1. Field of the Invention
The present invention relates to an information processing apparatus, a sound material capturing method, and a program.
2. Description of the Related Art
To remix music, sound materials to be used for the remixing have to be provided. To perform remixing, it has been common to use sound materials picked up from material collection on the market or to use sound materials that one has captured using a waveform editing software or the like. However, it is troublesome to find a material collection including sound materials matching one's intentions. It is also troublesome to look for a part which may serve as the desired sound material from massive amounts of music data, or to capturing the part with high accuracy. Moreover, there is a description relating to remixed playback of music in JP-A-2008-164932, for example. In JP-A-2008-164932, a technology is disclosed for combining a plurality of sound materials by a simple operation and creating music with high degree of perfection.
However, JP-A-2008-164932 does not disclose a technology for automatically detecting, with high accuracy, a feature quantity included in each music piece and automatically capturing a sound material based on the feature quantity. Thus, in light of the foregoing, it is desirable to provide a novel and improved information processing apparatus, sound material capturing method and program that are capable of accurately extracting a feature quantity from music data and capturing a sound material based on the feature quantity.
According to an embodiment of the present invention, there is provided an information processing apparatus including a music analysis unit for analyzing an audio signal serving as a capture source for a sound material and for detecting beat positions of the audio signal and a presence probability of each instrument sound in the audio signal, and a capture range determination unit for determining a capture range for the sound material by using the beat positions and the presence probability of each instrument sound detected by the music analysis unit.
Furthermore, the information processing apparatus may further include a capture request input unit for inputting a capture request including, as information, at least one of length of a range to be captured as the sound material, types of instrument sounds and strictness for capturing. In this case, the capture range determination unit determines the capture range for the sound material so that the sound material meets the capture request input by the capture request input unit.
Furthermore, the information processing apparatus may further include a material capturing unit for capturing the capture range determined by the capture range determination unit from the audio signal and for outputting the capture range as the sound material.
Furthermore, the information processing apparatus may further include a sound source separation unit for separating, in case signals of a plurality of types of sound sources are included in the audio signal, the signal of each sound source from the audio signal.
Furthermore, the music analysis unit may further detect a chord progression of the audio signal by analyzing the audio signal. In this case, the capture range determination unit determines the capture range for the sound material and outputs, along with information on the capture range, a chord progression in the capture range.
Furthermore, the music analysis unit may further detect a chord progression of the audio signal by analyzing the audio signal. In this case, the material capturing unit outputs, as the sound material, an audio signal of the capture range, and also outputs a chord progression in the capture range.
Furthermore, the music analysis unit may generate a calculation formula for extracting information relating to the beat positions and information relating to the presence probability of each instrument sound by using a calculation formula generation apparatus capable of automatically generating a calculation formula for extracting feature quantity of an arbitrary audio signal, and detect the beat positions of the audio signal and the presence probability of each instrument sound in the audio signal by using the calculation formula, the calculation formula generation apparatus automatically generating the calculation formula by using a plurality of audio signals and the feature quantity of each of the audio signals.
Furthermore, the capture range determination unit may include a material score computation unit for totalling presence probabilities of instrument sounds of types specified by the capture request for each range of the audio signal and for computing, as a material score, a value obtained by dividing the totalled presence probability by a total of presence probabilities of all instrument sounds in the range, each range having a length of the capture range specified by the capture request, and determine, as a capture range meeting the capture request, a range where the material score computed by the material score computation unit is higher than a value of the strictness for capturing.
Furthermore, the sound source separation unit may separate a signal for foreground sound and a signal for background sound from the audio signal and also may separate from each other a centre signal localized around a centre, a left-channel signal and a right-channel signal in the signal for foreground sound.
According to another embodiment of the present invention, there is provided a sound material capturing method including, when an audio signal serving as a capture source for a sound material is input to an information processing apparatus, the steps of analyzing the audio signal and detecting beat positions of the audio signal and a presence probability of each instrument sound in the audio signal, and determining a capture range for the sound material by using the beat positions and the presence probability of each instrument sound detected by the step of analyzing and detecting. The steps are performed by the information processing apparatus.
According to another embodiment of the present invention, there is provided a program for causing a computer to realize, when an audio signal serving as a capture source for a sound material is input, a music analysis function for analyzing the audio signal and for detecting beat positions of the audio signal and a presence probability of each instrument sound in the audio signal, and a capture range determination function for determining a capture range for the sound material by using the beat positions and the presence probability of each instrument sound detected by the music analysis function.
According to another embodiment of the present invention, there may be provided a recording medium which stores the program and which can be read by a computer.
According to the embodiments of the present invention described above, it becomes possible to accurately extract a feature quantity from music data and to capture a sound material based on the feature quantity.
Hereinafter, preferred embodiments of the present invention will be described in detail with reference to the appended drawings. Note that, in this specification and the appended drawings, structural elements that have substantially the same function and structure are denoted with the same reference numerals, and repeated explanation of these structural elements is omitted.
In this specification, explanation will be made in the order shown below.
1. Infrastructure Technology
1-1. Configuration Example of Calculation Formula Generation Apparatus 10
2. Embodiment
2-1. Overall Configuration of Information Processing Apparatus 100
2-2. Configuration of Sound Source Separation Unit 104
2-3. Configuration of Log Spectrum Analysis Unit 106
2-4. Configuration of Music Analysis Unit 108
2-5. Configuration of Capture Range Determination Unit 110
2-6. Conclusion
First, before describing a technology according to an embodiment of the present invention, an infrastructure technology used for realizing the technological configuration of the present embodiment will be briefly described. The infrastructure technology described here relates to an automatic generation method of an algorithm for quantifying in the form of feature quantity (also referred to as “FQ”) the feature of arbitrary input data. Various types of data such as a signal waveform of an audio signal or brightness data of each colour included in an image may be used as the input data, for example. Furthermore, when taking a music piece for an example, by applying the infrastructure technology, an algorithm for computing feature quantity indicating the cheerfulness of the music piece or the tempo is automatically generated from the waveform of the music data. Moreover, a learning algorithm disclosed in JP-A-2008-123011 can also be used instead of the configuration example of a feature quantity calculation formula generation apparatus 10 described below.
(1-1. Configuration Example of Feature Quantity Calculation Formula Generation Apparatus 10)
First, referring to
As shown in
First, the extraction formula generation unit 14 generates a feature quantity extraction formula (hereinafter, an extraction formula), which serves a base for a calculation formula, by combining a plurality of operators stored in the operator storage unit 12. The “operator” here is an operator used for executing specific operation processing on the data value of the input data. The types of operations executed by the operator include a differential computation, a maximum value extraction, a low-pass filtering, an unbiased variance computation, a fast Fourier transform, a standard deviation computation, an average value computation, or the like. Of course, it is not limited to these types of operations exemplified above, and any type of operation executable on the data value of the input data may be included.
Furthermore, a type of operation, an operation target axis, and parameters used for the operation are set for each operator. The operation target axis means an axis which is a target of an operation processing among axes defining each data value of the input data. For example, when taking music data as an example, the music data is given as a waveform for volume in a space formed from a time axis and a pitch axis (frequency axis). When performing a differential operation on the music data, whether to perform the differential operation along the time axis direction or to perform the differential operation along the frequency axis direction has to be determined. Thus, each parameter includes information relating to an axis which is to be the target of the operation processing among axes forming a space defining the input data.
Furthermore, a parameter becomes necessary depending on the type of an operation. For example, in case of the low-pass filtering, a threshold value defining the range of data values to be passed has to be fixed as a parameter. Due to these reasons, in addition to the type of an operation, an operation target axis and a necessary parameter are included in each operator. For example, operators are expressed as F#Differential, F#MaxIndex, T#LPF—1;0.861, T#UVariance, . . . . F and the like added at the beginning of the operators indicate the operation target axis. For example, F means frequency axis, and T means time axis.
Differential and the like added, being divided by #, after the operation target axis indicate the types of the operations. For example, Differential means a differential computation operation, MaxIndex means a maximum value extraction operation, LPF means a low-pass filtering, and UVariance means an unbiased variance computation operation. The number following the type of the operation indicates a parameter. For example, LPF—1;0.861 indicates a low-pass filter having a range of 1 to 0.861 as a passband. These various operators are stored in the operator storage unit 12, and are read and used by the extraction formula generation unit 14. The extraction formula generation unit 14 first selects arbitrary operators by the operator selection unit 16, and generates an extraction formula by combining the selected operators.
For example, F#Differential, F#MaxIndex, T#LPF—1;0.861 and T#UVariance are selected by the operator selection unit 16, and an extraction formula f expressed as the following equation (1) is generated by the extraction formula generation unit 14. However, 12 Tones added at the beginning indicates the type of input data which is a processing target. For example, when 12 Tones is described, signal data (log spectrum described later) in a time-pitch space obtained by analyzing the waveform of input data is made to be the operation processing target. That is, the extraction formula expressed as the following equation (1) indicates that the log spectrum described later is the processing target, and that, with respect to the input data, the differential operation and the maximum value extraction are sequentially performed along the frequency axis (pitch axis direction) and the low-pass filtering and the unbiased variance operation are sequentially performed along the time axis.
[Equation 1]
f={12Tones,F#Differential,F#MaxIndex,T#LPF—1;0.861,T#UVariance} (1)
As described above, the extraction formula generation unit 14 generates an extraction formula as shown as the above-described equation (1) for various combinations of the operators. The generation method will be described in detail. First, the extraction formula generation unit 14 selects operators by using the operator selection unit 16. At this time, the operator selection unit 16 decides whether the result of the operation by the combination of the selected operators (extraction formula) on the input data is a scalar or a vector of a specific size or less (whether it will converge or not).
Moreover, the above-described decision processing is performed based on the type of the operation target axis and the type of the operation included in each operator. When combinations of operators are selected by the operator selection unit 16, the decision processing is performed for each of the combinations. Then, when the operator selection unit 16 decides that an operation result converges, the extraction formula generation unit 14 generates an extraction formula by using the combination of the operators, according to which the operation result converges, selected by the operator selection unit 16. The generation processing for the extraction formula by the extraction formula generation unit 14 is performed until a specific number (hereinafter, number of selected extraction formulae) of extraction formulae are generated. The extraction formulae generated by the extraction formula generation unit 14 are input to the extraction formula list generation unit 20.
When the extraction formulae are input to the extraction formula list generation unit 20 from the extraction formula generation unit 14, a specific number of extraction formulae are selected from the input extraction formulae (hereinafter, number of extraction formulae in list≦number of selected extraction formulae) and an extraction formula list is generated. At this time, the generation processing by the extraction formula list generation unit 20 is performed until a specific number of the extraction formula lists (hereinafter, number of lists) are generated. Then, the extraction formula lists generated by the extraction formula list generation unit 20 are input to the extraction formula selection unit 22.
A concrete example will be described in relation to the processing by the extraction formula generation unit 14 and the extraction formula list generation unit 20. First, the type of the input data is determined by the extraction formula generation unit 14 to be music data, for example. Next, operators OP1, OP2, OP3 and OP4 are randomly selected by the operator selection unit 16. Then, the decision processing is performed as to whether or not the operation result of the music data converges by the combination of the selected operators. When it is decided that the operation result of the music data converges, an extraction formula f1 is generated with the combination of OP1 to OP4. The extraction formula f1 generated by the extraction formula generation unit 14 is input to the extraction formula list generation unit 20.
