WO2011059562A1 - System and method for hybrid processing in a natural language voive services environment - Google Patents
System and method for hybrid processing in a natural language voive services environment Download PDFInfo
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- WO2011059562A1 WO2011059562A1 PCT/US2010/049077 US2010049077W WO2011059562A1 WO 2011059562 A1 WO2011059562 A1 WO 2011059562A1 US 2010049077 W US2010049077 W US 2010049077W WO 2011059562 A1 WO2011059562 A1 WO 2011059562A1
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- G—PHYSICS
- G10—MUSICAL INSTRUMENTS; ACOUSTICS
- G10L—SPEECH ANALYSIS OR SYNTHESIS; SPEECH RECOGNITION; SPEECH OR VOICE PROCESSING; SPEECH OR AUDIO CODING OR DECODING
- G10L15/00—Speech recognition
- G10L15/08—Speech classification or search
- G10L15/18—Speech classification or search using natural language modelling
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- G—PHYSICS
- G06—COMPUTING; CALCULATING OR COUNTING
- G06F—ELECTRIC DIGITAL DATA PROCESSING
- G06F3/00—Input arrangements for transferring data to be processed into a form capable of being handled by the computer; Output arrangements for transferring data from processing unit to output unit, e.g. interface arrangements
- G06F3/01—Input arrangements or combined input and output arrangements for interaction between user and computer
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- G—PHYSICS
- G06—COMPUTING; CALCULATING OR COUNTING
- G06F—ELECTRIC DIGITAL DATA PROCESSING
- G06F3/00—Input arrangements for transferring data to be processed into a form capable of being handled by the computer; Output arrangements for transferring data from processing unit to output unit, e.g. interface arrangements
- G06F3/01—Input arrangements or combined input and output arrangements for interaction between user and computer
- G06F3/017—Gesture based interaction, e.g. based on a set of recognized hand gestures
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- G—PHYSICS
- G10—MUSICAL INSTRUMENTS; ACOUSTICS
- G10L—SPEECH ANALYSIS OR SYNTHESIS; SPEECH RECOGNITION; SPEECH OR VOICE PROCESSING; SPEECH OR AUDIO CODING OR DECODING
- G10L15/00—Speech recognition
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- G—PHYSICS
- G10—MUSICAL INSTRUMENTS; ACOUSTICS
- G10L—SPEECH ANALYSIS OR SYNTHESIS; SPEECH RECOGNITION; SPEECH OR VOICE PROCESSING; SPEECH OR AUDIO CODING OR DECODING
- G10L15/00—Speech recognition
- G10L15/22—Procedures used during a speech recognition process, e.g. man-machine dialogue
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- G—PHYSICS
- G10—MUSICAL INSTRUMENTS; ACOUSTICS
- G10L—SPEECH ANALYSIS OR SYNTHESIS; SPEECH RECOGNITION; SPEECH OR VOICE PROCESSING; SPEECH OR AUDIO CODING OR DECODING
- G10L15/00—Speech recognition
- G10L15/28—Constructional details of speech recognition systems
- G10L15/30—Distributed recognition, e.g. in client-server systems, for mobile phones or network applications
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- G—PHYSICS
- G06—COMPUTING; CALCULATING OR COUNTING
- G06F—ELECTRIC DIGITAL DATA PROCESSING
- G06F2203/00—Indexing scheme relating to G06F3/00 - G06F3/048
- G06F2203/038—Indexing scheme relating to G06F3/038
- G06F2203/0381—Multimodal input, i.e. interface arrangements enabling the user to issue commands by simultaneous use of input devices of different nature, e.g. voice plus gesture on digitizer
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- G—PHYSICS
- G10—MUSICAL INSTRUMENTS; ACOUSTICS
- G10L—SPEECH ANALYSIS OR SYNTHESIS; SPEECH RECOGNITION; SPEECH OR VOICE PROCESSING; SPEECH OR AUDIO CODING OR DECODING
- G10L15/00—Speech recognition
- G10L15/22—Procedures used during a speech recognition process, e.g. man-machine dialogue
- G10L2015/226—Procedures used during a speech recognition process, e.g. man-machine dialogue using non-speech characteristics
Definitions
- the invention relates to hybrid processing in a natural language voice services environment that includes a plurality of multi-modal devices, wherein hybrid processing in the natural language voice services environment may include the plurality of multimodal devices cooperatively interpreting and processing one or more natural language utterances included in one or more multi-modal requests.
- voice recognition software which has the potential to enable users to exploit features that would otherwise be unfamiliar, unknown, or difficult to use.
- Navteq Corporation which provides data used in a variety of applications such as automotive navigation and web-based applications, demonstrates that voice recognition often ranks among the features most desired by consumers of electronic devices. Even so, existing voice user interfaces, when they actually work, still require significant learning on the part of the user.
- a system and method for hybrid processing in a natural language voice services environment may address one or more of the aforementioned problems with existing systems.
- hybrid processing in the natural language voice services environment may generally include a plurality of multi-modal devices cooperatively interpreting and processing one or more natural language utterances included in one or more multi-modal requests, as described in further detail herein.
- hybrid processing in the natural language voice services environment may generally include a plurality of multi-modal devices cooperatively interpreting and processing one or more natural language utterances included in one or more multi-modal requests.
- a virtual router may receive various messages that include encoded audio corresponding to a natural language utterance contained in a multi-modal interaction provided to one or more of the devices. The virtual router may then analyze the encoded audio to select a cleanest sample of the natural language utterance and communicate with one or more other devices in the environment to determine an intent of the multi-modal interaction. The virtual router may then coordinate resolving the multi-modal interaction based on the intent of the multi-modal interaction.
- a method for hybrid processing in a natural language voice services environment may comprise detecting at least one multi-modal interaction at an electronic device, wherein the multi-modal interaction includes at least a natural language utterance.
- One or more messages containing information relating to the multi-modal interaction may then be communicated to a virtual router in communication with the electronic device, wherein the electronic device communicates the one or more messages to the virtual router through a messaging interface.
- the method may further comprise receiving one or more messages containing information relating to an intent of the multi-modal interaction at the electronic device through the messaging interface.
- the multi-modal interaction may be resolved at the electronic device based on the information contained in the one or more messages received from the virtual router.
- a method for hybrid processing in a natural language voice services environment may comprise one or more electronic devices in communication with the virtual router.
- the electronic device may be configured to detect at least one multi-modal interaction that includes at least a natural language utterance and communicate one or more messages containing information relating to the multi-modal interaction to the virtual router through a messaging interface.
- the electronic device may then receive one or more messages containing information relating to an intent of the multi-modal interaction from the virtual router through the messaging interface and resolve the multi-modal interaction at the electronic device based on the information contained in the one or more messages received from the virtual router.
- Figure 1 illustrates a block diagram of an exemplary voice-enabled device that can be used for hybrid processing in a natural language voice services environment, according to one aspect of the invention.
- Figure 2 illustrates a block diagram of an exemplary system for hybrid processing in a natural language voice service environment, according to one aspect of the invention.
