KR20200092501A - Method for generating synthesized speech signal, neural vocoder, and training method thereof - Google Patents

Abstract

Provided is a method for generating a synthesized speech signal by a neural vocoder to obtain a plurality of acoustic parameters including parameters related to a spectrum and parameters related to excitation, estimating an excitation signal based on the plurality of acoustic parameters, and generating a target speech signal by applying a linear synthesis filter based on at least one of the parameters related to the spectrum for the estimated excitation signal.

Description

Synthetic speech signal generation method, neural vocoder and training method of neural vocoder{METHOD FOR GENERATING SYNTHESIZED SPEECH SIGNAL, NEURAL VOCODER, AND TRAINING METHOD THEREOF}

The following description relates to a method for generating a synthesized speech signal using a neural vocoder and a training method for the neural vocoder and the neural vocoder.

Speech synthesis technology is a technology that produces synthesized sounds similar to human speech based on input data. For example, TTS (Text to Speech) converts and provides input text to human speech.

This synthesized voice is generated by a vocoder that generates a voice signal based on the input acoustic parameters. Recently, with the development of artificial intelligence and deep learning technology, neural vocoders using artificial neural networks in the generation of synthetic speech have been proposed. The neural vocoder can be trained speaker-independently or speaker-dependently using speech data from speakers, and use the results of the training to generate a synthesized speech signal for the input acoustic parameters.

However, since the voice signal has dynamic characteristics, it is difficult for an artificial neural network (eg, CNN) to fully capture the dynamic characteristics of the voice signal. In particular, spectrum distortion is likely to occur in a high frequency region of a voice signal, which may lead to a deterioration in the quality of the synthesized voice signal.

Accordingly, there is a need for a neural vocoder system that can reduce spectral distortion in the high frequency region and improve the quality of a synthesized speech signal, while also simplifying the process of training speech data.

In Korean Patent Publication No. 10-2018-0113325 (published on October 16, 2018), when a speech synthesizer synthesizes a speech waveform, the speech of the speech synthesizer can be used to modulate the speech of the synthesized sound as intended by the developer or user. A speech synthesis apparatus and method are described that provide a function for encoding a model, transforming a speech model code, and decoding a speech model to synthesize a modulated speech waveform.

The information described above is for illustrative purposes only, may include content that does not form part of the prior art, and may not include what the prior art can present to those skilled in the art.

Acquire a plurality of acoustic parameters including spectrum related parameters and excitation related parameters, estimate an excitation signal based on the plurality of acoustic parameters, and linear synthesis based on at least one of the spectrum related parameters for the estimated excitation signal By applying a filter, a method for generating a voice signal by a neural vocoder generating a target voice signal can be provided.

In one aspect, in a voice signal generation method performed by a computer-implemented neural vocoder, excitation-related parameters classified according to spectral parameters and periodicity of excitation Obtaining a plurality of acoustic parameters including, estimating an excitation signal based on the plurality of acoustic parameters and linear synthesis based on at least one of the spectrum related parameters for the estimated excitation signal A method of generating a voice signal is provided, comprising generating a target voice signal by applying a filter.

The excitation-related parameters may include a first excitation parameter indicating excitation below a predetermined cutoff frequency and a second excitation parameter indicating excitation above the cutoff frequency.

The first excitation parameter may indicate a harmonic spectrum of the excitation, and the second excitation parameter may indicate other parts of the excitation.

The spectrum-related parameters include a frequency parameter representing the pitch of the voice signal, an energy parameter representing the energy of the voice signal, a parameter indicating whether the voice signal is voiced or unvoiced, and the line spectrum frequency of the voice signal (Line Spectral). Frequency (LSF).

The generating of the target speech signal may include transforming a parameter representing the LSF into Linear Predictive Coding (LPC) and applying the linear synthesis filter based on the transformed LPC to the estimated excitation signal. It may include the steps.

The plurality of acoustic parameters may be generated by an acoustic model based on input text or input voice signals.

The neural vocoder is trained based on an input speech signal for training, and the training is an excitation signal from the input speech signal by applying a linear prediction analysis filter to the input speech signal. Separating and modeling a probability distribution of the separated excitation signal, wherein estimating the excitation signal comprises: using the probability distribution of the modeled excitation signal, for the plurality of acoustic parameters. The excitation signal can be estimated.

The step of separating the excitation signal includes: converting a parameter representing the LSF of the input speech signal into linear predictive coding (LPC); and converting the input speech signal to the input speech signal. And applying the linear predictive analysis filter based on LPC.

The separated excitation signal may be a residual component for the input voice signal.

In another aspect, in a computer-implemented method of training a neural vocoder, receiving a voice signal, including spectrum-related parameters from the input voice signal and excitation-related parameters classified according to periodicity thereof Extracting a plurality of acoustic parameters, separating the excitation signal from the input speech signal by applying a linear predictive analysis filter based on at least one of the spectrum-related parameters to the input speech signal and the separated excitation A method of training a neural vocoder is provided, comprising modeling the probability distribution of a signal.

The step of separating the excitation signal may include converting a parameter representing the LSF of the input speech signal to LPC among the spectrum-related parameters and based on the converted LPC of the input speech signal for the input speech signal. And applying the linear predictive analysis filter.

The excitation-related parameters may include a first excitation parameter indicating excitation below a predetermined cutoff frequency and a second excitation parameter indicating excitation above the cutoff frequency.

In another aspect, in a neural vocoder, a parameter acquiring unit for acquiring a plurality of acoustic parameters including excitation-related parameters classified according to a spectral parameter and a periodicity of excitation, the plurality of A target speech signal is generated by applying an excitation signal estimator for estimating an excitation signal based on acoustic parameters and a linear synthesis filter based on at least one of the spectrum-related parameters to the estimated excitation signal. A neural vocoder is provided, which includes an audio signal generator.

The speech signal generation unit includes a transform unit that converts a parameter representing the LSF of the speech signal from among the spectrum-related parameters into Linear Predictive Coding (LPC), based on the transformed LPC for the estimated excitation signal. The linear synthesis filter can be applied

The neural vocoder is trained based on an input speech signal for training, and the neural vocoder is excited from the input speech signal by applying a linear prediction analysis filter to the input speech signal. An excitation signal separation unit for separating the signal and a modeling unit for modeling a probability distribution of the separated excitation signal may be further included, and the excitation signal estimation unit may use the probability distribution of the modeled excitation signal to generate the plurality of sounds. It is possible to estimate the excitation signal for the parameters.

The excitation signal separation unit includes a conversion unit for converting a parameter representing the LSF of the input speech signal into Linear Predictive Coding (LPC), and the converted LPC of the input speech signal for the input speech signal Based on the linear prediction analysis filter can be applied.

The target voice signal is generated by the neural vocoder performing estimation using the excitation signal as a target, and applying a linear prediction filter to the estimated excitation signal, thereby improving the quality of the generated target voice signal. Spectral distortion in the high-frequency region of the signal can be reduced.

1 illustrates a method for generating a synthesized voice signal based on input text or voice signals according to an embodiment.
2 is a block diagram showing the structure of a neural vocoder system according to an embodiment.
3 is a block diagram showing the structure of a processor of a neural vocoder system according to an embodiment.
4 is a flowchart illustrating a method for generating a voice signal according to an embodiment.
5 is a flowchart illustrating a method of training a neural vocoder according to an embodiment.
6 illustrates a method of generating a synthesized speech of a target speaker by constructing a speaker adaptive model according to an embodiment.
7 is a block diagram showing the structure of a processor of a neural vocoder according to an embodiment.
8 is a flowchart illustrating a training method of a neural vocoder for constructing a speaker adaptive model according to an embodiment.
9 shows a voice signal and an excitation signal according to an example, and a relationship therebetween.
10A to 10C show statistical parametric speech synthesis (SPSS) systems for generating synthetic speech signals using different types of vocoders.
11 and 13 illustrate a method of training a neural vocoder by separating an excitation signal from an input voice signal for training according to an embodiment.
12 and 14 illustrate a method of generating a synthesized speech signal by estimating an excitation signal from acoustic parameters generated by an acoustic model based on input text according to an embodiment.
FIG. 15 is an acoustic parameter of a negative log-likelihood (NLL) obtained during a training process/generating a synthesized speech signal according to an example. It is a graph showing.
16 schematically shows a speaker-dependent characteristic and a speaker-independent characteristic of a voice signal for a voice signal from a plurality of speakers according to an example.
17 is a diagram of a synthesized speech of a target speaker using a source model constructed by training speech data sets from a plurality of speakers and a speaker adaptive model constructed by training speech data sets from a target speaker according to an example It shows how to generate.
18 and 19 show the result of comparing and evaluating the quality of the synthesized speech signal generated according to whether or not a speaker adaptation algorithm is applied according to an example.
FIG. 20 shows a result of MOS (Mean Opinion Score) (MOS) evaluation between an ExcitNet vocoder and another vocoder according to an example.
21 shows a performance change of a neural vocoder constructing a speaker adaptive model in a case where the F0 scaling factor is different according to an example

Hereinafter, embodiments of the present invention will be described in detail with reference to the accompanying drawings.