Furthermore, the extraction formula generation unit 14 repeats the processing same as the generation processing for the extraction formula f1 and generates extraction formulae f2, f3 and f4, for example. The extraction formulae f2, f3 and f4 generated in this manner are input to the extraction formula list generation unit 20. When the extraction formulae f1, f2, f3 and f4 are input, the extraction formula list generation unit 20 generates an extraction formula list L1={f1, f2, f4), and an extraction formula list L2={f1, f3, f4), for example. The extraction formula lists L1 and L2 generated by the extraction formula list generation unit 20 are input to the extraction formula selection unit 22. As described above with a concrete example, extraction formulae are generated by the extraction formula generation unit 14, and extraction formula lists are generated by the extraction formula list generation unit 20 and are input to the extraction formula selection unit 22. However, although a case is described in the above-described example where the number of selected extraction formulae is 4, the number of extraction formulae in list is 3, and the number of lists is 2, it should be noted that, in reality, extremely large numbers of extraction formulae and extraction formula lists are generated.
Now, when the extraction formula lists are input from the extraction formula list generation unit 20, the extraction formula selection unit 22 selects, from the input extraction formula lists, extraction formulae to be inserted into the calculation formula described later. For example, when the extraction formulae f1 and f4 in the above-described extraction formula list L1 are to be inserted into the calculation formula, the extraction formula selection unit 22 selects the extraction formulae f1 and f4 with regard to the extraction formula list L1. The extraction formula selection unit 22 performs the above-described selection processing for each of the extraction formula lists. Then, when the selection processing is complete, the result of the selection processing by the extraction formula selection unit 22 and each of the extraction formula lists are input to the calculation formula setting unit 24.
When the selection result and each of the extraction formula lists are input from the extraction formula selection unit 22, the calculation formula setting unit 24 sets a calculation formula corresponding to each of the extraction formula, taking into consideration the selection result of the extraction formula selection unit 22. For example, as shown as the following equation (2), the calculation formula setting unit 24 sets a calculation formula Fm by linearly coupling extraction formula fk included in each extraction formula list Lm={f1, . . . , fK}. Moreover, m=1, . . . , M (M is the number of lists), k=1, . . . , K (K is the number of extraction formulae in list), and B0, . . . , BK are coupling coefficients.
[Equation 2]
Fm=B0+B1f1+ . . . +BKfK (2)
Moreover, the calculation formula Fm can also be set to a non-linear function of the extraction formula fk (k=1 to K). However, the function form of the calculation formula Fm set by the calculation formula setting unit 24 depends on a coupling coefficient estimation algorithm used by the calculation formula generation unit 26 described later. Accordingly, the calculation formula setting unit 24 is configured to set the function form of the calculation formula Fm according to the estimation algorithm which can be used by the calculation formula generation unit 26. For example, the calculation formula setting unit 24 may be configured to change the function form according to the type of input data. However, in this specification, the linear coupling expressed as the above-described equation (2) will be used for the convenience of the explanation. The information on the calculation formula set by the calculation formula setting unit 24 is input to the calculation formula generation unit 26.
Furthermore, the type of feature quantity desired to be computed by the calculation formula is input to the calculation formula generation unit 26 from the feature quantity selection unit 32. The feature quantity selection unit 32 is means for selecting the type of feature quantity desired to be computed by the calculation formula. Furthermore, evaluation data corresponding to the type of the input data is input to the calculation formula generation unit 26 from the evaluation data acquisition unit 34. For example, in a case the type of the input data is music, a plurality of pieces of music data are input as the evaluation data. Also, teacher data corresponding to each evaluation data is input to the calculation formula generation unit 26 from the teacher data acquisition unit 36. The teacher data here is the feature quantity of each evaluation data. Particularly, the teacher data for the type selected by the feature quantity selection unit 32 is input to the calculation formula generation unit 26. For example, in a case where the input data is music data and the type of the feature quantity is tempo, correct tempo value of each evaluation data is input to the calculation formula generation unit 26 as the teacher data.
When the evaluation data, the teacher data, the type of the feature quantity, the calculation formula and the like are input, the calculation formula generation unit 26 first inputs each evaluation data to the extraction formulae f1, . . . , fK included in the calculation formula Fm and obtains the calculation result by each of the extraction formulae (hereinafter, an extraction formula calculation result) by the extraction formula calculation unit 28. When the extraction formula calculation result of each extraction formula relating to each evaluation data is computed by the extraction formula calculation unit 28, each extraction formula calculation result is input from the extraction formula calculation unit 28 to the coefficient computation unit 30. The coefficient computation unit 30 uses the teacher data corresponding to each evaluation data and the extraction formula calculation result that is input, and computes the coupling coefficients expressed as B0, . . . , BK in the above-described equation (2). For example, the coefficients B0, . . . , BK can be determined by using a least-squares method. At this time, the coefficient computation unit 30 also computes evaluation values such as a mean square error.
The extraction formula calculation result, the coupling coefficient, the mean square error and the like are computed for each type of feature quantity and for the number of the lists. The extraction formula calculation result computed by the extraction formula calculation unit 28, and the coupling coefficients and the evaluation values such as the mean square error computed by the coefficient computation unit 30 are input to the formula evaluation unit 38. When these computation results are input, the formula evaluation unit 38 computes an evaluation value for deciding the validity of each of the calculation formulae by using the input computation results. As described above, a random selection processing is included in the process of determining the extraction formulae configuring each calculation formula and the operators configuring the extraction formulae. That is, there are uncertainties as to whether or not optimum extraction formulae and optimum operators are selected in the determination processing. Thus, evaluation is performed by the formula evaluation unit 38 to evaluate the computation result and to perform recalculation or correct the calculation result as appropriate.
The calculation formula evaluation unit 40 for computing the evaluation value for each calculation formula and the extraction formula evaluation unit 42 for computing a contribution degree of each extraction formula are provided in the formula evaluation unit 38 shown in
[Equation 3]
AIC=number of teachers×{log 2n+1+log(mean square error)}+2(K+1) (3)
According to the above-described equation (3), the accuracy of the calculation formula is higher as the AIC is smaller. Accordingly, the evaluation value for a case of using the AIC is set to become larger as the AIC is smaller. For example, the evaluation value is computed by the inverse number of the AIC expressed by the above-described equation (3). Moreover, the evaluation values are computed by the calculation formula evaluation unit 40 for the number of the types of the feature quantities. Thus, the calculation formula evaluation unit 40 performs averaging operation for the number of the types of the feature quantities for each calculation formula and computes the average evaluation value. That is, the average evaluation value of each calculation formula is computed at this stage. The average evaluation value computed by the calculation formula evaluation unit 40 is input to the extraction formula list generation unit 20 as the evaluation result of the calculation formula.
On the other hand, the extraction formula evaluation unit 42 computes, as an evaluation value, a contribution rate of each extraction formula in each calculation formula based on the extraction formula calculation result and the coupling coefficients. For example, the extraction formula evaluation unit 42 computes the contribution rate according to the following equation (4). The standard deviation for the extraction formula calculation result of the extraction formula fK is obtained from the extraction formula calculation result computed for each evaluation data. The contribution rate of each extraction formula computed for each calculation formula by the extraction formula evaluation unit 42 according to the following equation (4) is input to the extraction formula list generation unit 20 as the evaluation result of the extraction formula.
Here, StDev( . . . ) indicates the standard deviation. Furthermore, the feature quantity of an estimation target is the tempo or the like of a music piece. For example, in a case where log spectra of 100 music pieces are given as the evaluation data and the tempo of each music piece is given as the teacher data, StDev(feature quantity of estimation target) indicates the standard deviation of the tempos of the 100 music pieces. Furthermore, Pearson( . . . ) included in the above-described equation (4) indicates a correlation function. For example, Pearson(calculation result of fK, estimation target FQ) indicates a correlation function for computing the correlation coefficient between the calculation result of fK and the estimation target feature quantity. Moreover, although the tempo of a music piece is indicated as an example of the feature quantity, the estimation target feature quantity is not limited to such.
When the evaluation results are input from the formula evaluation unit 38 to the extraction formula list generation unit 20 in this manner, an extraction formula list to be used for the formulation of a new calculation formula is generated. First, the extraction formula list generation unit 20 selects a specific number of calculation formulae in descending order of the average evaluation values computed by the calculation formula evaluation unit 40, and sets the extraction formula lists corresponding to the selected calculation formulae as new extraction formula lists (selection). Furthermore, the extraction formula list generation unit 20 selects two calculation formulae by weighting in the descending order of the average evaluation values computed by the calculation formula evaluation unit 40, and generates a new extraction formula list by combining the extraction formulae in the extraction formula lists corresponding to the calculation formulae (crossing-over). Furthermore, the extraction formula list generation unit 20 selects one calculation formula by weighting in the descending order of the average evaluation values computed by the calculation formula evaluation unit 40, and generates a new extraction formula list by partly changing the extraction formulae in the extraction formula list corresponding to the calculation formula (mutation). Furthermore, the extraction formula list generation unit 20 generates a new extraction formula list by randomly selecting extraction formulae.
In the above-described crossing-over, the lower the contribution rate of an extraction formula, the better it is that the extraction formula is set unlikely to be selected. Also, in the above-described mutation, a setting is preferable where an extraction formula is apt to be changed as the contribution rate of the extraction formula is lower. The processing by the extraction formula selection unit 22, the calculation formula setting unit 24, the calculation formula generation unit 26 and the formula evaluation unit 38 is again performed by using the extraction formula lists newly generated or newly set in this manner. The series of processes is repeatedly performed until the degree of improvement in the evaluation result of the formula evaluation unit 38 converges to a certain degree. Then, when the degree of improvement in the evaluation result of the formula evaluation unit 38 converges to a certain degree, the calculation formula at the time is output as the computation result. By using the calculation formula that is output, the feature quantity representing a target feature of input data is computed with high accuracy from arbitrary input data different from the above-described evaluation data.
As described above, the processing by the feature quantity calculation formula generation apparatus 10 is based on a genetic algorithm for repeatedly performing the processing while proceeding from one generation to the next by taking into consideration elements such as the crossing-over or the mutation. A computation formula capable of estimating the feature quantity with high accuracy can be obtained by using the genetic algorithm. However, in the embodiment described later; a learning algorithm for computing the calculation formula by a method simpler than that of the genetic algorithm can be used. For example, instead of performing the processing such as the selection, crossing-over and mutation described above by the extraction formula list generation unit 20, a method can be conceived for selecting a combination for which the evaluation value by the calculation formula evaluation unit 40 is the highest by changing the extraction formula to be used by the extraction formula selection unit 22. In this case, the configuration of the extraction formula evaluation unit 42 can be omitted. Furthermore, the configuration can be changed as appropriate according to the operational load and the desired estimation accuracy.
Hereunder, an embodiment of the present invention will be described. The present embodiment relates to a technology for automatically extracting, from an audio signal of a music piece, a feature amount of the music piece with high accuracy, and for capturing a sound material by using the feature amount. The sound material captured by the technology enables to change the arrangement of another music piece by being combined with the other music piece while being synchronized with the beats of the other music piece. Moreover, in the following, the audio signal of a music piece may also be referred to as music data.
