Abstract:
A voice response unit (VRU) includes a silent prompt feature in the form of an intentional delay inserted after a message is given to a caller, during which delay the caller may invoke alternative processing or interrupt current processing. If appropriate alternative or interrupt commands are not received during the delay period, then processing continues as provided in accordance with the previously played message. The duration of this silent prompt delay is carefully selected to provide sufficient response time for the caller to request alternative processing, while avoiding a perceptible or objectionable delay to the average caller not requiring alternative processing.

Description:
CROSS-REFERENCE TO RELATED APPLICATIONS 
     This application is a continuation of U.S. application Ser. No. 13/611,989, filed Sep. 12, 2012, which is a continuation of U.S. application Ser. No. 11/767,853, filed Jun. 25, 2007, which is a continuation of U.S. application Ser. No. 09/309,274, filed May 11, 1999, the contents of which are incorporated herein by reference. 
    
    
     BACKGROUND OF THE INVENTION 
     1. Field of the Invention 
     The present invention relates generally to telecommunications and particularly to voice response platforms and methods. 
     2. Description of the Related Technology 
     Voice response units (VRUs) and systems are widely used to replace or supplement human operators and attendants. VRUs provide user access to information using a conventional telephone by providing voice prompts and information. The user accesses the platform using a conventional telephone and interacts using, typically, either the touch tone pad and DTMF signaling or by speaking requests and responses. The VRU, in response, greets callers and provides instructions, prompts, menus, and information to the user using prerecorded or synthesized speech. These voice response units are extensively used by service providers, such as banks, government offices, customer service organizations, etc. to automate telephone call answering, routing and responding to inquiries. VRUs are also used to interface users with other applications, such as voice mail systems and telephone directory services. 
     VRUs are programmed to provide set responses to particular events and requests. Thus, a VRU may answer an incoming telephone call with a standard greeting followed by a menu or other information describing available choices and sub-menus available to the user together with the appropriate access method. For example, the user may be prompted to enter the number “1” using the telephone touch tone pad to indicate that a first option is desired, the number “2” to select a second option, etc. Alternatively, if the VRU includes a speech recognition capability, the VRU may prompt the user to speak a desired option or to input other information such as the name of a called party. As the VRU interacts with the user, it will provide information and prompting using appropriate prestored or synthesized voice messages. 
     As part of the scripting process, some VRUs take into account additional information in selecting an appropriate voice message. For example, some VRUs will greet a caller with a message appropriate to the time of day, day of week, etc. Certain VRUs also take into consideration information obtained about the caller to tailor an appropriate response. For example, once a caller has been identified either through the user entering identifying information such as a Social Security number or automatically through the use of automatic number identification (ANI), the VRU may tailor its scripts and messaging to that user by, for example, incorporating the user&#39;s name into the script as appropriate. Other VRUs allow the user to select the types of messages used or automatically attempt to select one of several available scripts appropriate to a particular user. For example, an inexperienced user may manually select detailed instructions for using an unfamiliar system while more experienced users may elect to receive more abbreviated prompts. Alternatively, the system may automatically select an appropriate level of detail based on user response time or the number of erroneous or incomplete responses received from the caller to prior prompts. However, while the system will adapt to a user by providing an appropriate script, the wording of each script is fixed and invariable. 
     While VRUs have consistently improved the speech quality of prompts and information provided to a user, present systems still fail to fully simulate typical human conversation modalities. For example, while VRUs are used to obtain telephone directory information and provide automatic dialing of telephone numbers, the scripting does not readily adapt to human conventions for handling alternative and exception processing. In particular, conventional VRUs include extensive prompts for a wide variety of processing options. However, before a user can select a desired option, he or she must first access the associated menu and, either wait for the corresponding message and prompts to be played, or manually bypass the announcements by entering a selection prior to completion of the announcements. In either case, the VRU does not provide the type and quality of interactivity expected of a human operator. 
     Accordingly, a need exists for a more user friendly VRU which provides an improved man-machine interface, enhances user interaction with the system and minimizes user frustration. A further need exists for a VRU which reduces the monotony characteristic of conventional automated response systems. A still further need exists for a VRU capable of simulating typical human conversation modalities and patterns and which can handle alternative processing without requiring the user to access additional menus. A still further need exists for a VRU that can handle normal system uses while accommodating exception processing. A still further need exists for a VRU that provides a wide variety options and alternative processes without impeding or burdening users of primary functionalities of the system. 
