The present invention relates to an encoding technique for audio signals and, in particular, to an encoding technique to encode a sequence obtained by dividing a sample string derived from an audio signal by gain.
Adaptive encoding that encodes orthogonal coefficients such as DFT (Discrete Fourier Transform) and MDCT (Modified Discrete Cosine Transform) coefficients is known as a method for encoding speech signals and audio signals at low bit rates (for example about 10 to 20 Kbits/s). For example, AMR-WB+ (Extended Adaptive Multi-Rate Wideband), which is a standard technique, has the TCX (transform coded excitation) encoding mode. In the TCX encoding, gain is determined for a coefficient string obtained by normalizing an audio digital signal sequence in the frequency domain with a power spectrum envelope coefficient string so that a sequence obtained by dividing each of the coefficient in the coefficient string by the gain can be encoded with a predetermined number of bits.
<TCX Encoder 1000>
<Frequency-Domain Transformer 1001>
A frequency-domain transformer 1001 transforms an input audio digital signal to an MDCT coefficient string X(1), . . . , X(N) at N points in the frequency domain on a frame-by-frame basis in a given time period and outputs the MDCT coefficient string. Here, N is a positive integer.
<Power-Spectrum-Envelope-Coefficient-String Arithmetic Unit 1002>
A power-spectrum-envelope-coefficient-string arithmetic unit 1002 performs linear prediction analysis of an audio digital signal in each frame to obtain liner predictive coefficients and uses the linear predictive coefficients to obtain and output a power spectrum envelope coefficient string W(1), . . . , W(N) of the audio digital signal at N points.
<Weighted Envelope Normalizer 1003>
A weighted envelope normalizer 1003 uses a power spectrum envelope coefficient string obtained by the power-spectrum-envelope-coefficient-string arithmetic unit 1002 to normalize each of the coefficients in an MDCT coefficient string obtained by the frequency-domain transformer 1001 and outputs a weighted normalized MDCT coefficient string XN(1), . . . , XN(N). Here, in order to achieve quantization that auditorily minimizes distortion, the weighted envelope normalizer 1003 uses a weighted power spectrum envelope coefficient string obtained by moderating a power spectrum envelope to normalize the coefficients in the MDCT coefficient strings on a frame-by-frame basis. As a result, the weighted normalized MDCT coefficient string XN(1), . . . , XN(N) does not have a steep slope of amplitude or large variations in amplitude as compared with the input MDCT coefficient string but has variations in magnitude similar to those of the power spectrum envelope coefficient string of the audio digital signal. That is, the weighted normalized MDCT coefficient string has somewhat greater amplitudes in a region of coefficients corresponding to low frequencies and has a fine structure due to a pitch period.
<Initializer 1004>
An initializer 1004 sets an initial value of gain (global gain) g. The initial value of the gain can be determined from the energy of a weighted normalized MDCT coefficient string XN(1), . . . , XN(N) and the number of bits allocated beforehand to an encode output from a variable-length encoder 1006, for example. The number of bits allocated beforehand to a code output from the variable-length encoder 1006 is hereinafter referred to as the number B of allocated bits. The initializer also sets 0 as the initial value of the number of updates of gain.
<Gain Update Loop Processor 1130>
A gain update loop processor 1130 determines gain such that a sequence obtained by dividing each coefficient in a weighted normalized MDCT coefficient string XN(1), . . . , XN(N) by the gain can be encoded with a predetermined number of bits, and outputs an integer signal code obtained by variable length encoding of the sequence obtained by dividing each coefficient in the weighted normalized MDCT coefficient string XN(1), . . . , XN(N) by the determined gain and a gain code obtained by encoding the determined gain.
The update loop processor 1130 includes a quantizer 1005, the variable-length encoder 1006, a determiner 1007, a gain expansion updater 1131, a gain reduction updater 1132, a truncation unit 1016, and a gain encoder 1017.
<Quantizer 1005>
The quantizer 1005 quantizes a value obtained by dividing each coefficient in a weighted normalized MDCT coefficient string XN(1), . . . , XN(N) by gain g to obtain and output a quantized normalized coefficient sequence XQ(1), . . . , XQ(N), which is a sequence of integer values.
<Variable-Length Encoder 1006>
The variable-length encoder 1006 encodes a quantized normalized coefficient sequence XQ(1), . . . , XQ(N) to obtain and output a code. The code is referred to as integer signal code. The variable-length encoding may use a method that encodes a plurality of coefficients in a quantized normalized coefficient string at a time, for example. In addition, the variable-length encoder 1006 measures the number of bits in the integer signal code obtained by the variable-length encoding. The number of bits is hereinafter referred to as the number c of consumed bits.
<Determiner 1007>
The determiner 1007 outputs gain, integer signal code, and the number c of consumed bits when the number of updates of gain is equal to a predetermined number.
When the number of updates of gain is less than the predetermined number, the determiner 1007 performs control to cause a gain expansion updater 1131 to perform a next process if the number c of consumed bits measured by the variable-length encoder 1006 is greater than the number B of allocated bits, or to cause a gain reduction updater 1132 to perform a next process if the number c of consumed bits measured by the variable-length encoder 1006 is smaller than the number B of allocated bits. Note that if the number c of consumed bits is equal to the number B of allocated bits, it means that the current value of gain is optimum and therefore the determiner 1007 outputs the gain, the integer signal code and the number c of consumed bits.
<Gain Expansion Updater 1131>
The gain expansion updater 1131 sets a value greater than the current value of gain g as new gain g′>g. The gain expansion updater 1131 includes a lower limit gain setter 1008, a first branch controller 1009, a first gain updater 1010, and a gain expander 1011.
<Lower Limit Gain Setter 1008>
The lower limit gain setter 1008 sets the current value of gain g as the lower limit gain gmin (gmin←g). The lower limit gain gmin means the lowest value of gain allowed.
<First Branch Controller 1009>
When the lower limit gain gmin is set by the lower limit gain setter 1008, the first branch controller 1009 performs control to cause the first gain updater 1010 to perform a next process if an upper limit gain value gmax has been already set or to cause the gain expander 1011 to perform a next process if the upper limit gain gmax has not been set.
<First Gain Updater 1010>
The first gain updater 1010 sets the average of the current value of gain g and the upper limit gain gmax as a new value of gain g (g←(g+gmax)/2). This is because an optimum value of gain is between the current value of gain g and the upper limit gain gmax. Since the current value of gain g has been set as the lower limit gain gmin, it can be said that the average of the upper limit gain gmax and the lower limit gain gmin is set as a new value of gain g (g←(gmax+gmin)/2). Then the control returns to the process in the quantizer 1005.
<Gain Expander 1011>
The gain expander 1011 sets a value greater than the current value of gain g as a new value of gain g. For example, the gain expander 1011 sets a value that is equal to the current value of gain g plus a gain change amount Δg, which is a predetermined value, as a new value of gain g (g←g+Δg). If the upper limit gain gmax has not been set and the number c of consumed bits has been greater than the number B of allocated bits successive times, for example, a value greater than the predetermined value is used as the gain change amount Δg. Then the control returns to the process in the quantizer 1005.
