The invention is related to the field of speech processing, and in particular to a speech processing system utilizing speech production components, speech analysis components, noise generators, and computing differences in signal attributes, and controlling speech production arranged in a feedback configuration.
The invention provides an approach in modeling speech synthesis techniques with an analog vocal tract.
According to one aspect of the invention, there is provided a speech processing system. The speech processing system includes a plurality of signal analyzers that extract salient signal attributes of an input voice signal. A difference module computes the differences in the salient signal attributes. One or more control modules control a plurality of speech generators using an output signal from the difference module in a speech-locked loop (SLL), the speech generators use the output signal to generate a voice signal.
According to another aspect of the invention, there is provided a method of performing the operations of a speech processing system. The method includes extracting salient signal attributes of an input voice signal using a plurality of signal analyzers. Also, the method includes computing the differences in the salient signal attributes using a difference module. Moreover, the method includes controlling a plurality of speech generators using an output signal from the difference module in a speech-locked loop (SLL) using one, or more control modules. The speech generators use the output signal to generate a voice signal.
According to another aspect of the invention, there is provided a method of developing a speech processing system. The method includes providing a plurality of signal analyzers that extract salient signal attributes of an input voice signal. Also, the method includes implementing a difference module for computing the differences in the salient signal attributes. Furthermore, the method includes implementing one or more control modules for controlling a plurality of speech generators using an output signal from, the difference module in a speech-locked loop (SLL), the speech generators use the output signal to generate a voice signal.
According to another aspect of the invention, there is provided a vocal tract system. The vocal tract system includes an electronically adjustable component having an automatic gate terminal, control for controlling a plurality of devices using feedback and feedforward techniques so as to allow the electronically adjustable component to behave similarly to a linear and/or nonlinear resistor.
The invention relates to a speech processing apparatus utilizing speech production components, speech analysis components, noise generators, means to compute differences in signal attributes, and means to control speech production arranged in a feedback configuration hereinafter known as the speech-locked loop (SLL). Previous attempts to build speech apparatus based on an analysis-by-synthesis method required intensive computation and thus hard to ado in real time with low power consumption and hardware complexity.
In particular, the invention employs speech analysis, components modeled after the biological cochlea and speech production components modeled after the vocal tract. The speech production component are modeled as an analog electrical transmission line, which allows us to naturally map acoustic elements such as mass, compressibility and viscous damping, to their electrical equivalents corresponding to inductance, capacitance and resistance. Linear and non-linear constriction resistances may be modeled with a transistor circuit. Also, the speech analysis component is modeled with an analog circuit inspired by the human auditory system. An analog VLSI implementation of the speech apparatus has the following advantages—low power consumption and low hardware complexity.
The techniques used for driving the speech production component allow us to directly synthesize speech from a target sound using an analog vocal tract. By combining these techniques with the speech production and analysis components in feedback, we developed a speech processing apparatus that functions as speech-locked loop (SLL). These techniques together with our speech apparatus find applications to speech synthesis, speech recognition, speech coding, speech compression, speaker identification, language identification, voice identification, text to speech, speech restoration, noise reduction and speech prosthetics.
The concept of SLL is not limited to operating within the audio frequency range and may be extended to processing signals at frequency ranges (e.g., radio frequency) outside the audio range. In this case, the input signal is translated to the proper frequency, and the SLL is operated at the appropriate frequency. The SLL may also be configured to process arbitrary sound signals for signal transmission. In this case, SG is an arbitrary sound generator not limited to producing natural speech signals.
The speech production component is a representation of the vocal tract described herein. It is modeled using a non-uniform acoustic tube, with time-varying cross-sectional areas, that is terminated by the vocal cords at one end, and the lips and/or nose at the other. If the cross sectional dimensions of the tube are small compared to the wavelength of sound, the waves that propagate along the tube are approximately planar. The acoustic properties of such a tube are indistinguishable from that of a tube with a circular cross section. The wave equation for planar sound propagation (one dimensional) in a lossless uniform tube of circular cross section can be derived as:
where P is the pressure, U is the volume velocity, ρ is the density of the medium, c the velocity of sound in the medium and A is the area of cross section. The volume of air in a tube exhibits an acoustic inertance ρ/A due to its mass which, opposes acceleration and an acoustic compliance A/ρc2 due, to its compressibility. Note that acoustic wave propagation in a tube is analogous to plane-wave propagation along an electrical transmission line where voltage and current are analogous to pressure and volume velocity. The voltage V and current I for a lossless transmission, line can be described by the following coupled partial differential equations:
where L and C are the inductance and capacitance per unit length.
