Seminar Report on Voice XML

May 3, 2018 | Author: Krista Smith | Category: Cloud Computing, Speech Synthesis, Technology, World Wide Web, Web Server
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VOICEXML 2.0 AND THE W3C SPEECH INTERFACE FRAMEWORK

1. INTRODUCTION

Cloud Computing has great potential of providing robust computational power to the society at reduced cost. It enables customers with limited computational resources to outsource their large computation workloads to the cloud, and economically enjoy the massive computational  power, bandwidth, storage, and even appropriate software that can be shared in a pay-per-use manner. Despite the tremendous benefits, security is the primary obstacle that prevents the wide adoption of this promising computing model, especially for customers when their confidential data are consumed and produced during the computation.

On the one hand, the outsourced computation workloads often contain sensitive information, such as the business financial records, proprietary research data, or personally identifiable health information etc. To combat against unauthorized information leakage, sensitive data have to be encrypted before outsourcing so as to provide end to- end data confidentiality assurance in the cloud and beyond. However, ordinary data encryption techniques in essence prevent cloud from  performing any meaningful operation of the underlying plaintext data, making the computation over encrypted data a very hard problem. On the other hand, the operational details inside the cloud are not transparent enough to customers. As a result, there do exist various motivations for cloud server to behave unfaithfully and to return incorrect results, i.e., they may behave beyond the classical semi honest model.

Fully homomorphic encryption (FHE) scheme, a general result of secure computation outsourcing has been shown viable in theory, where the computation is represented by an encrypted combinational Boolean circuit that allows to be evaluated with encrypted private inputs.

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Existing System Despite the tremendous benefits, outsourcing computation to the commercial public cloud is also depriving customers’ direct control over the systems that consume and produce their data during the computation, which inevitably brings in new security concerns and challenges towards this promising computing model. On the one hand, the outsourced computation workloads often contain sensitive information, such as the business financial records, proprietary research data, or personally identifiable health information etc.

To combat against unauthorized information leakage, sensitive data have to be encrypted  before outsourcing. so as to provide end to- end data confidentiality assurance in the cloud and  beyond. However, ordinary data encryption techniques in essence prevent c loud from performing any meaningful operation of the underlying plaintext data, making the computation over encrypted data a very hard problem. On the other hand, the operational details inside the cloud are not transparent enough to customers. As a result, there do exist various motivations for cloud server to behave unfaithfully and to return incorrect results, i.e., they may behave beyond the classical semi hones model. For example, for the computations that require a large amount of computing computing resources, there are huge financial incentives for the cloud to be “lazy” if the customers cannot tell the correctness of the output. Besides, possible software bugs, hardware failures, or even outsider attacks might also affect the qu ality of the computed results.

Thus, we argue that the cloud is intrinsically not secure from the viewpoint of customers. Without providing a mechanism for secure computation outsourcing, i.e., to protect the sensitive input and output information of the workloads and to validate the integrity of the computation result, it would be hard to expect cloud customers to turn over control of their workloads from local machines to cloud solely based on its economic savings and resource flexibility. For  practical consideration, such a design should further ensure that customers perform less amount of operations following the mechanism than completing the computations by themselves directly. Otherwise, there is no point for customers to seek help from cloud. Recent researches in both the cryptography and the theoretical computer science communities have made steady advances in “secure outsourcing expensive computations”. computations”. DEPT OF IT

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Proposed System

On the one hand, the outsourced computation workloads often contain sensitive information, such as the business financial records, proprietary research data, or personally identifiable health information etc. To combat against unauthorized information leakage, sensitive data have to be encrypted before outsourcing so as to provide end to- end data confidentiality assurance in the cloud and beyond. However, ordinary data encryption techniques in essence prevent cloud from  performing any meaningful operation of the underlying plaintext data, making the computation over encrypted data a very hard problem. On the other hand, the operational details inside the cloud are not transparent enough to customers. As a result, there do exist various motivations for cloud server to behave unfaithfully and to return incorrect results, i.e., they may behave beyond the classical semi honest model.