<Gain Reduction Updater 1132>
The gain reduction updater 1132 sets a value smaller than the current value of gain g as a new gain g′<g. The gain reduction updater 1132 includes an upper limit gain setter 1012, a second branch controller 1013, a second gain updater 1014, and a gain reducer 1015.
<Upper Limit Gain Setter 1012>
The upper limit gain setter 1012 sets the current value of gain g as the upper limit gain gmax (gmax←g). The upper limit gain gmax means the highest gain allowed.
<Second Branch Controller 1013>
When the upper limit gain gmax is set by the upper limit gain setter 1012, the second branch controller 1013 performs control to cause the second gain updater 1014 to perform a next process if the lower limit gain gmin has already been set or to cause the gain reducer 1015 to perform a next process if the lower limit gain gmin has not yet been set.
<Second Gain Updater 1014>
The second gain updater 1014 sets the average of the current the current value of gain g and the lower limit gain gmin as a new value of gain g (g←(g+gmin)/2). This is because an optimum gain value is between the current value of gain g and the lower limit gain gmin. Since the current value of gain g has been set as the upper limit gain gmax, it can be said that the average of the upper limit gain gmax and the lower limit gain gmin is set as a new value of gain g (g←(gmax+gmin)/2). Then the control returns to the process in the quantizer 1005.
<Gain Reducer 1015>
The gain reducer 1015 sets a value smaller than the current value of gain g as a new value of gain g. For example, the gain reducer 1015 sets a value equal to the current value of gain g minus a gain change amount Δg, which is a predetermined value, as a new value of gain g (g←g−Δg). If the lower limit gain gmin has not been set and the number c of consumed bits has been smaller than the number B of allocated bits successive times, for example, a value greater than the predetermined value is used as the gain change amount Δg. Then the control returns to the process in the quantizer 1005.
<Truncation Unit 1016>
When the number c of consumed bits output from the determiner 1007 is greater than the number B of allocated bits, the truncation unit 1016 removes an amount of code equivalent to bits by which the number c of consumed bits exceeds the number B of allocated bits from the code corresponding to quantized normalized coefficients at the high frequency side in an integer signal code output from the determiner 1007 and outputs the resulting code as a new integer signal code. That is, the truncation unit 1016 removes the amount of code equivalent to the number of bits c−B by which the number c of consumed bits exceeds the number B of allocated bits that corresponds to quantized normalized coefficients at the high frequency side from the integer signal code and outputs the remaining code as a new integer signal code.
<Gain Encoder 1017>
The gain encoder 1017 encodes gain output from the determiner 1007 with a predetermined number of bits to obtain and output a gain code.
The gain expander 1011 of the conventional encoder 1000 sets a value of gain g plus a gain change amount Δg, which is a predetermined value, as a new value of gain g to expand the value of gain at a constant rate.
If the upper limit gain is not set and the process in the gain expander 1011 needs to be repeated a number of times, the initial value of gain may be far too small. Therefore the gain change amount Δg needs to be increased above the predetermined value to increase the probability of the upper limit gain being reached. As a result, however, a value that is significantly greater than an optimum gain can possibly be set as a new value of gain, the process may need to be repeated many times to achieve convergence, and a specified number of time may be reached before an appropriate value of gain can be obtained.
Similarly, the gain reducer 1015 of the conventional encoder 1000 sets a value of gain g minus a gain change amount Δg, which is a predetermined value, as a new value of gain g to reduce the value of gain at a constant rate.
If the upper limit gain is not set and the process in the gain reducer 1015 needs to be repeated a number of times, the initial value of gain may be far too large. Therefore the gain change amount Δg needs to be increased above the predetermined value to increase the probability of the upper limit gain being reached. As a result, however, a value that significantly greater than an optimum gain can possibly be set as a new value of gain, the process may need to be repeated many times to achieve convergence, and a specified number of time may be reached before an appropriate value of gain can be obtained.
If a value obtained when the specified number of times is reached is too small, the number of bits in a code obtained by variable-length encoding is greater than the number of allocated bits and therefore only part of the code obtained by variable-length encoding can be output as an integer signal code and code corresponding to quantized normalized coefficients in a high-frequency band are not output from the encoder and are not provided to the decoder. Consequently, the decoder has to use 0 as coefficients in the high-frequency band to obtain a decoded signal, which can lead to a large distortion of the decoded signal. If the value of gain obtained when the specified number of times is reached is too large, the number of bits in the integer signal code is smaller than the number of allocated bits and therefore sufficiently good audio signal quality cannot be achieved.
A value of gain is updated so that the greater the difference between the number of bits or estimated number of bits in a code obtained by encoding a string of integer value samples obtained by dividing each sample in a sample string derived from an input audio signal in a given interval by gain before the update and a predetermined number B of allocated bits, the greater the difference between the gain before the update and the updated gain. A gain code corresponding to the updated gain and an integer signal code obtained by encoding a string of integer value samples that can be obtained by dividing each sample in the sample string by the gain are obtained.
Encoding according to the present invention facilitates convergence of gain to an optimum value. Accordingly, the number of bits in a code obtained by variable-length encoding can be made closer to the number of allocated bits than possible with the conventional technique and encoding of higher quality can be achieved than the quality that can be achieved with the conventional technique.
Embodiments of the present invention will be described with reference to drawings. Same components or processes are assigned same reference numerals and repeated description of those components and processes may be omitted. Note that audio digital signals (input audio signals) handled in the embodiments are signals produced by digitizing audio signals such as speech or music. It is assumed in the embodiments that an input audio digital signal is a time-domain signal in a given time period, the audio digital signal is transformed to a frequency-domain signal and a string obtained by normalizing the frequency-domain signal using a power spectrum envelope coefficient string is a sample string to be encoded (a sample string derived from the input audio signal). However, an input audio digital signal may be a time-domain signal in a given time period and the audio digital signal may be a sample string to be encoded, or a residual signal obtained by linear prediction analysis of the audio digital signal may be a sample string to be encoded, or a frequency-domain signal transformed from the audio digital signal may be a sample string to be encoded. Alternatively, an input audio digital signal may be a frequency-domain signal in a given interval (a frequency-domain signal corresponding to a given time period or a frequency-domain signal in a given frequency interval of the frequency domain signal) and the audio digital signal may be a sample string to be encoded, or a time-domain signal transformed from the audio digital signal may be a sample string to be encoded, or a residual signal obtained by linear prediction analysis of the time-domain signal may be a sample string to be encoded. That is, an input audio digital signal may be a time-domain signal or a frequency-domain signal and a sample string to be encoded may be a time-domain signal or a frequency-domain signal. Furthermore, any method of transforming a time-domain signal to a frequency-domain signal may be used and any method of transforming a frequency-domain signal to a time-domain signal may be used. For example, MDCT (Modified Discrete Cosine Transform) or DCT (Discrete Cosine Transform) or inverse transform of any of these may be used.