The vocal tract is approximately 17 cm in length for an average man, which is comparable to the wavelength of sound in air at audible frequencies. Hence, a lumped approximation of the major vocal tract components does not provide an accurate analysis. However, the tube may be discretized in space and the entire tube represented in terms of a concatenation of incremental cylindrical sections. The error introduced by area quantization may be kept small if the length, l, of the approximating cylindrical sections are kept short compared to the wavelength of sound corresponding to the maximum frequency of interest.
The electrical analog of a section of a lossy acoustic tube with uniform circular cross sectional area A is depicted in
The model of a glottal constriction employs a linear resistance Rlinear in series with a nonlinear resistance Rnonlinear as shown in
In the nonlinear resistance Rnonlinear, the current, Ugl is proportional to the square root of the voltage ΔP2 across its terminals. In circuit terminology, it has a square-root I-V characteristic:
An exemplary embodiment of the complete glottis consists of two glottal constrictions connected in series to represent the upper and lower part of the vocal folds. There are two glottal constrictions because the upper and lower folds abduct and adduct with a time lag between them. The opening and closing of the vocal folds are controlled by a glottal oscillator.
In
Another major component of the SLL is the speech analysis component, which is an apparatus that, analyses speech/noise signals and extracts salient characteristics of the signals. A particular embodiment of the component is a frequency analysis system such as a perceptually shaped filter bank or cochlea-like apparatus. Other components of the SLL may also be implemented using custom analog or digital VLSI, general purpose DSP or computer.
SG is an apparatus that produces speech like signals. It has a set of control parameters (driven by C) that shape'its output.
NG is an apparatus that produces non-speech (noise) signals. It has a set of control parameters (driven by C) that shape its output. An example of NG is a model of vehicle noise. A pre-recorded or real-time feed of the desired signal and/or noise can be included as additional SGs and/or NGs.
SA is an apparatus that analyses speech/noise signals and extracts salient characteristics of the signals. An example of SA is a frequency analysis system such as a perceptually shaped filter bank or cochlea-like apparatus. The extracted characteristics of the input signal and feedback signal are compared by D to produce an error signal. An example of D is an apparatus which computes L2-norm.
The output 16 of D is processed by the control module (C) to generate a control signal which drives SGs and NGs such that the error signal is eventually minimized through feedback action. In this way the output signal 20 is locked to the input signal 18. In the speech locked condition the parameters characterizing SGs and NGs are the optimal description optimal description of the input sound.
The SLL, can be operated at frequency range higher than audio range (e.g., radio frequency). The input signal 18 is mixed to the radio frequency, and SGs, SA, and NGs are also mixed to the appropriate frequency. Such an operation shortens the time required for the loop to lock.
Multiple SLLs 26, 28, 30 functioning in parallel can be used to process the input, as shown in
Different strategies may be used to set the initial condition of control modules (Cs). For example they could be learned a priori in a way that guarantees minimum error. This can be done by trying all the possible initial conditions and input signals, and finding the minimal set of initial conditions that will guarantee convergence to the global minimum by the feedback loop. As arrival at global minimum is assured, a fully parallel architecture with multiple feedback loops starting from the minimum set may be useful to speed, up the convergence process. Otherwise, one or multiple initial conditions of the minimum set are processed serially.
In order to generate an optimal control signal which drives SGs and NGs such that the error signal is eventually minimized through feedback action, a perturbation-method-based model (or other models that correlate the error signal to the control parameters) can be employed. In such an embodiment, the SAs may be MEL-filter banks whose outputs are subtracted to produce a vector representing the spectral error. The spectral error vector is used with perturbation methods to vary the control parameters in the feedback loop.
The SLL may contain feedforward paths 50, 52 from SAs to C, as shown in
For the purpose of producing turbulent air flow, VT cross-sectional areas may be appropriately perturbed with colored noise. Alternatively, turbulent air flow may be produced by a noise generator appropriately inserted in the vocal tract. In this way, it is not necessary to insert an explicit turbulent noise source in series with the transmission line at the location of the constriction.
