30 be encoded, and makes high frequency band voice signal S30 be encoded as the representation of high frequency band spectrum envelope and high band excitation signal.This embodiment can be configured to according to the information relevant with the time deviation that comprises in the encoded narrow-band pumping signal high frequency band residual signal execution time deviation, or otherwise time deviation is included in the encoded high band excitation signal.For instance, high band encoder can comprise the embodiment that is configured to time deviation is applied to the lag line D120 and/or the length of delay mapper D110 of high frequency band residual signal described herein.The potential advantage of this operation comprise to the high frequency band residual signal than efficient coding, and the better coupling between synthesis of narrow frequency band and the high frequency band voice signal.
As mentioned above, embodiment described herein comprises and can be used for carrying out the compatible of embedded encoded embodiment, support and narrow band system and needing to avoid code conversion.Support to the high frequency band coding also can be used on cost distinguishing chip, chipset, device and/or the network with the broadband support that has back compatible and only has chip, chipset, device and/or the network that narrow-band is supported.As described herein to the support of high frequency band coding also can be used to support the technology of low-frequency band coding be used in combination, and according to system, method or the equipment of this embodiment can support to for example about 50 or 100Hz until about 7 or the coding of the frequency component of 8kHz.
As mentioned above, add the high frequency band support to speech coder and can improve sharpness, especially about the sharpness of fricative differentiation.Although this differentiation may be derived out according to specific context usually by human listener, the high frequency band support can be served as the feature of enabling of speech recognition and other machine decipher application (system that for example is used for automated voice menu navigation and/or automatic call treatment).
Equipment according to an embodiment can be embedded in the portable radio communication device (for example, cellular phone or PDA(Personal Digital Assistant)).Perhaps, this equipment can be included in another communicator, for example the VoIP mobile phone, be configured to support the personal computer of VoIP communication or be configured to routing telephone or the network equipment of VoIP communication.For instance, the equipment according to an embodiment may be implemented in the chip or chipset of communicator.Decide on application-specific, this device also can comprise for example following feature: analog to digital and/or digital-to-analog to voice signal are changed, are used for voice signal is carried out the circuit of amplification and/or other signal processing operations, and/or are used to launch and/or receive the radio circuit of encoded voice signal.
Clearly expection and announcement embodiment can comprise the 60/667th, No. 901 and the 60/673rd, in the further feature that discloses in No. 965 U.S. Provisional Patent Application cases any one or one above and/or therewith use advocated the rights and interests of described temporary patent application case in the application's case.This category feature comprises removal and betides in the high frequency band and the non-existent substantially high-energy burst with short duration in narrow-band.This category feature comprises for example fixing or adaptive smooth of the coefficient representation of high frequency band LSF.Fixing or the self-adaptation that this category feature comprises the noise that is associated with the quantification of the coefficient representation of for example LSF is shaped.This category feature also comprises the fixing or adaptive smooth of gain envelope, and the adaptive attenuation of gain envelope.
Provide above introduction to description embodiment so that make the those skilled in the art can make or use the present invention.May make various modifications to these embodiment, and General Principle provided herein also can be applicable to other embodiment.For instance, but be embodied as to embodiment a part or whole part hard-wired circuit, be embodied as the circuit arrangement that is fabricated onto in the special IC, perhaps be embodied as machine readable code and be loaded into the firmware program in the Nonvolatile memory devices or load or be loaded into software program the data storage medium from data storage medium, described code be can be by the instruction of the array of logic elements execution of for example microprocessor or other digital signal processing unit.Data storage medium can be memory element array, for example semiconductor memory (its can comprise (being not limited to) dynamically or static RAM (SRAM) (random access memory), ROM (ROM (read-only memory)) and/or quickflashing RAM), or ferroelectric, magnetic resistance, two-way switch semiconductor, polymkeric substance or phase transition storage; The perhaps disc type medium of disk or CD for example.Any one or instruction group or sequence more than one that term " software " is interpreted as comprising source code, assembly language code, machine code, binary code, firmware, macrocode, microcode, can be carried out by array of logic elements, and any combination of this type of example.