Based on the assumption described above, embodiments will be described with examples in which an encoder includes a frequency-domain transformer, a power-spectrum-envelope-coefficient-string arithmetic unit, and a weighted envelope normalizer and a sample string obtained in the weighted envelope normalizer is input in a quantizer. However, if an input audio digital signal itself is a sample string to be encoded, the frequency-domain transformer, the power-spectrum-envelope-coefficient-string arithmetic unit and the weighted envelope normalizer may be omitted and the sample string of the audio digital string may be directly input in the quantizer. If a residual signal obtained by linear prediction analysis of an audio digital signal that is an input time-domain signal is a sample string to be encoded, the encoder may include a linear prediction unit that takes an input of an audio digital signal and obtains linear predicative coefficients or coefficients that can be transformed to linear predictive coefficients and a residual arithmetic unit that obtains predictive residuals from a linear predication filter for the linear predictive coefficients and an audio digital signal in place of the frequency-domain transformer, the power-spectrum-envelope-coefficient-string arithmetic unit and the weighted envelope normalizer, and the a sample string of the residual signal may be input into the quantizer. If a frequency-domain signal transformed from an audio digital signal that is an input time-domain signal is a sample string to be encoded, the power-spectrum-envelope-coefficient-string arithmetic unit and the weighted envelope normalizer may be omitted and a sample string of a frequency-domain signal obtained in the frequency-domain transformer may be input into the quantizer. If a time-domain signal transformed from an audio digital signal that is an input frequency-domain signal is a sample string to be encoded, the encoder may include a time-domain transformer that transforms an audio digital signal to a time-domain signal in place of the frequency-domain transformer, the power-spectrum-envelope-coefficient-string arithmetic unit and the weighted envelope normalizer and a sample string of the time-domain signal may be input into the quantizer. If a residual signal obtained by linear prediction analysis of a time-domain signal transformed from an audio digital signal that is an input frequency-domain signal is a sample string to be encoded, the encoder may include a time-domain transformer, a linear prediction unit and a residual arithmetic unit in place of the frequency-domain transformer, the power-spectrum-envelope-coefficient-string arithmetic unit and the weighted envelope normalizer and a sample string of the residual signal obtained in the residual arithmetic unit may be input into the quantizer.
[First Embodiment]
<Encoder 100>
Referring to
<Frequency-Domain Transformer 101>
A frequency-domain transformer 101 transforms an input audio digital signal (input audio signal) to an MDCT coefficient string X(1), . . . , X(N) at N points in the frequency domain on a frame-by-frame basis in a given time period and outputs the MDCT coefficient string X(1), . . . , X(N), where N is a positive integer.
<Power-Spectrum-Envelope-Coefficient-String Arithmetic Unit 102>
A power-spectrum-envelope-coefficient-string arithmetic unit 102 performs frame-by-frame linear prediction analysis of an audio digital signal to obtain linear predictive coefficients, uses the linear predictive coefficients to obtain a power spectrum envelope coefficient string W(1), . . . , W(N) of the audio digital signal at N points and outputs the power spectrum envelope coefficient string W(1), . . . , W(N).
<Weighted Envelope Normalizer 103>
A weighted envelope normalizer 103 uses a power spectrum envelope coefficient string obtained by the power-spectrum-envelope-coefficient-string arithmetic unit 102 to normalize each of the coefficients in an MDCT coefficient string obtained by the frequency-domain transformer 101 and outputs a weighted normalized MDCT coefficient string XN(1), . . . , XN(N). Here, in order to achieve quantization that auditorily minimizes distortion, the weighted envelope normalizer 103 uses a weighted power spectrum envelope coefficient string obtained by moderating power spectrum envelope to normalize the coefficients in the MDCT coefficient string on a frame-by-frame basis. As a result, the weighted normalized MDCT coefficient string XN(1), . . . , XN(N) does not have a steep slope of amplitude or large variations in amplitude as compared with the input MDCT coefficient string but has variations in magnitude similar to those of the power spectrum envelope coefficient string of the audio digital signal, that is, the weighted normalized MDCT coefficient string has somewhat greater amplitudes in a region of coefficients corresponding to low frequencies and has a fine structure due to a pitch period.
[Examples of Weighted Envelope Normalization Process]
Coefficients W(1), . . . , W(N) of a power spectrum envelope coefficient string that correspond to the coefficients X(1), . . . , X(N) of an MDCT coefficient string at N points can be obtained by transforming linear predictive coefficients to a frequency domain. For example, according to a p-order autoregressive process (where p is a positive integer), which is an all-pole model, a time signal x(t) at a time t can be expressed by formula (1) with past values x(t−1), . . . , x(t−p) of the time signal itself at the past p time points, predictive residuals e(t) and linear predictive coefficients α1, . . . , αp. Then, the coefficients W(n) [1≦n≦N] of the power spectrum envelope coefficient string can be expressed by formula (2), where exp(•) is an exponential function with a base of Napier's constant, j is an imaginary unit, and σ2 is predictive residual energy.
The linear predictive coefficients may be obtained by liner predictive analysis by the weighted envelope normalizer 103 of an audio digital signal input in the frequency-domain transformer 101 or may be obtained by linear predictive analysis of an sound digital signal by other means, not depicted, in the encoder 100. In that case, the weighted envelope normalizer 103 obtains the coefficients W(1), . . . , W(N) in the power spectrum envelope coefficient string by using a linear predictive coefficient. If the coefficients W(1), . . . , W(N) in the power spectrum envelope coefficient string have been already obtained with other means (such as the power-spectrum-envelope-coefficient-string arithmetic unit 102) in the encoder 100, the weighted envelope normalizer 103 can use the coefficients W(1), . . . , W(N) in the power spectrum envelope coefficient string. Note that since a decoder needs to obtain the same values obtained in the encoder 100, quantized linear predictive coefficients and/or power spectrum envelope coefficient strings are used. Hereinafter, the term “linear predictive coefficient” or “power spectrum envelope coefficient string” means a quantized linear predictive coefficient or a quantized power spectrum envelope coefficient string unless otherwise stated. The linear predictive coefficients are encoded using a conventional encoding technique and predictive coefficient code is then transmitted to the decoding side. The conventional encoding technique may be an encoding technique that provides code corresponding to liner predictive coefficients themselves as predictive coefficients code, an encoding technique that converts linear predictive coefficients to LSP parameters and provides code corresponding to the LSP parameters as predictive coefficient code, or an encoding technique that converts liner predictive coefficients to PARCOR coefficients and provides code corresponding to the PARCOR coefficients as predictive coefficient code, for example. If power spectrum envelope coefficients strings are obtained with other means provided in the encoder 100, other means in the encoder 100 encodes the linear predictive coefficients by a conventional encoding technique and transmits predictive coefficient code to the decoding side.
While two examples of a weighing envelope normalization process will be given here, the present invention is not limited to the examples.
The weighted envelope normalizer 103 divides the coefficients X(1), . . . , X(N) in an MDCT coefficient string by correction Wγ(1), . . . , Wγ(N) of the coefficients in a power spectrum envelope coefficient string that correspond to the coefficients to obtain the coefficients X(1)/Wγ(1), . . . , X(N)/Wγ(N) in a weighted normalized MDCT coefficient string. The correction values Wγ(n) [1≦n≦N] are given by formula (3), where γ is a positive constant less than or equal to 1 and moderates power spectrum coefficients.