     SUMMARY OF THE INVENTION 
     The present invention is directed to a voice response unit (VRU) and a method of responding to spoken commands which provides a predetermined silent period after an information message or announcement has been played. During this silent period the user may command the system to perform alternate processing including aborting the default processing but without having been prompted to provide such commands or requiring a confirmation command before performing default processing. Thus, if no alternative processing is requested or commanded by the user, default processing is performed consistent with the prior message or announcement. However, if an alternative processing command or interrupt request is recognized during the delay period, default processing is suspended in favor of the requested option or appropriate error processing. This silent delay period, in effect, constitutes a “silent prompt” during which the user can interrupt processing and initiate alternative processing without accessing a separate menu or receiving verbal prompts from the system for inputting such commands. 
     The silent delay period is preferably in the range of 1.2 to 2.3 seconds, an optimal period being within the range of 1.5 to 2.0 seconds, an optimal time being approximately 1.8 seconds. The VRU is advantageously included as part of a voice activated dialer which receives speech from a calling party to access and identify a telephone number of a called party. Prior to initiation of dialing, and immediately after announcing the name of the party being called, a silent delay period within the aforementioned ranges is provided to allow the user to abort the default dialing process and, instead, invoke alternative or error processing. The alternative processing may include automatic consideration of other close matches, i.e., “second guesses,” to handle processing of called parties with similar sounding names. Error processing may include another opportunity to input the name of the called party. 
     According to one aspect of the invention, a method of providing voice responses to commands includes steps of receiving a first command and selecting a first processing option in response to the first command. The method further includes providing a voice message indicative of the first processing option selected and providing a silent period of a predetermined duration immediately subsequent to a completion of the step of providing the voice message. Finally, the method selectively (i) initiates alternative processing in response to a receipt of a second command input during the silent delay period or (ii) initiates the first processing option in response to an absence of the second command input for a duration of the silent delay period. Advantageously, a duration of the silent delay period is in the range of 1.2 to 2.3 seconds, a preferable range being 1.5 to 2.0 seconds with an optimal delay of 1.8 seconds. The commands may comprise a variety of signals including a speech input, DTMF, or other formats and protocols. 
     According to another aspect of the invention, a method of telephone dialing uses a voice activated dialer including a directory of subscriber names and telephone numbers. The method includes the steps of selecting one of the subscribers most closely corresponding to the speech input and providing a speech output corresponding to the selected one of the subscribers. A silent delay period of a predetermined duration is provided immediately subsequent to a completion of provision of the speech output. The method further includes the step of selectively (i) initiating alternative processing in response to a receipt of a command input during the silent delay period or (ii) dialing the telephone number corresponding to the selected one of the subscribers immediately after the delay period and in response to an absence of (i.e., failure to detect) the command input for the duration of the silent delay period. According to a feature of the invention, the command input comprises a DTMF audio signal or, alternatively, a speech input wherein the method further includes the step of listening for the second speech input. The second speech input may include a predetermined spoken command or one of a plurality of predetermined spoken commands. 
     According to another feature of the invention, the step of listening includes recognizing the second speech input to provide speech content data and comparing the speech content data with a list of alternative processing commands. 
     According to another feature of the invention, the method includes the steps of receiving a first speech input, recognizing a content of the first speech input, and comparing the content with the directory of names. Further, the command input may include a second speech signal wherein the method further includes a step of listening for the second speech input, receiving it, recognizing a content thereof, and comparing the content with a list of alternative processing commands. The step of providing a speech output may further include retrieving audio data corresponding to the selected one of the subscribers and converting the audio data into a speech output. This conversion step may further include decoding the audio data, concatenating a plurality of phonemes, and/or synthesizing speech from the audio data. 
     According to yet another feature of the invention, the alternative processing includes providing a speech output corresponding to the telephone number of the selected one of the subscribers. Alternatively, the alternative processing may include providing an alternate telephone number for the selected subscriber, dialing the alternate number and supplying a data signal corresponding to the selected subscriber to a remote system, e.g., a voice mail system (VMS). The data signal may represent the telephone number of the selected subscriber for provision to the VMS to provide for access of the subscriber&#39;s voice mailbox on that system. 