1 illustrates a method for generating a synthesized voice signal based on input text or voice signals according to an embodiment.

The voice signal may represent a voice, and in the detailed description below, for convenience of description, the terms'voice signal' and'voice' may be used interchangeably.

The acoustic model 110 may generate acoustic parameter(s) from input text or voice signals to generate a synthesized voice signal. The acoustic model 110 may be designed using a deep learning-based statistical parametric speech synthesis (SPSS) system. The acoustic model 110 may be composed of multiple feed forward and short and long term memory layers trained to represent a nonlinear mapping function between language input and sound output parameters. The acoustic model 110 may be, for example, a DNN TTS module. The acoustic parameter may be a feature used to generate a synthesized speech signal, or a parameter used to construct a feature.

The vocoder 120 may generate a synthesized voice signal by converting the acoustic parameters generated by the acoustic model 110 into a voice signal. The vocoder 120 may be a neural vocoder. Neural vocoders may be trained using deep learning models. The neural vocoder can be, for example, WaveNet, SampleRNN, or WaveRNN. Further, the neural vocoder may be a general generative model that is not limited to these.

A “neural vocoder” can be used to indicate a device that includes a model trained for the generation of a (synthetic) speech signal (eg, WaveNet, SampleRNN, WaveRNN or a generic model) and various filters.

The vocoder 120 may estimate an excitation signal of the voice signal based on the acoustic parameters obtained from the acoustic model 110. That is, the excitation signal of the voice signal may be the target of the vocoder 120.

The excitation signal is a component representing voice trembling among voice signals, and may be distinguished from a component (spectral component) representing a change in the voice signal that changes according to the mouth shape of the speaker. Changes in the excitation signal can only be limited to those caused by the vocal cord movement of the talker. The excitation signal may be a residual signal of the voice signal.

For the excitation signal estimated by the vocoder 120, a target speech signal (that is, a synthesized speech signal) is generated as a linear prediction filter generated based on an acoustic parameter representing a spectral component of the speech signal is applied. Can.

The target voice signal is generated by applying the linear prediction filter to the estimated excitation signal by targeting the excitation signal, not the voice signal, by the vocoder 120, thereby improving the quality of the generated target voice signal. , It is possible to reduce spectral distortion in the high frequency region of the audio signal.

A more specific method of generating a target voice signal through estimating the excitation signal and a more specific method of training a neural vocoder to estimate the excitation signal will be described in more detail with reference to FIGS. 2 to 5 to be described later.

2 is a block diagram showing the structure of a neural vocoder system according to an embodiment.

A more detailed configuration of the neural vocoder system 200 will be described with reference to FIG. 2. The illustrated neural vocoder system 200 may represent a computer (computer system) including a neural vocoder.

The neural vocoder system 200 may be a fixed terminal implemented as a computer system or a mobile terminal. For example, the neural vocoder system 200 includes AI speakers, smart phones, mobile phones, navigation devices, computers, notebooks, digital broadcasting terminals, PDAs (Personal Digital Assistants), PMPs (Portable Multimedia Players), tablet PCs, and game consoles. (game console), a wearable device (wearable device), an Internet of Things (IoT) device, a virtual reality (VR) device, an augmented reality (AR) device, and the like. Alternatively, the neural vocoder system 200 may be implemented as a server or other computing device that communicates with the above-described terminal through a network.

The neural vocoder system 200 may include a memory 210, a processor 220, a communication module 230, and an input/output interface 240. The memory 210 is a non-transitory computer-readable recording medium, and non-destructive large capacity such as random access memory (RAM), read only memory (ROM), disk drive, solid state drive (SSD), flash memory, etc. It may include a storage device (permanent mass storage device). Here, a non-volatile mass storage device such as a ROM, SSD, flash memory, disk drive, etc., may be included in the neural vocoder system 200 as a separate permanent storage device separate from the memory 210. In addition, the memory 210 has an operating system and at least one program code (for example, a code for an application installed in the neural vocoder system 200 for providing a browser or a specific service installed and operated in the neural vocoder system 200). ) Can be stored. These software components may be loaded from a computer-readable recording medium separate from the memory 210. Such a separate computer-readable recording medium may include a computer-readable recording medium such as a floppy drive, disk, tape, DVD/CD-ROM drive, and memory card. In other embodiments, software components may be loaded into memory 210 through communication module 230 rather than a computer-readable recording medium. For example, at least one program may be loaded into the memory 210 based on a computer program installed by files provided through a file distribution system (eg, an external server) that distributes installation files of developers or applications. Can.

The processor 220 may be configured to process instructions of a computer program by performing basic arithmetic, logic, and input/output operations. Instructions may be provided to the processor 220 by the memory 210 or the communication module 230. For example, the processor 220 may be configured to execute a received command according to program code stored in a recording device such as the memory 210.

The communication module 230 may provide a function for the neural vocoder system 200 to communicate with other electronic devices or servers through a network. The communication module 230 may be a hardware module such as a network interface card, a network interface chip, and a networking interface port of the neural vocoder system 200 or a software module such as a network device driver or a networking program.

The input/output interface 240 may be a means for interfacing with an input/output device (not shown). For example, the input device may include devices such as a keyboard, mouse, microphone, camera, and the output device may include devices such as a display, a speaker, a haptic feedback device, and the like. As another example, the input/output interface 240 may be a means for interfacing with a device in which functions for input and output are integrated into one, such as a touch screen. The input/output device may be a component of the neural vocoder system 200. When the neural vocoder system 200 is implemented as a server, the neural vocoder system 200 may not include an input/output device and an input/output interface 240.

Further, in other embodiments, the neural vocoder system 200 may include more components than the components shown. However, it is not necessary to clearly show most of the prior art components, which have been omitted.

Referring to FIG. 3, a method of generating a target voice signal through estimating an excitation signal based on more detailed configurations of the processor 220 and a method of training a neural vocoder to estimate the excitation signal will be described. .

The description of the technical features described above with reference to FIG. 1 may be applied to FIG. 2 as it is, and redundant description will be omitted.

3 is a block diagram showing the structure of a processor of a neural vocoder system according to an embodiment.

Each of the components 310 to 340 of the processor 220 to be described below may be implemented by one or more software modules and/or hardware modules. Depending on the embodiment, the components of the processor 220 may be selectively included or excluded from the processor 220. In addition, according to an embodiment, components of the processor 220 may be separated or merged to express the function of the processor 220.

The components of the processor 220 may be representations of different functions of the processor 220 performed by the processor 220 according to instructions provided by program code stored in the neural vocoder system 200. .

The parameter acquiring unit 310 of the processor 220 may acquire a plurality of acoustic parameters including spectral parameters and excitation-related parameters classified according to the periodicity of excitation. The plurality of acoustic parameters acquired by the parameter acquisition unit 310 may be generated by an acoustic model based on text input from a user or a voice signal input from a speaker.

The excitation signal estimator 320 of the processor 220 may estimate an excitation signal based on a plurality of acoustic parameters. The excitation signal estimator 320 (neural vocoder) may be trained based on an input voice signal for training. The excitation signal estimator 320 may estimate an excitation signal for a plurality of acoustic parameters using a probability distribution of an excitation signal modeled through training.

