Aspects of the present invention have been disclosed by the inventors in the published paper arXiv:2204.09224, Entitled: “CONTENTVEC: An Improved Self-Supervised Speech Representation by Disentangling Speakers”, by Qian et al. and submitted on Apr. 20, 2022. The following disclosure is submitted under 35 U.S.C. §102(b)(1)(A).
The present invention relates generally to the field of speech processing and more particularly to techniques for providing self-supervised speech representations.
In recent years, self-supervised learning (SSL) has emerged as a state-of-the-art solution to many speech processing problems with relatively few annotated data. The basic idea of SSL in speech may be to train a speech representation network on large-scale unannotated corpora, with an objective to capture and elicit meaningful speech structures and information. The resulting speech representation may then be applied to the training of downstream tasks with a small amount of annotated data.
Speech SSL has demonstrated advantages in a surprisingly wide range of tasks. One of the primary foci of speech SSL may be on tasks that process the content of speech, which can include speech recognition, speech phone classification, speech content generation and the like. For these tasks, the most desirable speech representations may be the ones that can disentangle content information in speech from other interfering variations. However, this disentanglement may be difficult because removing interfering variations may cause the desirable content to also be removed. In most content related downstream tasks, the cost of losing content information far outweighs the advantage of disentangling speakers to remove interference.
Embodiments of the present invention disclose a method, computer system, and a computer program product for providing a self-supervised speech representation. In one embodiment, audio input is received including speech utterances. A label sequence is generated from these speech utterances by a teacher label generator. A speech representation is generated of a partially masked version of the speech utterance using a speech representation network. The speech utterance is passed into two random transformations that alter only speaker information prior to the partial masking. A predictor will then predict the label sequence. In one embodiment, a performance-based assessment is made on a cross-entropy loss between the generated label sequence and a predicted label sequence.
These and other objects, features and advantages of the present invention will become apparent from the following detailed description of illustrative embodiments thereof, which may be to be read in connection with the accompanying drawings. The various features of the drawings are not to scale as the illustrations are for clarity in facilitating one skilled in the art in understanding the invention in conjunction with the detailed description. In the drawings:
Detailed embodiments of the claimed structures and methods may be disclosed herein; however, it can be understood that the disclosed embodiments may be merely illustrative of the claimed structures and methods that may be embodied in various forms. This invention may, however, be embodied in many different forms and should not be construed as limited to the exemplary embodiments set forth herein. Rather, these exemplary embodiments may be provided so that this disclosure will be thorough and complete and will fully convey the scope of this invention to those skilled in the art. In the description, details of well-known features and techniques may be omitted to avoid unnecessarily obscuring the presented embodiments.
Various aspects of the present disclosure are described by narrative text, flowcharts, block diagrams of computer systems and/or block diagrams of the machine logic included in computer program product (CPP) embodiments. With respect to any flowcharts, depending upon the technology involved, the operations can be performed in a different order than what is shown in a given flowchart. For example, again depending upon the technology involved, two operations shown in successive flowchart blocks may be performed in reverse order, as a single integrated step, concurrently, or in a manner at least partially overlapping in time.
A computer program product embodiment (“CPP embodiment” or “CPP”) is a term used in the present disclosure to describe any set of one, or more, storage media (also called “mediums”) collectively included in a set of one, or more, storage devices that collectively include machine readable code corresponding to instructions and/or data for performing computer operations specified in a given CPP claim. A “storage device” is any tangible device that can retain and store instructions for use by a computer processor. Without limitation, the computer readable storage medium may be an electronic storage medium, a magnetic storage medium, an optical storage medium, an electromagnetic storage medium, a semiconductor storage medium, a mechanical storage medium, or any suitable combination of the foregoing. Some known types of storage devices that include these mediums include: diskette, hard disk, random access memory (RAM), read-only memory (ROM), erasable programmable read-only memory (EPROM or Flash memory), static random access memory (SRAM), compact disc read-only memory (CD-ROM), digital versatile disk (DVD), memory stick, floppy disk, mechanically encoded device (such as punch cards or pits/lands formed in a major surface of a disc) or any suitable combination of the foregoing. A computer readable storage medium, as that term is used in the present disclosure, is not to be construed as storage in the form of transitory signals per se, such as radio waves or other freely propagating electromagnetic waves, electromagnetic waves propagating through a waveguide, light pulses passing through a fiber optic cable, electrical signals communicated through a wire, and/or other transmission media. As will be understood by those of skill in the art, data is typically moved at some occasional points in time during normal operations of a storage device, such as during access, de-fragmentation or garbage collection, but this does not render the storage device as transitory because the data is not transitory while it is stored.