(2-1. Overall Configuration of Information Processing Apparatus 100)
First, referring to
As shown in
Furthermore, a feature quantity calculation formula generation apparatus 10 is included in the information processing apparatus 100 illustrated in
Overall flow of the processing is as described next. First, capture conditions (hereinafter, capture request) for a waveform are input to the capture request input unit 102. The type of instrument to be captured, the length of a waveform material to be captured, strictness of the capture conditions to be used at the time of capturing, or the like is input as the capture request. The capture request input to the capture request input unit 102 is input to the capture range determination unit 110, and is used in a capturing, process for the waveform material.
For example, drums, guitar or the like is specified as the type of instrument. Also, the length of a waveform material can be specified in terms of frames or bars. For example, one bar, two bars, four bars or the like is specified as the length of a waveform material. Furthermore, the strictness of the capture conditions is specified by continuous values, e.g. from 0.0 (lenient) to 1.0 (strict). For example, when the strictness of the capture conditions is specified to be 0.9 or the like (up to 1.0), only the waveform material meeting the capture conditions is captured. On the contrary, when the strictness of the capture conditions is specified to be 0.1 or the like (down to 0.0), even if a portion is included which does not exactly meet the capture conditions, that section is captured as the waveform material.
On the other hand, music data is input to the sound source separation unit 104. The music data is separated, by the sound source separation unit 104, into a left-channel component (foreground component), a right-channel component (foreground component), a centre component (foreground component), and a background component. Then, the music data separated into each component is input to the log spectrum analysis unit 106. Each component of the music data is converted to a log spectrum described later by the log spectrum analysis unit 106. The log spectrum output from the log spectrum analysis unit 106 is input to the feature quantity calculation formula generation apparatus 10 or the like. Moreover, the log spectrum may be used by structural elements other than the feature quantity calculation formula generation apparatus 10. In this case, a desired log spectrum is provided as appropriate to each structural element directly or indirectly from the log spectrum analysis unit 106.
The music analysis unit 108 analyses the waveform of the music data, and extracts beat positions, chord progression and each of instrument sounds included in the music data. The beat positions are detected by the beat detection unit 132. The chord progression is detected by the chord progression detection unit 134. Each of the instrument sounds is extracted by the instrument sound analysis unit 136. At this time, the music analysis unit 108 generates, by using the feature quantity calculation formula generation apparatus 10, calculation formulae for feature quantities used for detecting the beat positions, the chord progression and each of the instrument sounds, and detects the beat positions, the chord progression and each of the instrument sounds from the feature quantities computed by the calculation formulae. The analysis processing by the music analysis unit 108 will be described later in detail. The beat positions, the chord progression and each of the instrument sounds obtained by the analysis processing by the music analysis unit 108 are input to the capture range determination unit 110.
The capture range determination unit 110 determines a range to be captured as a sound material from the music data, based on the capture request input from the capture request input unit 102 and the analysis result of the music analysis unit 108. Then, the information on the capture range determined by the capture range determination unit 110 is input to the waveform capturing unit 112. The waveform capturing unit 112 captures from the music data the waveform of the capture range determined by the capture range determination unit 110 as the sound material. Then, the waveform material captured by the waveform capturing unit 112 is recorded in a storage device provided externally or internally to the information processing apparatus 100. A rough flow relating to the capturing process for a waveform material is as described above. In the following, the configurations of the sound source separation unit 104, the log spectrum analysis unit 106 and the music analysis unit 108, which are the main structural elements of the information processing apparatus 100, will be described in detail.
(2-2. Configuration Example of Sound Source Separation Unit 104)
First, the sound source separation unit 104 will be described. The sound source separation unit 104 is means for separating sound source signals localized at the left, right and centre (hereunder, a left-channel signal, a right-channel signal, a centre signal), and a sound source signal for background sound. Here, referring to an extraction method of the sound source separation unit 104 for a centre signal, a sound source separation method of the sound source separation unit 104 will be described in detail. As shown in
First, a left-channel signal sL of the stereo signal input to the sound source separation unit 104 is input to the left-channel band division unit 142. A non-centre signal L and a centre signal C of the left channel are present in a mixed manner in the left-channel signal sL. Furthermore, the left-channel signal sL is a volume level signal changing over time. Thus, the left-channel band division unit 142 performs a DFT processing on the left-channel signal sL that is input and converts the same from a signal in a time domain to a signal in a frequency domain (hereinafter, a multi-band signal fL(0), . . . , fL(N−1)). Here, fL(K) is a sub-band signal corresponding to the k-th (k=0, . . . , N−1) frequency band. Moreover, the above-described DFT is an abbreviation for Discrete Fourier Transform. The left-channel multi-band signal output from the left-channel band division unit 142 is input to the band pass filter 146.
In a similar manner, a right-channel signal sR of the stereo signal input to the sound source separation unit 104 is input to the right-channel band division unit 144. A non-centre signal R and a centre signal C of the right channel are present in a mixed manner in the right-channel signal sR. Furthermore, the right-channel signal sR is a volume level signal changing over time. Thus, the right-channel band division unit 144 performs the DFT processing on the right-channel signal sR that is input and converts the same from a signal in a time domain to a signal in a frequency domain (hereinafter, a multi-band signal fR(0), . . . , fR(N−1)). Here, fR(k′) is a sub-band signal corresponding to the k′-th (k′=0, . . . , N−1) frequency band. The right-channel multi-band signal output from the right-channel band division unit 144 is input to the band pass filter 146. Moreover, the number of bands into which the multi-band signals of each channel are divided is N (for example, N=8192).
As described above, the multi-band signals fL(k) (k=0, . . . , N−1) and fR(k′) (k′=0, . . . , N−1) of respective channels are input to the band pass filter 146. In the following, frequency is labeled in the ascending order such as k=0, . . . , N−1, or k′=0, . . . , N−1. Furthermore, each of the signal components fL(k) and fR(k′) are referred to as a sub-channel signal. First, in the band pass filter 146, the sub-channel signals fL(k) and fR(k′) (k′=k) in the same frequency band are selected from the multi-band signals of both channels, and a similarity a(k) between the sub-channel signals is computed. The similarity a(k) is computed according to the following equations (5) and (6), for example. Here, an amplitude component and a phase component are included in the sub-channel signal. Thus, the similarity for the amplitude component is expressed as ap(k), and the similarity for the phase component is expressed as ai(k).
Here, | . . . | indicates the norm of “ . . . ”. θ indicates the phase difference (0≦|θ|≦π) between fL(k) and fR(k). The superscript * indicates a complex conjugate. Re[ . . . ] indicates the real part of “ . . . ”. As is clear from the above-described equation (6), the similarity ap(k) for the amplitude component is 1 in case the norms of the sub-channel signals fL(k) and fR(k) agree. On the contrary, in case the norms of the sub-channel signals fL(k) and fR(k) do not agree, the similarity ap(k) takes a value less than 1. On the other hand, regarding the similarity ai(k) for the phase component, when the phase difference θ is 0, the similarity ai(k) is 1; when the phase difference θ is π/2, the similarity ai(k) is 0; and when the phase difference θ is π, the similarity ai(k) is −1. That is, the similarity ai(k) for the phase component is 1 in case the phases of the sub-channel signals fL(k) and fR(k) agree, and takes a value less than 1 in case the phases of the sub-channel signals fL(k) and fR(k) do not agree.
When a similarity a(k) for each frequency band k (k=0, . . . , N−1) is computed by the above-described method, a frequency band q corresponding to the similarities ap(q) and ai(q) (o≦q≦N−1) less than a specific threshold value is extracted by the band pass filter 146. Then, only the sub-channel signal in the frequency band q extracted by the band pass filter 146 is input to the left-channel band synthesis unit 148 or the right-channel band synthesis unit 150. For example, the sub-channel signal fL(q) (q=q0, . . . , qn−1) is input to the left-channel band synthesis unit 148. Thus, the left-channel band synthesis unit 148 performs an IDFT processing on the sub-channel signal fL(q) (q=q0, . . . , qn−1) input from the band pass filter 146, and converts the same from the frequency domain to the time domain. Moreover, the above-described IDFT is an abbreviation for Inverse Discrete Fourier Transform.
In a similar manner, the sub-channel signal fR(q) (q=q0, . . . , qn−1) is input to the right-channel band synthesis unit 150. Thus, the right-channel band synthesis unit 150 performs the IDFT processing on the sub-channel signal fR(q) (q=q0, . . . , qn−1) input from the band pass filter 146, and converts the same from the frequency domain to the time domain. A centre signal component sL′ included in the left-channel signal sL is output from the left-channel band synthesis unit 148. On the other hand, a centre signal component sR′ included in the right-channel signal sR is output from the right-channel band synthesis unit 150. The sound source separation unit 104 can extract the centre signal from the stereo signal by the above-described method.
Furthermore, the left-channel signal, the right-channel signal and the signal for background sound can be separated in the same manner as for the centre signal by changing the conditions for passing the band pass filter 146 as shown in
The left-channel signal, the right-channel signal and the centre signal are foreground signals. Thus, either of the signals is in a band according to which the phase difference between the left and the right is small. On the other hand, the signal for background sound is a signal in a band according to which the phase difference between the left and the right is large. Thus, in case of extracting the signal for background sound, the passband of the band pass filter 146 is set to a band according to which the phase difference between the left and the right is large. The left-channel signal, the right-channel signal, the centre signal and the signal for background sound separated by the sound source separation unit 104 in this manner are input to the log spectrum analysis unit 106 (refer to
(2-3. Configuration Example of Log Spectrum Analysis Unit 106)
Next, the log spectrum analysis unit 106 will be described. The log spectrum analysis unit 106 is means for converting the input audio signal to an intensity distribution of each pitch. Twelve pitches (C, C#, D, D#, E, F, F#, G, G#, A, A#, B) are included in the audio signal per octave. Furthermore, a centre frequency of each pitch is logarithmically distributed. For example, when taking a centre frequency fA3 of a pitch A3 as the standard, a centre frequency of A#3 is expressed as fA#3=fA3*21/12. Similarly, a centre frequency fB3 of a pitch B3 is expressed as fB3=fA#3*21/12. In this manner, the ratio of the centre frequencies of the adjacent pitches is 1:21/12. However, when handling an audio signal, taking the audio signal as a signal intensity distribution in a time-frequency space will cause the frequency axis to be a logarithmic axis, thereby complicating the processing on the audio signal. Thus, the log spectrum analysis unit 106 analyses the audio signal, and converts the same from a signal in the time-frequency space to a signal in a time-pitch space (hereinafter, a log spectrum).
Referring to
First, the audio signal is input to the resampling unit 152. Then, the resampling unit 152 converts a sampling frequency (for example, 44.1 kHz) of the input audio signal to a specific sampling frequency. A frequency obtained by taking a frequency at the boundary between octaves (hereinafter, a boundary frequency) as the standard and multiplying the boundary frequency by a power of two is taken as the specific sampling frequency. For example, the sampling frequency of the audio signal takes a boundary frequency 1016.7 Hz between an octave 4 and an octave 5 as the standard and is converted to a sampling frequency 25 times the standard (32534.7 Hz). By converting the sampling frequency in this manner, the highest and lowest frequencies obtained as a result of a band division processing and a down sampling processing that are subsequently performed by the resampling unit 152 will agree with the highest and lowest frequencies of a certain octave. As a result, a process for extracting a signal for each pitch from the audio signal can be simplified.