Fully homomorphic encryption (FHE) scheme, a general result of secure computation outsourcing has been shown viable in theory, where the computation is represented by an encrypted combinational Boolean circuit that allows to be evaluated with encrypted private inputs.

Motorola embraced the markup approach as a way to provide mobile users with up-tothe-minute information and interactions. Given the corporate focus on mobile productivity, Motorola's efforts focused on hands-free access. This led to an emphasis on speech recognition rather than touch-tones as an input mechanism. Also, by starting later, Motorola was able to base its language on the recently-developed XML framework. These efforts led to the October 1998 announcement of the VoxML™ technology. Since the announcement, thousands of developers have downloaded the VoxML language specification and software development kit.

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There has been growing interest in this general concept of using a markup language to define voice access to Web-based applications. For several years Netphonic has had a product known as Web-on-Call that used an extended HTML and software server to provide telephone access to Web services; in 1998, General Magic acquired Netphonic to support Web access for  phone customers. In October 1998, the World Wide Web Consortium (W3C) sponsored a workshop on Voice Browsers. A number of leading companies, including AT&T, IBM, Lucent, Microsoft, Motorola, and Sun, participated. Some systems, such as Vocalis' SpeecHTML, use a subset of HTML, together with a fixed set of interaction policies, to provide interactive voice services. Most recently, IBM has announced SpeechXML, which provides a markup language for speech interfaces to Web pages; the current version provides a speech interface for desktop PC  browsers. The VoiceXML Forum will explore public domain ideas from existing work in the voice  browser arena, and where appropriate include these in its final proposal. As the standardization  process for voice browsers develops, the VoiceXML Forum will work with others to find common ground and the right solution for business needs.

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GOALS OF VOICEXML VoiceXML’s main goal is to bring the full power of web development and content delivery to voice response applications, and to free the authors of such applications from lowlevel programming and resource management. It enables integration of voice services with data services using the familiar client-server paradigm. A voice service is viewed as a sequence of interaction dialogs between a user and an implementation platform. The dialogs are provided by document servers, which may be external to the implementation platform. Document servers maintain overall service logic, perform database and legacy system operations, and produce dialogs. A VoiceXML document specifies each interaction dialog to  be conducted by a VoiceXML interpreter. User input affects dialog interpretation and is collected into requests submitted to a document server. The document server may reply with another VoiceXML document to continue the user’s session with other dialogs. VoiceXML is a markup language that: 

Minimizes client/server interactions by specifying multiple interactions per document.



Shields application authors from low-level, and platform-specific details.

Separates user interaction code (in VoiceXML) from service logic (CGI scripts). 

Promotes service portability across implementation platforms. VoiceXML is a common

language for content providers, tool providers, and platform providers. 

Is easy to use for simple interactions, and yet provides language features to support

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While VoiceXML strives to accommodate the requirements of a majority of voice response services, services with stringent requirements may best be served by dedicated applications that employ a finer level of control.

SCOPE OF VOICEXML The language describes the human-machine interaction provided by voice response systems, which includes: 

Output of synthesized speech (text-to-speech).



Output of audio files.



Recognition of spoken input.



Recognition of DTMF input.



Recording of spoken input.



Telephony features such as call transfer and disconnect. The language provides means for collecting character and/or spoken input, assigning

the input to document-defined request variables, and making decisions that affect the interpretation of documents written in the language. A document may be linked to other documents through Universal Resource Identifiers (URIs).

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CREATING A BASIC VOICE XML DOCUMENT VoiceXML is an extensible markup language (XML) for the creation of automated speech recognition (ASR) and interactive voice response (IVR) applications. Based on the XML tag/attribute format, the VoiceXML syntax involves enclosing instructions (items) within a tag structure in the following manner: < element_name attribute_name="attribute_value"> ......contai ......contai ned i tems...... tems......

< /element_name>

A VoiceXML application consists of one or more text files called documents. These document files are denoted by a ".vxml" file extension and contain the various VoiceXML instructions for the application. It is recommended tha t the first instruction in any document to be seen by the interpreter be the XML version tag: < ?xml version="1.0"?>

The remainder of the document's instructions should be enclosed by the vxml tag with the version attribute set equal to the version of VoiceXML being used ("1.0" in the present case) as follows: < vxml version="1.0">

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VOICEXML VOICEXML ELEMENTS Element

Purpose



Assign a variable a value.



