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Table Of Contents

Contents
Figures
Tables
Revision History
About This Publication
- Purpose
- Applicability
- Intended Audience
- How to Use This Publication
- Related Information
1. Product Description
- 1.1 Overview
- 1.2 R4 API
- 1.3 Call Progress Analysis
- 1.4 Tone Generation and Detection Features
- 1.5 Dial Pulse Detection
- 1.6 Play and Record Features
- 1.7 Send and Receive FSK Data
- 1.8 Caller ID
- 1.9 R2/MF Signaling
- 1.10 TDM Bus Routing
2. Programming Models
- 2.1 Standard Runtime Library
- 2.2 Asynchronous Programming Models
- 2.3 Synchronous Programming Model
3. Device Handling
- 3.1 Device Concepts
- 3.2 Voice Device Names
4. Event Handling
- 4.1 Overview of Event Handling
- 4.2 Event Management Functions
5. Error Handling
6. Application Development Guidelines
- 6.1 General Considerations
- 6.2 Fixed and Flexible Routing Configurations
- 6.3 Fixed Routing Configuration Restrictions
- 6.4 Additional DM3 Considerations
- 6.5 Using Wink Signaling
7. Call Progress Analysis
- 7.1 Call Progress Analysis Overview
- 7.2 Call Progress and Call Analysis Terminology
- 7.3 Call Progress Analysis Components
- 7.4 Using Call Progress Analysis on DM3 Boards
- 7.5 Call Progress Analysis Tone Detection on DM3 Boards
- 7.6 Media Tone Detection on DM3 Boards
  - 7.6.1 Positive Voice Detection (PVD)
  - 7.6.2 Positive Answering Machine Detection (PAMD)
- 7.7 Default Call Progress Analysis Tone Definitions on DM3 Boards
- 7.8 Modifying Default Call Progress Analysis Tone Definitions on DM3 Boards
- 7.9 Call Progress Analysis Errors
- 7.10 Using Call Progress Analysis on Springware Boards
- 7.11 Call Progress Analysis Tone Detection on Springware Boards
- 7.12 Media Tone Detection on Springware Boards
  - 7.12.1 Positive Voice Detection (PVD)
  - 7.12.2 Positive Answering Machine Detection (PAMD)
- 7.13 Default Call Progress Analysis Tone Definitions on Springware Boards
- 7.14 Modifying Default Call Progress Analysis Tone Definitions on Springware Boards
- 7.15 SIT Frequency Detection (Springware Only)
- 7.16 Cadence Detection in Basic Call Progress Analysis (Springware Only)
8. Recording and Playback
- 8.1 Overview of Recording and Playback
- 8.2 Digital Recording and Playback
- 8.3 Play and Record Functions
- 8.4 Play and Record Convenience Functions
- 8.5 Voice Encoding Methods
- 8.6 G.726 Voice Coder
- 8.7 Transaction Record
- 8.8 Silence Compressed Record
- 8.9 Recording with the Voice Activity Detector
- 8.10 Streaming to Board
- 8.11 Pause and Resume Play
- 8.12 Echo Cancellation Resource
9. Speed and Volume Control
- 9.1 Speed and Volume Control Overview
- 9.2 Speed and Volume Convenience Functions
- 9.3 Speed and Volume Adjustment Functions
- 9.4 Speed and Volume Modification Tables
- 9.5 Play Adjustment Digits
- 9.6 Setting Play Adjustment Conditions
- 9.7 Explicitly Adjusting Speed and Volume
10. Send and Receive FSK Data
- 10.1 Overview of ADSI and Two-Way FSK Support
- 10.2 ADSI Protocol
- 10.3 ADSI Operation
- 10.4 One-Way ADSI
- 10.5 Two-Way ADSI
  - 10.5.1 Transmit to On-Hook CPE
  - 10.5.2 Two-Way FSK
- 10.6 Fixed-Line Short Message Service (SMS)
- 10.7 ADSI and Two-Way FSK Voice Library Support
  - 10.7.1 Library Support on DM3 Boards
  - 10.7.2 Library Support on Springware Boards
- 10.8 Developing ADSI Applications
- 10.9 Modifying Older One-Way ADSI Applications
11. Caller ID
- 11.1 Overview of Caller ID
- 11.2 Caller ID Formats
- 11.3 Accessing Caller ID Information
- 11.4 Enabling Channels to Use the Caller ID Feature
- 11.5 Error Handling
- 11.6 Caller ID Technical Specifications
12. Cached Prompt Management
- 12.1 Overview of Cached Prompt Management
- 12.2 Using Cached Prompt Management
- 12.3 Cached Prompt Management Example Code
13. Global Tone Detection and Generation, and Cadenced Tone Generation
- 13.1 Global Tone Detection (GTD)
- 13.2 Global Tone Generation (GTG)
- 13.3 Cadenced Tone Generation
14. Global Dial Pulse Detection
- 14.1 Key Features
- 14.2 Global DPD Parameters
- 14.3 Enabling Global DPD
- 14.4 Global DPD Programming Considerations
- 14.5 Retrieving Digits from the Digit Buffer
- 14.6 Retrieving Digits as Events
- 14.7 Dial Pulse Detection Digit Type Reporting
- 14.8 Defines for Digit Type Reporting
- 14.9 Global DPD Programming Procedure
- 14.10 Global DPD Example Code
15. R2/MF Signaling
- 15.1 R2/MF Overview
- 15.2 Direct Dialing-In Service
- 15.3 R2/MF Multifrequency Combinations
- 15.4 R2/MF Signal Meanings
- 15.5 R2/MF Compelled Signaling
- 15.6 R2/MF Voice Library Functions
- 15.7 R2/MF Tone Detection Template Memory Requirements
16. Syntellect License Automated Attendant
- 16.1 Overview of Automated Attendant Function
- 16.2 Syntellect License Automated Attendant Functions
- 16.3 How to Use the Automated Attendant Function Call
17. Building Applications
- 17.1 Voice and SRL Libraries
- 17.2 Compiling and Linking
Glossary
Index