The various elements of the embodiment of high band excitation generator A300 and B300, high band encoder A100, high band decoder B200, wideband speech coding device A100 and broadband Voice decoder B100 can be embodied as (for example) and reside on the same chip in the chipset or electronics and/or optical devices between two or more chips, but also there is other configuration that does not have this restriction in expection.One or more elements of this equipment can be embodied as one or more instruction groups in whole or in part, described instruction group be configured to one or more fix or programmable logic element (for example, transistor, door) to carry out on the array, described element for example is microprocessor, embedded processor, the IP kernel heart, digital signal processor, FPGA (field programmable gate array), ASSP (Application Specific Standard Product) and ASIC (special IC).One or more these class components also (for example may have common structure, be used in the different time execution corresponding to the processor of the code section of different elements, through carrying out) to carry out instruction group at different time, perhaps in the configuration of different time at the electronics and/or the optical devices of different elements executable operations corresponding to the task of different elements.In addition, one or more these class components may be used to carry out task or other the instruction group not directly related with the operation of equipment, for example relevant with another operation of device that is embedded with described equipment or system task.
Figure 30 shows the process flow diagram that the described highband part of voice signal with narrow-band part and highband part is carried out Methods for Coding M100 according to an embodiment.Task X100 calculates one group of filter parameter of the feature of the spectrum envelope of representing highband part.Task X200 extends signal by nonlinear function being applied to calculate frequency spectrum from the signal that narrow-band partly derives.Task X300 produces synthetic high-frequency band signals according to (A) the described group of filter parameter and the high band excitation signal of (B) extending signal based on described frequency spectrum.Task X400 comes the calculated gains envelope based on the relation between the energy of the energy of (C) highband part and the signal of (D) partly deriving from narrow-band.
Figure 31 a shows the process flow diagram that produces the method M200 of high band excitation signal according to an embodiment.Task Y100 extends signal by nonlinear function being applied to calculate through harmonic wave from the narrow-band pumping signal that the narrow-band of voice signal partly derives.Task Y200 will extend signal and mix through the zoop signal to produce high band excitation signal through harmonic wave.Figure 31 b shows the process flow diagram that produces the method M210 of high band excitation signal according to another embodiment that comprises task Y300 and Y400.Task Y300 calculates temporal envelope according to the narrow-band pumping signal with through the energy in time that harmonic wave extends one in the signal.Task Y400 according to temporal envelope zoop signal to produce through the zoop signal.
Figure 32 shows the process flow diagram of the method M300 that the described highband part of voice signal with narrow-band part and highband part is decoded according to an embodiment.Task Z100 receives one group of gain factor of feature of the temporal envelope of one group of filter parameter of feature of spectrum envelope of the described highband part of expression and the described highband part of expression.Task Z200 extends signal by nonlinear function being applied to calculate frequency spectrum from the signal that narrow-band partly derives.Task Z300 produces synthetic high-frequency band signals according to (A) the described group of filter parameter and the high band excitation signal of (B) extending signal based on described frequency spectrum.Task Z400 modulates the gain envelope of described synthetic high-frequency band signals based on described group of gain factor.For instance, task Z400 can be configured to by the pumping signal that described group of gain factor is applied to partly derive from narrow-band, be applied to frequency spectrum extends signal, is applied to high band excitation signal, or be applied to synthetic high-frequency band signals, modulate the gain envelope of described synthetic high-frequency band signals.
Embodiment also comprises as herein (for example) by additional voice decoding as described in the description of the structure embodiment that is configured to carry out additional voice decoding, Code And Decode method is clearly disclosed, Code And Decode method.Each of these methods also (for example can positively be implemented, in one or more data storage mediums of enumerating as mentioned) one or more instruction groups for reading and/or carry out by the machine that comprises logic element (for example, processor, microprocessor, microcontroller or other finite state machine) array.Therefore, the present invention is without wishing to be held to the embodiment that above shows, but should meet with herein the principle and the consistent widest range of novel feature of (comprising in the appended claims of a part of the original disclosure of being submitted to of formation) announcement by any way.