- Figure 3 illustrates a flow diagram of an exemplary method for initializing various devices that cooperate to perform hybrid processing in a natural language voice services environment, according to one aspect of the invention.
- FIGS 4-5 illustrate flow diagrams of exemplary methods for hybrid processing in a natural language voice services environment, according to one aspect of the invention.
- Figure 1 illustrates a block diagram of an exemplary voice-enabled device 100 that can be used for hybrid processing in a natural language voice services environment.
- the voice-enabled device 100 illustrated in Figure 1 may generally include an input device 1 12, or a combination of input devices 1 12, which may enable a user to interact with the voice-enabled device 100 in a multi-modal manner.
- the input devices 1 12 may generally include any suitable combination of at least one voice input device 1 12 (e.g., a microphone) and at least one non-voice input device 1 12 (e.g., a mouse, touch-screen display, wheel selector, etc.).
- the input devices 1 12 may include any suitable combination of electronic devices having mechanisms for receiving both voice-based and non-voice- based inputs (e.g., a microphone coupled to one or more of a telematics device, personal navigation device, mobile phone, VoIP node, personal computer, media device, embedded device, server, or other electronic device).
- a microphone coupled to one or more of a telematics device, personal navigation device, mobile phone, VoIP node, personal computer, media device, embedded device, server, or other electronic device.
- the voice-enabled device 100 may enable the user to engage in various multi-modal conversational interactions, which the voice-enabled device 100 may process in a free-form and cooperative manner to execute various tasks, resolve various queries, or otherwise resolve various natural language requests included in the multi-modal interactions.
- the voice-enabled device 100 may include various natural language processing components, including at least a voice-click module coupled to the one or more input devices 1 12, as described in further detail in co-pending U.S. Patent Application Serial No. 12/389,678, entitled "System and Method for Processing Multi-Modal Device Interactions in a Natural Language Voice Services Environment," filed February 20, 2009, the contents of which are hereby incorporated by reference in their entirety.
- the one or more input devices 1 12 and the voice-click module may be collectively configured to process various multimodal interactions between the user and the voice-enabled device 100.
- the multi-modal interactions may include at least one natural language utterance, wherein the natural language utterance may be converted into an electronic signal.
- the electronic signal may then be provided to an Automatic Speech Recognizer (ASR) 120, which may also be referred to as a speech recognition engine 120 and/or a multi-pass speech recognition engine 120.
- ASR Automatic Speech Recognizer
- the ASR 120 may generate one or more preliminary interpretations of the utterance and provide the preliminary interpretation to a conversational language processor 130.
- the multi-modal interactions may include one or more non-voice interactions with the one or more input devices 1 12 (e.g., button pushes, multi-touch gestures, point of focus or attention focus selections, etc.).
- the voice-click module may extract context from the non-voice interactions and provide the context to the conversational language processor 130 for use in generating an interpretation of the utterance (i.e., via the dashed line illustrated in Figure 1 ).
- the conversational language processor 130 may analyze the utterance and any accompanying non-voice interactions to determine an intent of the multi-modal interactions with the voice-enabled device 100.
- the voice-enabled device 100 may include various natural language processing components that can support free-form utterances and/or other forms of non-voice device interactions, which may liberate the user from restrictions relating to the manner of formulating commands, queries, or other requests.
- the user may provide the utterance to the voice input device 1 12 using any manner of speaking, and may further provide other non-voice interactions to the non-voice input device 1 12 to request any content or service available through the voice-enabled device 100.
- the utterance in response to receiving the utterance at the voice input device 1 12, the utterance may be processed using techniques described in U.S. Patent Application Serial No.
- the user may interact with one or more of the non-voice input devices 1 12 to provide buttons pushes, multi-touch gestures, point of focus or attention focus selections, or other non-voice device interactions, which may provide further context or other information relating to the natural language utterances and/or the requested content or service.
- the voice-enabled device 100 may be coupled to one or more additional systems that may be configured to cooperate with the voice-enabled device 100 to interpret or otherwise process the multi-modal interactions that include combinations of natural language utterances and/or non-voice device interactions.
- the one or more additional systems may include one or more multi-modal voice-enabled devices having similar natural language processing capabilities to the voice-enabled device 100, one or more non-voice devices having data retrieval and/or task execution capabilities, and a virtual router that coordinates interaction among the voice-enabled device 100 and the additional systems.
- the voice-enabled device 100 may include an interface to an integrated natural language voice services environment that includes a plurality of multi-modal devices, wherein the user may request content or services available through any of the multi-modal devices.
- the conversational language processor 130 may include a constellation model 132b that provides knowledge relating to content, services, applications, intent determination capabilities, and other features available in the voice services environment, as described in co-pending U.S. Patent Application Serial No. 12/127,343, entitled "System and Method for an Integrated, Multi-Modal, Multi-Device Natural Language Voice Services Environment," filed May 27, 2008, the contents of which are hereby incorporated by reference in their entirety.
- the voice-enabled device 100 may have access to shared knowledge relating to natural language processing capabilities, context, prior interactions, domain knowledge, short-term knowledge, long-term knowledge, and cognitive models for the various systems and multi-modal devices, providing a cooperative environment for resolving the multi-modal interactions received at the voice-enabled device 100.
- the input devices 1 12 and the voice-click module coupled thereto may be configured to continually monitor for one or more multi-modal interactions received at the voice-enabled device 100.
- the input devices 1 12 and the voice-click module may continually monitor for one or more natural language utterances and/or one or more distinguishable non-voice device interactions, which may collectively provide the relevant context for retrieving content, executing tasks, invoking services or commands, or processing any other suitable requests.
- the input devices 1 12 and/or the voice-click module may signal the voice-enabled device 100 that an utterance and/or a non-voice interaction have been received.
- the non-voice interaction may provide context for sharpening recognition, interpretation, and understanding of an accompanying utterance, and moreover, the utterance may provide further context for enhancing interpretation of the accompanying non-voice interaction. Accordingly, the utterance and the non-voice interaction may collectively provide relevant context that various natural language processing components may use to determine an intent of the multi-modal interaction that includes the utterance and the non-voice interaction.
- processing the utterance included in the multi-modal interaction may be initiated at the ASR 120, wherein the ASR 120 may generate one or more preliminary interpretations of the utterance.
- the ASR 120 may be configured to recognize one or more syllables, words, phrases, or other acoustic characteristics from the utterance using one or more dynamic recognition grammars and/or acoustic models.
- the ASR 120 may use the dynamic recognition grammars and/or the acoustic models to recognize a stream of phonemes from the utterance based on phonetic dictation techniques, as described in U.S. Patent Application Serial No.
- the dynamic recognition grammars and/or the acoustic models may include unstressed central vowels (e.g., "schwa”), which may reduce a search space for recognizing the stream of phonemes for the utterance.