The audio signal for which the sampling frequency is converted by the resampling unit 152 is input to the octave division unit 154. Then, the octave division unit 154 divides the input audio signal into signals for respective octaves by repeatedly performing the band division processing and the down sampling processing. Each of the signals obtained by the division by the octave division unit 154 is input to a band pass filter bank 156 (BPFB (O1), BPFB (O8)) provided for each of the octaves (O1, . . . , O8). Each band pass filter bank 156 is configured from 12 band pass filters each having a passband for one of 12 pitches so as to extract a signal for each pitch from the input audio signal for each octave. For example, by passing through the band pass filter bank 156 (BPFB (O8)) of octave 8, signals for 12 pitches (C8, C#8, D8, D#8, E8, F8, F#8, G8, G#8, A8, A#8, B) are extracted from the audio signal for the octave 8.
A log spectrum showing signal intensities (hereinafter, energies) of 12 pitches in each octave can be obtained by the signals output from each band pass filter bank 156.
Referring to the vertical axis (pitch) of
(2-4. Configuration Example of Music Analysis Unit 108)
Next, the configuration of the music analysis unit 108 will be described. The music analysis unit 108 is means for analyzing music data by using a learning algorithm, and extracting feature quantity included in the music data. Particularly, the music analysis unit 108 extracts the beats, the chord progression and each of the instrument sounds included in the music data. Therefore, the music analysis unit 108 includes the beat detection unit 132, the chord progression detection unit 134, and the instrument sound analysis unit 136 as shown in
The flow of processing by the music analysis unit 108 is as shown in
All the four sound sources (left-channel sound, right-channel sound, centre sound and background sound) are used as the sound sources to be combined. The combination may be, for example, (1) all the four sound sources, (2) only the foreground sounds (left-channel sound, right-channel sound and centre sound), (3) left-channel sound+right-channel sound+background sound, or (4) centre sound+background sound. Furthermore, other combination may be, for example, (5) left-channel sound+right-channel sound, (6) only the background sound, (6) only the left-channel sound, (8) only the right-channel sound, or (9) only the centre sound. The processing within the loop started at step S106 is performed for the above-described (1) to (9), for example.
Next, the music analysis unit 108 performs instrument sound analysis processing by the instrument sound analysis unit 136 and extracts each of the instrument sounds included in the music data (S108). The type of each of the instrument sounds extracted here is vocals, a guitar sound, a bass sound, a keyboard sound, a drum sound, strings sounds or a brass sound, for example. Of course, other types of instrument sounds can also be extracted. When the instrument sound analysis processing is performed for all the combinations of the sound sources, the music analysis unit 108 ends the loop processing relating to the combinations of the sound sources (S110), and a series of processes relating to the music analysis is completed. When the series of processes is completed, the beats, the chord progression and each of the instrument sounds are input to the capture range determination unit 110 from the music analysis unit 108.
Hereunder, the configurations of the beat detection unit 132, the chord progression detection unit 134 and the instrument sound analysis unit 136 will be described in detail.
(2-4-1. Configuration Example of Beat Detection Unit 132)
First, the configuration of the beat detection unit 132 will be described. As shown in
First, the beat probability computation unit 162 will be described. The beat probability computation unit 162 computes, for each of specific time units (for example, 1 frame) of the log spectrum input from the log spectrum analysis unit 106, the probability of a beat being included in the time unit (hereinafter referred to as “beat probability”). Moreover, when the specific time unit is 1 frame, the beat probability may be considered to be the probability of each frame coinciding with a beat position (position of a beat on the time axis). A formula to be used by the beat probability computation unit 162 to compute the beat probability is generated by using the learning algorithm by the feature quantity calculation formula generation apparatus 10. Also, data such as those shown in
As shown in
Furthermore, the beat probability supplied as the teacher data indicates, for example, whether a beat is included in the centre frame of each partial log spectrum, based on the known beat positions and by using a true value (1) or a false value (0). The positions of bars are not taken into consideration here, and when the centre frame corresponds to the beat position, the beat probability is 1; and when the centre frame does not correspond to the beat position, the beat probability is 0. In the example shown in
Moreover, the beat probability formula used by the beat probability computation unit 162 may be generated by another learning algorithm. However, it should be noted that, generally, the log spectrum includes a variety of parameters, such as a spectrum of drums, an occurrence of a spectrum due to utterance, and a change in a spectrum due to change of chord. In case of a spectrum of drums, it is highly probable that the time point of beating the drum is the beat position. On the other hand, in case of a spectrum of voice, it is highly probable that the beginning time point of utterance is the beat position. To compute the beat probability with high accuracy by collectively using the variety of parameters, it is suitable to use the feature quantity calculation formula generation apparatus 10 or the learning algorithm disclosed in JP-A-2008-123011. The beat probability computed by the beat probability computation unit 162 in the above-described manner is input to the beat analysis unit 164.
The beat analysis unit 164 determines the beat position based on the beat probability of each frame input from the beat probability computation unit 162. As shown in
The onset detection unit 172 detects onsets included in the audio signal based on the beat probability input from the beat probability computation unit 162. The onset here means a time point in an audio signal at which a sound is produced. More specifically, a point at which the beat probability is above a specific threshold value and takes a maximal value is referred to as the onset. For example, in
Here, referring to
With the onset detection process by the onset detection unit 172 as described above, a list of the positions of the onsets included in the audio signal (a list of times or frame numbers of respective onsets) is generated. Also, with the above-described onset detection process, positions of onsets as shown in
The beat score calculation unit 174 calculates, for each onset detected by the onset detection unit 172, a beat score indicating the degree of correspondence to a beat among beats forming a series of beats with a constant tempo (or a constant beat interval).
First, the beat score calculation unit 174 sets a focused onset as shown in
Here, referring to
As shown in
With the beat score calculation process by the beat score calculation unit 174 as described above, the beat score BS(k,d) across a plurality of the shift amounts d is output for every onset detected by the onset detection unit 172. A beat score distribution chart as shown in
The beat search unit 176 searches for a path of onset positions showing a likely tempo fluctuation, based on the beat scores computed by the beat score calculation unit 174. A Viterbi search algorithm based on hidden Markov model may be used as the path search method by the beat search unit 176, for example. For the Viterbi search by the beat search unit 176, the onset number is set as the unit for the time axis (horizontal axis) and the shift amount used at the time of beat score computation is set as the observation sequence (vertical axis) as schematically shown in
With regard to the node as described, the beat search unit 176 sequentially selects, along the time axis, any of the nodes, and evaluates a path formed from a series of the selected nodes. At this time, in the node selection, the beat search unit 176 is allowed to skip onsets. For example, in the example of
For example, for the evaluation of a path, four evaluation values may be used, namely (1) beat score, (2) tempo change score, (3) onset movement score, and (4) penalty for skipping. Among these, (1) beat score is the beat score calculated by the beat score calculation unit 174 for each node. On the other hand, (2) tempo change score, (3) onset movement score and (4) penalty for skipping are given to a transition between nodes. Among the evaluation values to be given to a transition between nodes, (2) tempo change score is an evaluation value given based on the empirical knowledge that, normally, a tempo fluctuates gradually in a music piece. Thus, a value given to the tempo change score is higher as the difference between the beat interval at a node before transition and the beat interval at a node after the transition is smaller.
Here, referring to
Next, referring to
Here, when assuming an ideal path where all the nodes on the path correspond, without fail, to the beat positions in a constant tempo, the interval between the onset positions of adjacent nodes is an integer multiple (same interval when there is no rest) of the beat interval at each node. Thus, as shown in
Next, referring to
Accordingly, in case of transition from the node N9 to the node N10, no onset is skipped. On the other hand, in case of transition from the node N9 to the node N11, the k+1st onset is skipped. Also, in case of transition from the node N9 to the node N12, the k+1st and k+2nd onsets are skipped. Thus, the penalty for skipping takes a relatively high value in case of transition from the node N9 to the node N10, an intermediate value in case of transition from the node N9 to the node N11, and a low value in case of transition from the node N9 to the node N12. As a result, at the time of the path search, a phenomenon that a larger number of onsets are skipped to thereby make the interval between the nodes constant can be prevented.
Heretofore, the four evaluation values used for the evaluation of paths searched out by the beat search unit 176 have been described. The evaluation of paths described by using
The constant tempo decision unit 178 decides whether the optimum path determined by the beat search unit 176 indicates a constant tempo with low variance of beat intervals that are assumed for respective nodes. First, the constant tempo decision unit 178 calculates the variance for a group of beat intervals at nodes included in the optimum path input from the beat search unit 176. Then, when the computed variance is less than a specific threshold value given in advance, the constant tempo decision unit 178 decides that the tempo is constant; and when the computed variance is more than the specific threshold value, the constant tempo decision unit 178 decides that the tempo is not constant. For example, the tempo is decided by the constant tempo decision unit 178 as shown in
For example, in the example shown in
When the optimum path extracted by the beat search unit 176 is decided by the constant tempo decision unit 178 to indicate a constant tempo, the beat re-search unit 180 for constant tempo re-executes the path search, limiting the nodes which are the subjects of the search to those only around the most frequently appearing beat intervals. For example, the beat re-search unit 180 for constant tempo executes a re-search process for a path by a method illustrated in
For example, it is assumed that the mode of the beat intervals at the nodes included in the path determined to be the optimum path by the beat search unit 176 is d4, and that the tempo for the path is decided to be constant by the constant tempo decision unit 178. In this case, the beat re-search unit 180 for constant tempo searches again for a path with only the nodes for which the beat interval d satisfies d4−Th2≦d≦d4+Th2 (Th2 is a specific threshold value) as the subjects of the search. In the example of
Moreover, the flow of the re-search process for a path by the beat re-search unit 180 for constant tempo is similar to the path search process by the beat search unit 176 except for the range of the nodes which are to be the subjects of the search. According to the path re-search process by the beat re-search unit 180 for constant tempo as described above, errors relating to the beat positions which might partially occur in a result of the path search can be reduced with respect to a music piece with a constant tempo. The optimum path redetermined by the beat re-search unit 180 for constant tempo is input to the beat determination unit 182.
The beat determination unit 182 determines the beat positions included in the audio signal, based on the optimum path determined by the beat search unit 176 or the optimum path redetermined by the beat re-search unit 180 for constant tempo as well as on the beat interval at each node included in the path. For example, the beat determination unit 182 determines the beat position by a method as shown in
With respect to such onsets, first, the beat determination unit 182 takes the positions of the onsets included in the optimum path as the beat positions of the music piece. Then, the beat determination unit 182 furnishes supplementary beats between adjacent onsets included in the optimum path according to the beat interval at each onset. At this time, the beat determination unit 182 first determines the number of supplementary beats to furnish the beats between onsets adjacent to each other on the optimum path. For example, as shown in
Here, Round ( . . . ) indicates that “ . . . ” is rounded off to the nearest whole number. According to the above equation (8), the number of supplementary beats to be furnished by the beat determination unit 182 will be a number obtained by rounding off, to the nearest whole number, the value obtained by dividing the interval between adjacent onsets by the beat interval, and then subtracting 1 from the obtained whole number in consideration of the fencepost problem.
Next, the beat determination unit 182 furnishes the supplementary beats, by the determined number of beats, between onsets adjacent to each other on the optimum path so that the beats are arranged at an equal interval. In
The tempo revision unit 184 revises the tempo indicated by the beat positions determined by the beat determination unit 182. The tempo before revision is possibly a constant multiple of the original tempo of the music piece, such as 2 times, ½ times, 3/2 times, ⅔ times or the like (refer to
On the other hand, with pattern (C-1), 3 beats are included in the same time range. That is, the beat positions of pattern (C-1) indicate a ½-time tempo with the beat positions of pattern (A) as the reference. Also, with pattern (C-2), as with pattern (C-1), 3 beats are included in the same time range, and thus a ½-time tempo is indicated with the beat positions of pattern (A) as the reference. However, pattern (C-1) and pattern (C-2) differ from each other by the beat positions which will be left to remain at the time of changing the tempo from the reference tempo. The revision of tempo by the tempo revision unit 184 is performed by the following procedures (S1) to (S3), for example.