The weighted envelope normalizer 103 raises the coefficients in a power spectrum envelope coefficient string that correspond to the coefficients X(1), . . . , X(N) in an MDCT coefficient string to the β-th power (0<β<1) and divides the coefficients X(1), . . . , X(N) by the raised values W(1)β, . . . , W(N)β to obtain the coefficients X(1)/W(1)β, . . . , X(N)/W(N)β in a weighted normalized MDCT coefficient string.
As a result, a weighted normalized MDCT coefficient string in a frame is obtained. The weighted normalized MDCT coefficient string does not have a steep slope of amplitude or large variations in amplitude as compared with the input MDCT coefficient string but has variations in magnitude similar to those of the power spectrum envelope of the input MDCT coefficient string, that is, the weighted normalized MDCT coefficient string has somewhat greater amplitudes in a region of coefficients corresponding to low frequencies and has a fine structure due to a pitch period.
Note that the inverse process of the weighted envelope normalization process, that is, the process for reconstructing the MDCT coefficient string from the weighted normalized MDCT coefficient string, is performed at the decoding side, settings for the method for calculating weighted power spectrum envelope coefficient strings from power spectrum envelope coefficient strings need to be common between the encoding and decoding sides.
<Initializer 104>
An initializer 104 sets an initial value of gain (global gain) g. The initial value of the gain can be determined from the energy of a weighted normalized coefficient string XN(1), . . . , XN(N) and the number of bits allocated beforehand to code output from a variable-length encoder 106, for example. The initial value of gain g is a positive value. The number of bits allocated beforehand to code output from the variable-length encoder 106 is hereinafter referred to as the number of allocated bits B. The initializer also sets 0 as the initial value of the number of updates of gain.
<Gain Update Loop Processor 130>
A gain update loop processor 130 determines gain such that a sequence (a sequence of integer value samples) obtained by dividing each coefficient in a weighted normalized MDCT coefficient string XN(1), . . . , XN(N) by the gain can be encoded with a predetermined number of bits, and outputs an integer signal code obtained by variable length encoding of the sequence (the sequence of integer value samples) obtained by dividing the weighted normalized MDCT coefficient string XN(1), . . . , XN(N) by the determined gain and a gain code (the gain code corresponding to the gain) obtained by encoding the determined gain. The gain update loop processor 130 updates the value of gain so that the greater the difference between the number of bits in the code obtained by encoding the sequence of integer value samples and the given number of allocated bits B, the greater the difference between the gain before the update and the updated gain.
The gain update loop processor 130 includes a quantizer 105, the variable-length encoder 106, a determiner 107, a gain expansion updater 131, a gain reduction updater 132, a truncation unit 116, and a gain encoder 117.
<Quantizer 105>
The quantizer 105 quantizes a value obtained by dividing each coefficient (each sample) in an input weighted normalized MDCT coefficient string XN(1), . . . , XN(N) (a sample string derived from an input audio signal in a given interval) by gain g to obtain a quantized normalized coefficient sequence XQ(1), . . . , XQ(N) which is a sequence of integer values (quantized normalized samples) and outputs the quantized normalized coefficient sequence XQ(1), . . . , XQ(N).
The quantizer 105 also measures the number s of samples in the range from the quantized normalized coefficient at the lowest frequency to the quantized normalized coefficient which is not zero at the highest frequency and outputs the number s of samples.
<Variable-Length Encoder 106>
The variable-length encoder 106 encodes an input quantized normalized coefficient sequence XQ(1), . . . , XQ(N) by variable-length encoding to obtain and output a code (sample string code). The code is referred to as integer signal code. The variable-length encoding may use a method that encodes a plurality of coefficients in a quantized normalized coefficient string at a time, for example. In addition, the variable-length encoder 106 measures the number of bits in the integer signal code obtained by the variable-length encoding. In this embodiment, the number of bits is referred to as the number c of consumed bits.
<Determiner 107>
The determiner 107 outputs gain g, integer signal code, and the number c of consumed bits when the number of updates of gain is equal to a predetermined number.
When the number of updates of gain is less than the predetermined number, the determiner 107 performs control to cause a gain expansion updater 131 to perform a next process if the number c of consumed bits measured by the variable-length encoder 106 is greater than the number B of allocated bits, or to cause a gain reduction updater 132 to perform a next process if the number c of consumed bits measured by the variable-length encoder 106 is smaller than the number B of allocated bits. Note when the number c of consumed bits measured by the variable-length encoder 106 is equal to the number B of allocated bits, the determiner 107 outputs the gain g, the integer signal code and the number c of consumed bits.
<Gain Expansion Updater 131>
The gain expansion updater 131 sets a value greater than the current value of gain g as new gain g′>g. The gain expansion updater 131 includes a sample counter 118, a lower limit gain setter 108, a first branch controller 109, a first gain updater 110, and a gain expander 111.
<Sample Counter 118>
When the number c of consumed bits is greater than the number B of allocated bits, the sample counter 118 outputs the number t of samples of quantized normalized coefficients corresponding to a code remaining after removing an amount of code corresponding to quantized normalized coefficients at the high-frequency side from an integer signal code output from the determiner 107, so that the number c of consumed bits does not exceed the number B of allocated bits.
Specifically, the sample counter 118 outputs the number t of samples of quantized normalized coefficients that have been left after removing quantized normalized coefficients at the high frequency side that correspond to code (truncation code) corresponding to the amount c−B by which the number c of consumed bits exceeds the number B of allocated bits from a quantized normalized coefficient string output from the quantizer 105, that is, the number t of samples of quantized normalized coefficients whose corresponding code has not been removed. An example of truncation code is a code with a number of bits greater than or equal to c−B and the smallest among the code corresponding to one or more quantized normalized coefficients in a region including the highest frequency. In other words, t is the number of samples of quantized normalized coefficients to be encoded when the length of the corresponding variable-length code is less than or equal to the number B of allocated bits and is the largest by excluding quantized normalized coefficients at the high frequency side to leave only quantized normalized coefficients at the low frequency sides as coefficients to be encoded.
<Lower Limit Gain Setter 108>
When the number c of consumed bits is greater than the number B of allocated bits, the lower limit gain setter 108 sets the current value of gain g (gain g corresponding to the number c of consumed bits) as the lower limit gain gmin (gmin←g). The lower limit gain gmin means the lowest value of gain allowed.
<First Branch Controller 109>
When the lower limit gain gmin is set by the lower limit gain setter 108, the first branch controller 109 performs control to cause the first gain updater 110 to perform a next process if an upper limit gain value gmax has been already set or to cause the gain expander 111 to perform a next process if the upper limit gain gmax has not been set.
<First Gain Updater 110>
The first gain updater 110 sets a value between the current value of gain g (the value of gain g corresponding to the number c of consumed bits) and the upper limit gain gmax as a new value of gain g. This is because an optimum value of gain is between the current value of gain g and the upper limit gain gmax. For example, the first gain updater 110 sets the average of the current value of gain g and the upper limit gain gmax as a new value of gain g (g←(g+gmax)/2). Since the current value of gain g has been set as the lower limit gain gmin, it can be said that the average of the upper limit gain gmax and the lower limit gain gmin is set as a new value of gain g (g←(gmax+gmin)/2). Then the control returns to the process in the quantizer 105.