- the ASR 120 may be configured as a multipass speech recognition engine 120, as described in U.S. Patent Application Serial No. 1 1/197,504, entitled “Systems and Methods for Responding to Natural Language Speech Utterance," which issued as U.S. Patent No. 7,640,160 on December 29, 2009, the contents of which are hereby incorporated by reference in their entirety.
- the multi-pass speech recognition 120 may be configured to initially invoke a primary speech recognition engine to generate a first transcription of the utterance, and further to optionally subsequently invoke one or more secondary speech recognition engines to generate one or more secondary transcriptions of the utterance.
- the first transcription may be generated using a large list dictation grammar
- the secondary transcriptions may be generated using virtual dictation grammars having decoy words for out-of-vocabulary words, reduced vocabularies derived from a conversation history, or other dynamic recognition grammars.
- the secondary speech recognition engines may be invoked to sharpen the interpretation of the primary speech recognition engine.
- the multi-pass speech recognition engine 120 may interpret the utterance using any suitable combination of techniques that results in a preliminary interpretation derived from a plurality of transcription passes for the utterance (e.g., the secondary speech recognition engines may be invoked regardless of the confidence level for the first transcription, or the primary speech recognition engine and/or the secondary speech recognition engines may employ recognition grammars that are identical or optimized for a particular interpretation context, etc.).
- the dynamic recognition grammars used in the ASR 120 may be optimized for different languages, contexts, domains, memory constraints, and/or other suitable criteria.
- the voice-enabled device 100 may include one or more applications 134 that provide content or services for a particular context or domain, such as a navigation application 134.
- the dynamic recognition grammars may be optimized for various physical, temporal, directional, or other geographical characteristics (e.g., as described in co-pending U.S. Patent Application Serial No.
- an utterance containing the word "traffic” may be subject to different interpretations depending on whether the user intended a navigation context (i.e., traffic on roads), a music context (i.e., the 1960's rock band), or a movie context (i.e., the Steven Soderbergh film).
- a navigation context i.e., traffic on roads
- a music context i.e., the 1960's rock band
- a movie context i.e., the Steven Soderbergh film
- the recognition grammars used in the ASR 120 may be dynamically adapted to optimize accurate recognition for any given utterance (e.g., in response to incorrectly interpreting an utterance to contain a particular word or phrase, the incorrect interpretation may be removed from the recognition grammar to prevent repeating the incorrect interpretation).
- the ASR 120 may provide the preliminary interpretations to the conversational language processor 130.
- the conversational language processor 130 may generally include various natural language processing components, which may be configured to model human-to-human conversations or interactions.
- the conversational language processor 130 may invoke one or more of the natural language processing components to further analyze the preliminary interpretations of the utterance and any accompanying non-voice interactions to determine the intent of the multi-modal interactions received at the voice-enabled device 100.
- the conversational language processor 120 may invoke an intent determination engine 130a configured to determine the intent of the multimodal interactions received at the voice-enabled device 100.
- the intent determination engine 130a may invoke a knowledge-enhanced speech recognition engine that provides long-term and short-term semantic knowledge for determining the intent, as described in co-pending U.S. Patent Application Serial No. 1 1 /212,693, entitled "Mobile Systems and Methods of Supporting Natural Language Human-Machine Interactions," filed August 29, 2005, the contents of which are hereby incorporated by reference in their entirety.
- the semantic knowledge may be based on a personalized cognitive model derived from one or more prior interactions with the user, a general cognitive model derived from one or more prior interactions with various different users, and/or an environmental cognitive model derived from an environment associated with the user, the voice- enabled device 100, and/or the voice services environment (e.g., ambient noise characteristics, location sensitive information, etc.).
- a personalized cognitive model derived from one or more prior interactions with the user e.g., a general cognitive model derived from one or more prior interactions with various different users
- an environmental cognitive model derived from an environment associated with the user, the voice- enabled device 100, and/or the voice services environment (e.g., ambient noise characteristics, location sensitive information, etc.).
- the intent determination engine 132a may invoke a context tracking engine 132d to determine the context for the multi-modal interactions. For example, any context derived from the natural language utterance and/or the non- voice interactions in the multi-modal interactions may be pushed to a context stack associated with the context tracking engine 132d, wherein the context stack may include various entries that may be weighted or otherwise ranked according to one or more contexts identified from the cognitive models and the context for the current multi-modal interactions. As such, the context tracking engine 132d may determine one or more entries in the context stack that match information associated with the current multi-modal interactions to determine a most likely context for the current multimodal interactions. The context tracking engine 132d may then provide the most likely context to the intent determination engine 132a, which may determine the intent of the multi-modal interactions in view of the most likely context.
- the intent determination engine 132a may reference the constellation model 132b to determine whether to invoke any of the various systems or multi-modal devices in the voice services environment.
- the constellation model 132b may provide intent determination capabilities, domain knowledge, semantic knowledge, cognitive models, and other information available through the various systems and multi-modal devices.
- the intent determination engine 132a may reference the constellation model 132b to determine whether one or more of the other systems and/or multi-modal devices should be engaged to participate in determining the intent of the multi-modal interactions.
- the intent determination engine 132a may forward information relating to the multi-modal interactions to such systems and/or multi-modal devices, which may then determine the intent of the multimodal interactions and return the intent determination to the voice-enabled device 100.
- the conversational language processor 130 may be configured to engage the user in one or more cooperative conversations to resolve the intent or otherwise process the multi-modal interactions, as described in co-pending U.S. Patent Application Serial No. 1 1 /580,926, entitled “System and Method for a Cooperative Conversational Voice User Interface,” filed October 16, 2006, the contents of which are hereby incorporated by reference in their entirety.
- the conversational language processor 130 may generally identify a conversational goal for the multi-modal interactions, wherein the conversational goal may be identifying from analyzing the utterance, the non-voice interactions, the most likely context, and/or the determined intent.
- the conversational goal identified for the multi-modal interactions may generally control the cooperative conversation between the conversational language processor 130 and the user.
- the conversational language processor 130 may generally engage the user in one or more query conversations, didactic conversations, and/or exploratory conversations to resolve or otherwise process the multi-modal interactions.
- the conversational language processor 130 may engage the user in a query conversation in response to identifying that the conversational goal relates to retrieving discrete information or performing a particular function.
- the user may lead the conversation towards achieving the particular conversational goal, while the conversational language processor 130 may initiate one or more queries, tasks, commands, or other requests to achieve the goal and thereby support the user in the conversation.
- the conversational language processor 130 may engage the user in a didactic conversation to resolve the ambiguity or uncertainty (e.g., where noise or malapropisms interfere with interpreting the utterance, multiple likely contexts cannot be disambiguated, etc.).
- the conversational language processor 130 may lead the conversation to clarify the intent of the multi-modal interaction (e.g., generating feedback provided through an output device 1 14), while the user may regulate the conversation and provide additional multi-modal interactions to clarify the intent.
- the conversational language processor 130 may engage the user in an exploratory conversation to resolve the goal.
- the conversational language processor 130 and the user may share leader and supporter roles, wherein the ambiguous or uncertain goal may be improvised or refined over a course of the conversation.