COMPUTER 101 of
PROCESSOR SET 110 includes one, or more, computer processors of any type now known or to be developed in the future. Processing circuitry 120 may be distributed over multiple packages, for example, multiple, coordinated integrated circuit chips. Processing circuitry 120 may implement multiple processor threads and/or multiple processor cores. Cache 121 is memory that is located in the processor chip package(s) and is typically used for data or code that should be available for rapid access by the threads or cores running on processor set 110. Cache memories are typically organized into multiple levels depending upon relative proximity to the processing circuitry. Alternatively, some, or all, of the cache for the processor set may be located “off chip.” In some computing environments, processor set 110 may be designed for working with qubits and performing quantum computing.
Computer readable program instructions are typically loaded onto computer 101 to cause a series of operational steps to be performed by processor set 110 of computer 101 and thereby effect a computer-implemented method, such that the instructions thus executed will instantiate the methods specified in flowcharts and/or narrative descriptions of computer-implemented methods included in this document (collectively referred to as “the inventive methods”). These computer readable program instructions are stored in various types of computer readable storage media, such as cache 121 and the other storage media discussed below. The program instructions, and associated data, are accessed by processor set 110 to control and direct performance of the inventive methods. In computing environment 100, at least some of the instructions for performing the inventive methods may be stored in block 1200 in persistent storage 113.
COMMUNICATION FABRIC 111 is the signal conduction paths that allow the various components of computer 101 to communicate with each other. Typically, this fabric is made of switches and electrically conductive paths, such as the switches and electrically conductive paths that make up busses, bridges, physical input/output ports and the like. Other types of signal communication paths may be used, such as fiber optic communication paths and/or wireless communication paths.
VOLATILE MEMORY 112 is any type of volatile memory now known or to be developed in the future. Examples include dynamic type random access memory (RAM) or static type RAM. Typically, the volatile memory is characterized by random access, but this is not required unless affirmatively indicated. In computer 101, the volatile memory 112 is located in a single package and is internal to computer 101, but, alternatively or additionally, the volatile memory may be distributed over multiple packages and/or located externally with respect to computer 101.
PERSISTENT STORAGE 113 is any form of non-volatile storage for computers that is now known or to be developed in the future. The non-volatility of this storage means that the stored data is maintained regardless of whether power is being supplied to computer 101 and/or directly to persistent storage 113. Persistent storage 113 may be a read only memory (ROM), but typically at least a portion of the persistent storage allows writing of data, deletion of data and re-writing of data. Some familiar forms of persistent storage include magnetic disks and solid state storage devices. Operating system 122 may take several forms, such as various known proprietary operating systems or open source Portable Operating System Interface type operating systems that employ a kernel. The code included in block 1200 typically includes at least some of the computer code involved in performing the inventive methods.
PERIPHERAL DEVICE SET 114 includes the set of peripheral devices of computer 101. Data communication connections between the peripheral devices and the other components of computer 101 may be implemented in various ways, such as Bluetooth connections, Near-Field Communication (NFC) connections, connections made by cables (such as universal serial bus (USB) type cables), insertion type connections (for example, secure digital (SD) card), connections made though local area communication networks and even connections made through wide area networks such as the internet. In various embodiments, UI device set 123 may include components such as a display screen, speaker, microphone, wearable devices (such as goggles and smart watches), keyboard, mouse, printer, touchpad, game controllers, and haptic devices. Storage 124 is external storage, such as an external hard drive, or insertable storage, such as an SD card. Storage 124 may be persistent and/or volatile. In some embodiments, storage 124 may take the form of a quantum computing storage device for storing data in the form of qubits. In embodiments where computer 101 is required to have a large amount of storage (for example, where computer 101 locally stores and manages a large database) then this storage may be provided by peripheral storage devices designed for storing very large amounts of data, such as a storage area network (SAN) that is shared by multiple, geographically distributed computers. IoT sensor set 125 is made up of sensors that can be used in Internet of Things applications. For example, one sensor may be a thermometer and another sensor may be a motion detector.