The processor 220 may include a configuration 340 for performing the training of the neural vocoder. The excitation signal separation unit 342 of the processor 220 may separate the excitation signal from the voice signal input for training by applying a linear prediction analysis filter to the voice signal input for training. . Here, the signal separation unit 342 includes a conversion unit 343 that converts a parameter representing a line spectral frequency (LSF) of the voice signal input for training into Linear Predictive Coding (LPC). can do. The linear predictive analysis filter may be generated based on the transformed LPC as being based on a parameter representing LSF. The modeling unit 344 of the processor 220 may model the probability distribution of the separated excitation signal.

The speech signal generation unit 330 of the processor 220 applies a target speech signal by applying a linear (prediction) synthesis filter based on at least one of spectrum-related parameters to the excitation signal estimated by the excitation signal estimation unit 320. Can be created. The target voice signal may be an embedded voice signal.

The speech signal generation unit 330 may include a conversion unit 332 that converts a parameter representing the LSF of the speech signal from among the acquired spectrum-related parameters into Linear Predictive Coding (LPC). The linear prediction synthesis filter may be generated based on the transformed LPC as being based on a parameter representing the LSF of a speech signal among acquired spectrum-related parameters. That is, the speech signal generator 330 may generate a target speech signal by applying a linear prediction synthesis filter based on the transformed LPC to the estimated excitation signal.

A more specific method of generating a target voice signal through estimating the excitation signal will be described in more detail with reference to the flowchart of FIG. 4 to be described later, and a more specific method of training a neural vocoder to estimate the excitation signal will be described later. It will be described in more detail with reference to the flow chart of 5.

As described above, the description of the technical features described above with reference to FIGS. 1 and 2 may be applied to FIG. 3 as it is, and redundant description will be omitted.

4 is a flowchart illustrating a method for generating a voice signal according to an embodiment.

In step 410, the parameter acquiring unit 310 may acquire a plurality of acoustic parameters including spectrum-related parameters and excitation-related parameters classified according to the periodicity of the excitation. The plurality of acoustic parameters acquired by the parameter obtaining unit 310 may be generated by an acoustic model based on text input from a user or a voice signal input from a speaker. That is, the parameter acquisition unit 310 may receive the plurality of acoustic parameters from the acoustic model.

The spectrum-related parameters may be parameters indicating a spectral component of a spectral component constituting a voice signal. Here, the related parameters may be parameters indicating a component corresponding to a residual signal (excitation signal) excluding the spectral component from the speech signal. The signal of the spectral component may represent a portion of the speech signal that changes depending on the mouth shape of the speaker. The excitation signal may represent a portion of the voice signal that indicates the tremor of the voice. Changes in the excitation signal can only be limited to those caused by the speaker's vocal movements.

The spectrum-related parameters include, for example, a frequency parameter (F0) indicating the pitch of the speech signal, an energy parameter indicating the energy of the speech signal (for example, a parameter indicating gain), a voice or unvoice of the speech signal ) May include a parameter (v/uv) indicating whether or not and a parameter indicating a line spectral frequency (LSF) of the audio signal.

The parameters related to the excitation may include parameters classified according to the periodicity of the excitation. Here, the related parameters may be, for example, Time-Frequency Trajectory Excitation (TFTE) parameters. TFTE can exhibit spectral shape of excitation along the frequency axis and evolution of this shape along the time axis. The excitation-related parameters include a first excitation parameter (SEW (Slowly Evolving Waveform) parameter) that represents a component that changes more slowly on the time-frequency axis of the excitation signal and a second that represents a component that changes faster on the time-frequency axis of the excitation signal. Here, a parameter (REW (Rapidly Evolving Waveform) parameter) may be included.

The first excitation parameter may indicate excitation below a predetermined cutoff frequency, and the second excitation parameter may indicate excitation above the cutoff frequency. The first excitation parameter may indicate a harmonic spectrum of the excitation, and the second excitation parameter may indicate other parts of the excitation. For example, a first excitation parameter (SEW parameter) corresponding to a harmonic excitation spectrum can be obtained by low-pass filtering each frequency component of the TFTE along a time domain axis (with a predetermined cutoff frequency). The residual noise spectrum exceeding a predetermined cut-off frequency is a second excitation parameter (REW parameter), which can be obtained by subtracting SEW from TFTE. By using the first excitation parameter (SEW parameter) and the second excitation parameter, the periodicity of excitation can be more effectively expressed. The first excitation parameter and the second excitation parameter may correspond to an ITFTE (Improved Time-Frequency Trajectory Excitation) parameter.

In step 420, the excitation signal estimator 320 may estimate an excitation signal based on a plurality of acoustic parameters. That is, the excitation signal estimator 320 may estimate the excitation signal as inputs of spectrum-related parameters and excitation-related parameters. The estimated excitation signal may be a time sequence of the excitation signal.

The excitation signal estimator 320 is trained based on a voice signal input for training, and the excitation signal estimator 320 uses a probability distribution of an excitation signal modeled according to training to obtain a plurality of acoustic parameters You can estimate the excitation signal for the field. The training method of the neural vocoder including the excitation signal estimator 320 will be described in more detail with reference to FIG. 5 to be described later.

The excitation signal estimator 320 may be implemented with, for example, WaveNet, SampleRNN, or WaveRNN. In addition, the excitation signal estimator 320 may be implemented as a general generative model, which is not limited to these.

In step 430, the voice signal generation unit 330 applies the linear (prediction) synthesis filter based on at least one of the spectrum-related parameters to the excitation signal estimated by the excitation signal estimation unit 320, thereby generating a target voice signal. Can generate The target voice signal may be an embedded voice signal. Step 430 will be described in more detail with reference to steps 432 and 434.

In step 432, the transform unit 332 may convert a parameter representing the LSF of the speech signal among the acquired spectrum-related parameters into linear predictive coding (LPC). The linear prediction synthesis filter is based on a parameter representing the LSF of the speech signal among the obtained spectrum-related parameters, and may be generated based on the transformed LPC.

In step 434, the speech signal generator 330 may generate a target speech signal by applying a linear prediction synthesis filter based on the LPC transformed in step 432 to the estimated excitation signal.

The target voice signal generated by the steps 410 to 430 is superior in quality to the voice signal generated by directly estimating the voice signal without estimating the excitation signal as a target, particularly in the high frequency region of the voice signal. Spectral distortion of can be reduced.

As described above, the description of the technical features described above with reference to FIGS. 1 to 3 may be applied to FIG. 4 as it is, and redundant description will be omitted.

5 is a flowchart illustrating a method of training a neural vocoder according to an embodiment.

Referring to FIG. 5, a method for modeling a probability distribution of an excitation signal capable of estimating an excitation signal based on the acquired acoustic parameters will be described in detail.

In step 510, the neural vocoder system 200 may receive a voice signal for training. The voice signal for training may be directly input from the speaker to the neural vocoder system 200, or data including the voice signal may be input from the electronic device receiving the voice signal to the neural vocoder system 200.

In step 520, the neural vocoder system 200 may extract a plurality of acoustic parameters including spectrum-related parameters and excitation-related parameters classified according to the periodicity of the excitation. The neural vocoder system 200 may extract a plurality of acoustic parameters from a voice signal through speech analysis. For example, the neural vocoder system 200 may extract a plurality of acoustic parameters from a voice signal using a parametric vocoder existing inside or outside.