     According to another aspect of the invention, a method of telephone dialing using a voice activated dialer, including a directory of subscriber names and telephone numbers, includes the steps of: receiving a first speech input; recognizing the first speech input to provide first speech content data; selecting one of the subscribers most closely corresponding to the first speech content data; providing a speech output corresponding to the selected one of the subscribers; providing a silent delay period of a predetermined duration within a range of 1.2 to 2.3 seconds immediately subsequent to a completion of the step of providing the speech output; listening for a second speech input during the silent period; recognizing the second speech input to provide second speech content data; and, selectively, (i) initiating alternate processing in response to the second speech content data including an alternate processing command, and, otherwise, (ii) dialing the telephone number corresponding to the selected one of the subscribers immediately after the delay period. 
     According to another aspect of the invention, a voice response unit includes means for receiving a first command for selecting a first processing option in response to the first command. The unit further includes means for providing a voice message indicative of the first processing option selected, providing a silent delay period of a predetermined duration immediately subsequent to a completion of provision of the voice message, and selectively (i) initiating alternate processing in response to a receipt of a second command input during the silent delay period and (ii) initiating the first processing option in response to an absence of the second command input for a duration of and during the silent delay period. 
     According to another aspect of the invention, a voice activated dialer includes a memory storing a directory of subscriber names and telephone numbers; comparison means for selecting one of the subscribers most closely corresponding to a first speech input; speech output means for providing a speech output corresponding to a selected one of the subscribers; timer means for providing a silent delay period of a predetermined duration immediately subsequent to a completion of providing the speech output; and control means for selectively (i) initiating alternate processing in response to a receipt of a command input during the silent delay period and (ii) dialing the telephone number corresponding to the selected one of the subscribers immediately after the delay period and in response to an absence of the command input for a duration of and during the silent delay period. 
     These, together with other objects and advantages which will be subsequently apparent, reside in the details of construction and operation as more fully hereinafter described in the claims, with reference being had to the accompanying drawings forming a part thereof, wherein like numerals refer to like elements throughout. 
    
    
     
       BRIEF DESCRIPTION OF THE DRAWINGS 
         FIG. 1  is a block diagram of a voice response unit including silent prompting for exception processing. 
         FIG. 2  is a flow processing diagram for a voice response unit implementing a speech dialer including silent prompting. 
         FIGS. 3   a - 3   d  are flow processing diagrams for a voice response unit providing telephone directory and call completion services including a silent prompting period. 
     
    
    
     DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENT 
       FIG. 1 . is a functional block diagram of a voice response unit  100  for providing telephone directory information to a caller and for providing related services including call completion to the named party. VRU  100  includes a processor  102  connected to, controlling, and receiving a recognized speech output from a speech recognition engine  116 . Processor  102  is also connected to a sound card  118  for playing and/or synthesizing voice messages to a caller. Telephone line interface card  120 , under control of processor  102 , supplies an audio output from telephone equipment represented by telco switch  130  to speech recognition engine  116 . Sound card  118 , in turn, provides a speech audio output to telephone line interface card  120  for transmission to telco switch  130 . 
     Processor  102  further has access to mass storage, conventionally in the form of a hard disk memory, including stored voice messages  122  and telephone directory  124 . Processor  102  includes and runs several software systems including a supervisory operating system  104  (including PseudoRandom Number Generator  108 ), Delay Timer  106 , Speech Recognition Client  110 , Telephony module  112 , and Voice Dialing Application and Interface  114 . Conventionally, pseudorandom number generator  108  may be implemented in software as an operating system supplied function, although specialized applications and even hardware implementations are also possible. Also depicted in  FIG. 1 , for purposes of illustration of the VRU, are calling party  132  connected to telco switch  130  and a called party  134 , likewise connected to telco switch  130 . 
     Processor  102  may be a dedicated, specialized central processing unit (CPU) board running specialized software, or may be a general purpose personal computer or workstation running an appropriate operating system such as Windows NT or UNIX. Other suitable platforms include the SUN Sparc20, Pentium 200, Periphonics VAS, IBM RS6000 with direct talk, or the Dialogic Antares card utilizing digital signal processing (DSP) technology. 
     Delay timer  106  may be a standard operating system-supplied timer or clock function. In one implementation, a call is made to the system clock upon start of the delay, and a program loop continues to read the clock time until (i) a predetermined time has elapsed or (ii) an alternative processing command is received and the loop is exited. Alternatively, a series of nested loops may be used to provide a desired time delay during which an alternative processing command may be received. Delay timer  106  provides a predetermined silent period between announcement of the name or telephone number identified by the system and default dialing of the number. During the silent period the system listens for an alternative command from the user, either in the form of a DTMF signal or, more preferably, by speaking the alternative action requested, such as “stop”, “listing”, “voice mail”, etc. 