(S1) Determination of Estimated Tempo estimated based on Waveform
(S2) Determination of Optimum Basic Multiplier among a Plurality of Multipliers
(S3) Repetition of (S2) until Basic Multiplier is 1
First, explanation will be made on (S1) Determination of Estimated Tempo estimated based on waveform. The tempo revision unit 184 determines an estimated tempo which is estimated to be adequate from the sound features appearing in the waveform of the audio signal. For example, the feature quantity calculation formula generation apparatus 10 or a calculation formula for estimated tempo discrimination (an estimated tempo discrimination formula) generated by the learning algorithm disclosed in JP-A-2008-123011 are used for the determination of the estimated tempo. For example, as shown in
Next, explanation will be made on (2) Determination of Optimum Basic Multiplier among a Plurality of Multiplier. The tempo revision unit 184 determines a basic multiplier, among a plurality of basic multipliers, according to which a revised tempo is closest to the original tempo of a music piece. Here, the basic multiplier is a multiplier which is a basic unit of a constant ratio used for the revision of tempo. For example, any of seven types of multipliers, i.e. ⅓, ½, ⅔, 1, 3/2, 2 and 3 is used as the basic multiplier. However, the application range of the present embodiment is not limited to these examples, and the basic multiplier may be any of five types of multipliers, i.e. ⅓, ½, 1, 2 and 3, for example. To determine the optimum basic multiplier, the tempo revision unit 184 first calculates an average beat probability after revising the beat positions by each basic multiplier. However, in case of the basic multiplier being 1, an average beat probability is calculated for a case where the beat positions are not revised. For example, the average beat probability is computed for each basic multiplier by the tempo revision unit 184 by a method as shown in
In
As described using patterns (C-1) and (C-2) of
After calculating the average beat probability for each basic multiplier, the tempo revision unit 184 computes, based on the estimated tempo and the average beat probability, the likelihood of the revised tempo for each basic multiplier (hereinafter, a tempo likelihood). The tempo likelihood can be expressed by the product of a tempo probability shown by a Gaussian distribution centring around the estimated tempo and the average beat probability. For example, the tempo likelihood as shown in
The average beat probabilities computed by the tempo revision unit 184 for the respective multipliers are shown in
In this manner, by taking the tempo probability which can be obtained from the estimated tempo into account in the determination of a likely tempo, an appropriate tempo can be accurately determined among the candidates, which are tempos in constant multiple relationships and which are hard to discriminate from each other based on the local waveforms of the sound. When the tempo is revised in this manner, the tempo revision unit 184 performs (S3) Repetition of (S2) until Basic Multiplier is 1. Specifically, the calculation of the average beat probability and the computation of the tempo likelihood for each basic multiplier are repeated by the tempo revision unit 184 until the basic multiplier producing the highest tempo likelihood is 1. As a result, even if the tempo before the revision by the tempo revision unit 184 is ¼ times, ⅙ times, 4 times, 6 times or the like of the original tempo of the music piece, the tempo can be revised by an appropriate multiplier for revision obtained by a combination of the basic multipliers (for example, ½ times×½ times=¼ times).
Here, referring to
Then, when the loop is over for all the basic multipliers (S1452), the tempo revision unit 184 determines the basic multiplier producing the highest tempo likelihood (S1454). Then, the tempo revision unit 184 decides whether the basic multiplier producing the highest tempo likelihood is 1 (S1456). If the basic multiplier producing the highest tempo likelihood is 1, the tempo revision unit 184 ends the revision process. On the other hand, when the basic multiplier producing, the highest tempo likelihood is not 1, the tempo revision unit 184 returns to the process of step S1444. Thereby, a revision of tempo according to any of the basic multipliers is again conducted based on the tempo (beat positions) revised according to the basic multiplier producing the highest tempo likelihood.
Heretofore, the configuration of the beat detection unit 132 has been described. With the above-described processing, a detection result for the beat positions as shown in
(2-4-2. Configuration Example of Chord Progression Detection Unit 134)
Next, the configuration of the chord progression detection unit 134 will be described. The chord progression detection unit 134 is means for detecting the chord progression of music data based on a learning algorithm. As shown in
(Structure Analysis Unit 202)
First, the structure analysis unit 202 will be described. As shown in FIG. 32, the structure analysis unit 202 is input with a log spectrum from the log spectrum analysis unit 106 and beat positions from the beat analysis unit 164. The structure analysis unit 202 calculates similarity probability of sound between beat sections included in the audio signal, based on the log spectrum and the beat positions. As shown in
The beat section feature quantity calculation unit 222 calculates, with respect to each beat detected by the beat analysis unit 164, a beat section feature quantity representing the feature of a partial log spectrum of a beat section from the beat to the next beat. Here, referring to
The beat section feature quantity calculation unit 222 calculates the beat section feature quantity by methods as shown in
Next, reference will be made to
The values of weights W1, W2, . . . , Wn for respective octaves used for weighting and summing are preferably larger in the midrange where melody or chord of a common music piece is distinct. This configuration enables the analysis of a music piece structure, reflecting more clearly the feature of the melody or chord.
The correlation calculation unit 224 calculates, for all the pairs of the beat sections included in the audio signal, the correlation coefficients between the beat sections by using the beat section feature quantity (energies-of-respective-12-notes for each beat section) input from the beat section feature quantity calculation unit 222. For example, the correlation calculation unit 224 calculates the correlation coefficients by a method as shown in
For example, to calculate the correlation coefficient between the two focused beat sections, the correlation calculation unit 222 first obtains the energies-of-respective-12-notes of the first focused beat section BDi and the preceding and following N sections (also referred to as “2N+1 sections”) (in the example of
The similarity probability generation unit 226 converts the correlation coefficients between the beat sections input from the correlation calculation unit 224 to similarity probabilities by using a conversion curve generated in advance. The similarity probabilities indicate the degree of similarity between the sound contents of the beat sections. A conversion curve used at the time of converting the correlation coefficient to the similarity probability is as shown in
Two probability distributions obtained in advance are shown in
The similarity probability which has been converted can be visualized as
Moreover, in the present embodiment, since the time averages of the energies in a beat section are used for the calculation of the beat section feature quantity, information relating a temporal change in the log spectrum in the beat section is not taken into consideration for the analysis of a music piece structure by the structure analysis unit 202. That is, even if the same melody is played in two beat sections, being temporally shifted from each other (due to the arrangement by a player, for example), the played contents are decided to be the same as long as the shift occurs only within a beat section.
(Chord Probability Detection Unit 204)
Next, the chord probability detection unit 204 will be described. The chord probability detection unit 204 computes a probability (hereinafter, chord probability) of each chord being played in the beat section of each beat detected by the beat analysis unit 164. As described above, the chord probability computed by the chord probability detection unit 204 is used, as shown in
As described above, the information on the beat positions detected by the beat detection unit 132 and the log spectrum are input to the chord probability detection unit 204. Thus, the beat section feature quantity calculation unit 232 calculates energies-of-respective-12-notes as beat section feature quantity representing the feature of the audio signal in a beat section, with respect to each beat detected by the beat analysis unit 164. The beat section feature quantity calculation unit 232 calculates the energies-of-respective-12-notes as the beat section feature quantity, and inputs the same to the root feature quantity preparation unit 234. The root feature quantity preparation unit 234 generates root feature quantity to be used for the computation of the chord probability for each beat section based on the energies-of-respective-12-notes input from the beat section feature quantity calculation unit 232. For example, the root feature quantity preparation unit 234 generates the root feature quantity by methods shown in
First, the root feature quantity preparation unit 234 extracts, for a focused beat section BDi, the energies-of-respective-12-notes of the focused beat section BDi and the preceding and following N sections (refer to
The root feature quantity preparation unit 234 performs the root feature quantity generation process as described above for all the beat sections, and prepares a root feature quantity used for the computation of the chord probability for each section. Moreover, in the examples of
For example, the chord probability calculation unit 236 generates the chord probability formula to be used for the calculation of the chord probability by a method shown in
First, a plurality of root feature quantities (for example, 12×5×12-dimensional vectors described by using
By performing the logistic regression analysis for a sufficient number of the root feature quantities, each for a beat section, by using the independent variables and the dummy data as described above, chord probability formulae for computing the chord probabilities from the root feature quantity for each beat section are generated. Then, the chord probability calculation unit 236 applies the root feature quantities input from the root feature quantity preparation unit 234 to the generated chord probability formulae, and sequentially computes the chord probabilities for respective types of chords for each beat section. The chord probability calculation process by the chord probability calculation unit 236 is performed by a method as shown in
For example, the chord probability calculation unit 236 applies the chord probability formula for a major chord to the root feature quantity with the note C as the root, and calculates a chord probability CPC of the chord being “C” for each beat section. Furthermore, the chord probability calculation unit 236 applies the chord probability formula for a minor chord to the root feature quantity with the note C as the root, and calculates a chord probability CPCm of the chord being “Cm” for the beat section. In a similar manner, the chord probability calculation unit 236 applies the chord probability formula for a major chord and the chord probability formula for a minor chord to the root feature quantity with the note C# as the root, and can calculate a chord probability CPC# for the chord “C#” and a chord probability CPC#m for the chord “C#m” (B). A chord probability CPB for the chord “B” and a chord probability CPBm for the chord “Bm” are calculated in the same manner (C).
The chord probability as shown in
The chord probability is computed by the chord probability detection unit 204 by the processes by the beat section feature quantity calculation unit 232, the root feature quantity preparation unit 234 and the chord probability calculation unit 236 as described above. Then, the chord probability computed by the chord probability detection unit 204 is input to the key detection unit 206 (refer to
(Key Detection Unit 206)
Next, the configuration of the key detection unit 206 will be described. As described above, the chord probability computed by the chord probability detection unit 204 is input to the key detection unit 206. The key detection unit 206 is means for detecting the key (tonality/basic scale) for each beat section by using the chord probability computed by the chord probability detection unit 204 for each beat section. As shown in
First, the chord probability is input to the relative chord probability generation unit 238 by the chord probability detection unit 204. The relative chord probability generation unit 238 generates a relative chord probability used for the computation of the key probability for each beat section, from the chord probability for each beat section that is input from the chord probability detection unit 204. For example, the relative chord probability generation unit 238 generates the relative chord probability by a method as shown in
Next, the relative chord probability generation unit 238 shifts, by a specific number, the element positions of the 12 notes of the extracted chord probability values for the major chord and the minor chord. By shifting in this manner, 11 separate relative chord probabilities are generated. Moreover, the number of shifts by which the element positions are shifted is the same as the number of shifts at the time of generation of the root feature quantities as described using
The feature quantity preparation unit 240 generates a feature quantity to be used for the computation of the key probability for each beat section. A chord appearance score and a chord transition appearance score for each beat section that are generated from the relative chord probability input to the feature quantity preparation unit 240 from the relative chord probability generation unit 238 are used as the feature quantity to be generated by the feature quantity preparation unit 240.