The spectrum-related parameters include, for example, a frequency parameter (F0) indicating the pitch of the speech signal, an energy parameter indicating the energy of the speech signal (for example, a parameter indicating gain), a voice or unvoice of the speech signal ) May include a parameter (v/uv) indicating whether or not and a parameter indicating a line spectral frequency (LSF) of the audio signal. The parameters related to the excitation may include parameters classified according to the periodicity of the excitation. Here, the related parameters may be, for example, Time-Frequency Trajectory Excitation (TFTE) parameters. TFTE can exhibit spectral shape of excitation along the frequency axis and evolution of this shape along the time axis. The excitation related parameters may include a SEW parameter representing a component that changes more slowly on the time-frequency axis of the excitation signal and a REW parameter representing a component that changes faster on the time-frequency axis of the excitation signal. The SEW parameter may indicate excitation below a predetermined cutoff frequency, and the REW parameter may indicate excitation above the cutoff frequency. The SEW parameter may indicate a harmonic spectrum of the excitation, and the REW parameter may indicate other parts of the excitation. For example, the SEW parameter corresponding to the harmonic excitation spectrum can be obtained by low-pass filtering each frequency component of the TFTE along a time domain axis (with a predetermined cutoff frequency). Residual noise spectrum exceeding a predetermined cut-off frequency is a REW parameter and can be obtained by subtracting SEW from TFTE.

The above-described steps 510 and 520 may be performed by the processor 220 of the neural vocoder system 200 similarly to the steps 530 and 540 to be described later.

In step 530, the excitation signal separation unit 342 applies the linear prediction analysis filter based on at least one of spectrum-related parameters to the input speech signal to extract the excitation signal from the input speech signal. Can be separated. The linear predictive analysis filter may be a filter that separates a spectral formant structure from a speech signal. The separated excitation signal may be a residual component (ie, a residual signal) for the input voice signal. The excitation signal can be used to reduce the amount of information among various types of excitation models, such as pulse or noise (PoN), band aperiodic (BAP), glottal excitation, and time-frequency trajectory excitation (TFTE) models. It may be approximated by at least one.

A method of separating the excitation signal from the speech signal will be described in more detail with reference to steps 532 and 534.

In operation 532, the conversion unit 343 of the excitation signal separation unit 342 may convert a parameter representing the LSF of the input speech signal among the spectrum-related parameters to LPC. The linear predictive analysis filter is based on a parameter representing the LSF of the speech signal among the acquired spectrum-related parameters, and may be generated based on the transformed LPC.

In step 534, the excitation signal separation unit 342 may separate the excitation signal from the speech signal by applying a linear predictive analysis filter based on the LPC to the input speech signal.

In step 540, the modeling unit 344 may model the probability distribution of the separated excitation signal. The modeling unit 344 may be implemented with, for example, WaveNet, SampleRNN, or WaveRNN. In addition, the modeling unit 344 may be implemented as a general generative model, which is not limited to these.

The excitation signal estimator 320 may perform estimation of the excitation signal of step 420 described above using the probability distribution of the excitation signal modeled by the modeling unit 344.

The neural vocoder of the embodiment described above with reference to FIGS. 1 to 4 may be referred to as an ExcitNet vocoder in that it trains an excitation signal and estimates the excitation signal to generate a synthesized speech signal.

Since the change in the excitation signal can be limited only to the movement of the speaker's vocal cords, the process of training the excitation signal can be much simpler (compared to training the voice signal). In addition, by using the ITFTE parameter as a conditional feature that effectively represents the degree of periodicity of the excitation signal, the probability distribution modeling accuracy of the excitation signal can be greatly improved.

As described above, the description of the technical features described above with reference to FIGS. 1 to 4 may be applied to FIG. 5 as it is, and redundant description will be omitted.

In the following, referring to FIGS. 6 to 8, a speaker adaptive model capable of generating a synthesized voice of a high-quality target speaker with only a small amount (ie, a short time) of voice data from the target speaker is constructed, and the target Describes how to create a speaker's synthesized speech.

6 illustrates a method of generating a synthesized speech of a target speaker by constructing a speaker adaptive model according to an embodiment.

In the detailed description to be described later, the voice data set may represent a voice signal or data including a voice signal. For example, the voice data set may represent a voice signal recorded for a certain period of time from the speaker.

Source model 610 may be an acoustic model trained on speech data sets from a plurality of speakers. The source model 610 may be a speaker-independent trained acoustic model for a plurality of speakers. For example, the source model 610 may be a speaker-independent trained acoustic model, using a 1 hour voice data set from each of the 10 speakers. The source model 610 may be designed using a deep learning-based statistical parametric speech synthesis (SPSS) system. The acoustic model 110 may be, for example, a DNN TTS module.

The source model 610 trained speaker-independent through voice data sets from a plurality of speakers may be used as an initializer of the speaker adaptive model 620. In other words, weight values from the source model 610 may be set as initial values in training the speech data set from the target speaker of the speaker adaptive model 620. The weight values from the source model 610 can, for example, correspond to the acoustic parameters described above.

The speaker adaptive model 620 may be implemented using a neural vocoder. Neural vocoders may be trained using deep learning models. The neural vocoder can be, for example, WaveNet, SampleRNN, ExcitNet or WaveRNN. Further, the neural vocoder may be a general generative model that is not limited to these.

The speaker adaptation model 620 may be trained speaker-dependent for a specific speaker by applying a speaker adaptation algorithm. For example, the speaker adaptive model 620 may be trained speaker-specific for a specific target speaker (eg, celebrity, celebrity, etc.). The speaker adaptive model 620 can generate updated weight value(s) by training a set of speech data from the target speaker.

The speaker adaptive model 620 trains a set of speech data from the target speaker by using the weight values from the speaker-independently trained source model 610 as an initial value, rather than a random value, so that the relatively small size ( That is, it is possible to generate a synthesized speech (synthetic speech signal) of a high-quality target speaker only by training a short time) speech data set. For example, the speaker adaptive model 620 can generate a synthesized voice of a high-quality target speaker just by training a voice data set of the target speaker within 10 minutes.

Through an embodiment, it is possible to obtain a voice data set of about 10 minutes for a celebrity that is difficult to secure a voice data set of several hours to tens of hours or more, and use it as training data. It is possible to build a speaker adaptive model 620 that can generate.

As described above, the description of the technical features described above with reference to FIGS. 1 to 5 may be applied to FIG. 6 as it is, and redundant description will be omitted.

7 is a block diagram showing the structure of a processor of a neural vocoder according to an embodiment.

The processor 220 described with reference to FIG. 7 may correspond to the processor 220 described above with reference to FIG. 3. Each of the components 710 to 720 of the processor 220 to be described below may be implemented by one or more software modules and/or hardware modules. Depending on the embodiment, the components of the processor 220 may be selectively included or excluded from the processor 220. In addition, according to an embodiment, components of the processor 220 may be separated or merged to express the function of the processor 220. The components 710 to 720 may be representations of different functions of the processor 220 performed by the processor 220 according to an instruction provided by the program code stored in the neural vocoder system 200. .

The processor 220 may include a speaker adaptive model building unit 720. The speaker adaptive model construction unit 720 may set weight values from the source model 610 trained independently for the speech data sets from a plurality of speakers as initial values, and set initial values For, we can build a speaker adaptive model 620 that generates updated weight values by training a set of speech data from a target speaker. The updated weight values generated through the speaker adaptive model 620 may be used to generate a synthesized speech corresponding to the target speaker.

The processor 220 may further include a source model building unit 710. The source model construction unit 710 may build a source model 610 that trains voice data sets from a plurality of speakers independently of a speaker. The built source model 610 can be operated as an initializer of the model for training a set of speech data from the target speaker.

The source model building unit 710 is not included in the processor 220 and may be implemented in a separate device from the neural vocoder system 200. The speaker adaptive model building unit 720 obtains a weight value from the source model 610 built by the source model building unit 710 implemented in such a separate device to build the speaker adaptive model 620 You can train the target speaker's voice data set to do so.

As described above, the description of the technical features described above with reference to FIGS. 1 to 6 may be applied to FIG. 7 as it is, and redundant description will be omitted.

8 is a flowchart illustrating a training method of a neural vocoder for constructing a speaker adaptive model according to an embodiment.

In step 810, the source model building unit 710 may build a source model 610 for training the speaker data independently from a plurality of speakers. The plurality of speakers may be any users providing a set of voice data for training the source model 610.

In step 820, the speaker adaptive model building unit 720 may obtain weight values from the source model 610. The weight values from the source model 610 may represent values representing global characteristics that are not classified for each speaker included in speech data sets from a plurality of speakers. The global characteristic may indicate, for example, a formant characteristic or an amplitude-frequency characteristic (pattern) for a specific pronunciation (eg,'ah' or'ee'). In other words, the source model 610 can train speaker-independent global characteristics of such speech using speech data sets from multiple speakers.