- the conversational language processor 130 may generally engage in one or more cooperative conversations to determine the intent and resolve a particular goal for the multi-modal interactions received at the voice-enabled device 100. The conversational language processor 130 may then initiate one or more queries, tasks, commands, or other requests in furtherance of the intent and the goal determined for the multi-modal interactions.
- the conversational language processor 130 may invoke one or more agents 132c having capabilities for processing requests in a particular domain or application 134, a voice search engine 132f having capabilities for retrieving information requested in the multi-modal interactions (e.g., from one or more data repositories 136, networks, or other information sources coupled to the voice-enabled device 100), or one or more other systems or multi-modal devices having suitable processing capabilities for furthering the intent and the goal for the multi-modal interactions (e.g., as determined from the constellation model 132b).
- agents 132c having capabilities for processing requests in a particular domain or application 134
- a voice search engine 132f having capabilities for retrieving information requested in the multi-modal interactions (e.g., from one or more data repositories 136, networks, or other information sources coupled to the voice-enabled device 100)
- one or more other systems or multi-modal devices having suitable processing capabilities for furthering the intent and the goal for the multi-modal interactions (e.g., as determined from the constellation model 132b
- the conversational language processor 130 may invoke an advertising application 134 in relation to the queries, tasks, commands, or other requests initiated to process the multi-modal interactions, wherein the advertising application 134 may be configured to select one or more advertisements that may be relevant to the intent and/or the goal for the multi-modal interactions, as described in co-pending U.S. Patent Application Serial No. 1 1/671 ,526, entitled “System and Method for Selecting and Presenting Advertisements Based on Natural Language Processing of Voice-Based Input,” filed February 6, 2007, the contents of which are hereby incorporated by reference in their entirety.
- the conversational language processor 130 may format the results for presentation to the user through the output device 1 14.
- the results may be formatted into a natural language utterance that can be converted into an electronic signal and provided to the user through a speaker coupled to the output device 1 14, or the results may be visually presented on a display coupled to the output device 1 14, or in any other suitable manner (e.g., the results may indicate whether a particular task or command was successfully performed, or the results may include information retrieved in response to one or more queries, or the results may include a request to frame a subsequent multi-modal interaction if the results are ambiguous or otherwise incomplete, etc.).
- the conversational language processor 130 may include a misrecognition engine 132e configured to determine whether the conversational language processor 130 incorrectly determined the intent for the multimodal interactions.
- the misrecognition engine 132e may determine that the conversational language processor 130 incorrectly determined the intent in response to one or more subsequent multi-modal interactions provided proximately in time to the prior multi-modal interactions, as described in U.S. Patent Application Serial No. 1 1 /200,164, entitled "System and Method of Supporting Adaptive Misrecognition in Conversational Speech," which issued as U.S. Patent No. 7,620,549 on November 17, 2009, the contents of which are hereby incorporated by reference in their entirety.
- the misrecognition engine 132e may monitor for one or more subsequent multi-modal interactions that include a stop word, override a current request, or otherwise indicate an unrecognized or misrecognized event. The misrecognition engine 132e may then determine one or more tuning parameters for various components associated with the ASR 120 and/or the conversational language processor 130 to improve subsequent interpretations.
- the voice-enabled device 100 may generally include various natural language processing components and capabilities that may be used for hybrid processing in the natural language voice services environment.
- the voice-enabled device 100 may be configured to determine the intent for various multi-modal interactions that include any suitable combination of natural language utterances and/or non-voice interactions and process one or more queries, tasks, commands, or other requests based on the determined intent.
- one or more other systems and/or multi-modal devices may participate in determining the intent and processing the queries, tasks, commands, or other requests for the multi-modal interactions to provide a hybrid processing methodology, wherein the voice-enabled device 100 and the various other systems and multi-modal devices may each perform partial processing to determine the intent and otherwise process the multi-modal interactions in a cooperative manner.
- the cooperatively processed multi-modal interactions may include requests to dedicate content (e.g., to a particular person or entity), wherein the multimodal interactions may be processed using techniques described in U.S. Provisional Patent Application Serial No. 61/259,820, entitled “System and Method for Providing a Natural Language Content Dedication Service,” filed November 10, 2009, the contents of which are hereby incorporated by reference in their entirety.
- Figure 2 illustrates a block diagram of an exemplary system for hybrid processing in a natural language voice service environment.
- the system illustrated in Figure 2 may generally include a voice-enabled client device 210 similar to the voice-enabled device described above in relation to Figure 1 .
- the voice-enabled client device 210 may include any suitable combination of input and output devices 215a respectively arranged to receive natural language multi-modal interactions and provide responses to the natural language multi-modal interactions.
- the voice-enabled client device 210 may include an Automatic Speech Recognizer (ASR) 220a configured to generate one or more preliminary interpretations of natural language utterances received at the input device 215a, and further configured to provide the preliminary interpretations to a conversational language processor 230a.
- ASR Automatic Speech Recognizer
- the conversational language processor 230a on the voice-enabled client device 210 may include one or more natural language processing components, which may be invoked to determine an intent for the multi-modal interactions received at the voice-enabled client device 210. The conversational language processor 230a may then initiate one or more queries, tasks, commands, or other requests to resolve the determined intent.
- the conversational language processor 230a may invoke one or more applications 234a to process requests in a particular domain, query one or more data repositories 236a to retrieve information requested in the multi-modal interactions, or otherwise engage in one or more cooperative conversations with a user of the voice-enabled client device 210 to resolve the determined intent.
- the voice-enabled client device 210 may also cooperate with one or more other systems or multi-modal devices having suitable processing capabilities for initiating queries, tasks, commands, or other requests to resolve the intent of the multi-modal interactions.
- the voice-enabled client device 210 may use a messaging interface 250a to communicative with a virtual router 260, wherein the messaging interface 250a may generally include a light client (or thin client) that provides a mechanism for the voice-enabled client device 210 to transmit input to and receive output from the virtual router 260.
- the virtual router 260 may further include a messaging interface 250b providing a mechanism for communicating with one or more additional voice-enabled devices 270a-n, one or more non-voice devices 280a-n, and a voice-enabled server 240.
- FIG 2 illustrates messaging interface 250a and messaging interface 250b as components that are distinct from the devices to which they are communicatively coupled, it will be apparent that such illustration is for ease of description only, as the messaging interfaces 250a-b may be provided as on-board components that execute on the various devices illustrated in Figure 2 to facilitate communication among the various devices in the hybrid processing environment.
- the messaging interface 250a that executes on the voice-enabled client device 210 may transmit input from the voice- enabled client device 210 to the virtual router 260 within one or more XML messages, wherein the input may include encoded audio corresponding to natural language utterances, preliminary interpretations of the natural language utterances, data corresponding to multi-touch gestures, point of focus or attention focus selections, and/or other multi-modal interactions.
- the virtual router 260 may then further process the input using a conversational language processor 230c having capabilities for speech recognition, intent determination, adaptive misrecognition, and/or other natural language processing.