Claims (33)

1. equipment, it comprises:
First speech coder, its low-frequency band voice signal that is configured to encode;
Second speech coder, its high frequency band voice signal that is configured to encode; And
Bank of filters, it has (A) low-frequency band and handles the path, described low-frequency band handle the path be configured to receive have be at least 1000 and 6000Hz between frequency content the broadband voice signal and produce described low-frequency band voice signal and (B) high frequency band handle the path, described high frequency band is handled the path and is configured to receive described broadband voice signal and produces described high frequency band voice signal
Wherein said low-frequency band voice signal is based on the first of the frequency content of described broadband signal, described first comprise described broadband signal be in 1000 and 2000Hz between part, and
Wherein said high frequency band voice signal is based on the second portion of the frequency content of described broadband signal, described second portion comprise described broadband signal be in 5000 and 6000Hz between part, and
Each third part of wherein said low-frequency band voice signal and described high frequency band voice signal, described third part based on the frequency content of described broadband signal comprise described broadband signal be in 2000 and 5000Hz between have a part of the width of 250Hz at least.
2. equipment according to claim 1, the first of wherein said broadband signal comprise described broadband signal be in 1000 and 3000Hz between part, and
The second portion of wherein said broadband signal comprise described broadband signal be in 4000 and 6000Hz between part, and
Wherein said third part comprise described broadband signal be in 3000 and 4000Hz between have a part of the width of 250Hz at least.
3. equipment according to claim 2, wherein said third part have the width of 400Hz at least.
4. equipment according to claim 2, wherein said low-frequency band voice signal comprises the frequency content of described first and the frequency content of described third part, and
Wherein said high frequency band voice signal comprises the frequency content of described second portion and the frequency content of described third part.
5. equipment according to claim 1, wherein said low-frequency band voice signal has different sampling rates with described high frequency band voice signal.
6. equipment according to claim 1, the summation of the sampling rate of wherein said low-frequency band voice signal and described high frequency band voice signal is not more than the sampling rate of described broadband signal.
7. equipment according to claim 1, described equipment comprises cellular phone.
8. it is at least one encoded low band excitation signal and a plurality of low band filter parameter that equipment according to claim 1, wherein said first speech coder are configured to described low-frequency band speech signal coding, and
Wherein said second speech coder is configured to produce high band excitation signal based on described encoded low band excitation signal, and according to described high band excitation signal described high-frequency band signals is encoded to a plurality of at least high band filter parameters.
9. equipment according to claim 8, wherein said second speech coder are configured to described high-frequency band signals is encoded to a plurality of at least high band filter parameters and a plurality of gain factor.
10. equipment according to claim 8, described equipment comprises the device that is configured to launch a plurality of bags consistent with the version of Internet Protocol, and wherein said a plurality of bags are described described encoded low band excitation signal, described a plurality of low band filter parameters and described a plurality of high band filter parameter.
11. an equipment, it comprises:
Bank of filters, it has (A) low-frequency band and handles the path, described low-frequency band handle the path be configured to receive the broadband voice signal and based on the low frequency of described broadband voice signal partly produce the low-frequency band voice signal and (B) high frequency band handle the path, described high frequency band is handled the path and is configured to receive described broadband voice signal and partly produces the high frequency band voice signal based on the high-frequency of described broadband voice signal, and it is overlapping with the passband in described high frequency band processing path that wherein said low-frequency band is handled the passband in path;
First speech coder, it is configured to described low-frequency band speech signal coding is at least one encoded low band excitation signal and a plurality of low band filter parameter; And
Second speech coder, it is configured to produce high band excitation signal based on described encoded low band excitation signal, and according to described high band excitation signal described high-frequency band signals is encoded to a plurality of at least high band filter parameters.
12. equipment according to claim 11, wherein said second speech coder are configured to extend signal and produce described high band excitation signal to produce frequency spectrum based on the signal of described encoded low band excitation signal by nonlinear function is applied to, and
Wherein said high band excitation signal is extended signal based on described frequency spectrum.
The gain envelope of described high-frequency band signals 13. equipment according to claim 11, wherein said second speech coder are configured to encode.
14. equipment according to claim 13, wherein said second speech coder are configured to produce synthetic high-frequency band signals according to described high band excitation signal and described a plurality of high band filter parameter, and
Wherein said second speech coder is configured to based on the described synthetic high-frequency band signals described gain envelope of encoding.