In operation 830, the speaker adaptive model construction unit 720 may set weight values obtained from the source model 610 as initial values. In other words, the source model 610 may be used as an initializer of the speaker adaptive model 620 built by the speaker adaptive model building unit 720.

In step 840, the speaker adaptive model building unit 720 may generate updated weight values by training a speech data set from the target speaker with respect to the obtained initial value. In other words, the speaker adaptive model building unit 720 adapts to the target speaker (ie, is dependent on the target speaker) by training a set of speech data from the target speaker on initial values from the source model 610. An adaptive model 620 can be built.

The speaker adaptive model building unit 720 may generate updated weight values by adjusting the weight values from the source model 610 to reflect the unique characteristics of the target speaker included in the speech data set from the target speaker. have. For example, the speaker adaptive model constructing unit 720 uniquely targets the target speaker with a value indicating a global characteristic that is not classified for each speaker from the source model 610 through training a voice data set from the target speaker. By fine-tuning to include, it is possible to generate updated weight values.

The generated updated weight values can be used to generate a synthesized speech signal corresponding to the target speaker. The synthesized voice signal corresponding to the target speaker may be, for example, a synthesized voice of the celebrity corresponding to the target speaker.

Each size of the voice data sets from a plurality of speakers for training the source model 610 (i.e., the length of the recorded voice signal, e.g., 1 hour or more) is the size of the voice data set from the target speaker ( That is, the length of the recorded audio signal may be greater than, for example, 10 minutes).

The target speaker's unique characteristics can be captured from the target speaker's speech data set through a fine-tuning mechanism of the adaptation process as described in step 830. Therefore, through the method of the described embodiment, even if the voice data set for training from the target speaker is insufficient, vocoding performance may be improved.

The training method of the neural vocoder described above with reference to FIGS. 6 to 8 may be combined with the training method of the neural vocoder of the embodiment described above with reference to FIGS. 1 to 4 and the method of generating a synthesized speech signal. For example, the ExcitNet vocoder described above can be combined with the embodiments described above with reference to FIGS. 6 to 8.

In one example, a neural vocoder trained by performing steps 810 to 840 may correspond to the neural vocoder system 200 described above with reference to FIGS. 1 to 4. The target voice signal generated in step 430 may be a synthesized voice signal corresponding to the target speaker trained by the speaker adaptive model 620.

By combining the training method of the neural vocoder described above with reference to FIGS. 6 to 8 and the technical features of the ExcitNet model described above with reference to FIGS. 1 to 4, it is possible to increase the quality of the synthesized speech corresponding to the target speaker.

As described above, the description of the technical features described above with reference to FIGS. 1 to 7 may be applied to FIG. 8 as it is, and redundant description will be omitted.

9 shows a voice signal and an excitation signal according to an example, and a relationship therebetween.

As illustrated, assuming that the speech signal is S(n) and the excitation signal included in S(n) is e(n), the relationship between S(n) and e(n) is expressed by Equation 1 below. Can be expressed together.

h(n) may represent a linear prediction synthesis filter. h(n) may represent other components (ie, spectral components) except for the e(n) component of S(n). h(n) may be generated based on a parameter representing LSF of S(n).

Target by applying a linear predictive synthesis filter (i.e., h(n)) to the excitation signal (i.e., e(n)) estimated by step 420 described above with reference to FIG. 4 according to the relationship of Equation (1) An audio signal S(n) may be generated. A specific example of the linear prediction synthesis filter will be described in more detail with reference to FIG. 14.

The relationship of Equation 1 can be similarly applied to the separation of the excitation signal (ie, e(n)) of step 530 described above with reference to FIG. 5. That is, the excitation signal e(n) can be separated from the speech signal S(n) by applying a linear predictive analysis filter to the speech signal S(n) input for training. A specific example of the linear predictive analysis filter will be described in more detail with reference to FIG. 13.

As described above, the description of the technical features described above with reference to FIGS. 1 to 8 may be applied to FIG. 9 as it is, and redundant description will be omitted.

10A to 10C show statistical parametric speech synthesis (SPSS) systems for generating synthetic speech signals using different types of vocoders.

FIG. 10A is for speech synthesis including an acoustic model 1010 and an LPC synthesis module 1020 that generates a speech signal by synthesizing acoustic features (sound parameters) from the acoustic model 1010 by Linear Predictive Coding (LPC). Represents a framework. The LPC synthesis module 1020 is an LPC vocoder, and may correspond to, for example, the linear predictive synthesis filter described above.

10B shows a framework for speech synthesis including a WaveNet vocoder 1022 as a neural vocoder that estimates a speech signal based on the acoustic model 1010 and acoustic features (acoustic parameters) from the acoustic model 1010.

10C can illustrate a framework for speech synthesis using the ExcitNet vocoder 1024, as described above with reference to FIGS. 1-5. The structure illustrated in FIG. 10C may be a combination of the LPC coder 1020 of FIG. 10A and the WaveNet vocoder 1022 of FIG. 10B.

In the structure of FIG. 10C, the ExcitNet vocoder 1022 can estimate the excitation signal based on the acoustic features (acoustic parameters) from the acoustic model 1010. The estimated excitation signal may be converted as a target speech signal according to LPC (Linear Predictive Coding) synthesis through the linear prediction synthesis filter 1030.

A more detailed example of the structure of FIG. 10C is described in more detail with reference to FIGS. 12 and 14.

As described above, the description of the technical features described above with reference to FIGS. 1 to 9 may be applied to FIGS. 10A to 10C as it is, and redundant description will be omitted.

11 and 13 illustrate a method of training a neural vocoder by separating an excitation signal from an input voice signal for training according to an embodiment.

As shown in FIG. 11, for a voice signal input for training, the parametric vocoder 1110 may extract acoustic parameters. For the input speech signal, the linear prediction analysis filter 1140 generated based on the spectrum-related parameters among the extracted acoustic parameters is applied, so that the excitation signal can be separated from the input speech signal.

The WaveNet vocoder 1130 may configure and receive the extracted acoustic parameters as auxiliary features (1120). The auxiliary feature may include the above-described spectrum related parameters and excitation related parameters. The WaveNet vocoder 1130 may model the probability distribution of the excitation signal based on the auxiliary feature and the separated excitation signal. The WaveNet vocoder 1130 may also be implemented as an excitNet vocoder or a neural vocoder of other general generative models.

The structure of FIG. 11 will be described in more detail with reference to FIG. 13. The audio signals input for training may be extracted with acoustic features (acoustic parameters) according to the speech analysis 1310. Among the acoustic parameters, a parameter indicating LSF may be converted to LPC (1320). A linear predictive analysis filter 1340 may be implemented based on the transformed LPC. The linear prediction analysis filter 1340 is applied to the input speech signal, so that the excitation signal can be separated from the input speech signal. The separated excitation signal may be input to an ExcitNet model (ie, ExcitNet vocoder) 1350. Meanwhile, acoustic parameters may be configured as auxiliary features (1330), and auxiliary features may be input to the ExcitNet model (1350. ExcitNet model 1350 is input auxiliary features (ie, acoustic) Parameters) and the probability distribution of the excitation signal based on the separated excitation signal, in the illustrated example, e _n may correspond to the separated excitation signal.

12 and 14 illustrate a method of generating a synthesized speech signal by estimating an excitation signal from acoustic parameters generated by an acoustic model based on input text according to an embodiment.

As shown in FIG. 12, the acoustic model 1150 can generate acoustic parameters based on the received language parameters. The WaveNet vocoder 1170 may configure and receive acoustic parameters as auxiliary features (1160). The auxiliary feature may include the above-described spectrum related parameters and excitation related parameters. The WaveNet vocoder 1170 may estimate an excitation signal based on acoustic parameters. The WaveNet vocoder 1170 may also be implemented as an excitNet vocoder or other neural vocoder of a general generative model. A target synthesized speech may be generated by applying a linear prediction synthesis filter 1180 generated based on a spectrum-related parameter among the extracted acoustic parameters to the estimated excitation signal.