NETWORK MODULE 115 is the collection of computer software, hardware, and firmware that allows computer 101 to communicate with other computers through WAN 102. Network module 115 may include hardware, such as modems or Wi-Fi signal transceivers, software for packetizing and/or de-packetizing data for communication network transmission, and/or web browser software for communicating data over the internet. In some embodiments, network control functions and network forwarding functions of network module 115 are performed on the same physical hardware device. In other embodiments (for example, embodiments that utilize software-defined networking (SDN)), the control functions and the forwarding functions of network module 115 are performed on physically separate devices, such that the control functions manage several different network hardware devices. Computer readable program instructions for performing the inventive methods can typically be downloaded to computer 101 from an external computer or external storage device through a network adapter card or network interface included in network module 115.
WAN 102 is any wide area network (for example, the internet) capable of communicating computer data over non-local distances by any technology for communicating computer data, now known or to be developed in the future. In some embodiments, the WAN may be replaced and/or supplemented by local area networks (LANs) designed to communicate data between devices located in a local area, such as a Wi-Fi network. The WAN and/or LANs typically include computer hardware such as copper transmission cables, optical transmission fibers, wireless transmission, routers, firewalls, switches, gateway computers and edge servers.
END USER DEVICE (EUD) 103 is any computer system that is used and controlled by an end user (for example, a customer of an enterprise that operates computer 101), and may take any of the forms discussed above in connection with computer 101. EUD 103 typically receives helpful and useful data from the operations of computer 101. For example, in a hypothetical case where computer 101 is designed to provide a recommendation to an end user, this recommendation would typically be communicated from network module 115 of computer 101 through WAN 102 to EUD 103. In this way, EUD 103 can display, or otherwise present, the recommendation to an end user. In some embodiments, EUD 103 may be a client device, such as thin client, heavy client, mainframe computer, desktop computer and so on.
REMOTE SERVER 104 is any computer system that serves at least some data and/or functionality to computer 101. Remote server 104 may be controlled and used by the same entity that operates computer 101. Remote server 104 represents the machine(s) that collect and store helpful and useful data for use by other computers, such as computer 101. For example, in a hypothetical case where computer 101 is designed and programmed to provide a recommendation based on historical data, then this historical data may be provided to computer 101 from remote database 130 of remote server 104.
PUBLIC CLOUD 105 is any computer system available for use by multiple entities that provides on-demand availability of computer system resources and/or other computer capabilities, especially data storage (cloud storage) and computing power, without direct active management by the user. Cloud computing typically leverages sharing of resources to achieve coherence and economies of scale. The direct and active management of the computing resources of public cloud 105 is performed by the computer hardware and/or software of cloud orchestration module 141. The computing resources provided by public cloud 105 are typically implemented by virtual computing environments that run on various computers making up the computers of host physical machine set 142, which is the universe of physical computers in and/or available to public cloud 105. The virtual computing environments (VCEs) typically take the form of virtual machines from virtual machine set 143 and/or containers from container set 144. It is understood that these VCEs may be stored as images and may be transferred among and between the various physical machine hosts, either as images or after instantiation of the VCE. Cloud orchestration module 141 manages the transfer and storage of images, deploys new instantiations of VCEs and manages active instantiations of VCE deployments. Gateway 140 is the collection of computer software, hardware, and firmware that allows public cloud 105 to communicate through WAN 102.
Some further explanation of virtualized computing environments (VCEs) will now be provided. VCEs can be stored as “images.” A new active instance of the VCE can be instantiated from the image. Two familiar types of VCEs are virtual machines and containers. A container is a VCE that uses operating-system-level virtualization. This refers to an operating system feature in which the kernel allows the existence of multiple isolated user-space instances, called containers. These isolated user-space instances typically behave as real computers from the point of view of programs running in them. A computer program running on an ordinary operating system can utilize all resources of that computer, such as connected devices, files and folders, network shares, CPU power, and quantifiable hardware capabilities. However, programs running inside a container can only use the contents of the container and devices assigned to the container, a feature which is known as containerization.