- the conversational language processor 230c may include knowledge relating to content, services, applications, natural language processing capabilities, and other features available through the various devices in the hybrid processing environment.
- the virtual router 260 may further communicate with the voice-enabled devices 270, the non-voice devices 280, and/or the voice- enabled server 240 through the messaging interface 250b to coordinate processing for the input received from the voice-enabled client device 210. For example, based on the knowledge relating to the features and capabilities of the various devices in the hybrid processing environment, the virtual router 260 may identify one or more of the devices that have suitable features and/or capabilities for resolving the intent of the input received from the voice-enabled client device 210.
- the virtual router 260 may then forward one or more components of the input to the identified devices through respective messaging interfaces 250b, wherein the identified devices may be invoked to perform any suitable processing for the components of the input forwarded from the virtual router 260. In one implementation, the identified devices may then return any results of the processing to the virtual router 260 through the respective messaging interfaces 250b, wherein the virtual router 260 may collate the results of the processing and return the results to the voice-enabled client device 210 through the messaging interface 250a.
- the virtual router 260 may communicate with any of the devices available in the hybrid processing environment through messaging interfaces 250a-b to coordinate cooperative hybrid processing for multi-modal interactions or other natural language inputs received from the voice-enabled client device 210.
- the cooperative hybrid processing may be used to enhance performance in embedded processing architectures in which the voice-enabled client device 210 includes a constrained amount of resources (e.g., the voice-enabled client device 210 may be a mobile device having a limited amount of internal memory or other dedicated resources for natural language processing).
- one or more components of the voice-enabled client device 210 may be configured to optimize efficiency of on-board natural language processing to reduce or eliminate bottlenecks, lengthy response times, or degradations in performance.
- optimizing the efficiency of the on-board natural language processing may include configuring the ASR 220a to use a virtual dictation grammar having decoy words for out-of-vocabulary words, reduced vocabularies derived from a conversation history, or other dynamic recognition grammars (e.g., grammars optimized for particular languages, contexts, domains, memory constraints, and/or other suitable criteria).
- the on-board applications 234a and/or data repositories 236a may be associated with an embedded application suite providing particular features and capabilities for the voice-enabled client device 210.
- the voice-enabled client device 210 may be embedded within an automotive telematics system, a personal navigation device, a global positioning system, a mobile phone, or another device in which users often request location-based services.
- the on-board applications 234a and the data repositories 236a in the embedded application suite may be optimized to provide certain location-based services that can be efficiently processed on-board (e.g., destination entry, navigation, map control, music search, hands-free dialing, etc.).
- the components of the voice-enabled client device 210 may be optimized for efficiency in embedded architectures, a user may nonetheless request any suitable content, services, applications, and/or other features available in the hybrid processing environment, and the other devices in the hybrid processing environment may collectively provide natural language processing capabilities to supplement the embedded natural language processing capabilities for the voice- enabled client device 210.
- the voice-enabled client device 210 may perform preliminary processing for a particular multi-modal interaction using the embedded natural language processing capabilities (e.g., the on-board ASR 220a may perform advanced virtual dictation to partially transcribe an utterance in the multi-modal interaction, the on-board conversational language processor 230a may determine a preliminary intent of the multi-modal interaction, etc.), wherein results of the preliminary processing may be provided to the virtual router 260 for further processing.
- the embedded natural language processing capabilities e.g., the on-board ASR 220a may perform advanced virtual dictation to partially transcribe an utterance in the multi-modal interaction, the on-board conversational language processor 230a may determine a preliminary intent of the multi-modal interaction, etc.
- the voice-enabled client device 210 may also communicate input corresponding to the multi-modal interaction to the virtual router 260 in response to determining that on-board capabilities cannot suitably interpret the interaction (e.g., if a confidence level for a partial transcription does not satisfy a particular threshold), or in response to determining that the interaction should be processed off-board (e.g., if a preliminary interpretation indicates that the interaction relates to a local search request requiring large computations to be performed on the voice-enabled server 240).
- the virtual router 260 may capture the input received from the voice-enabled client device 210 and coordinate further processing among the voice-enabled devices 270 and the voice-enabled server 240 that provide natural language processing capabilities in addition to the non-voice devices 280 that provide capabilities for retrieving data or executing tasks. Furthermore, in response to the virtual router 260 invoking one or more of the voice-enabled devices 270, the input provided to the voice-enabled devices 270 may be optimized to suit the processing requested from the invoked voice-enabled devices 270 (e.g., to avoid over-taxing processing resources, a particular voice-enabled device 270 may be provided a partial transcription or a preliminary interpretation and resolve the intent for a given context or domain).
- the input provided to the voice-enabled devices 270 may further include encoded audio corresponding to natural language utterances and any other data associated with the multi-modal interaction.
- the voice-enabled server 240 may have a natural language processing architecture similar to the voice-enabled client device 210, except that the voice-enabled server 240 may include substantial processing resources that obviate constraints that the voice- enabled client device 210 may be subject to.
- the voice-enabled server 240 when the voice-enabled server 240 cooperates in the hybrid processing for the multi-modal interaction, the encoded audio corresponding to the natural language utterances and the other data associated with the multi-modal interaction may be provided to the voice-enabled server 240 to maximize a likelihood of the voice-enabled server 240 correctly determining the intent of the multi-modal interaction (e.g., the ASR 220b may perform multi-pass speech recognition to generate an accurate transcription for the natural language utterance, the conversational language processor 230b may arbitrate among intent determinations performed in any number of different contexts or domains, etc.).
- the hybrid processing techniques performed in the environment illustrated in Figure 2 may generally include various different devices, which may or may not include natural language capabilities, cooperatively determining the intent of a particular multi-modal interaction and taking action to resolve the intent.
- the voice-enabled client device 210 may include a suitable amount of memory or other resources that can be dedicated to natural language processing (e.g., the voice-enabled client device 210 may be a desktop computer or other device that can process natural language without substantially degraded performance).
- one or more of the components of the voice-enabled client device 210 may be configured to optimize the on-board natural language processing in a manner that could otherwise cause bottlenecks, lengthy response times, or degradations in performance in an embedded architecture.
- optimizing the on-board natural language processing may include configuring the ASR 220a to use a large list dictation grammar in addition to and/or instead of the virtual dictation grammar used in embedded processing architectures.
- cooperative hybrid processing techniques may be substantially similar regardless of whether the voice-enabled client device 210 has an embedded or non- embedded architecture.
- cooperative hybrid processing may include the voice- enabled client device 210 optionally performing preliminary processing for a natural language multi-modal interaction and communicating input corresponding to the multimodal interaction to the virtual router 260 for further processing through the messaging interface 250a.
- the cooperative hybrid processing may include the virtual router 260 coordinating the further processing for the input among the various devices in the hybrid environment through messaging interface 250b, and subsequently returning any results of the processing to the voice-enabled client device 210 through messaging interface 250a.
- Figure 3 illustrates a flow diagram of an exemplary method for initializing various devices that cooperate to perform hybrid processing in a natural language voice services environment.