<Gain Expander 111>
The gain expander 111 increases the value of gain so that the greater the number s of samples in the range from the quantized normalized coefficient at the lowest frequency to the quantized normalized coefficient which is not zero at the highest frequency minus the number t of samples output from the sample counter 118, u=s−t, the greater the amount by which the current gain increases to a new gain. For example, the gain expander 111 increases the value of gain such that new gain g←current gain g×(1+u/N×α), where α is a predetermined positive constant.
Alternatively, the gain expander 111 increases the value of gain so that the greater the number N of all of the samples to be encoded minus the number t of samples output from the sample counter 118, v=N−t, the greater the amount by which the current gain increases to a new gain. For example, the gain expander 111 increases the value of gain such that new gain g←current gain g×(1+v/N×α).
Specifically, the greater the number of some or all of the samples in a quantized normalized sample string minus the number of samples of quantized normalized coefficients whose corresponding code has not been removed, the greater the amount by which the gain expander 111 increases the value of gain g. Then the control returns to the process in the quantizer 105. In other words, the gain expander 111 updates the value of gain so that the greater the number of some or all of the samples in a quantized normalized sample string minus the number of samples of quantized normalized coefficients whose corresponding code has not been removed, the greater the amount by which the value of gain before the update increases to an updated value. Then the gain expander 111 causes the quantizer 105 to perform the subsequent process.
<Gain Reduction Updater 132>
The gain reduction updater 132 sets a value smaller than the current value of gain g as a new gain g′<g. The gain reduction updater 132 includes an upper limit gain setter 112, a second branch controller 113, a second gain updater 114, and a gain reducer 115.
<Upper Limit Gain Setter 112>
When the number c of consumed bits is smaller than the number B of allocated bits, the upper limit gain setter 112 sets the current value of gain g (the value of gain g corresponding to the number c of consumed bits) as the upper limit gain gmax (gmax←g). The upper limit gain gmax means the highest gain allowed.
<Second Branch Controller 113>
When the upper limit gain gmax is set by the upper limit gain setter 112, the second branch controller 113 performs control to cause the second gain updater 114 to perform a next process if the lower limit gain gmin has already been set or cause the gain reducer 115 to perform a next process if the lower limit gain gmin has not yet been set.
<Second Gain Updater 114>
The second gain updater 114 sets a value between the current value of gain g (the value of gain g corresponding to the number c of consumed bit) and the lower limit gain gmin as a new value of gain g. This is because an optimum value of gain is between the current value of gain g and the lower limit gain gmin. For example, the second gain updater 114 sets the average of the current value of gain g and the lower limit gain gmin as a new value of gain g (g←(g+gmin)/2). Since the current value of gain g has been set as the upper limit gain gmax, it can be said that the average of the upper limit gain gmax and the lower limit gain gmin is set as a new value of gain g (g←(gmax+gmin)/2). Then the control returns to the process in the quantizer 105.
<Gain Reducer 115>
The gain reducer 115 reduces the value of gain g so that the greater the number of residual bits which is the number B of allocated bits minus the number c of consumed bits, B−c, the greater the amount by which the current value of gain g decreases to a new value of gain g. Here, the new value of gain g is also a positive value. For example, new gain g←current gain g×(1−(B−c)/B×β), where β is a predetermined positive constant. That is, the greater the number B of allocated bits minus the number c of consumed bits, B−c, the greater the amount by which the gain reducer 115 decreases the value of gain g. Then the control returns to the process in the quantizer 105. In other words, the gain reducer 115 updates the value of gain g so that the greater the number B of allocated bits minus the number c of consumed bits, B−c, the greater the amount by which the value of gain g before the update decreases to an updated value and then causes the quantizer 105 to perform the subsequent process.
<Truncation Unit 116>
When the number c of consumed bits output from the determiner 107 is greater than the number B of allocated bits, the truncation unit 116 removes an amount of code equivalent to bits by which the number c of consumed bits exceeds the number B of allocated bits from the code corresponding to quantized normalized coefficients at the high frequency side in an integer signal code output from the determiner 107 and outputs the resulting code as a new integer signal code. That is, the truncation unit 116 removes the amount of code (truncation code) equivalent to the number of bits c−B by which the number c of consumed bits exceeds the number B of allocated bits that corresponds to quantized normalized coefficients at the high frequency side from the integer signal code (sample string code) and outputs the remaining code (truncated sample string code) as a new integer signal code.
<Gain Encoder 117>
The gain encoder 117 encodes gain output from the determiner 107 with a predetermined number of bits to obtain and output a gain code.
[Modification of First Embodiment]
<Encoder 150>
An encoding process performed by an encoder 150 of a modification of the first embodiment will be described with reference to
Differences from the first embodiments will be described below.
<Bit Count Estimator 156>
The bit count estimator 156 obtains an estimated value of the number of bits (estimated number of bits) in a code that can be obtained by variable-length encoding of a quantized normalized coefficient code sequence XQ(1), . . . , XQ(N). In the modification of the first embodiment, the estimated number of bits is referred to as the number c of consumed bits.
<Determiner 157>
The determiner 157 outputs gain g and a quantized normalized coefficient sequence XQ(1), . . . , XQ(N) when the number of updates of gain is equal to a predetermined number.
When the number of updates of gain is less than the predetermined number, the determiner 157 performs control to cause the gain expansion updater 191 to perform a next process if the number c of consumed bits estimated by the bit count estimator 156 is greater than the number B of allocated bits, or to cause the gain reduction updater 132 to perform a next process if the number c of consumed bits estimated by the bit count estimator 156 is smaller than the number B of allocated bits. Note if the number c of consumed bits estimated by the bit count estimator 156 is equal to the number B of allocated bits, the determiner 157 outputs gain g and a quantized normalized coefficient sequence XQ(1), . . . , XQ(N).
<Sample Counter 168>
When the number c of consumed bits is greater than the number B of allocated bits, the sample counter 168 outputs the number t of samples of quantized normalized coefficients that have been left after removing quantized normalized coefficients at the high frequency side that are directed to code (truncation code) corresponding to the amount c−B by which the number c of consumed bits exceeds the number B of allocated bits from a quantized normalized coefficient sequence XQ(1), . . . , XQ(N) output from the quantizer 105.
<Gain Expander 151>
The gain expander 151 is the same as the gain expander 111 of the first embodiment, except that the gain expander 151 uses the number t of samples output from the sample counter 168 instead of the number t of samples output from the sample counter 118 in the gain expander 111.
The gain expander 151 increases the value of gain so that the greater the number s of samples in the range from the quantized normalized coefficient at the lowest frequency to the quantized normalized coefficient which is not zero at the highest frequency minus the number t of samples output from the sample counter 118, u=s−t, the greater the amount by which the current gain increases to a new gain. For example, the gain expander 151 increases the value of gain such that new gain g←current gain g×(1+u/N×α), where α is a predetermined positive constant.
Alternatively, the gain expander 151 increases the value of gain so that the greater the number N of all of the samples to be encoded minus the number t of samples output from the sample counter 118, v=N−t, the greater the amount by which the current gain increases to a new gain. For example, the gain expander 151 increases the value of gain such that new gain g←current gain g×(1+v/N×α).