PRIVATE CLOUD 106 is similar to public cloud 105, except that the computing resources are only available for use by a single enterprise. While private cloud 106 is depicted as being in communication with WAN 102, in other embodiments a private cloud may be disconnected from the interne entirely and only accessible through a local/private network. A hybrid cloud is a composition of multiple clouds of different types (for example, private, community or public cloud types), often respectively implemented by different vendors. Each of the multiple clouds remains a separate and discrete entity, but the larger hybrid cloud architecture is bound together by standardized or proprietary technology that enables orchestration, management, and/or data/application portability between the multiple constituent clouds. In this embodiment, public cloud 105 and private cloud 106 are both part of a larger hybrid cloud.
Self-supervised learning (SSL) in speech involves training a speech representation network on a large-scale unannotated speech corpus, and then applying the learned representations to downstream tasks. Since the majority of the downstream tasks of SSL learning in speech largely focus on the content information in speech, the most desirable speech representations should be able to disentangle unwanted variations, such as speaker variations and overlapping and background noise from the content. However, disentangling speakers is very challenging, because removing the speaker information could easily result in a loss of content as well, and the damage of the latter usually far outweighs the benefit of the former.
Conventionally, SSL's self-training often involves a labeling technique that utilizes unlabeled speech and audio. This process may start with some supervised data to train a “teacher” model in one specific downstream task. The teacher uses K-means to generate labels, which does not require supervision. In the techniques provided herein as will be discussed in more detail, the training is unsupervised.
Next, a “student” model is trained using the combined supervised and teacher-labeled data. Note that the student only uses the labels from “teacher.” Again, this ensures that the process does not require supervised data.
Now referring to
In Step 220, a representation may be produced of a partially masked version of the speech utterance using a (speech representation) network (See
In Step 230, the label sequence will be predicted by a predictor using the output of the representation network.
In Step 240, the performance may be assessed based on a cross-entropy loss between the generated label sequence and the predicted label sequence. The objective may be for the predictive loss to be applied only over some regions (in one embodiment the masked regions) forcing the model to learn good high-level representations (of unmasked inputs) in order to infer the targets of other regions (masked ones) correctly.
In one embodiment, three modules are used to achieve the disentanglement process. These modules are the teacher module, the student module and a speaker module.
In Step 310, a self-supervised learning model may be provided for speech that can achieve speaker disentanglement by providing a teacher disentanglement which obscures voice variations from the training target. In the teacher's modules, disentanglement may refer to removing the speaker information from the teacher labels.
In Step 320, the process provides a disentanglement in a student. This will obscure timbre and pitch variations using the representation network. Disentanglement in student modules may refer to introducing a regularization loss that directly enforce speaker invariance on the speech representations.
In Step 330 speaker condition may be provided. This will disentangle speaker information using the Predictor. Speaker conditioning modules may refer to inputting speaker information to the predictor so that the need for the speech representation to encode speaker information may be relieved. In one embodiment, speaker disentanglement may achieve a consistent performance advantage over the baseline speech representations on content-related applications.
In one embodiment, an Improved Self-Supervised Speech Representation by Disentangling Speakers framework may be established as seen in the block diagram of
In
In one instance in
HuBERT may be used because some of its practices can be used. For example, the continuous speech features are masked in both instances. Masking occurs randomly and loss (predictive loss especially) may be applied over the masked regions, to allow the model to learn representation of inputs. This allows both speech as well as other acoustic inputs to be learned.
In one embodiment, k-means mapping from audio inputs can be used to enable the sequencing structure of input data. In one embodiment, K-means mapping can be used. K-means clustering uses an algorithmthat trains a model that groups similar objects together. The K-means algorithm accomplishes this by mapping each observation in the input dataset to a point in the n-dimensional space. In K-means clustering, each duster has a center. During model training, the k-means algorithm uses the distance of the point thatcorresponds to each observation in the dataset to the cluster centers as the basis for lustering. In some embodiments, random selection of k centroids may be made, where k may he equal to the number of clusters to be chosen. Centroids are data points representing the center of a cluster. The main element of the algorithm works by a two-step process called expectation-maximization.