- the hybrid processing environment may generally include communication among various different devices that may cooperatively process natural language multi-modal interactions.
- the various devices in the hybrid processing environment may include a virtual router having one or more messaging interfaces for communicating with one or more voice-enabled devices, one or more non-voice devices, and/or a voice-enabled server.
- the method illustrated in Figure 3 may be used to initialize communication in the hybrid processing environment to enable subsequent cooperative processing for one or more natural language multi-modal interactions received at any particular device in the hybrid processing environment.
- the various devices in the hybrid processing environment may be configured to continually listen or otherwise monitor respective input devices to determine whether a natural language multi-modal interaction has occurred.
- the method illustrated in Figure 3 may be used to calibrate, synchronize, or otherwise initialize the various devices that continually listen for the natural language multi-modal interactions.
- the virtual router, the voice-enabled devices, the non-voice devices, the voice-enabled server, and/or other devices in the hybrid processing environment may be configured to provide various different capabilities or services, wherein the initialization method illustrated in Figure 3 may be used to ensure that the hybrid processing environment obtains a suitable signal to process any particular natural language multi-modal interaction and appropriately invoke one or more of the devices to cooperatively process the natural language multi-modal interaction.
- the method illustrated in Figure 3 and described herein may be invoked to register the various devices in the hybrid processing environment, register new devices added to the hybrid processing environment, publish domains, services, intent determination capabilities, and/or other features supported on the registered devices, synchronize local timing for the registered devices, and/or initialize any other suitable aspect of the devices in the hybrid processing environment.
- initializing the various devices in the hybrid processing environment may include an operation 310, wherein a device listener may be established for each of the devices in the hybrid processing environment.
- the device listeners established in operation 310 may generally include any suitable combination of instructions, firmware, or other routines that can be executed on the various devices to determine capabilities, features, supported domains, or other information associated with the devices.
- the device listeners established in operation 310 may be configured to communicate with the respective devices using the Universal Plug and Play protocol designed for ancillary computer devices, although it will be apparent that any appropriate mechanism for communicating with the various devices may be suitably substituted.
- the device listeners may then be synchronized in an operation 320.
- each of the registered devices may have an internal clock or other timing mechanism that indicates local timing for an incoming natural language multi-modal interaction, wherein operation 320 may be used to synchronize the device listeners established in operation 310 according to the internal clocks or timing mechanisms for the respective devices.
- synchronizing the device listeners in operation 320 may include each device listener publishing information relating to the internal clock or local timing for the respective device.
- the device listeners may publish the information relating to the internal clock or local timing to the virtual router, whereby the virtual router may subsequently coordinate cooperative hybrid processing for natural language multi-modal interactions received at one or more of the devices in the hybrid processing environment.
- the information relating to the internal clock or local timing for the various devices in the hybrid processing environment may be further published to the other voice-enabled devices, the other non-voice devices, the voice-enabled server, and/or any other suitable device that may participate in cooperative processing for natural language nnulti-nnodal interactions provided to the hybrid processing environment.
- the device listeners may continually listen or otherwise monitor respective devices on the respective registered devices in an operation 330 to detect information relating to one or more natural language multi-modal interactions.
- the device listeners may be configured to detect occurrences of the natural language multi-modal interactions in response to detecting an incoming natural language utterance, a point of focus or attention focus selection associated with an incoming natural language utterance, and/or another interaction or sequence of interactions that relates to an incoming natural language multi-modal interaction.
- operation 330 may further include the appropriate device listeners capturing the natural language utterance and/or related non-voice device interactions that relate to the natural language utterance.
- the captured natural language utterance and related non-voice device interactions may then be analyzed in an operation 340 to manage subsequent cooperative processing in the hybrid processing environment.
- operation 340 may determine whether one device listener or multiple device listeners captured information relating to the natural language multi-modal interaction detected in operation 330.
- the hybrid processing environment may generally include various different devices that cooperate to process natural language multi-modal interactions, whereby the information relating to the natural language multi-modal interaction may be provided to one or a plurality of the devices in the hybrid processing environment.
- operation 340 may determine whether one device listener or multiple device listeners captured the information relating to the natural language multi-modal interaction in order to determine whether the hybrid processing environment needs to synchronize signals among various device listeners that captured information relating to the multi-modal interaction.
- a user interacting with the hybrid processing environment may view a web page presented on a non-voice display device and provide a natural language multi-modal interaction that requests more information about purchasing a product displayed on the web page.
- the user may then select text on the web page containing the product name using a mouse, keyboard, or other non-voice input device and provide a natural language utterance to a microphone or other voice-enabled device such as "Is this available on Amazon.com?"
- a device listener associated with the non-voice display device may detect the text selection for the product name in operation 330, and a device listener associated with the voice- enabled device may further detect the natural language utterance inquiring about the availability of the product in operation 330.
- the user may be within a suitable range of multiple voice-enabled devices, which may result in multiple device listeners capturing different signals corresponding to the natural language utterance (e.g., the interaction may occur within range of a voice- enabled mobile phone, a voice-enabled telematics device, and/or other voice-enabled devices, depending on the arrangement and configuration of the various devices in the hybrid processing environment).
- a sequence of operations that synchronizes different signals relating to the multi-modal interaction received at the multiple device listeners may be initiated in response to operation 340 determining that multiple device listeners captured information relating to the natural language multi-modal interaction.
- the natural language multi-modal interaction may be processed in an operation 390 without executing the sequence of operations that synchronizes different signals (i.e., the one device listener provides all of the input information relating to the multi-modal interaction, such that hybrid processing for the interaction may be initiated in operation 390 without synchronizing different input signals).
- sequence of synchronization operations may also be initiated in response to one device listener capturing a natural language utterance and one or more non-voice interactions to align different signals relating to the natural language multi-modal interaction, as described in greater detail herein.
- each device listener that receives an input relating to the natural language multi-modal interaction detected in operation 330 may have an internal clock or other local timing mechanism.
- the sequence of synchronization operations for the different signals may be initiated in an operation 350.
- operation 350 may include the one or more device listeners determining local timing information for the respective signals based on the internal clock or other local timing mechanism associated with the respective device listeners, wherein the local timing information determined for the respective signals may then be synchronized.
- synchronizing the local timing information for the respective signals may be initiated in an operation 360.
- operation 360 may generally include notifying each device listener that received an input relating to the multi-modal interaction of the local timing information determined for each respective signal.
- each device listener may provide local timing information for a respective signal to the virtual router, and the virtual router may then provide the local timing information for all of the signals to each device listener.
- operation 360 may result in each device listener receiving a notification that includes local timing information for each of the different signals that relate to the natural language multi-modal interaction detected in operation 330.
- the virtual router may collect the local timing information for each of the different signals from each of the device listeners and further synchronize the local timing information for the different signals to enable hybrid processing for the natural language multi-modal interaction.
- any particular natural language multi-modal interaction may include at least a natural language utterance, and may further include one or more additional device interactions relating to the natural language utterance.