Play an audio clip within a prompt.



A container of (non-interactive) executable code.



JSML element to insert a pause in output.



Catch an event.



Define a menu item.



Clear one or more form item variables.

Disconnect a session.

JSML element to classify a region of text as a particular type.



Specify a touch-tone key grammar.



Used in elements.



Used in elements.



JSML element to change the emphasis of speech output.

Shorthand for enumerating the choices in a menu.

Catch an error event.



Exit a session.



Declares an input field in a form.



An action executed when fields are filled.



A dialog for presenting information and collecting data.



Go to another dialog in the same or different document.



Specify a speech recognition grammar.



Catch a help event.



Simple conditional logic.



Declares initial logic upon entry into a (mixed-initiative) form.



Specify a transition common to all dialogs in the link’s scope.



A dialog for choosing amongst alternative destinations.

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Element

Purpose



Define a meta data item as a name/value pair.



Catch a noinput event.



Catch a nomatch event.



Interact with a custom extension.



Specify an option in a



Parameter in or .



Queue TTS and audio output to the user.



Control implementation platform settings.



JSML element to change the prosody of speech output.



Record an audio sample.



Play a field prompt when a field is re-visited after an event.



Return from a subdialog.



Top-level element in each VoiceXML document.



Specify a block of ECMAScript client-side scripting logic.



Invoke another dialog as a subdialog of the current one.



Submit values to a document server.



Throw an event.



Transfer the caller to another destination.



Insert the value of a expression in a prompt.

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ARCHITECTURAL MODEL The architectural model assumed by this document has the following components:

FIG. 7.1 A document server  (e.g.   (e.g. a web server) processes requests from requests from a client application, the VoiceXML Interpreter , through the VoiceXML interpreter context . The server produces VoiceXML documents  documents  in reply, which are processed by the VoiceXML Interpreter. The VoiceXML interpreter context may monitor user inputs in parallel with the VoiceXML interpreter. For example, one VoiceXML interpreter context may always listen for a special escape phrase that takes the user to a high-level personal assistant, and another may listen for escape phrases that alter user preferences like volume or text-to-speech characteristics. DEPT OF IT

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The implementation platform  platform  is controlled by the VoiceXML interpreter context and  by the VoiceXML interpreter. For instance, in an interactive voice response application, the VoiceXML interpreter context may be responsible for detecting an incoming call, acquiring the initial VoiceXML document ,   ,  and answering the call, while the VoiceXML interpreter conducts the dialog after answer. The implementation platform generates events in response to user actions (e.g. spoken or character input received, disconnect) and system events (e.g. timer expiration). Some of these events are acted upon by the VoiceXML interpreter itself, as specified by the VoiceXML document, while others are acted upon by the VoiceXML interpreter context.

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PRINCIPLES OF DESIGN VoiceXML is an XML schema. For details about XML, refer to the Annotated XML Reference Manual. 1. The language promotes portability of services through ab straction of platform resources. 2. The language accommodates platform diversity in supported audio file formats, speech grammar formats, and URI schemes. While platforms will respond to market pressures and support common formats, the language per se will not specify them. 3. The language supports ease of authoring for common types of interactions. 4. The language has a well-defined semantics that preserves the author's intent regarding the behavior of interactions with the user. Client heuristics are not required to determine document element interpretation. 5. The language has a control flow mechanism. 6. The language enables a separation of service logic from interaction behavior. 7. It is not intended for heavy computation, database operations, or legacy system operations. These are assumed to be handled by resources outside the document interpreter, e.g. a document server. 8. General service logic, state management, dialog generation, and dialog sequencing are assumed to reside outside the document interpreter. 9. The language provides ways to link documents using URIs, and also to submit data to server scripts using URIs. 10. VoiceXML provides ways to identify exactly which data to submit to the server, and which HTTP method (get or post) to use in the submittal. 11. The language does not require document authors to explicitly allocate and deallocate dialog resources, or deal with concurrency. Resource allocation and concurrent threads of control are to be handled by the implementation platform.