First, the feature quantity preparation unit 240 generates the chord appearance score for each beat section by a method as shown in
Next, the feature quantity preparation unit 240 generates the chord transition appearance score for each beat section by a method as shown in
[Equation 9]
CTC→C#(i)=CPC(i−M)·CPC#(i−M+1)+ . . . +CPC(i+M)·CPC#(i+M+1) (10)
In this manner, the feature quantity preparation unit 240 performs the above-described 24×24 separate calculations for the chord transition appearance score CT for each case assuming one of the 12 notes from the note C to the note B to be the key. According to this calculation, 12 separate chord transition appearance scores are obtained for one focused beat section. Moreover, unlike the chord which is apt to change for each bar, for example, the key of a music piece remains unchanged, in many cases, for a longer period. Thus, the value of M defining the range of relative chord probabilities to be used for the computation of the chord appearance score or the chord transition appearance score is suitably a value which may include a number of bars such as several tens of beats, for example. The feature quantity preparation unit 240 inputs, as the feature quantity for calculating the key probability, the 24-dimensional chord appearance score CE and the 24×24-dimensional chord transition appearance score that are calculated for each beat section to the key probability calculation unit 242.
The key probability calculation unit 242 computes, for each beat section, the key probability indicating the probability of each key being played, by using the chord appearance score and the chord transition appearance score input from the feature quantity preparation unit 240. “Each key” means a key distinguished based on, for example, the 12 notes (C, C#, D, . . . ) or the tonality (major/minor). For example, a key probability formula learnt in advance by the logistic regression analysis is used for the calculation of the key probability. For example, the key probability calculation unit 242 generates the key probability formula to be used for the calculation of the key probability by a method as shown in
As shown in
By performing the logistic regression analysis by using a sufficient number of pairs of the independent variable and the dummy data, the key probability formula for computing the probability of the major key or the minor key from a pair of the chord appearance score and the chord progression appearance score for each beat section is generated. The key probability calculation unit 242 applies a pair of the chord appearance score and the chord progression appearance score input from the feature quantity preparation unit 240 to each of the key probability formulae, and sequentially computes the key probabilities for respective keys for each beat section. For example, the key probability is calculated by a method as shown in
For example, in
By such calculations, a key probability as shown in
Here, the key probability calculation unit 242 calculates a key probability (simple key probability), which does not distinguish between major and minor, from the key probabilities values calculated for the two types of keys, i.e. major and minor, for each of 12 notes from the note C to the note B. For example, the key probability calculation unit 242 calculates the simple key probability by a method as shown in
Now, the key determination unit 246 determines a likely key progression by a path search based on the key probability of each key computed by the key probability calculation unit 242 for each beat section. The Viterbi algorithm described above is used as the method of path search by the key determination unit 246, for example. The path search for a Viterbi path is performed by a method as shown in
With regard to the node as described, the key determination unit 246 sequentially selects, along the time axis, any of the nodes, and evaluates a path formed from a series of selected nodes by using two evaluation values, (1) key probability and (2) key transition probability. Moreover, skipping of beat is not allowed at the time of selection of a node by the key determination unit 246. Here, (1) key probability to be used for the evaluation is the key probability that is computed by the key probability calculation unit 242. The key probability is given to each of the node shown in
Twelve separate values in accordance with the modulation amounts for a transition are defined as the key transition probability for each of the four patterns of key transitions: from major to major, from major to minor, from minor to major, and from minor to minor.
The key determination unit 246 sequentially multiplies with each other (1) key probability of each node included in a path and (2) key transition probability given to a transition between nodes, with respect to each path representing the key progression. Then, the key determination unit 246 determines the path for which the multiplication result as the path evaluation value is the largest as the optimum path representing a likely key progression. For example, a key progression as shown in
(Bar Detection Unit 208)
Next, the bar detection unit 208 will be described. The similarity probability computed by the structure analysis unit 202, the beat probability computed by the beat detection unit 132, the key probability and the key progression computed by the key detection unit 206, and the chord probability detected by the chord probability detection unit 204 are input to the bar detection unit 208. The bar detection unit 208 determines a bar progression indicating to which ordinal in which meter each beat in a series of beats corresponds, based on the beat probability, the similarity probability between beat sections, the chord probability for each beat section, the key progression and the key probability for each beat section. As shown in
The first feature quantity extraction unit 252 extracts, for each beat section, a first feature quantity in accordance with the chord probabilities and the key probabilities for the beat section and the preceding and following L sections as the feature quantity used for the calculation of a bar probability described later. For example, the first feature quantity extraction unit 252 extracts the first feature quantity by a method as shown in
(1) No-Chord-Change Score
First, the no-chord-change score will be described. The no-chord-change score is a feature quantity representing the degree of a chord of a music piece not changing over a specific range of sections. The no-chord-change score is obtained by dividing a chord stability score described next by a chord instability score (refer to
For example, by adding up the products of the chord probabilities of the chords bearing the same names among the chord probabilities for a beat section BDi−L−1 and a beat section BDi−L, a chord stability score CC(i−L) is computed. In a similar manner, by adding up the products of the chord probabilities of the chords bearing the same names among the chord probabilities for a beat section BDi+L−1 and a beat section BDi+L, a chord stability score CC(i+L) is computed. The first feature quantity extraction unit 252 performs the calculation as described for over the focused beat section BDi and the preceding and following L sections, and computes 2L+1 separate chord stability scores.
On the other hand, as shown in
After computing the beat stability score and the beat instability score, the first feature quantity extraction unit 252 computes, for the focused beat section BDi, the no-chord-change scores by dividing the chord stability score by the chord instability score for each set of 2L+1 elements. For example, let us assume that the chord stability scores CC are (CCi−L, . . . , CCi+L) and the chord instability scores CU are (CUi−L, . . . , CUi+L) for the focused beat section. BDi. In this case, the no-chord-change scores CR are (CCi−L/CUi−L, . . . , CCi+L/CUi+L). The no-chord-change score computed in this manner indicates a higher value as the change of chords within a given range around the focused beat section is less. The first feature quantity extraction unit 252 computes, in this manner, the no-chord-change score for all the beat sections included in the audio signal.
(2) Relative Chord Score
Next, the relative chord score will be described. The relative chord score is a feature quantity representing the appearance probabilities of chords across sections in a given range and the pattern thereof. The relative chord score is generated by shifting the element positions of the chord probability in accordance with the key progression input from the key detection unit 206. For example, the relative chord score is generated by a method as shown in
At this time, the first feature quantity extraction unit 252 generates, for a beat section whose key is “B,” a relative chord probability where the positions of the elements of a 24-dimensional chord probability, including major and minor, of the beat section are shifted so that the chord probability CPB comes at the beginning. Also, the first feature quantity extraction unit 252 generates, for a beat section whose key is “C#m,” a relative chord probability where the positions of the elements of a 24-dimensional chord probability, including major and minor, of the beat section are shifted so that the chord probability CPC#m comes at the beginning. The first feature quantity extraction unit 252 generates such a relative chord probability for each of the focused beat section and the preceding and following L sections, and outputs a collection of the generated relative chord probabilities ((2L+1)×24-dimensional feature quantity vector) as the relative chord score.
The first feature quantity formed from (1) no-chord-change score and (2) relative chord score described above is output from the first feature quantity extraction unit 252 to the bar probability calculation unit 256 (refer to
The second feature quantity extraction unit 254 extracts, for each beat section, a second feature quantity in accordance with the feature of change in the beat probability over the beat section and the preceding and following L sections as the feature quantity used for the calculation of a bar probability described later. For example, the second feature quantity extraction unit 254 extracts the second feature quantity by a method as shown in
For example, as shown in
The second feature quantity extracted in this manner is input to the bar probability calculation unit 256 from the second feature quantity extraction unit 254.
As described above, the first feature quantity and the second feature quantity are input to the bar probability calculation unit 256. Thus, the bar probability calculation unit 256 computes the bar probability for each beat by using the first feature quantity and the second feature quantity. The bar probability here means a collection of probabilities of respective beats being the Y-th beat in an X meter. In the subsequent explanation, each ordinal in each meter is made to be the subject of the discrimination, where each meter is any of a ¼ meter, a 2/4 meter, a ¾ meter and a 4/4 meter, for example. In this case, there are 10 separate sets of X and Y, namely, (1, 1), (2, 1), (2, 2), (3, 1), (3, 2), (3, 3), (4, 1), (4, 2), (4, 3), and (4, 4). Accordingly, 10 types of bar probabilities are computed.
Moreover, the probability values computed by the bar probability calculation unit 256 are corrected by the bar probability correction unit 258 described later taking into account the structure of the music piece. Accordingly, the probability values computed by the bar probability calculation unit 256 are intermediary data yet to be corrected. A bar probability formula learnt in advance by a logistic regression analysis is used for the computation of the bar probability by the bar probability calculation unit 256, for example. For example, a bar probability formula used for the calculation of the bar probability is generated by a method as shown in
First, a plurality of pairs of the first feature quantity and the second feature quantity which are extracted by analyzing the audio signal and whose correct meters (X) and correct ordinals of beats (Y) are known are provided as independent variables for the logistic regression analysis. Next, dummy data for predicting, the generation probability for each of the provided pairs of the first feature quantity and the second feature quantity by the logistic regression analysis is provided. For example, when learning a formula for discriminating a first beat in a ¼ meter to compute the probability of a beat being the first beat in a ¼ meter, the value of the dummy data will be a true value (1) if the known meter and ordinal are (1, 1), and a false value (0) for any other case. Also, when learning a formula for discriminating a first beat in 2/4 meter to compute the probability of a beat being the first beat in a 2/4 meter, for example, the value of the dummy data will be a true value (1) if the known meter and ordinal are (2, 1), and a false value (0) for any other case. The same can be said for other meters and ordinals.
By performing the logistic regression analysis by using a sufficient number of pairs of the independent variable and the dummy data as described above, 10 types of bar probability formulae for computing the bar probability from a pair of the first feature quantity and the second feature quantity are obtained in advance. Then, the bar probability calculation unit 256 applies the bar probability formula to a pair of the first feature quantity and the second feature quantity input from the first feature quantity extraction unit 252 and the second feature quantity extraction unit 254, and computes the bar probabilities for respective beat sections. For example, the bar probability is computed by a method as shown in
The bar probability calculation unit 256 repeats the calculation of the bar probability for all the beats, and computes the bar probability for each beat. The bar probability computed for each beat by the bar probability calculation unit 256 is input to the bar probability correction unit 258 (refer to
The bar probability correction unit 258 corrects the bar probabilities input from the bar probability calculation unit 256, based on the similarity probabilities between beat sections input from the structure analysis unit 202. For example, let us assume that the bar probability of an i-th focused beat being a Y-th beat in an X meter, where the bar probability is yet to be corrected, is Pbar′ (i, x, y), and the similarity probability between an i-th beat section and a j-th beat section is SP(i, j). In this case, a bar probability after correction Pbar(i, x, y) is given by the following equation (11), for example.