Specifically, the greater the number of some or all of the samples in a quantized normalized sample string minus the number of samples of quantized normalized coefficients whose corresponding code has not been removed, the greater the amount by which the gain expander 151 increases the value of gain g. Then the control returns to the process in the quantizer 105. In other words, the gain expander 111 updates the value of gain so that the greater the number of some or all of the samples in a quantized normalized sample string minus the number t of samples of quantized normalized coefficients left after removing quantized normalized coefficients at the high frequency side that are directed to the truncation code from a quantized normalized coefficient sequence XQ(1), . . . , XQ(N) output from the quantizer 105, the greater the amount by which the value of gain before the update increases to an updated value and then causes the quantizer 105 to perform the subsequent process.
<Variable-Length Encoder 159>
The variable-length encoder 159 encodes a quantized normalized coefficient sequence XQ(1), . . . , XQ(N) output from the determiner 157 by variable-length encoding to obtain a code and outputs the obtained code as an integer signal code (a sample string code). When the number of bits in the code obtained by the variable-length encoding exceeds the number B of allocated bits, the variable-length encoder 159 removes the amount of code by which the number B of allocated bits is exceeded from code corresponding to quantized normalized coefficients at the high-frequency side in the code obtained by the variable-length encoding and outputs the resulting code as an integer signal code.
[Second Embodiment]
<Encoder 200>
An encoding process performed by an encoder 200 of a second embodiment will be described with reference to
<Quantizer 205>
The quantizer 205 quantizes a value obtained by dividing each coefficient (each sample) in an input weighted normalized MDCT coefficient string XN(1), . . . , XN(N) (a sample string derived from an input audio signal in a given interval) by gain g to obtain a quantized normalized coefficient sequence XQ(1), . . . , XQ(N) which is a sequence of integer values (quantized normalized samples) and outputs the quantized normalized coefficient sequence XQ(1), . . . , XQ(N).
<Determiner 207>
The determiner 207 outputs gain, integer signal code, and the number c of consumed bits when the number of updates of gain is equal to a predetermined number.
When the number of updates of gain is less than the predetermined number, the determiner 207 performs control to cause the gain expansion updater 231 to perform a next process if the number c of consumed bits measured by the variable-length encoder 106 is greater than the number B of allocated bits, or to cause a gain reduction updater 132 to perform a next process if the number c of consumed bits measured by the variable-length encoder 106 is smaller than the number B of allocated bits. Note if the number c of consumed bits is equal to the number B of allocated bits, the determiner 207 outputs gain, the integer signal code and the number c of consumed bits.
<Truncation Unit 216>
When the number c of consumed bits output from the determiner 207 is greater than the number B of allocated bits, the truncation unit 216 removes an amount of code equivalent to bits by which the number c of consumed bits exceeds the number B of allocated bits from the code corresponding to quantized normalized coefficients at the high frequency side in an integer signal code output from the determiner 207 and outputs the resulting code as a new integer signal code. That is, the truncation unit 216 removes the amount of code (truncation code) equivalent to the number of bits c−B by which the number c of consumed bits exceeds the number B of allocated bits that corresponds to quantized normalized coefficients at the high frequency side from the integer signal code (sample string code) and outputs the remaining code (truncated sample string code) as a new integer signal code.
<Gain Expander 211>
The gain expander 211 increases gain so that the greater a shortfall of bits which is the number c of consumed bits minus the number B of allocated bits, c−B, the greater the amount by which the current gain increases to new gain. For example, new gain g←current gain g×(1+(c−B)/B×α), where α is a predetermined positive constant. That is, when the number c of consumed bits is greater than the number B of allocated bits and the upper limit gain gmax has not been set, the gain expander 211 increases the value of gain g so that the greater the number c of consumed bits minus the number B of allocated bits, c−B, the greater the amount by which the value of gain g is increased. Then the control returns to the process in the quantizer 205. In other words, the gain expander 211 updates the value of gain g so that the greater the number c of consumed bits minus the number B of allocated bits, c−B, the greater the amount by which the value of gain g before the update increases to an updated value and causes the quantizer 205 to perform the subsequent process.
[Modification of Second Embodiment]
<Encoder 250>
An encoding process performed by an encoder 205 of a modification of the second embodiment will be described with reference to
<Bit Count Estimator 156>
The bit count estimator 156 is the same as that of the modification of the first embodiment.
<Determiner 257>
When the number of updates of gain is equal to a predetermine number of updates, the determiner 257 outputs gain, a quantized normalized coefficient sequence, and the number c of consumed bits.
When the number of updates is less than the predetermined number of updates, the determiner 257 performs control to cause the gain expansion updater 231 to perform the process described in the first embodiment if the number c of consumed bits estimated by the bit count estimator 156 is greater than the number B of allocated bits, or to cause the gain reduction updater 132 to perform the process described in the first embodiment if the number c of consumed bits estimated by the bit count estimator 156 is less than the number B of allocated bits. Note that if the number c of consumed bits estimated by the bit count estimator 156 is equal to the number B of allocated bits, the determiner 257 outputs gain, a quantized normalized coefficient sequence, and the number c of consumed bits.
<Variable-Length Encoder 159>
The variable-length encoder 159 is the same as that of the modification of the first embodiment.
[Third Embodiment]
<Encoder 300>
An encoding process performed by an encoder 300 of a third embodiment will be described with reference to
<Lower Limit Gain Setter 308>
The lower limit gain setter 308 sets the current value of gain g as the lower limit gain gmin (gmin←g). Additionally, the lower limit gain setter 308 stores the number c of consumed bits as the number cL of consumed-bits-at-lower-limit-setting in the bit consumption storage 320. That is, when the number c of consumed bits is greater than the number B of allocated bits, the lower limit gain setter 308 sets the number c of consumed bits as the number cL of consumed-bits-with-lower-limit-setting and stores the number cL of consumed-bits-at-lower-limit-setting in the bit consumption storage 320 in addition to performing the process in the lower limit gain setter 108 of the first embodiment.
<Upper Limit Gain Setter 312>
The upper limit gain setter 312 sets the current value of gain g as the upper limit gain gmax (gmax←g). Additionally the upper limit gain setter 312 stores the number c of consumed bits in the bit consumption storage 320 as the number cU of consumed-bits-at-upper-limit-setting. That is, when the number c of consumed bits is smaller than the number B of allocated bits, the upper limit gain setter 312 sets the number c of consumed bits as the number cU of consumed-bits-at-upper-limit-setting and stores the number cU of consumed-bits-at-upper-limit-setting in the bit consumption storage 320 in addition to performing the process in the upper limit gain setter 112 of the first embodiment.
<First Gain Updater 310>
When the number c of consumed bits is greater than the number B of allocated bits and the upper limit gain gmax has already been set, the first gain updater 310 obtains at least one of an indicator of the likelihood of the lower limit gain gmin and an indicator of the likelihood of the upper limit gain gmax based on the number B of allocated bits, the number cU of consumed-bits-at-upper-limit-setting and the number cL of consumed-bits-at-lower-limit-setting. Note that the “indicator of the likelihood” means an indicator of the likelihood of a value of gain g.