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IMPLEMENTATION IMPLEMENTATION PLATFORM REQUIREMENTS This section outlines the requirements on the hardware/software platforms that will support a VoiceXML interpreter. Document acquisition.   The interpreter context is expected to acquire documents for the

VoiceXML interpreter to act on. In some cases, the document request is generated by the interpretation of a VoiceXML document, while other requests are generated by the interpreter context in response to events outside the scope of the language, for example an incoming  phone call. Audio output.  An implementation platform can provide audio output using audio files and/or

using text-to-speech (TTS). When both are supported, the platform must be able to freely sequence TTS and audio output. Audio files are referred to by a URI. The language does not specify a required set of audio file formats. Audio input.  An implementation platform is required to detect and report character and/or

spoken input simultaneously and to control input detection interval duration with a timer whose length is specified by a VoiceXML document. 

It must report characters (for example, DTMF) entered by a u ser.



It must be able to receive speech recognition grammar data dynamically. Some

VoiceXML elements contain speech grammar data; others refer to speech grammar data through a URI. The speech recognizer must be able to accommodate dynamic update of the spoken input for which it is listening through either method of speech grammar data specification. 

It should be able to record audio received from the user. The implementation platform

must be able to make the recording available to a request  variable.  variable.

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CONCEPTS A VoiceXML document   (or a set of documents called an application) application) forms a conversational finite state machine. The user is always in one conversational state, or dialog , at a time. Each dialog determines the next dialog to transition to. Transitions  Transitions  are specified using URIs, which define the next document and dialog to use. If a URI does not refer to a document, the current document is assumed. If it does not refer to a dialog, the first dialog in the document is assumed. Execution is terminated when a dialog does not specify a successor, or if it has an element that explicitly e xplicitly exits the conversation. 10.1 DIALOGS AND SUBDIALOGS

There are two kinds of dialogs:  forms   forms  and menus. menus. Forms define an interaction that collects values for a set of field item variables. Each field may specify a grammar that defines the allowable inputs for that field. If a form-level grammar is present, it can be used to fill several fields from one utterance. A menu presents the user with a choice of options and then transitions to another dialog based on that choice. A subdialog  is   is like a function call, in that it provides a mechanism for invoking a new interaction, and returning to the original form. Local data, grammars, and state information are saved and are available upon returning to the calling document. Subdialogs can be used, for example, to create a confirmation sequence that may require a database query; to create a set of components that may be shared among documents in a single application; or to create a reusable library of dialogs shared among many applications. 10.2 SESSIONS

A session begins  session begins when the user starts to interact with a VoiceXML interpreter context, continues as documents are loaded and processed, and ends when requested by the user, a document, or the interpreter context.

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10.3 APPLICATIONS

An application  application  is a set of documents sharing the same application root document . Whenever the user interacts with a document in an application, its application root document is also loaded. The application root document remains loaded while the user is transitioning  between other documents in the same application, and it is unloaded when the user transitions to a document that is not in in the application. While it is loaded, the application root document’s variables are available to the other documents as application variables, variables, and its grammars can also be set to remain active for the duration d uration of the application.

Figure 10.3.1: Transitioning between documents in an application. 10.4 GRAMMARS

Each dialog has one or more speech and/or DTMF  grammars   grammars  associated with it. In machine directed applications, directed applications, each dialog’s grammars are active only when the user is in that dialog. In mixed initiative  initiative  applications, where the user and the machine alternate in determining what to do next, some of the dialogs are flagged to make their grammars active (i.e., listened for) even when the user is in another dialog in the same document, or on another loaded document in the same application. In this situation, if the user says something matching another dialog’s active grammars, execution transitions to that other dialog, with the user’s utterance treated as if it were said in that dialog. Mixed initiative adds flexibility and power to voice applications.