- the utterance may generally be received prior to, contemporaneously with, or subsequent to the additional device interactions.
- the local timing information for the different signals may be synchronized in an operation 370 to enable hybrid processing for the natural language multi-modal interaction.
- operation 370 may include aligning the local timing information for one or more signals corresponding to the natural language utterance and/or one or more signals corresponding to any additional device interactions that relate to the natural language utterance.
- operation 370 may further include aligning the local timing information for the natural language utterance signals with the signals corresponding to the additional device interactions.
- any devices that participate in the hybrid processing for the natural language multi-modal interaction may be provided with voice components and/or non-voice components that have been aligned with one another.
- operation 370 may be executed on the virtual router, which may then provide the aligned timing information to any other device that may be invoked in the hybrid processing.
- one or more of the other devices that participate in the hybrid processing may locally align the timing information (e.g., in response to the virtual router invoking the voice-enabled server in the hybrid processing, resources associated with the voice-enabled server may be employed to align the timing information and preserve communication bandwidth at the virtual router).
- the virtual router and/or other devices in the hybrid processing environment may analyze the signals corresponding to the natural language utterance in an operation 380 to select the cleanest sample for further processing.
- the virtual router may include a messaging interface for receiving an encoded audio sample corresponding to the natural language utterance from one or more of the voice-enabled devices.
- the audio sample received at the virtual router may include the natural language utterance encoded in the MPEG-1 Audio Layer 3 (MP3) format or another lossy format to preserve communication bandwidth in the hybrid processing environment.
- MP3 MPEG-1 Audio Layer 3
- the audio sample may alternatively (or additionally) be encoded using the Free Lossless Audio Codec (FLAC) format or another lossless format in response to the hybrid processing environment having sufficient communication bandwidth for processing lossless audio that may provide a better sample of the natural language utterance.
- FLAC Free Lossless Audio Codec
- the signal corresponding to the natural language utterance that provides the cleanest sample may be selected in operation 380.
- one voice-enabled device may be in a noisy environment or otherwise associated with conditions that interfere with generating a clean audio sample, while another voice- enabled device may include a microphone array or be configured to employ techniques that maximize fidelity of encoded speech.
- the cleanest signal in response to multiple signals corresponding to the natural language utterance being received in operation 330, the cleanest signal may be selected in operation 380 and hybrid processing for the natural language utterance may then be initiated in an operation 390.
- the synchronization and initialization techniques illustrated in Figure 3 and described herein may ensure that the hybrid processing environment synchronizes each of the signals corresponding to the natural language multi-modal interaction and generates an input for further processing in operation 390 most likely to result in a correct intent determination. Furthermore, in synchronizing the signals and selecting the cleanest audio sample for the further processing in operation 390, the techniques illustrated in Figure 3 and described herein may ensure that none of the devices in the hybrid processing environment take action on a natural language multimodal interaction until the appropriate signals to be used in operation 390 have been identified. As such, hybrid processing for the natural language multi-modal interaction may be initiated in operation 390, as described in further detail herein.
- Figure 4 illustrates a flow diagram of am exemplary method for performing hybrid processing at one or more client devices in a natural language voice services environment.
- the one or more client devices may perform the hybrid processing in cooperation with a virtual router through a messaging interface that communicatively couples the client devices and the virtual router.
- the messaging interface may generally include a light client (or thin client) that provides a mechanism for the client devices to transmit input relating to a natural language multi-modal interaction to the virtual router, and that further provides a mechanism for the client devices to receive output relating to the natural language multi-modal interaction from the virtual router.
- the hybrid processing at the client devices may be initiated in response to one or more of the client devices receiving a natural language multi-modal interaction in an operation 410.
- the natural language multi-modal interaction may generally include a natural language utterance received at a microphone or other voice-enabled input device coupled to the client device that received the natural language multi-modal interaction, and may further include one or more other additional input modalities that relate to the natural language utterance (e.g., text selections, button presses, multi-touch gestures, etc.).
- the natural language multi-modal interaction received in operation 410 may include one or more queries, commands, or other requests provided to the client device, wherein the hybrid processing for the natural language multi-modal interaction may then be initiated in an operation 420.
- the natural language voice services environment may generally include one or more voice-enabled client devices, one or more non-voice devices, a voice-enabled server, and a virtual router arranged to communicate with each of the voice-enabled client devices, the non-voice devices, and the voice-enabled server.
- the virtual router may therefore coordinate the hybrid processing for the natural language multi-modal interaction among the voice-enabled client devices, the non-voice devices, and the voice-enabled server.
- the hybrid processing techniques described herein may generally refer to the virtual router coordinating cooperative processing for the natural language multi-modal interaction in a manner that involves resolving an intent of the natural language multi-modal interaction in multiple stages.
- each of the client devices that received an input relating to the natural language multi-modal interaction may perform initial processing for the respective input in an operation 420.
- a client device that received the natural language utterance included in the multi-modal interaction may perform initial processing in operation 420 that includes encoding an audio sample corresponding to the utterance, partially or completely transcribing the utterance, determining a preliminary intent for the utterance, or performing any other suitable preliminary processing for the utterance.
- the initial processing in operation 420 may also be performed at a client device that received one or more of the additional input modalities relating to the utterance.
- the initial processing performed in operation 420 for the additional input modalities may include identifying selected text, selected points of focus or attention focus, or generating any other suitable data that can be used to further interpret the utterance.
- an operation 430 may then include determining whether the hybrid processing environment has been configured to automatically route inputs relating to the natural language multi-modal interaction to the virtual router.
- operation 430 may determine that automatic routing has been configured to occur in response to multiple client devices receiving the natural language utterance included in the multi-modal interaction in operation 410.
- the initial processing performed in operation 420 may include the multiple client devices encoding respective audio samples corresponding to the utterance, wherein messages that include the encoded audio samples may then be sent to the virtual router in an operation 460.
- the virtual router may then select one of the encoded audio samples that provides a cleanest signal and coordinate subsequent hybrid processing for the natural language multi-modal interaction, as will be described in greater detail below with reference to Figure 5.
- operation 430 may determine that automatic routing has been configured to occur in response to the initial processing resulting in a determination that the multi-modal interaction relates to a request that may be best suited for processing on the voice-enabled server (e.g., the request may relate to a location-based search query or another command or task that requires resources managed on the voice-enabled server, content, applications, domains, or other information that resides on one or more devices other than the client device that received the request, etc.).
- the hybrid processing environment may be configured for automatic routing in response to other conditions and/or regardless of whether any attendant conditions exist, as appropriate.
- the virtual router in response to the virtual router coordinating the hybrid processing for the natural language multi-modal interaction, may provide results of the hybrid processing to the client device in an operation 470.
- the results provided to the client device in operation 470 may include a final intent determination for the natural language multi-modal interaction, information requested in the interaction, data generated in response to executing a command or task requested in the interaction, and/or other results that enable the client device to complete processing for the natural language request in operation 480.