은 생성된 타겟 음성 신호에 대응할 수 있고,

은 추정된 여기 신호에 대응할 수 있다. The structure of FIG. 12 will be described in more detail with reference to FIG. 14. Language features (corresponding to the above-described language parameters) can be extracted by performing a text analysis on the input text (1410) for the generation of the synthesized speech signal. In extracting language features, a duration model 1420 for estimating phoneme duration may be further used, as illustrated. The acoustic model 1430 can generate acoustic features (acoustic parameters) from the extracted language features. Among the acoustic parameters, a parameter indicating LSF may be converted to LPC (1440). A linear prediction synthesis filter 1470 may be implemented based on the transformed LPC. The acoustic parameters may be configured as auxiliary features (1450), and the auxiliary features may be input to an ExcitNet model (ie, ExcitNet vocoder) 1460. The ExcitNet model 1460 can estimate the excitation signal based on the input auxiliary features (ie, acoustic parameters). A target speech signal may be generated by applying a linear predictive synthesis filter 1470 based on the transformed LPC to the estimated excitation signal. In the illustrated example,

Can correspond to the generated target voice signal,

Can correspond to the estimated excitation signal.

As described above, descriptions of the technical features described above with reference to FIGS. 1 to 10C may be applied to FIGS. 11 to 14 as they are, and redundant descriptions will be omitted.

FIG. 15 is an acoustic parameter of a negative log-likelihood (NLL) obtained during a training process/generating a synthesized speech signal according to an example, according to whether or not to use parameters classified according to periodicity. It is a graph showing.

In the training process, the lower the NLL, the higher the accuracy of modeling. In the illustrated graph, it can be confirmed that the NLL in the case of using the ITFTE parameters such as the above-described SEW parameter and REW parameter is lower than that in the case where it is not.

Also, in the validation process, the lower the NLL, the better the quality of the generated synthetic speech. In the graph shown, it can be confirmed that the NLL in the case of using ITFTE parameters such as SEW parameter and REW parameter is lower than that in the case where it is not.

In other words, through the illustrated graph, errors in modeling the probability distribution of the excitation signal can be greatly reduced through the use of the ITFTE parameter in training the neural vocoder, and ITFTE in the estimation of the excitation signal for the generation of synthetic speech. It can be seen that the use of parameters can significantly reduce errors in the generation of a synthesized speech signal.

As described above, the description of the technical features described above with reference to FIGS. 1 to 14 may be applied to FIG. 15 as it is, and redundant description will be omitted.

16 schematically shows a speaker-dependent characteristic and a speaker-independent characteristic of a voice signal for a voice signal from a plurality of speakers according to an example. 17 is a diagram of a synthesized speech of a target speaker using a source model constructed by training speech data sets from a plurality of speakers according to an example, and a speaker adaptive model constructed by training speech data sets from a target speaker. It shows how to create.

As shown in FIG. 16, speaker-independent features may be features common to the voices of speakers (speakers 1 to 3). In other words, speaker-independent features may represent global characteristics that are not distinguished by speaker. The speaker-dependent characteristics may represent unique characteristics for each speaker.

As shown in FIG. 17, the source model 610 can be built by training speech data sets from a plurality of speakers independently of a speaker, and based on weight values from this source model 610, from a target speaker. By training the speech data set, a speaker adaptive model 620 dependent on the target speaker can be built. The weight value from the source model 610 can be fine-tuned to reflect the unique characteristics of the target speaker as the speech data set from the target speaker is trained in the speaker adaptive model 620. As shown, the source model 610 and speaker adaptive model 620 can be implemented using an ExcitNet model. As illustrated, through the embodiment, a speaker adaptation algorithm may be applied to a neural vocoder. Although not shown, a speaker adaptation algorithm may be similarly applied to an acoustic model (eg, DNN TTS) corresponding to the source model 610.

As described above, descriptions of the technical features described above with reference to FIGS. 1 to 15 may be applied to FIGS. 16 and 17 as they are, and redundant descriptions will be omitted.

18 and 19 show the result of comparing and evaluating the quality of the synthesized speech signal generated according to whether or not a speaker adaptation algorithm is applied according to an example.

Scores in FIGS. 18 and 19 represent averages of scores evaluated by evaluators by listening to a voice signal. RAW may correspond to the original voice signal.

Referring to FIG. 18, it can be confirmed that the quality of the synthesized speech signal is high when the speaker adaptation algorithm is applied to both the WaveNet model and the ExcitNet model. That is, it can be confirmed that the case in which the synthesized speech signal is generated by constructing the speaker adaptive model 620 (with SA) as described above with reference to FIGS. 6 to 8 shows superior performance compared to the case where it is not.

19 shows a result of comparative evaluation of the quality of a more detailed synthetic speech signal. 19 will be described in more detail below.

As described above, descriptions of the technical features described above with reference to FIGS. 1 to 17 may be applied to FIGS. 18 and 19 as they are, and redundant descriptions will be omitted.

Hereinafter, the ExcitNet model described above with reference to FIGS. 1 to 5 will be described in more detail, and a comparison test result with other models will be further described.

The ExcitNet model (ExcitNet vocoder) may be a WaveNet based neural excitation model for a statistical parametric speech synthesis (SPSS) system. The WaveNet-based neural vocoding system greatly improves the recognition quality of a synthesized speech signal, but often outputs noise because it may not capture the complex time-varying characteristics of the speech signal. ExcitNet-based neural vocoding systems can be trained by separating residual components (i.e., excitation signals) using adaptive inverse filters (e.g. within the WaveNet framework) that separate spectral components from speech signals. In generating a signal, the excitation signal can be estimated as a target. Through this method, since the spectral component of the speech signal can be better represented by the deep learning framework and the residual component is efficiently generated by the WaveNet framework, the quality of the synthesized speech signal can be improved.

In the experimental results below, it was found that the excitNet-based neural vocoding system (speaker-dependent and speaker-independently trained) outperforms the existing linear predictive vocoder and WaveNet vocoder.

For the test, two speech rhythmically rich speech coppers were used to train the acoustic model and speaker-dependent (SD) ExcitNet vocoder. Each corpus was recorded by a professional Korean woman (KRF) and a Korean man (KRM). The audio signal was sampled at 24 kHz, and each sample was quantized to 16 bits. Table 1 below shows the number of ignitions of each set. To train the speaker-independent (SI) ExcitNet vocoder, a voice copper recorded by five Korean women and five Korean men was used. A total of 6,422 (10 hours) and 1,080 (1.7 hours) utterances were used for training and validation, respectively. Voice samples recorded by the same KRF and KRM speakers not included in the SI data set were used for the test.

Speaker training Verification exam KRF 3,826(7h) 270(30min) 270(30min) KRM 2,294(7h) 160(30min) 160(30min)

Tables 2 and 3 below show the distortion between the original voice and the generated voice as a result of an objective test in LSD (Log-Spectral Distance) (dB) and F0 RMSE (Root Mean Square Error) (Hz), respectively. WN denotes a WaveNet vocoder, WN-NS denotes the application of a noise-shaping method to the WaveNet vocoder, and ExcitNet denotes an ExcitNet vocoder. The area with the smallest error is shown in bold. Tables 2 and 3 may be the results measured for voiced sounds.

Speaker system SD SI 1h 3h 5h 7h KRF WN 4.21 4.19 4.18 4.13 4.18 WN-NS 4.15 4.12 4.07 4.01 4.06 ExcitNet 4.11 4.09 4.05 3.99 4.04 KRM WN 3.73 3.72 3.69 3.67 3.70 WN-NS 3.54 3.46 3.41 3.41 3.46 ExcitNet 3.53 3.46 3.41 3.40 3.45

Speaker system SD SI 1h 3h 5h 7h KRF WN 32.61 31.69 31.56 31.49 32.30 WN-NS 31.96 31.75 31.52 31.38 32.23 ExcitNet 31.44 31.43 31.37 31.29 31.88 KRM WN 12.60 12.39 12.05 12.05 13.96 WN-NS 12.32 12.16 11.97 11.97 13.34 ExcitNet 12.72 12.10 11.93 11.93 12.96

As shown in Tables 2 and 3, in most cases of SD and SI, the ExcitNet vocoder has the lowest distortion between the original voice and the generated voice. Table 4 below shows the LSD (dB) measured for unvoiced and transition regions.