In order to provide understanding of the solution presented, the following problem formulation can be used. First, it should be pointed out that upper-cased letters, X and X, are to represent random scalars and vectors, respectively, and lower-cased letters, x and x, are to represent deterministic scalars and vectors, respectively. Similarly, X=[X1, . . . , XT] as the sequence of a speech features, where Xt may be the speech feature vector at frame t, and T may be the total number of frames. The goal may be to learn a speech representation network R=f (X), where R=[R1, . . . , RT] and Rt may be the representation for frame t. R should desirably satisfy the following two properties:
There are three components:
During training, the speech representation network takes the partially masked speech utterance, {tilde over (X)} as the input, and produces a representation for the masked speech sequence, {tilde over (R)}=f({tilde over (X)}). On the other hand, the teacher label generator generates a label sequence L=g(X) from the unmasked speech. The goal of the predictor may be to predict the teacher labels L from the masked speech representation of {tilde over (R)}. The teacher label generator g(⋅) may be usually predefined and fixed during training. The other two modules, f(⋅)and p(⋅) are trained jointly to minimize the following prediction loss:
pred=E[mp o f({tilde over (X)}), g(X)]
Where m denotes the cross-entropy loss computed over the masked frames only. To make our description more intuitive, we will refer to f ({tilde over (X)}) as students, and g(X) as teachers.
Disentanglement in teachers aims to remove the speaker information in the teacher labels. In one embodiment, a voice conversion model may be provided to convert all utterances to the same speaker before generating the teacher labels.
Referring back to
Disentanglement in students enforces speaker-invariant student representations, which can be achieved by using a contrastive-learning-based algorithm. Specifically, as shown in
where cossim(⋅, ⋅) denotes the cosine similarity, and a set of random time indices at which the representations may be chosen as the negative examples for time t. The contrastive loss consists of two terms so that it may be symmetric with respect to R(1) and R(2). According to the pair of equations above, the negative examples for the utterance pair, (R(1)t, R(1)t), may uniformly and randomly drawn from the remaining frames within the same utterances. As an extension to Equation above, the contrastive loss can be applied to an intermediate layer, instead of the final layer, of f(⋅). Later this may be discussed further as the choice of layer may be explored. The selection of which of the contrastive loss may be imposed would affect the disentanglement behavior. The biggest challenge of applying the contrastive loss may be how to design a random transformation that only alters the speaker identity of the utterance with minimal changes in the other aspects. To this end, a random transformation algorithm can be adopted. In one embodiment, the algorithm consists of three steps of transformations. First, all the formant frequencies within an utterance may be scaled by a factor of ρ1; second, F0 in every frame may be scaled by a factor of ρ2; finally, a random equalizer may be applied to accommodate any channel effects. ρ1 and ρ2 may be both randomly drawn from the uniform distribution μ([1, 1.4]), and then flipped to their reciprocals with probability 0.5. Since the majority of voice information resides in the formant frequency and F0 frequency ranges while content information resides in the relative formant frequency ratios, uniform scaling of all the formant and F0 tends to change the speaker information while retaining the content. The masked prediction task equation can be modified as:
pred
=E[
m)p o f({tilde over (X)}(1)), g(X))+m(p o f({tilde over (X)}(2)), g(X))]
Again, the masked prediction loss is applied to both f({tilde over (X)}(1)) and f({tilde over (X)}(2)) for symmetry.
Although disentanglement in teacher can remove the majority of the speaker information from the teacher labels, certain speaker information would remain. As a result, the student representations may be undesirably forced to carry the same amount of speaker information as the teachers do in order to reasonably predict the teacher labels. To break this entailment between the speaker information in students and in teachers, the speaker embeddings may be fed to the predictor as shown in
pred
=E[
m)p(f({tilde over (X)}1), 8(X)), g(X)+m(p(f({tilde over (X)}(2)), 8(X)), g(X))]
Where s(X) denotes the speaker embeddings. The final loss is superposition of the prediction and contrastive losses:
=pred+λcontr
The descriptions of the various embodiments of the present invention have been presented for purposes of illustration but may be not intended to be exhaustive or limited to the embodiments disclosed. Many modifications and variations will be apparent to those of ordinary skill in the art without departing from the scope of the described embodiments. The terminology used herein was chosen to best explain the principles of the embodiments, the practical application or technical improvement over technologies found in the marketplace, or to enable others of ordinary skill in the art to understand the embodiments disclosed herein.