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10.5 EVENTS

VoiceXML provides a form-filling mechanism for handling "normal" user input. In addition, VoiceXML defines a mechanism for handling events not covered by the form mechanism. Events are thrown by the platform under a variety of circumstances, such as when the user does not respond, doesn't respond intelligibly, requests help, etc. The interpreter also throws events if it finds a semantic error in a VoiceXML document. Events are caught by catch elements or their syntactic shorthand. Each element in which an event can occur may specify catch elements. Catch elements are also inherited from enclosing elements "as if by copy". In this way, common event handling behavior can be specified at any level, and it applies to all lower levels. 10.6 LINKS

A link  supports  supports mixed initiative. It specifies a grammar that is active whenever the user is in the scope of the link. If user input matches the link’s grammar, control transfers to the link’s destination destination URI. A can be used to throw an event to go to a destination URI.

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SUPPORTED AUDIO FILE FORMATS VoiceXML recommends that a platform support the playing and recording audio formats specified below. Note: a platform need not support both A-law A-law and μ-law μ-law simultaneously.

Audio Format

MIME Type

Raw (headerless) 8kHz 8-bit mu-law [PCM] single channel.

audio/basic

Raw (headerless) 8kHz 8 bit A-law [PCM] single channel.

audio/x-alaw-basic

WAV (RIFF header) 8kHz 8-bit mu-law [PCM] single channel.

audio/wav

WAV (RIFF header) 8kHz 8-bit A-law [PCM] single channel.

audio/wav

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EXAMPLE The top-level element is , which is mainly a container for dialogs. dialogs. There are two types of dialogs:  forms   forms  and menus. menus. Forms present information and gather input; menus offer choices of what to do next. This example has a single form, which contains a block that synthesizes and presents “Hello World!” to the user. Since the form does not specify a successor dialog, the conversation ends. Our second example asks the user for a choice of drink and then submits it to a server script: Would you like coffee, tea, milk, or nothing?

A  field  is   is an input field. The user must provide a value for the field before proceeding to the next element in the form. A sample interaction is:C (computer): Would you like coffee, tea, milk, or nothing? H (human): Orange juice. C: I did not understand what you said. C: Would you like coffee, tea, milk, or nothing? H: TeaC: (continues in document drink2.asp)

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APPLICATIONS OF VOICE XML Below are a few examples in which VoiceXML applications can be used: 

Voice portals: Just like Web portals, voice portals can be used to provide personalized

services to access information like stock quotes, weather, restaurant listings, news, etc. 

Location-based services: You can receive targeted information specific to the location you

are dialing from. Applications use the telephone number you are dialing from. 

Voice alerts (such as for advertising): VoiceXML can be used to send targeted alerts to a

user. The user would sign up to receive special alerts informing him of upcoming events. 

Commerce: VoiceXML can be used to implement applications that allow users to purchase

over the phone. Because voice gives you less information than graphics, specific products that don't need a lot of description (such as tickets, CDs, office supplies, etc.) work well.

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CONCLUSION VoiceXML is designed for creating audio dialogs that feature synthesized speech, digitized audio, recognition of spoken and DTMF key input, recording of spoken input, telephony, and mixed-initiative conversations. Its major goal is to bring the advantages of web based development and content delivery to intera. With this we can conclude VoiceXML development in speech recognition application is greatly simplified by using familiar web infrastructure, including tools and Web servers. Instead of using a PC with a Web browser, any telephone can access VoiceXML applications via a VoiceXML "interpreter" (also known as a "browser") running on a telephony serverctive voice response applications.

Future versions of the standard: VoiceXML 3.0 will be the next major release of VoiceXML, with new major features. It includes a new XML statechart description language called SCXML.

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[13] Krafzig, D., Banke, K., Slama, D., Enterprise SOA: Service Oriented-Architecture Best Practices, Prentice Hall PTR, 2004, 416 pages. [14] Levin L. , Lavie A. , Woszczyna M. , Gates D. , Ga-valda M. , Koll D., Waibel A., The JANUS-III JANUS-III translation

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[27] http://www.microsoft.com/speech/download/sdk51/ [28] SOAP: Simple Object Access Protocol,http://www.w3.org/TR/soap [29] Telispeech 1.2 from Telisma, http://www.telisma.com/ [30]

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