Speaker system SD SI 1h 3h 5h 7h KRF WN 4.19 4.16 4.15 4.09 4.18 WN-NS 4.26 4.18 4.12 4.03 4.06 ExcitNet 4.15 4.10 4.06 3.98 4.04 KRM WN 3.95 3.96 3.92 3.92 3.70 WN-NS 4.41 3.95 3.88 3.88 3.46 ExcitNet 3.91 3.83 3.76 3.76 3.45

As shown in Table 4, in all cases of SD and SI, the ExcitNet vocoder has the lowest distortion between the original voice and the generated voice. Tables 5 and 6 below show the results (%) of the preference test as a result of the subjective test. The part with high preference from the listener is indicated in bold in the table. Compared to the rest, it can be confirmed that the recognition quality of the synthesized speech is remarkably excellent in the case of the ExcitNet vocoder. The evaluator was a listener who spoke 12 Koreans as their native language, and tests were conducted on 20 randomly selected utterances.

KRF WN WN-NS ExcitNet Neutral p-value SD 6.8 64.1 - 29.1 <10 ^-30 7.3 - 83.6 9.1 <10 ^-49 - 12.7 58.2 29.1 <10 ^-17 SI 12.7 66.8 - 20.5 <10 ^-22 8.6 - 73.6 27.7 <10 ^-35 - 19.5 38.6 41.8 <10 ^-3

KRF WN WN-NS ExcitNet Neutral p-value SD 11.8 60.5 - 27.7 <10 ^-19 17.3 - 77.7 5.0 <10 ^-24 - 16.4 73.6 10.0 <10 ^-22 SI 27.3 48.6 - 24.1 <10 ^-3 13.6 - 75.5 10.9 <10 ^-27 - 17.3 63.6 19.1 <10 ^-15

20 shows a result of an MOS (Mean Opinion Score) (MOS) evaluation between an ExcitNet vocoder and another vocoder according to an example. Evaluation of the results of analysis/synthesis (A/S), in which acoustic features are extracted from the recorded voice, and evaluation of results in SPSS when acoustic features are generated from acoustic models were made.

For S/A, the SI-ExcitNet vocoder showed similar performance to the ITFTE vocoder, but was much better than the WORLD system. In all cases, the SD-ExcitNet vocoder showed the best recognition quality (representing 4.35 and 4.47 MOS for KRF and KRM speakers, respectively). Because it is difficult to express a high-pitched female voice, MOS results for KRF speakers were worse than those of KRM speakers for SI vocoders (WORLD, ITFTE and SI-ExcitNet). On the other hand, SD-ExcitNet's results for KRF speakers are similar to those for KRM speakers, indicating that the characteristics of each speaker must be modeled to effectively express high-pitched voices. In terms of SPSS, both SD and SI-ExcitNet vocoders showed much better recognition quality than parametric ITFTE vocoders. Although the acoustic model produced overly flat speech parameters, the ExcitNet vocoder could mitigate the smoothing effect by directly estimating the time domain excitation signal. As a result, SPSS systems using SD-ExcitNet vocoder achieved 3.78 and 3.85 MOS for KRF and KRM speakers, respectively. The SI-ExcitNet vocoder achieved 2.91 and 2.89 MOS for KRF and KRM speakers, respectively.

Hereinafter, the neural vocoder for constructing the speaker adaptive model 620 described above with reference to FIGS. 6 to 8 will be described in more detail, and a comparison test result with other models will be further described. The neural vocoder of the embodiment can construct a high-quality speech synthesis system even when training data from the target speaker is insufficient, such as a speech data set of only 10 minutes.

The neural vocoder of the embodiment is a speaker-independently trained source model capable of extracting universal characteristics for a plurality of speakers in order to solve a problem of a lack of target speaker-related information caused by limited training data for a target speaker ( 610). The weight value from this source model 610 is used to initiate the training of the speaker adaptive model 620 and can be fine-tuned to indicate the unique characteristics of the target speaker. According to this adaptation process, since the deep neural network can capture the characteristics of the target speaker, the discontinuity problem occurring in the speaker-independent model can be reduced. The experimental results to be described later also show that the neural vocoder of the embodiment significantly improves the recognition quality of synthesized speech compared to the conventional method.

SD denotes a speaker-dependently trained model (without taking the weight from the source model 610 as an initial value), SI denotes a speaker-independently trained model, and SA is described above with reference to FIGS. 6 to 8. As described above, a speaker-adapted trained model (that is, a speaker-trained model using a weight from the source model 610 as an initial value) is represented.

In the SD and SA models, a voice copper recorded by a Korean female speaker was used. The audio signal was sampled at 24 kHz, and each sample was quantized to 16 bits. A total of 90 (10 minutes), 40 (5 minutes), and 130 (15 minutes) utterances were used for training, verification and testing. To train the SI model, voice data recorded by five Korean male speakers and five Korean female speakers, not included in the SD and SA model training, was used. For this, 6,422 (10 hours) and 1,080 (1.7 hours) utterances were used for training and verification, respectively. Test sets of SD and SA models were also used to evaluate SI models.

Table 7 and Table 8 below show the distortion between the original voice and the generated voice as a result of an objective test in LSD (Log-Spectral Distance) (dB) and F0 RMSE (Root Mean Square Error) (Hz), respectively. Table 7 shows the evaluation (A/S) of the results of analysis/synthesis when acoustic features extracted from the recorded voice are used directly to construct auxiliary features. Table 8 shows the evaluation of the results in SPSS. The area with the smallest error is shown in bold.

system WaveNet ExcitNet LSD F0 RMSE LSD F0 RMSE SD 3.65 38.27 2.10 19.83 SI 2.00 10.64 1.32 10.48 SA 1.79 10.70 1.12 9.66

system WaveNet ExcitNet LSD F0 RMSE LSD F0 RMSE SD 4.78 48.75 4.50 39.14 SI 4.51 35.53 4.42 36.28 SA 4.45 35.45 4.36 35.47

In Tables 7 and 8, it can be seen that in both the WaveNet vocoder and the ExcitNet vocoder, the SA case exhibits the least distortion between the original voice and the generated voice. FIG. 21 shows an F0 scaling factor according to an example It shows the performance change of the neural vocoder that builds the speaker adaptive model in the case where is different.

In order to verify the effectiveness of the training method to which the SA of the example was applied, the performance change of the neural vocoder when F0 was manually changed was investigated. It has been found that the SI model is effective in generating synthetic speech with pitch correction. The SA model also utilizes the SI model, so it can be expected to show higher performance than the SD approach.

In the test, the F0 trajectory was generated by the SPSS framework and then multiplied by scaling factors (0:6, 0:8, 1:0 and 1:2) to correct the auxiliary feature vector. The speech signal was synthesized using the neural vocode system.

21 shows F0 RMSE (Hz) test results for different F0 scaling factors. 21, it can be confirmed that the SA model includes a much smaller correction error than the existing SD model. Compared to the SI model, the SA-ExcitNet vocoder confirms that the equivalent quality is maintained even though all the weights are optimized for the characteristics of the target speaker.

In addition, it can be seen that the ExcitNet vocoder shows much better performance than the WaveNet vocoder. Since the ExcitNet vocoder trains changes in vocal cord movement (changes in the signal here), it can be seen that the F0 modified voice segment can be reconstructed more flexibly than the WaveNet-based approach.

19 shows subjective test results, and results of MOS evaluation between vocoders of SD, SI, and SA. Evaluation of the results of analysis/synthesis (A/S), in which acoustic features are extracted from the recorded voice, and evaluation of results in SPSS when acoustic features are generated from acoustic models were made.