[Indicator of Likelihood of Lower Limit Gain gmin]
The first gain updater 310 obtains an indicator w of the relative likelihood of lower limit gain gmin according to formula A, for example.
w=(B−CU)/(cL−cU) (Formula A)
Formula A is the same in meaning as formula B, which is based on the difference between the number B of allocated bits and the number cU of consumed-bits-at-upper-limit-setting and the difference between the number cL of consumed-bits-at-lower-limit-setting and the number of allocate bits B, with a modification to the right-hand side of formula B.
w=(B−cU)/(B−cU+cL−B) (Formula B)
Therefore, the indicator w may be obtained according to formula B instead of formula A.
When the indicator w obtained according to formula A or B is large, the lower limit gain gmin is more likely to be the value of gain; when the indicator w is small, the upper limit gain gmax is more likely to be the value of gain g.
[Indicator of Likelihood of Upper Limit Gain gmax]
The relative likelihood of the upper limit gain gmax is (1−w).
That is, the indicator (1−w) of the likelihood of the upper limit gain gmax may be obtained according to formula C instead of obtaining the indicator w according to formula A or B.
(1−w)=(cL−B)/(cL−cU) (Formula C)
Formula C is the same in meaning as formula D, which is based on the difference B−cU between the number B of allocated bits and the number cU of consumed-bits-at-upper-limit-setting and the difference cL−B between the number cL of consumed-bits-at-lower-limit-setting and the number B of allocated bits, with a modification to the right-hand side of formula D.
1−w=(cL−B)/(B−cU+cL−B) (Formula D)
Therefore, the indicator (1−w) may be obtained according to formula D instead of formula C.
When the indicator (1−w) obtained according to formula A or B is large, the upper limit gain gmax is more likely to be the value of gain g; when the indicator (1−w) is small, the lower limit gain gmin is more likely to be the value of gain g.
The first gain updater 310 then sets and outputs a weighted mean with a greater weight assigned to the upper limit gain gmax or lower limit gain gmin, whichever is more likely to be a new value of gain g (g←gmin×w+gmax×(1−w)). That is, when the difference between the number B of allocated bits and the number cU of consumed-bits-at-upper-limit-setting is greater than the difference between the number cL of consumed-bits-at-lower-limit-setting and the number B of allocated bits, the lower limit gain gmin is more likely and closer to a preferable value of the gain g.
Alternatively, the first gain updater 310 may use a constant C, which is a positive value, to obtain the indicator w with lessened weighting as w=(B−cU+C)/(cL−cU+2×C). In this case,
(1−w)=(cL−B+C)/(cL−cU+2×C)
and the new value of gain g is the intermediate between the arithmetic mean of the upper limit gain gmax and the lower limit gain gmin and the weighted mean based on the difference between the number of consumed bits and the number of allocated bits.
Note that if the number of quantized normalized samples corresponding to truncation code (the number of truncated samples Tr) has been obtained by the sample counter 118, the number Tr of truncated samples may be used instead of the difference between the number cL of consumed-bits-at-lower-limit-setting and the number B of allocated bits. This is because the greater the difference between the number cL of consumed-bits-at-lower-limit-setting and the number B of allocated bits, the greater the number Tr of truncated samples. The correlation between the difference between the number cL of consumed-bits-at-lower-limit-setting and the number B of allocated bits and the number Tr of truncated samples may be experimentally obtained beforehand and the number Tr of truncated samples may be approximately converted to the difference between the number cL of consumed-bits-at-lower-limit-setting and the number B of allocated bits. Replacing (cL−B)=γ×Tr, where γ is a coefficient experimentally determined for conversion, then w can be written as w=(B−cU)/(B−Cu+γ×Tr). Similarly, a constant C, which is a positive value, can be used to obtain the indicator w with lessened weighting as w=(B−cU+C)/(B−cU+γ×Tr+2×C). That is, the first gain updater 310 may use the number B of allocated bits, the number Tr of truncated samples and the number cU of consumed-bits-at-upper-limit-setting to obtain at least one of the indicator of the likelihood of a value of lower limit gain and indicator of the likelihood of a value of upper limit gain. While it is desirable that the latest number Tr of samples obtained in the latest process in the sample counter 118 be used, the number Tr of samples obtained in an earlier process in the sample counter 118 may be used.
Then the control returns to the process in the quantizer 105.
<Second Gain Updater 314>
When the number c of consumed bits is smaller than the number B of allocated bits and the lower limit gain gmin has already been set, the second gain updater 314 performs the same operation as that in the first gain updater 310.
The “indicator of the likelihood” described above represents toward which of the lower limit gain gmin and the upper limit gain gmax the value of gain g should be changed and how much in order for the gain g to approach an optimum value. Since gain g is updated to a new value based on the indicator in this embodiment, the number of updates needed for gain g to converge to an optimum value can be reduced.
The first gain updater 310 and the second gain updater 314 of this embodiment obtain at least one of the indicator of the likelihood of the value of the lower limit gain gmin and the indicator of the likelihood of the value of the upper limit gain gmax, assign a greater weight to the lower limit gain gmin or the upper limit gain gmax, whichever is more likely, and set the weighted mean of the lower limit gain gmin and the upper limit gain gmax as a new value of gain g. However, the first gain updater 310 and the second gain updater 314 may assign a greater weight to the lower limit gain gmin or the upper limit gain gmax, whichever is more likely, and the weighted mean of the lower limit gain gmin and the upper limit gain gmax may be set as a new value of gain g without obtaining an indicator of the likelihood. For example, based on the number cU of consumed-bits-at-upper-limit-setting and the number cL of consumed-bits-at-lower-limit-setting and the number B of allocated bits, the first gain updater 310 and the second gain updater 314 may set
as a new value of gain g without obtaining either of the indicators w and (1−W). It is essential only that the greater the difference between the number B of allocated bits and the number cU of consumed-bits-at-upper-limit-setting, the greater weight is assigned to the upper limit gain gmax, or the greater the difference between the number cL of consumed-bits-at-lower-limit-setting and the number B of allocated bits, the greater weight is assigned to the lower limit gain gmin, and the weighted mean of the lower limit gain gmin and the upper limit gain gmax is set as a new value of gain g. The process of setting a new value of gain g is not limited.
Alternatively, if the first gain updater 310 and the second gain updater 314 are configured to update gain g based on the number Tr of truncated samples, the first gain updater 310 may obtain
as a new value of gain g.
Alternatively, a weight may be assigned to the lower limit gain gmin or the upper limit gain gmax and the weighted mean of the lower limit gain gmin and the upper limit gain gmax may be set as a new value of gain g. For example,
(ω1×gmin+gmax)/(ω1+1)
may be set as a new value of gain g. Here, ω1 may be set to take a positive value greater than or equal to 1 when the gmin is more likely, i.e. when (B−cU)>(cL−B), take a positive value less than or equal to 1 when gmax is more likely, i.e. when (B−cU)<(cL−B), and increase with increasing B−cU. For example, ω1 may be a monotonically increasing function value with respect to B−cU. Alternatively,
(gmin+ω2×gmax)/(1+ω2)
may be set as a new value of gain g. Here, ω2 may be set to take a positive value greater than or equal to 1 when the gmax is more likely, take a positive value less than or equal to 1 when gmin is more likely, and increase with increasing cL−B. For example, ω2 may be a monotonically increasing function value with respect to cL−B. Alternatively, when gmin is more likely (when (B−cU)>(cL−B)),
(ω3×gmin+gmax)/(ω3+1)
may be set as a new value of gain g, and when gmax is more likely (when (B−cU)<(cL−B))
(gmin+ω4×gmax)/(1+ω4)
may be set as a new value of gain g, where ω3 takes a positive value that is greater than or equal to 1 and is a monotonically increasing function value with respect to B−cU, and ω4 takes a positive value that is greater than or equal to 1 and is a monotonically increasing function value with respect to cL−B.