     The selection of an appropriate silent delay period has been found to be critical to user acceptance of the system. Delay periods of less than 1.2 to 1.5 second have been found to be inadequate to signal a user that the system is available to receive an input and provide sufficient reaction time for the user to initiate the request, i.e., speak the alternate command word or words. On the other hand, silences of greater then 2.0 to 2.3 seconds are perceived as processing delays and are unacceptable, particularly to users who are not requesting alternate processing. Accordingly, a silent delay period should be in the range of 1.2 to 2.3 seconds and preferably in the range of 1.5 to 2.0 seconds, the optimal delay being 1.8 seconds. Use of a silent delay in these time ranges results in no perceptible or at least an acceptable delay while providing sufficient opportunity for those users requiring alternative processing to initiate the appropriate actions. 
     Pseudorandom number generator  108  may be a standard operating system-supplied random number function such as supported by ANSI C. Depending on the particular random function generator supported by the system, the result might need to be scaled to correspond to the number of messages comprising a particular group. For example, if the maximum value provided by the Pseudorandom number function call RAND were equal to RANDMAX and the number of prompts in a group were equal to N, then a Pseudorandom integer J between 1 and N could be obtained using the following code: 
     J=1+(INT)(N*RAND( )/RANDMAX)); 
     Alternatively, other random number generators may be used, although quality of the randomness is not a major factor in the present embodiment. 
     In addition to the operating system and Pseudorandom number generator, processor  102  runs software applications and modules written, for example, in “C” code for implementing a particular service, such as a voice dialing application. In this configuration, speech recognition client  110  receives a speech signal from telephone line interface card  120  and performs preprocessing of the speech signal including gross end-pointing and speech buffer management. The speech recognition client  110  further manages the results provided by speech recognition engine  116  to match the phonetic strings with the appropriate names and telephone numbers stored in telephone directory  122 . Telephone directory  122  includes three flat database files associated with matching including a names-file, nicknames-files and a phone book. 
     Telephony application  112  performs call answering, caller ID capture, speech capture, billing information processing and call transfer. The latter function, call transfer, may be provided by using the three-way calling feature of telco switch  130 . Using this feature, after an incoming call has been terminated at telephone line interface card  120  and the telephone number of a requested party has been identified, telephone line interface card  120  is instructed by telephony module  112  to perform a switchhook operation to obtain a second dial tone from telco switch  130 . The telephone number of the identified called party  134  is then outdialed to initiate a call to that party. Upon ring detection, telephone line interface card  120  performs a second flashhook operation to signal telco switch  130  to bridge calling party  132  and, subsequently, telephone line interface card  120  goes back on hook to drop out of the bridge and wait for the next user to call. 
     Voice dialing Application and Interface  114  provides system prompts, call error handling, call handling features (i.e., “call completion,” “listing,” “sent to mailbox,” etc.) and manages the speech client recognition results to determine the appropriate response or prompt group of messages. 
     Stored voice messages  122  are arranged in groups of content equivalent prompts or messages. All of the prompts within a group are interchangeable, conveying substantially the same substance but with variations in wording and/or phraseology and sentence structure to mimic normal variations in human speech. For example, a message group may include five suitable system greetings that might be played to a user when a call is first answered. One prompt may include “Bell Atlantic, who would you like to call?”; a second prompt might be “This is Bell Atlantic, who would you like to call?”; a third prompt “Corporate dialing, who would you like to call?”; a fourth prompt “This is the corporate dialer, who would you like to call?”; and a fifth “Bell Atlantic here, who would you like to call?”. Similarly, other message groups would include appropriate messages or prompts to be used in a particular situation, each of the prompts within a particular group being interchangeable with substantially the same content, i.e., content equivalent prompts. 
     Telephone directory  124  may be a flat file of names, organizations, functions, etc., with their respective telephone numbers or other handling or routing information as appropriate or as required by the particular application. 
     Speech recognition engine  116  is preferably speaker independent so that there is no requirement for users to train the system to respond to their voices. The basic speech recognition technology is commercially available through several sources including Nuance Communications, Inc. Although shown apart from processor  102 , speech recognition engine  116  may be implemented as an application running on processor  102 . Upon receipt of a speech signal from telephone line interface card  120 , speech recognition client  110  performs preprocessing of the speech signal for speech recognition engine  112  including gross end-pointing and speech buffer management. The buffered speech is processed to extract the phonetic components, match them with the appropriate speech models and return the highest probability string. The matching string is derived from a grammar file. The matching string is then associated with name files forming part of the telephone directory by a speech recognition client  110 . 