- operation 480 may include the client device executing a query, command, task, or other request based on the final intent determination returned from the virtual router, presenting the requested information returned from the virtual router, confirming that the requested command or task has been executed, and/or performing any additional processing to resolve the natural language request.
- the client device may further process the natural language multi-modal interaction in an operation 440.
- the further processing in operation 440 may include the client device attempting to determine an intent for the natural language multi-modal interaction using local natural language processing capabilities. For example, the client device may merge any non- voice input modalities included in the multi-modal interaction a transcription for the utterance included in the multi-modal interaction.
- the conversational language processor on the client device may then determine the intent for the multi-modal interaction utilizing local information relating to context, domains, shared knowledge, criteria values, or other information.
- the client device may then generate one or more interpretations for the utterance to determine the intent for the multi-modal interaction (e.g., identifying a conversation type, one or more requests contained in the interactions, etc.).
- operation 440 may further include determining a confidence level for the intent determination generated on the client device (e.g., the confidence level may be derived in response to whether the client devices includes a multi-pass speech recognition engine, whether the utterance contained any ambiguous words or phrases, whether the intent differs from one context to another, etc.).
- an operation 450 may then determine whether or not to invoke off- board processing depending on the confidence level determined in operation 440.
- operation 450 may generally include determining whether the intent determined in operation 440 satisfies a particular threshold value that indicates an acceptable confidence level for taking action on the determined intent. As such, in response to the confidence level for the intent determination satisfying the threshold value, operation 450 may determine to not invoke off-board processing.
- the confidence level satisfying the threshold value may indicate that the client device has sufficient information to take action on the determined intent, whereby the client device may then process one or more queries, commands, tasks, or other requests to resolve the multi-modal interaction in operation 480.
- operation 450 may invoke off-board processing, which may include sending one or more messages to the virtual router in operation 460.
- the one or more messages may cause the virtual router to invoke additional hybrid processing for the multi-modal interaction in a similar manner as noted above, and as will be described in greater detail herein with reference to Figure 5.
- Figure 5 illustrates a flow diagram of am exemplary method for performing hybrid processing at a virtual router in a natural language voice services environment.
- the virtual router may coordinate the hybrid processing for natural language multi-modal interactions received at one or more client devices.
- the virtual router may receive one or more messages relating to a natural language multi-modal interaction received at one or more of the client devices in the voice services environment.
- the virtual router may include a messaging interface that communicatively couples the virtual router to the client devices and a voice-enabled server, wherein the messaging interface may generally include a light client (or thin client) that provides a mechanism for the virtual router to receive input from one or more the client devices and/or the voice-enabled server, and further to transmit output to one or more the client devices and/or the voice-enabled server.
- the messages received in operation 510 may generally include any suitable processing results for the multi-modal interactions, whereby the virtual router may coordinate hybrid processing in a manner that includes multiple processing stages that may occur at the virtual router, one or more of the client devices, the voice-enabled server, or any suitable combination thereof.
- the virtual router may analyze the messages received in operation 510 to determine whether to invoke the hybrid processing in a peer-to-peer mode.
- one or more of the messages may include a preliminary intent determination that the virtual router can use to determine whether to invoke one or more of the client devices, the voice-enabled server, or various combinations thereof in order to execute one or more of the multiple processing stages for the multi-modal interaction.
- one or more of the messages may include an encoded audio sample that the virtual router forwards to one or more of the various devices in the hybrid processing environment.
- the virtual router may analyze the messages received in operation 510 to determine whether or not to invoke the voice-enabled server to process the multi-modal interaction (e.g., the messages may include a preliminary intent determination that indicates that the multi-modal interaction includes a location-based request that requires resources residing on the server).
- the virtual router may forward the messages to the server in an operation 530.
- the messages forwarded to the server may generally include the encoded audio corresponding to the natural language utterance and any additional information relating to other input modalities relevant to the utterance.
- the voice-enabled server may include various natural language processing components that can suitably determine the intent of the multi-modal interaction, whereby the messages sent to the voice- enabled server may include the encoded audio in order to permit the voice-enabled server to determine the intent independently of any preliminary processing on the client devices that may be inaccurate or incomplete.
- results of the processing may then be returned to the virtual router in an operation 570.
- the results may include the intent determination for the natural language multi-modal interaction, results of any queries, commands, tasks, or other requests performed in response to the determined intent, or any other suitable results, as will be apparent.
- the virtual router may coordinate the hybrid processing among one or more the client devices, the voice-enabled server, or any suitable combination thereof.
- the virtual router may determine a context for the natural language multi-modal interaction in an operation 540 and select one or more peer devices based on the determined context in an operation 550.
- one or more of the client devices may be configured to provide content and/or services in the determined context, whereby the virtual router may forward one or more messages to such devices in an operation 560 in order to request such content and/or services.
- the multi-modal interaction may include a compound request that relates to multiple contexts supported on different devices, whereby the virtual router may forward messages to each such device in operation 560 in order to request appropriate content and/or services in the different contexts.
- the interaction may include a request to be processed on the voice-enabled server, yet the request may require content and/or services that reside on one or more of the client devices (e.g., a location-based query relating to an entry in an address book on one or more of the client devices).
- the virtual router may generally forward various messages to the selected peer devices in operation 560 to manage the multiple stages in the hybrid processing techniques described herein. For example, the virtual router may send messages to one or more voice-enabled client devices that have intent determination capabilities in a particular context, one or more non-voice client devices that have access to content, services, and/or other resources needed to process the multi-modal interaction, or any appropriate combination thereof.
- the virtual router may therefore send messages to the client devices and/or the voice-enabled server in operation 560 and receive responsive messages from the client devices and/or the voice-enabled server in operation 570 in any appropriate manner (e.g., in parallel, sequentially, iteratively, etc.). The virtual router may then collate the results received in the responsive messages in operation 580 and return the results to one or more of the client devices for any final processing and/or presentation of the results.
- Implementations of the invention may be made in hardware, firmware, software, or various combinations thereof.
- the invention may also be implemented as instructions stored on a machine-readable medium, which may be read and executed by one or more processors.
- a machine-readable medium may include various mechanisms for storing or transmitting information in a form readable by a machine (e.g., a computing device).
- a machine-readable storage medium may include read only memory, random access memory, magnetic disk storage media, optical storage media, flash memory devices, or other storage media
- a machine- readable transmission media may include forms of propagated signals, such as carrier waves, infrared signals, digital signals, or other transmission media.
- firmware, software, routines, or instructions may be described in the above disclosure in terms of specific exemplary aspects and implementations of the invention, and performing certain actions. However, it will be apparent that such descriptions are merely for convenience, and that such actions in fact result from computing devices, processors, controllers, or other devices executing the firmware, software, routines, or instructions.
Abstract
Description
Claims
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CN201080061105.8A CN102792294B (en) | 2009-11-10 | 2010-09-16 | The system and method for the hybrid processing in natural language speech service environment |
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KR1020177032087A KR101912058B1 (en) | 2009-11-10 | 2010-09-16 | System and method for hybrid processing in a natural language voice services environment |
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