In this way, a weighted mean of the upper limit gain and the lower limit gain may be set as an updated gain where a weight based on at least the number B of allocated bits, the number cL of consumed-bits-at-lower-limit-setting and the number cU of consumed-bits-at-upper-limit-setting is assigned to at least one of the upper limit gain gmax and the lower limit gain gmin.
[Modification of Third Embodiment]
While the third embodiment has been described wherein the lower limit gain setter 108, the upper limit gain setter 112, the first gain updater 110 and the second gain updater 114 of the first embodiment are replaced, the lower limit gain setter 108, the upper limit gain setter 112, the first gain updater 110 and the second gain updater 114 of the second embodiment may be replaced with the sections described in the third embodiment, or the lower limit gain setter 1008, the upper limit gain setter 1012, the first gain updater 1010 and the second gain updater 1014 of the encoder 1000 for TCX encoding described in [Background Art] may be replaced with the sections described in the third embodiment.
Alternatively, the lower limit gain setter 108, the upper limit gain setter 112, the first gain updater 110 and the second gain updater 114 of the modification of the first embodiment may be replaced with the sections described in the third embodiment, or the lower limit gain setter 108, the upper limit gain setter 112, the first gain updater 110 and the second gain updater 114 of the modification of the second embodiment may be replaced with the sections described in the third embodiment.
That is, when the number of bits or estimated number of bits in a code obtained by encoding a string of integer value samples obtained by dividing each sample in a sample string by gain before an update is greater than a predetermined number B of allocated bits, the gain before the update may be set as the lower limit gain gmin, the number of bits or estimated number of bits may be set as the number cL of consumed-bits-at-lower-limit-setting; when the number of bits or estimated number of bits in a code obtained by encoding a string of integer value samples obtained by dividing each sample in a sample string by the gain before an update is smaller than the predetermined number B of allocated bits, the gain before the update may be set as the upper limit gain gmax, the number of bits or estimated number of bits may be set as the number cU of consumed-bits-at-upper-limit-setting. A weight based on at least the number B of allocated bits, the number cL of consumed-bits-at-lower-limit-setting and the number cU of consumed-bits-at-upper-limit-setting may be assigned to at least one of the upper limit gain gmax and the lower limit gain gmin and the weighted mean of the upper limit gain and the lower limit gain may be set as an updated gain.
<Exemplary Hardware Configuration of Encoder>
An encoder according to the embodiments described above includes an input unit to which a keyboard and the like can be connected, an output unit to which a liquid-crystal display and the like can be connected, a CPU (Central Processing Unit) (which may include a memory such as a cache memory), memories such as a RAM (Random Access Memory) and a ROM (Read Only Memory), an external storage, which is a hard disk, and a bus that interconnects the input unit, the output unit, the CPU, the RAM, the ROM and the external storage in such a manner that they can exchange data. A device (drive) capable of reading and writing data on a recording medium such as a CD-ROM may be provided in the encoder as needed.
Programs for performing encoding and data required for processing by the programs are stored in the external storage of the encoder (the storage is not limited to an external storage; for example the programs may be stored in a read-only storage device such as a ROM.). Data obtained in the processing of the programs is stored on the RAM or the external storage device as appropriate. A storage device that stores data and addresses of its storage locations is hereinafter simply referred to as the “storage”. Programs and the like for executing encoding are stored in the storage of the encoder.
In the encoder, the programs stored in the storage and data required for the processing of the programs are loaded into the RAM as required and are interpreted and executed or processed by the CPU. As a result, the CPU implements given functions to implement encoding.
<Addendum>
The present invention is not limited to the embodiments described above and modifications can be made without departing from the spirit of the present invention. For example, when the number of consumed bits is smaller than the number of allocated bits, the process in the gain reduction updater is performed whereas when the number of consumed bits is equal to the number of allocated bits, the determiner outputs gain and other information. However, the process in the gain reduction updater may be performed when the number of consumed bits is not greater than the number of allocated bits. Furthermore, the processes described in the embodiments may be performed not only in time sequence as is written or may be performed in parallel with one another or individually, depending on the throughput of the apparatuses that perform the processes or requirements.
If processing functions of any of the hardware entities (the encoder) described in the embodiments are implemented by a computer, the processing of the functions that the hardware entities should include is described in a program. The program is executed on the computer to implement the processing functions of the hardware entity on the computer.
The programs describing the processing can be recorded on a computer-readable recording medium. An example of the computer-readable recording medium is a non-transitory recording medium. The computer-readable recording medium may be any recording medium such as a magnetic recording device, an optical disc, a magneto-optical recording medium, and a semiconductor memory. Specifically, for example, a hard disk device, a flexible disk, or a magnetic tape may be used as a magnetic recording device, a DVD (Digital Versatile Disc), a DVD-RAM (Random Access Memory), a CD-ROM (Compact Disc Read Only Memory), or a CD-R (Recordable)/RW (ReWritable) may be used as an optical disk, MO (Magneto-Optical disc) may be used as a magneto-optical recoding medium, and an EEP-ROM (Electronically Erasable and Programmable Read Only Memory) may be used as a semiconductor memory.
The program is distributed by selling, transferring, or lending a portable recording medium on which the program is recorded, such as a DVD or a CD-ROM. The program may be stored on a storage device of a server computer and transferred from the server computer to other computers over a network, thereby distributing the program.
A computer that executes the program first stores the program recorded on a portable recording medium or transferred from a server computer temporally into a storage device of the computer. When the computer executes the processes, the computer reads the program stored on the recording medium of the computer and executes the processes according to the read program. In another mode of execution of the program, the computer may read the program directly from a portable recording medium and execute the processes according to the program or may execute the processes according to the received program each time the program is transferred from the server computer to the computer. Alternatively, the processes may be executed using a so-called ASP (Application Service Provider) service in which the program is not transferred from a server computer to the computer but process functions are implemented by instructions to execute the program and acquisition of the results of the execution. Note that the program in this mode encompasses information that is provided for processing by an electronic computer and is equivalent to the program (such as data that is not direct commands to a computer but has the nature that defines processing of the computer).
While the hardware entities are configured by causing a computer to execute a predetermined program in the embodiments described above, at least some of the processes may be implemented by hardware.
Number | Date | Country | Kind |
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2012-122785 | May 2012 | JP | national |
Filing Document | Filing Date | Country | Kind |
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PCT/JP2013/064877 | 5/29/2013 | WO | 00 |
Publishing Document | Publishing Date | Country | Kind |
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WO2013/180164 | 12/5/2013 | WO | A |
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