As described above, the bar probability after correction Pbar (i, x, y) is a value obtained by weighting and summing the bar probabilities before correction by using normalized similarity probabilities as weights where the similarity probabilities are those between a beat section corresponding to a focused beat and other beat sections. By such a correction of probability values, the bar probabilities of beats of similar sound contents will have closer values compared to the bar probabilities before correction. The bar probabilities for respective beats corrected by the bar probability correction unit 258 are input to the bar determination unit 260 (refer to
The bar determination unit 260 determines a likely bar progression by a path search, based on the bar probabilities input from the bar probability correction unit 258, the bar probabilities indicating the probabilities of respective beats being a Y-th beat in an X meter. The Viterbi algorithm is used as the method of path search by the bar determination unit 260, for example. The path search is performed by the bar determination unit 260 by a method as shown in
With regard to the subject node as described, the bar determination unit 260 sequentially selects, along the time axis, any of the nodes. Then, the bar determination unit 260 evaluates a path formed from a series of selected nodes by using two evaluation values, (1) bar probability and (2) meter change probability. Moreover, at the time of the selection of nodes by the bar determination unit 260, it is preferable that restrictions described below are imposed, for example. As a first restriction, skipping of beat is prohibited. As a second restriction, transition from a meter to another meter in the middle of a bar, such as transition from any of the first to third beats in a quadruple meter or the first or second beat in a triple meter, or transition from a meter to the middle of a bar of another meter is prohibited. As a third restriction, transition whereby the ordinals are out of order, such as from the first beat to the third or fourth beat, or from the second beat to the second or fourth beat, is prohibited.
Now, (1) bar probability, among the evaluation values used for the evaluation of a path by the bar determination unit 260, is the bar probability described above that is computed by correcting the bar probability by the bar probability correction unit 258. The bar probability is given to each of the nodes shown in
For example, an example of the meter change probability is shown in
The bar determination unit 260 sequentially multiplies with each other (1) bar probability of each node included in a path and (2) meter change probability given to the transition between nodes, with respect to each path representing the bar progression. Then, the bar determination unit 260 determines the path for which the multiplication result as the path evaluation value is the largest as the maximum likelihood path representing a likely bar progression. For example, a bar progression as shown in
Now, in a common music piece, it is rare that a triple meter and a quadruple meter are present in a mixed manner for the types of beats. Taking this circumstance into account, the bar redetermination unit 262 first decides whether a triple meter and a quadruple meter are present in a mixed manner for the types of beats appearing in the bar progression input from the bar determination unit 260. In case a triple meter and a quadruple meter are present in a mixed manner for the type of beats, the bar redetermination unit 262 excludes the less frequently appearing meter from the subject of search and searches again for the maximum likelihood path representing the bar progression. According to the path re-search process by the bar redetermination unit 262 as described, recognition errors of bars (types of beats) which might partially occur in a result of the path search can be reduced.
Heretofore, the bar detection unit 208 has been described. The bar progression detected by the bar detection unit 208 is input to the chord progression estimation unit 210 (refer to
(Chord Progression Estimation Unit 210)
Next, the chord progression estimation unit 210 will be described. The simple key probability for each beat, the similarity probability between beat sections and the bar progression are input to the chord progression estimation unit 210. Thus, the chord progression estimation unit 210 determines a likely chord progression formed from a series of chords for each beat section based on these input values. As shown in
As with the beat section feature quantity calculation unit 232 of the chord probability detection unit 204, the beat section feature quantity calculation unit 272 first calculates energies-of-respective-12-notes. However, the beat section feature quantity calculation unit 272 may obtain and use the energies-of-respective-12-notes computed by the beat section feature quantity calculation unit 232 of the chord probability detection unit 204. Next, the beat section feature quantity calculation unit 272 generates an extended beat section feature quantity including the energies-of-respective-12-notes of a focused beat section and the preceding and following N sections as well as the simple key probability input from the key detection unit 206. For example, the beat section feature quantity calculation unit 272 generates the extended beat section feature quantity by a method as shown in
As shown in
The root feature quantity preparation unit 274 shifts the element positions of the extended root feature quantity input from the beat section feature quantity calculation unit 272, and generates 12 separate extended root feature quantities. For example, the root feature quantity preparation unit 274 generates the extended beat section feature quantities by a method as shown in
The root feature quantity preparation unit 274 performs the extended root feature quantity generation process as described for all the beat sections, and prepares extended root feature quantities to be used for the recalculation of the chord probability for each section. The extended root feature quantities generated by the root feature quantity preparation unit 274 are input to the chord probability calculation unit 276 (refer to
The chord probability calculation unit 276 calculates, for each beat section, a chord probability indicating the probability of each chord being played, by using the root feature quantities input from the root feature quantity preparation unit 274. “Each chord” here means each of the chords distinguished by the root (C, C#, D, . . . ), the number of constituent notes (a triad, a 7th chord, a 9th chord), the tonality (major/minor), or the like, for example. An extended chord probability formula obtained by a learning process according to a logistic regression analysis is used for the computation of the chord probability, for example. For example, the extended chord probability formula to be used for the recalculation of the chord probability by the chord probability calculation unit 276 is generated by a method as shown in
First, a plurality of extended root feature quantities (for example, 12 separate 12×6-dimensional vectors described by using
By performing the logistic regression analysis for a sufficient number of the extended root feature quantities, each for a beat section, by using the independent variables and the dummy data as described above, an extended chord probability formula for recalculating each chord probability from the root feature quantity is obtained. When the extended chord probability formula is generated, the chord probability calculation unit 276 applies the extended chord probability formula to the extended root feature quantity input from the extended root feature quantity preparation unit 274, and sequentially computes the chord probabilities for respective beat sections. For example, the chord probability calculation unit 276 recalculates the chord probability by a method as shown in
In
The chord probability calculation unit 276 repeats the recalculation process for the chord probabilities as described above for all the focused beat sections, and outputs the recalculated chord probabilities to the chord probability correction unit 278 (refer to
The chord probability correction unit 278 corrects the chord probability recalculated by the chord probability calculation unit 276, based on the similarity probabilities between beat sections input from the structure analysis unit 202. For example, let us assume that the chord probability for a chord X in an i-th focused beat section is CP′x(i), and the similarity probability between the i-th beat section and a j-th beat section is SP(i, j). Then, a chord probability after correction CP″x(i) is given by the following equation (12).
That is, the chord probability after correction CP″x(i) is a value obtained by weighting and summing the chord probabilities by using normalized similarity probabilities where each of the similarity probabilities between a beat section corresponding to a focused beat and another beat section is taken as a weight. By such a correction of probability values, the chord probabilities of beat sections with similar sound contents will have closer values compared to before correction. The chord probabilities for respective beat sections corrected by the chord probability correction unit 278 are input to the chord progression determination unit 280 (refer to
The chord progression determination unit 280 determines a likely chord progression by a path search, based on the chord probabilities for respective beat positions input from the chord probability correction unit 278. The Viterbi algorithm can be used as the method of path search by the chord progression determination unit 280, for example. The path search is performed by a method as shown in
With regard to the node as described, the chord progression determination unit 280 sequentially selects, along the time axis, any of the nodes. Then, the chord progression determination unit 280 evaluates a path formed from a series of selected nodes by using four evaluation values, (1) chord probability, (2) chord appearance probability depending on the key, (3) chord transition probability depending on the bar, and (4) chord transition probability depending on the key. Moreover, skipping of beat is not allowed at the time of selection of a node by the chord progression determination unit 280.
Among the evaluation values used for the evaluation of a path by the chord progression determination unit 280, (1) chord probability is the chord probability described above corrected by the chord probability correction unit 278. The chord probability is given to each node shown in
Furthermore, (3) chord transition probability depending on the bar is a transition probability for a chord depending on the type of a beat specified for each beat according to the bar progression input from the bar detection unit 208. The chord transition probability depending on the bar is predefined by aggregating the chord transition probabilities for a number of music pieces, for each pair of the types of adjacent beats in the bar progression of the music pieces. Generally, the probability of a chord changing at the time of change of the bar (beat after the transition is the first beat) or at the time of transition from a second beat to a third beat in a quadruple meter is higher than the probability of a chord changing at the time of other transitions. The chord transition probability depending on the bar is given to the transition between nodes. Furthermore, (4) chord transition probability depending on the key is a transition probability for a chord depending on a key specified for each beat section according to the key progression input from the key detection unit 206. The chord transition probability depending on the key is predefined by aggregating the chord transition probabilities for a large number of music pieces, for each type of key used in the music pieces. The chord transition probability depending on the key is given to the transition between nodes.
The chord progression determination unit 280 sequentially multiplies with each other the evaluation values of the above-described (1) to (4) for each node included in a path, with respect to each path representing the chord progression described by using
Heretofore, the configuration of the chord progression detection unit 134 has been described. As described above, the chord progression is detected from the music data by the processing by the structure analysis unit 202 through the chord progression estimation unit 210. The chord progression extracted in this manner is input to the capture range determination unit 110 (refer to
(2-4-3. Configuration Example of Instrument Sound Analysis Unit 136)
Next, the configuration of the instrument sound analysis unit 136 will be described. The instrument sound analysis unit 136 is means for computing presence probability of instrument sound indicating which instrument is being played at a certain timing. Moreover, the instrument sound analysis unit 136 computes the presence probability of instrument sound for each combination of the sound sources separated by the sound source separation unit 104. To estimate the presence probability of instrument sound, the instrument sound analysis unit 136 first generates calculation formulae for computing the presence probabilities of various types of instrument sounds by using the feature quantity calculation formula generation apparatus 10 (or another learning algorithm). Then, the instrument sound analysis unit 136 computes the presence probabilities of various types of instrument sounds by using the calculation formulae generated for respective types of the instrument sounds.
To generate a calculation formula for computing the presence probability of an instrument sound, the instrument sound analysis unit 136 prepares a log spectrum labeled in time series in advance. For example, the instrument sound analysis unit 136 captures partial log spectra from the labeled log spectrum in units of specific time (for example, about 1 second) as shown in
The partial log spectra in time series captured in this manner are input to the feature quantity calculation formula generation apparatus 10 as evaluation data. Furthermore, the label for each instrument sound assigned to each partial log spectrum is input to the feature quantity calculation formula generation apparatus 10 as teacher data. By providing the evaluation data and the teacher data as described, a calculation formula can be obtained which outputs, when a partial log spectrum of an arbitrary treated piece is input, whether or not each instrument sound is included in the capture section corresponding to the input partial log spectrum. Accordingly, the instrument sound analysis unit 136 inputs the partial log spectrum to calculation formulae corresponding to various types of instrument sounds while shifting the time axis little by little, and converts the output values to probability values according to a probability distribution computed at the time of learning processing by the feature quantity calculation formula generation apparatus 10. Then, by recording the probability values computed in time series, the instrument sound analysis unit 136 obtains a time series distribution of presence probability for each instrument sound. A presence probability of each instrument sound as shown in
(2-5. Configuration Example of Capture Range Determination Unit 110)
Next, the configuration of the capture range determination unit 110 will be described. As described above, the beats, the chord progression, and the presence probability of each instrument sound for the music data are input to the capture range determination unit 110 from the music analysis unit 108. Thus, the capture range determination unit 110 determines a range to be captured as a waveform material by a method as shown in
As shown in
First, the capture range determination unit 110 calculates a material score to be used for deciding whether a current bar and a current sound source combination specified in the bar loop and the sound source combination loop are appropriate for the sound material (S126). The material score is computed based on the capture request input from the capture request input unit 102 and the presence probability of each instrument sound included in the music data. More particularly, the presence probabilities of instrument sounds are totalled for a combination of instrument sounds over a number of bars specified as a capture length by the capture request, and the percentage of the total value in the total value of the presence probabilities of all the instrument sounds is computed as the material score.