In the result of A/S, the SD-WaveNet vocoder showed the worst result because it could not train the target speaker's characteristics with limited training data. SI-WaveNet vocoder showed similar performance to ITFTE vocoder and showed superior performance than WORLD system. It was confirmed that the utilization of SA in all WaveNet vocoders showed excellent performance. Although the results for the ExcitNet vocoder tended to be similar to that of the WaveNet vocoder, the ExcitNet vocoder showed much better performance overall by improving the modeling accuracy of the remaining signals by separating the formant components of the speech signal through the LP inverse filter. appear. As a result, SA-ExcitNet vocoder achieved 4.40 MOS in A/S results.

In the results of SPSS, both SI-WaveNet vocoder and SI-ExcitNet vocoder were found to provide better recognition quality than parametric ITFTE vocoder. As a result, it was confirmed that the SA training model of the embodiment significantly improves the quality of the synthesized speech signal compared to the existing speaker-dependent and speaker-independent methods. As in the A/S results, the ExcitNet vocoder performed better than the WaveNet vocoder in SPSS results. Although the acoustic model produced overly flat speech parameters, the ExcitNet vocoder could mitigate the smoothing effect by directly estimating the time domain excitation signal. As a result, the SPSS system with SA-ExcitNet vocoder achieved 3.77 MOS.

The device described above may be implemented with hardware components, software components, and/or combinations of hardware components and software components. For example, the devices and components described in the embodiments include a processor, controller, arithmetic logic unit (ALU), digital signal processor (micro signal processor), microcomputer, field programmable gate array (FPGA), programmable It may be implemented using one or more general purpose computers or special purpose computers, such as a logic unit, microprocessor, or any other device capable of executing and responding to instructions. The processing device may perform an operating system (OS) and one or more software applications running on the operating system. In addition, the processing device may access, store, manipulate, process, and generate data in response to the execution of the software. For convenience of understanding, a processing device may be described as one being used, but a person having ordinary skill in the art, the processing device may include a plurality of processing elements and/or a plurality of types of processing elements. It can be seen that may include. For example, the processing device may include a plurality of processors or a processor and a controller. In addition, other processing configurations, such as parallel processors, are possible.

The software may include a computer program, code, instruction, or a combination of one or more of these, and configure the processing device to operate as desired, or process independently or collectively You can command the device. Software and/or data may be embodied in any type of machine, component, physical device, computer storage medium or device in order to be interpreted by the processing device or to provide instructions or data to the processing device. have. The software may be distributed on networked computer systems, and stored or executed in a distributed manner. Software and data may be stored in one or more computer-readable recording media.

The method according to the embodiment may be implemented in the form of program instructions that can be executed through various computer means and recorded on a computer-readable medium. At this time, the medium may continue to store a program executable on a computer, or may be temporarily stored for execution or download. In addition, the medium may be various recording means or storage means in the form of a single or several hardware combinations, and is not limited to a medium directly connected to a computer system, but may be distributed on a network. Examples of the medium include magnetic media such as hard disks, floppy disks, and magnetic tapes, optical recording media such as CD-ROMs and DVDs, and magneto-optical media such as floptical disks, And program instructions including ROM, RAM, flash memory, and the like. In addition, examples of other media may include an application store for distributing applications or a recording medium or storage medium managed by a site, server, or the like that supplies or distributes various software.

As described above, although the embodiments have been described by a limited embodiment and drawings, those skilled in the art can make various modifications and variations from the above description. For example, the described techniques are performed in a different order than the described method, and/or the components of the described system, structure, device, circuit, etc. are combined or combined in a different form from the described method, or other components Alternatively, even if replaced or substituted by equivalents, appropriate results can be achieved.

Therefore, other implementations, other embodiments, and equivalents to the claims are also within the scope of the following claims.

Claims (17)

In the method for generating a voice signal performed by a neural vocoder implemented by a computer,
Obtaining a plurality of acoustic parameters including excitation-related parameters classified according to spectral parameters and periodicity of excitation;
Estimating an excitation signal based on the plurality of acoustic parameters; And
Generating a target speech signal by applying a linear synthesis filter based on at least one of the spectrum-related parameters to the estimated excitation signal.
A method of generating a voice signal, including. According to claim 1,
The excitation-related parameters include a first excitation parameter indicating excitation below a predetermined cutoff frequency and a second excitation parameter indicating excitation above the cutoff frequency. According to claim 2,
The first excitation parameter represents the harmonic spectrum of the excitation, and the second excitation parameter represents the other part of the excitation. According to claim 1,
The spectrum-related parameters,
Frequency parameter indicating the pitch of the voice signal, energy parameter indicating the energy of the voice signal, parameter indicating whether the voice signal is voiced or unvoiced, and the line spectrum frequency (LSF) of the voice signal. A method of generating a voice signal, comprising parameters. According to claim 4,
Generating the target voice signal,
Transforming a parameter representing the LSF into Linear Predictive Coding (LPC); And
Applying the linear synthesis filter based on the transformed LPC to the estimated excitation signal.
A method of generating a voice signal, including. According to claim 1,
The plurality of acoustic parameters are generated by an acoustic model (acoustic model) based on the input text or the input voice signal, the voice signal generation method. According to claim 1,
The neural vocoder is trained based on a voice signal input for training,
The training,
Separating an excitation signal from the input speech signal by applying a linear prediction analysis filter to the input speech signal; And
Modeling the probability distribution of the separated excitation signal
Including,
Estimating the excitation signal,
A method of generating a voice signal using the probability distribution of the modeled excitation signal, to estimate the excitation signal for the plurality of acoustic parameters. The method of claim 7,
Separating the excitation signal,
Transforming a parameter representing the LSF of the input speech signal into Linear Predictive Coding (LPC); And
Applying the linear predictive analysis filter based on the transformed LPC of the input speech signal to the input speech signal
A method of generating a voice signal, including. The method of claim 7,
The separated excitation signal is a residual component of the input speech signal, a method for generating a speech signal. In a computer-implemented method of training a neural vocoder,
Receiving an audio signal;
Extracting a plurality of acoustic parameters including spectrum-related parameters and excitation-related parameters classified according to the periodicity of the excitation from the input speech signal;
Separating an excitation signal from the input speech signal by applying a linear predictive analysis filter based on at least one of the spectrum-related parameters to the input speech signal; And
Modeling the probability distribution of the separated excitation signal
Including, training method of the neural vocoder. The method of claim 10,
Separating the excitation signal,
Converting a parameter representing the LSF of the input voice signal among the spectrum-related parameters into an LPC; And
Applying the linear predictive analysis filter based on the transformed LPC of the input speech signal to the input speech signal
Including, training method of the neural vocoder. The method of claim 10,
The excitation-related parameters include a first excitation parameter indicating excitation below a predetermined cutoff frequency and a second excitation parameter indicating excitation above the cutoff frequency. A non-transitory computer-readable recording medium on which a program for executing the method of any one of claims 1 to 12 is recorded on a computer. For neural vocoders,
A parameter acquiring unit for acquiring a plurality of acoustic parameters including excitation-related parameters classified according to spectral parameters and periodicity of excitation;
An excitation signal estimator estimating an excitation signal based on the plurality of acoustic parameters; And
A speech signal generator for generating a target speech signal by applying a linear synthesis filter based on at least one of the spectrum-related parameters to the estimated excitation signal
Including, neural vocoder. The method of claim 14,
The speech signal generation unit includes a conversion unit for converting a parameter representing the LSF of the speech signal among the spectrum-related parameters into Linear Predictive Coding (LPC),
A neural vocoder applying the linear synthesis filter based on the transformed LPC to the estimated excitation signal. The method of claim 14,
The neural vocoder is trained based on a voice signal input for training,
An excitation signal separating unit separating an excitation signal from the input speech signal by applying a linear prediction analysis filter to the input speech signal; And
Modeling unit for modeling the probability distribution of the separated excitation signal
Further comprising,
The excitation signal estimator estimates an excitation signal for the plurality of acoustic parameters using a probability distribution of the modeled excitation signal. The method of claim 16,
The excitation signal separation unit includes a conversion unit for converting a parameter representing the LSF of the input speech signal into Linear Predictive Coding (LPC),
A neural vocoder applying the linear prediction analysis filter based on the transformed LPC of the input speech signal to the input speech signal.

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