The SLL may be used in conjunction with an automatic speech recognition apparatus, to improve recognition performance. The SLL error signal and other SLL-locked parameters may be used to this end. The SLL may also be used for the purpose of generating realistic training sequences for an automatic speech recognition apparatus.
A good feature extraction apparatus must be insensitive to features that are not relevant to the goal. For example, MEL-cepstral coefficients (MCC) are the preferred choice for automatic speech recognition because they are relatively insensitive to speech properties that are less relevant to the identification of a phoneme (e.g., formant amplitude and bandwidth, channel properties). The SLL can be used to produce a set of control parameters that is characteristic of the input signal and can be used to replace features like MCC. For example, when the SLL is locked, a good model of the input is attained. In this state, parameters that are not important to speech recognition (e.g., vocal tract length, losses, etc) are decoupled from those that are (e.g., VT areas, velum position) through the use of the SLL. In this paradigm, SA does not have to be insensitive to irrelevant speech recognition features (FFT or time-domain matching could be used instead of MCC). The concept can be extended to focusing on different sets of SA features from time to time.
The locking process can be achieved in different phases where each phase attempts to lock on a different feature provided by the SA. For, example, in one phase, the SLL attempts to lock onto the unvoiced features of the input by suppressing the voiced control parameter and employing noise to generate a whispered feedback signal for comparison with the unvoiced input features. The use of broadband noise has the advantage of speeding up the locking process because it enables continuous excitation of all system modes. The lock can also be attempted only in a defined frequency range. In another phase, the loop attempts to lock on the voiced features of the input. The concept can be extended to locking on speaker specific features of the input, e.g., VT features (length, loss, nasal coupling), subglottal features (coupling, resonances). Language and contextual specific features can also be locked.
It is common that the input signal is recorded using microphone. The source waveform can be altered by the microphone, motion and other disturbances. To remove the effect of the channel path, the SA at the input can pre-compensate for the channel behavior. Additionally, the SA in the loop can be made to compensate for the input channel behavior. This is important for signal restoration purposes e.g. to restore the high frequency components of speech in, telephone communications. Each SG and NG can also contain a model of the channel path, controlled by C, connecting each source and the input of the SLL. Such an apparatus is useful to track movement of the source.
The concept of SLL can be easily extended to multiple feedback loops corresponding too many inputs (e.g., stereo recording). In embodiment, the set of SGs and NGs in each loop contains a model, of the channel path connecting the respective source and the input of the SLL. A main controller can be employed to minimize the difference, taking into account the signal quality, between the multiple sets of control parameters. For example, in stereo-recording, corresponding SGs and NGs in the two SLLs should be driven by equivalent control signals with different channel parameters for the channel models.
A particular embodiment 58 of control module C may contain a weighted time derivative 60 of the error, a non-linear gain function 62, a weighted time integral with initial conditions for each control parameter 66, a time multiplexer 64, and a controller 68 as illustrated in
The proportionality constant GM, the transconductance of the WLR OTA, is given by:
where IGM and VL are the biasing current and input linear range of the WLR OTA respectively. Hence, GM is electronically tunable via IGM. In
The translinear circuit 100 produces, an output current Iout that is a function of Iin. By using a translinear circuit that implements an appropriate function, the MOS resistor can be configured to have linear or nonlinear characteristics. Translinear circuits 102, 104, 106 which eventually result in compressive, linear and expansive I-V characteristics for the resistor are shown in
ID=√{square root over (IrefGMVXY)} (7)
The nonlinear resistor uses the translinear circuit depicted in
The invention can extract sequence of articulatory parameters (vocalogram), sequences of subglottal parameters and sequences of noise parameters for an improved speech synthesis system, speech recognition system, speech coding system, speech compression system, speaker identification system, language identification system, voice identification system, text to speech system, speech restoration-system, noise reduction system or a speech prosthetic system.
Although the present invention has been shown and described with respect several preferred embodiments thereof, various changes, omissions and additions to the form and detail thereof, may be made therein, without departing from the spirit and scope of the invention.
This application claims priority from provisional application Ser. No. 60/955,896 filed Aug. 15, 2007, which is incorporated herein by reference in its entirety.
Number | Date | Country | |
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60955896 | Aug 2007 | US |
Number | Date | Country | |
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Parent | PCT/US08/73240 | Aug 2008 | US |
Child | 12702676 | US |