15. equipment according to claim 14, wherein said second scrambler are configured to based on the described gain envelope of encoding of the relation between described high-frequency band signals and the described synthetic high-frequency band signals.
16. equipment according to claim 11, wherein said low-frequency band are handled the passband and the described high frequency band in path and are handled the overlapping 200Hz at least of passband in path.
17. equipment according to claim 11, wherein said low-frequency band are handled the passband and the described high frequency band in path and are handled the overlapping about 500Hz of passband in path.
18. equipment according to claim 11, wherein said low-frequency band are handled the passband in path and the passband overlapping about 400 to about 600Hz that described high frequency band is handled the path.
19. equipment according to claim 11, wherein said low-frequency band are handled the passband in path and the passband overlapping about 400 to about 1000Hz that described high frequency band is handled the path.
20. equipment according to claim 11, wherein said overlapping about 2000 at least a portion that comprise to the frequency range of about 5000Hz.
21. equipment according to claim 11, wherein said overlapping about 3000 at least a portion that comprise to the frequency range of about 4000Hz.
22. equipment according to claim 11, wherein said low-frequency band voice signal has different sampling rates with described high frequency band voice signal.
23. equipment according to claim 11, the summation of the sampling rate of wherein said low-frequency band voice signal and described high frequency band voice signal is not more than the sampling rate of described broadband signal.
24. equipment according to claim 11, described equipment comprises cellular phone.
25. equipment according to claim 11, described equipment comprises the device that is configured to launch a plurality of bags consistent with the version of Internet Protocol, and wherein said a plurality of bags are described described encoded low band excitation signal, described a plurality of low band filter parameters and described a plurality of high band filter parameter.
26. a signal processing method, described method comprises:
Based on have be at least 1000 and 6000Hz between the broadband voice signal of frequency content produce the low-frequency band voice signal;
The described low-frequency band voice signal of encoding;
Produce the high frequency band voice signal based on described broadband voice signal; And
The described high frequency band voice signal of encoding;
Wherein said generation low-frequency band voice signal comprises based on produce described low-frequency band voice signal with the lower part: (A) first of the frequency content of described broadband signal, described first comprise described broadband signal be in 1000 and 2000Hz between part, (B) third part of the frequency content of described broadband signal, described third part comprise described broadband signal be in 2000 and 5000Hz between have a part of the width of 250Hz at least, and
Wherein producing the high frequency band voice signal comprises based on produce described high frequency band voice signal with the lower part: (C) second portion of the frequency content of described broadband signal, described second portion comprise described broadband signal be in 5000 and 6000Hz between the part and (D) third part of the frequency content of described broadband signal.
27. method according to claim 26, the first of wherein said broadband signal comprise described broadband signal be in 1000 and 3000Hz between part, and
The second portion of wherein said broadband signal comprise described broadband signal be in 4000 and 6000Hz between part, and
Wherein said third part comprise described broadband signal be in 3000 and 4000Hz between have a part of the width of 250Hz at least.
28. method according to claim 26, wherein said third part have the width of 400Hz at least.
29. method according to claim 26, wherein said low-frequency band voice signal comprises the frequency content of described first and the frequency content of described third part, and
Wherein said high frequency band voice signal comprises the frequency content of described second portion and the frequency content of described third part.
30. method according to claim 26, wherein said low-frequency band voice signal has different sampling rates with described high frequency band voice signal.
31. method according to claim 26, the summation of the sampling rate of wherein said low-frequency band voice signal and described high frequency band voice signal is not more than the sampling rate of described broadband signal.
It is at least one encoded low band excitation signal and a plurality of low band filter parameter that 32. method according to claim 26, wherein said first speech coder are configured to described low-frequency band speech signal coding, and
Wherein said second speech coder is configured to produce high band excitation signal based on described encoded low band excitation signal, and according to described high band excitation signal described high-frequency band signals is encoded to a plurality of at least high band filter parameters.
33. method according to claim 26, wherein said second speech coder are configured to described high-frequency band signals is encoded to a plurality of at least high band filter parameters and a plurality of gain factor.
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