For example, in case the capture request is for a rhythm loop for two bars, first, the total of the presence probabilities of a drum sound in a current bar to two bars ahead is computed (hereinafter, a total drum probability value). Furthermore, the total of the presence probabilities of all the instruments is computed for the current bar to two bars ahead (hereinafter, a total probability value). After computing these two total values, the capture range determination unit 110 computes a value by dividing the total drum probability value by the total probability value and makes the computation result the material score.
As another example, when the capture request is for an accompaniment of a guitar and strings over four bars, first, the total of the presence probabilities of the guitar sound and the strings sound is computed for the current bar to four bars ahead (hereinafter, a total guitar-strings probability value). Furthermore, the total of the presence probabilities of all the instruments is computed for the current bar to four bars ahead (hereinafter, a total probability value). After computing these two total values, the capture range determination unit 110 computes a value by dividing the total guitar-strings probability value by the total probability value and makes the computation result the material score.
When the material score is calculated in step S126, the capture range determination unit 110 proceeds to the process of step S128. In step S128, it is judged whether or not the material score computed in step S126 is a specific value or more (S128). The specific value used for the decision process in step S128 is determined in a manner depending on the “strictness for capturing” specified by the capture request input from the capture request input unit 102. When the strictness for capturing is specified to be within the range of 0.0 to 1.0, the value of the strictness for capturing can be used as it is as the above-described specific value. In this case, the capture range determination unit 110 compares the material score computed in step S126 and the value of the strictness for capturing, and when the material score is equal to or higher than the value of the strictness for capturing, the capture range determination unit 110 proceeds to the process of step S130. On the other hand, when the material score is lower than the value of the strictness for capturing, the capture range determination unit 110 proceeds to the process of step S132.
In step S130, the capture range determination unit 110 registers as the capture range a target range which is a range having a length specified by the capture request starting from the current bar (S130). When the target range is registered, the capture range determination unit 110 proceeds to the process of step S132. The type of the combination of sound sources is updated in step S132 (S132), and the processing within the sound source combination loop from step S124 to step S132 is again performed. When the processing within the sound source combination loop is over, the capture range determination unit 110 proceeds to the process of step S134. The current bar is updated in step S134 (S134), and the processing within the bar loop from step S122 to step S134 is again performed. Then, when the processing of the bar loop is over, the series of processes by the capture range determination unit 110 is completed.
When the processing by the capture range determination unit 110 is complete, information indicating the range of music data registered as the capture range is input to the waveform capturing unit 112 from the capture range determination unit 110. Then, the capture range determined by the capture range determination unit 110 is captured from the music data and is output as the waveform material by the waveform capturing unit 112.
(2-10. Hardware Configuration (Information Processing Apparatus 100))
The function of each structural element of the above-described apparatus can be realized by a hardware configuration shown in
As shown in
The CPU 902 functions as an arithmetic processing unit or a control unit, for example, and controls an entire operation of the structural elements or some of the structural elements on the basis of various programs recorded on the ROM 904, the RAM 906, the storage unit 920, or a removal recording medium 928. The ROM 904 stores, for example, a program loaded on the CPU 902 or data or the like used in an arithmetic operation. The RAM 906 temporarily or perpetually stores, for example, a program loaded on the CPU 902 or various parameters or the like arbitrarily changed in execution of the program. These structural elements are connected to each other by, for example, the host bus 908 which can perform high-speed data transmission. The host bus 908 is connected to the external bus 912 whose data transmission speed is relatively low through the bridge 910, for example.
The input unit 916 is, for example, operation means such as a mouse, a keyboard, a touch panel, a button, a switch, or a lever. The input unit 916 may be remote control means (so-called remote control) that can transmit a control signal by using an infrared ray or other radio waves. The input unit 916 includes an input control circuit or the like to transmit information input by using the above-described operation means to the CPU 902 as an input signal.
The output unit 918 is, for example, a display device such as a CRT, an LCD, a PDP, or an ELD. Also, the output unit 918 is a device such an audio output device such as a speaker or headphones, a printer, a mobile phone, or a facsimile that can visually or auditorily notify a user of acquired information. The storage unit 920 is a device to store various data, and includes, for example, a magnetic storage device such as an HDD, a semiconductor storage device, an optical storage device, or a magneto-optical storage device. Moreover, the CRT is an abbreviation for Cathode Ray Tube. Also, the LCD is an abbreviation for Liquid Crystal Display. Furthermore, the PDP is an abbreviation for Plasma Display Panel. Furthermore, the ELD is an abbreviation for Electro-Luminescence Display. Furthermore, the HDD is an abbreviation for Hard Disk Drive.
The drive 922 is a device that reads information recorded on the removal recording medium 928 such as a magnetic disk, an optical disk, a magneto-optical disk, or a semiconductor memory or writes information in the removal recording medium 928. The removal recording medium 928 is, for example, a DVD medium, a Blue-ray medium, or an HD-DVD medium. Furthermore, the removable recording medium 928 is, for example, a compact flash (CF; CompactFlash) (registered trademark), a memory stick, or an SD memory card. As a matter of course, the removal recording medium 928 may be, for example, an IC card on which a non-contact IC chip is mounted. Moreover, the SD is an abbreviation for Secure Digital. Also, the IC is an abbreviation for Integrated Circuit.
The connection port 924 is a port such as an USB port, an IEEE1394 port, a SCSI, an RS-232C port, or a port for connecting an external connection device 930 such as an optical audio terminal. The external connection device 930 is, for example, a printer, a mobile music player, a digital camera, a digital video camera, or an IC recorder. Moreover, the USB is an abbreviation for Universal Serial Bus. Also, the SCSI is an abbreviation for Small Computer System Interface.
The communication unit 926 is a communication device to be connected to a network 932. The communication unit 926 is, for example, a communication card for a wired or wireless LAN, Bluetooth (registered trademark), or WUSB, an optical communication router, an ADSL router, or various communication modems. The network 932 connected to the communication unit 926 includes a wire-connected or wirelessly connected network. The network 932 is, for example, the Internet, a home-use LAN, infrared communication, visible light communication, broadcasting, or satellite communication. Moreover, the LAN is an abbreviation for Local Area Network. Also, the WUSB is an abbreviation for Wireless USB. Furthermore, the ADSL is an abbreviation for Asymmetric Digital Subscriber Line.
(2-6. Conclusion)
Lastly, the functional configuration of the information processing apparatus of the present embodiment, and the effects obtained by the functional configuration will be briefly described.
First, the functional configuration of the information processing apparatus according to the present embodiment can be described as follows. The information processing apparatus is configured from a capture request input unit, a music analysis unit and a capture range determination unit that are described as follows. The capture request input unit is for inputting a capture request including, as information, length of a range to be captured as the sound material, types of instrument sounds and strictness for capturing. Furthermore, the music analysis unit is for analyzing an audio signal and for detecting beat positions of the audio signal and a presence probability of each instrument sound in the audio signal. In this manner, by automatically detecting the beat positions and the presence probability of each instrument sound by the process of analyzing the audio signal, a sound material can be automatically captured from the audio signal of an arbitrary music piece. Also, the capture range determination unit is for determining a capture range for the sound material so that the sound material meets the capture request input by the capture request input unit, by using the beat positions and the presence probability of each instrument sound detected by the music analysis unit. In this manner, being able to know the beat positions makes it possible to determine the capture range by the unit of range having a specific length divided by the beat positions. Furthermore, since the presence probability of each instrument sound is computed for each range, a range in which a desired instrument sound is present can be easily captured. That is, a signal of a range suitable for a desired sound material can be easily captured from an audio signal of a music piece.
Furthermore, the information processing apparatus may further include a material capturing unit for capturing the capture range determined by the capture range determination unit from the audio signal and for outputting the capture range as the sound material. By mixing the sound material captured in this manner with another known music piece while synchronizing the sound material with the beats of the known music piece, the arrangement of the known music piece can be changed, for example. Furthermore, the information processing apparatus may further include a sound source separation unit for separating, in case signals of a plurality of types of sound sources are included in the audio signal, the signal of each sound source from the audio signal. By analyzing the audio signal separated for each sound source, the presence probability of each instrument sound can be detected more accurately.
Furthermore, the music analysis unit may be configured to further detect a chord progression of the audio signal by analyzing the audio signal. In this case, the capture range determination unit determines the capture range meeting the capture request and outputs, along with information on the capture range, a chord progression in the capture range. With the information on the chord progression being provided to a user along with the information on the capture range, it becomes possible to refer to the chord progression at the time of mixing with another known music piece. Moreover, the chord progression may be output by the material capturing unit along with the audio signal of the capture range which is output as the sound material.
Furthermore, the music analysis unit may be configured to generate a calculation formula for extracting information relating to the beat positions and information relating to the presence probability of each instrument sound by using a calculation formula generation apparatus capable of automatically generating a calculation formula for extracting feature quantity of an arbitrary audio signal, and to detect the beat positions of the audio signal and the presence probability of each instrument sound in the audio signal by using the calculation formula, the calculation formula generation apparatus automatically generating the calculation formula by using a plurality of audio signals and the feature quantity of each of the audio signals. The beat positions and the presence probability of each instrument sound can be computed by using the learning algorithm or the like already described. By using a method as described, it becomes possible to automatically extract the beat positions and the presence probability of each instrument sound from an arbitrary audio signal, and automatic capturing process for the sound material as described above is realized.
Furthermore, the capture range determination unit may include a material score computation unit for totalling presence probabilities of instrument sounds of types specified by the capture request for each range of the audio signal and for computing, as a material score, a value obtained by dividing the totalled presence probability by a total of presence probabilities of all instrument sounds in the range, each range having a length of the capture range specified by the capture request. In this case, the capture range determination unit determines, as a capture range meeting the capture request, a range where the material score computed by the material score computation unit is higher than a value of the strictness for capturing. In this manner, whether a capture range is suitable for a desired sound material can be determined based on the above-described material score. Furthermore, the value of the strictness for capturing is specified so as to match with the expression form of the material score, and can be directly compared with the material score.
Furthermore, the sound source separation unit may be configured to separate a signal for foreground sound and a signal for background sound from the audio signal and to also separate from each other a centre signal localized around a centre, a left-channel signal and a right-channel signal in the signal for foreground sound. As already described, the signal for foreground sound is separated as a signal with small phase difference between the left and the right. Also, the signal for background sound is separated as a signal with large phase difference between the left and the right. Also, the centre signal is separated from the signal for foreground sound as a signal with small volume difference between the left and the right. Furthermore, the left-channel signal and the right-channel signal are each separated as a signal with large left volume or right volume.
The above-described waveform capturing unit 112 is an example of the material capturing unit. Also, the feature quantity calculation formula generation apparatus 10 is an example of the calculation formula generation apparatus. A part of the functions of the above-described capture range determination unit 110 is an example of the material score computation unit.
It should be understood by those skilled in the art that various modifications, combinations, sub-combinations and alterations may occur depending on design requirements and other factors insofar as they are within the scope of the appended claims or the equivalents thereof.
The present application contains subject matter related to that disclosed in Japanese Priority Patent Application JP 2008-310721 filed in the Japan Patent Office on Dec. 5, 2008, the entire content of which is hereby incorporated by reference.
Number | Date | Country | Kind |
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P2008-310721 | Dec 2008 | JP | national |
This is a continuation of U.S. Application Ser. No. 12/630,584, filed Dec. 3, 2009, which claims the benefit of priority based on Japanese Patent Application No. 2008-310721, filed Dec. 5, 2008, the subject matter of both of which is incorporated herein by reference.
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Child | 13186832 | US |