       FIG. 2  is a flow diagram for a voice response unit (VRU) implementing a voice activated dialer. Entering the process at terminal  202 , an initialization routine  204  sets an interrupt flag to FALSE. The process includes a loop at decision  206  which is exited upon detection of a ring signal. Upon detecting an incoming call, the call is answered at  208  and an appropriate greeting is played to the caller at  210 . The caller is then prompted at process  212  to provide the name of a party to be called. A speech input from the caller is looked for at decision  214  and, if none is found, appropriate error processing is performed at  216 . The error processing detail could include prompting the caller to speak louder or to try again. If speech is received at  214 , the content of the speech segment is recognized at  218  and a match is attempted at  220  between the recognized speech segment and names present in a telephone directory. If no match is found at decision  222 , error processing  224  is performed. Conversely, if a match is found, the name is read back to the caller and a delay segment of code starting at process  228  and ending at decision  240  is entered. Specifically, the time upon entry of the delay is obtained at  228 . This time can be obtained from the system under most operating systems and languages. For example, the C library includes the standard time and date functions library &lt;time.h&gt;. Using these functions, a call to time will return the current calender time which is used as the start time upon entry into the subsequent “While” loop. Another variable such as “timenow” may be used to get the time during loop execution with the function “double difftime (time_t timenow time_t starttime)” used to compute the elapsed time in the loop. Processing continues in the While loop until the delay has expired or an alternative processing command is recognized. 
     Upon entry into the loop, the decision block  230  is encountered to decide if a speech segment has been received. If not, processing skips down to continue at “Get TimeNow” process  238 . A check is then performed at the bottom of the “While” loop to see if either (i) the elapsed time in the loop is equal to or exceeds the predetermined time “Delay Period” or (ii) if the interrupt flag has been set equal to “True,” (i.e., an alternative processing command has been recognized). Conversely, if a speech segment has been received, it is recognized at  232  and the resulting content is examined at decision box  234  to determine if alternate processing has been requested. If alternate processing has been recognized, then the interrupt flag is sent to True at  236 . Otherwise, the interrupt flag is not altered. Processing then continues at  238  to get the current time. Decision box  240  then decides if the predetermined delay period (“Delay Period”) has been achieved or if the interrupt flag is True indicating that alternative processing has been requested, either of which condition causes the process to exit the “While” loop and continue at decision box  242 . Alternatively, if the time in the loop has not reached the predetermined “Delay Period” and alternative processing has not been identified, the process loops back to continue at the top of the “While” loop at decision box  230 . 
     Since the loop can be exited by either of two conditions, decision box  242  is necessary to determine if the exit is due to a timeout condition or because alternative processing has been requested. If the exit from the loop is in response to a timeout, then the lefthand branch is taken out of decision box  242  and the telephone number is dialed at  244 . Otherwise, alternative processing is initiated at  246 . 
     A flow diagram of another automated dialer according to the invention is shown in  FIGS. 3   a - 3   d .  FIG. 3   a  shows call processing for call answer and provision of a welcome prompt. Speech recognition processing is further detailed in  FIG. 3   b . Processing for providing a second guess is shown in  FIG. 3   c . Finally, normal and special handling processing is shown in  FIG. 3   d.    
     Referring to  FIG. 3   a , at system start-up normal system configuration files are read and initialization of the speech server, client and telecom applications is performed. The program then enters a wait state until an incoming call is received. On detecting ringing, the call is answered by the telephone line interface card  120 . A pseudorandom number between 1 and 5 inclusive is generated and used to randomly select one of five content equivalent greetings to be played to the caller. The content equivalent greetings are substantively the same, but vary slightly in wording and phraseology. If no speech is detected within a predetermined period after the greeting has completed, the system will prompt the caller to speak a name of the party to be called. Again, the prompt is selected from among five content equivalent messages in response to a newly generated random number. If, after a second period following this prompt no speech is detected from the calling party, one of five error messages is selected in response to another random number informing the caller that he or she is being transferred to a trouble line. 
     If speech is detected after the initial greeting or after the caller is prompted, processing continues as shown in the call flow of  FIG. 3   b . First, the system attempts to identify phonemes from the speech signal of the calling party. The phonemes are then compared to names and nicknames contained in the telephone directory and, if a name is found, the system proceeds to retrieve the associated telephone number. If the telephone number is invalid or is otherwise recognized to require special handling, processing continues as shown at connector C in the lower left of  FIG. 3   d . For example, if the associated telephone number is all 9&#39;s, the WAV file associated with the name is played, but no telephone number is dialed and processing loops back near the beginning of the call flow to play a new greeting and give the caller an opportunity to try another name. Alternatively, if the telephone number is all 7&#39;s, the caller is informed that the person named is no longer in the directory served by the system and, again, processing continues back to give the caller the opportunity to lookup another name. 
     Referring back to  FIG. 3   b , if the name is found and no special handling is indicated, the system will attempt to open a WAV format audio file associated with the name. If such a WAV file corresponding to the called party&#39;s name is found, then the name is played back to the caller as confirmation that the correct directory listing has been identified by the system. Alternatively, if the system is unable to identify a WAV file associated with the found name, the corresponding telephone number is read back to the caller using a synthesized voice. In either case, the system waits for a predetermined time of between one and two and one-half seconds, and preferably within the range of 1.2 seconds to 2.3 seconds, an optimal time being 1.8 seconds, before proceeding to initiate default processing by dialing the telephone number as shown at the top of  FIG. 3   d . If, during the silent delay period, the system recognizes the caller speak an exception processing command, such as “cancel,” “listing,” “leave a message,” or “voice mail,” a flag indicating the appropriate alternative processing is set. If the caller commands the system to cancel dialing by speaking the word “cancel” or any equivalent phrase (e.g., “stop,” “no,” “wait,” “whoa,”, etc.) and the system has made less than six attempts toward dialing a number, then processing continues at the top of  FIG. 3   c . There, if the system recognizer has a second guess (i.e., there as another close match), then a new pseudorandom number is obtained to select one of five error messages to be played to the caller indicating that the system has a second best guess that it will attempt to use. Processing then continues at the entry point shown by connector H in  FIG. 3   b  to check for any special handling requirements as might be indicated by an invalid telephone number for the second guess. If no special handling is required, then the name of the second guess is played (or the corresponding telephone number is no WAV file is found). The system waits for 1.2 to 2.3 seconds for any alternative verbal instructions or processing interruption requests from the caller and, if none is received, dials the number. 
     If the calling party has indicated that the name or telephone number played is incorrect but the system does not have a second guess, then processing continues at entry point shown by connector A in  FIG. 3   a , affording the caller a chance to repeat the name or input another name. 
     If a name has been recognized and the caller has not indicated that the name or telephone number is incorrect, then processing continues at the top of  FIG. 3   d  at connector F. If the caller has spoken the word “listing,” or any equivalent recognized by the system (e.g., “number,” etc.) during the silent prompt period, then the telephone number corresponding to the found name is played and processing loops back to connector D in  FIG. 3   a . Special processing is also indicated by the caller speaking “leave a message” during the silent prompt period so that the voice mail telephone number of the called party is substituted for their direct dial number. The calling party is notified by the system they will be “leaving a message,” one of five randomly selected closing messages is played, and the call is transferred to the called party&#39;s voice mail platform. 
     If the called party has spoken the phrase “voice mail” during the silent prompt period indicating that they would like to access their own voice mail, then the calling party&#39;s voice mail access number is substituted, the message “voice mail” is played and processing continues as before. 
     If a name and valid telephone number have been identified, and no special processing has been requested, call flow continues in the middle of  FIG. 3   d  to generate a random number used to select one of five closing messages and the call is transferred to the telephone number identified. In the case of a caller having requested his or her own or the voice mail of the called party, the system delays release of the line until it can provide the voice mail platform with the appropriate voice mailbox identification using in-band DTMF signaling or equivalent as shown at the bottom of  FIG. 3   d.    
     The silent prompt provides a user friendly interface mimicking human speech modalities. While automated systems have traditionally stepped a user through seemingly endless menus of voice prompts and options, the present invention allows the user to interact much as if talking with a human operator or attendant. The majority of callers allow the system to proceed and process according to its default programming. If the process needs to be interrupted, the user need only so indicate during a short delay period and without accessing further menus. 
     Although several embodiments of the invention have been described in detail above, it should be clear that the present invention is capable of numerous modifications as would be apparent to one of ordinary skill in the art. Such modifications fall within the purview of the appended claims. 
     It will be readily seen by one of ordinary skill in the art that the present invention fulfills all of the objects set forth above. After reading the foregoing specification, one of ordinary skill will be able to effect various changes, substitutions of equivalents, and various other aspects of the invention as broadly disclosed herein. It is therefore intended that the protection granted herein be limited only by the definition contained in the appended claims and equivalents thereof.