Voice API Programming Guide — June 2005 131

Send and Receive FSK Data

10.8.4 Implementing Two-Way ADSI Using dx_TxIottData( )

The dx_TxIottData( ) function is used to implement two-way ADSI data transfer. The

dx_TxIottData( ) function transmits the CAS and the subsequent "Switch to Peripheral Mode

Message" to the CPE. To transfer ADSI FSK data, set the parameters and configure the structures

as described below:

• Set the wType parameter DT_ADSI.

• Configure the DX_IOTT structure with the appropriate ADSI FSK data file(s), including the

"Switch to Peripheral Mode" message. The application is responsible for constructing the

messages and checksums for each transmission.

• Set the termination conditions with the DV_TPT structure.

• Set dwTxDataMode within the ADSI_XFERSTRUC referenced by lpParams to

ADSI_ALERT to generate the CAS.

The following scenario illustrates the function calls that are required to generate an initial CAS to

the CPE and begin two-way ADSI data transfer.

1. Prior to executing dx_TxIottData( ), clear the digit buffer for the desired voice channel using

dx_clrdigbuf( ).

2. Issue dx_TxIottData( ). To generate an initial CAS to the CPE device, set dwTxDataMode

within ADSI_XFERSTRUC data structure to ADSI_ALERT.

3. The CAS is received by the CPE and the CPE sends an acknowledgment digit (DTMF ‘A’) to

the voice device.

Note: If the DTMF acknowledgment digit is not received from the CPE device within 500

ms following the end of the CAS, the function will return a 0 but the termination

mask returned by ATDX_TERMMSK( ) will be TM_MAXTIME to indicate an

ADSI protocol error. (The function will return a -1 if a failure is due to a general

transmission error.)

4. Upon receipt of the DTMF ‘A’ ACK, the voice device automatically transmits the data file

referenced in the DX_IOTT structure, which must include the "Switch to Peripheral Mode"

message.

5. After receiving the data file(s), the CPE responds with a DTMF ACK or NAK, indicating the

number of messages successfully received. (The application is responsible for determining

whether the message count acknowledgment matches the number of messages that were

transmitted and for re-transmitting any messages.)

Note: Upon successful completion, the function terminates with a TM_EOD (end of data)

termination mask returned by ATDX_TERMMSK( ).

6. The CPE responds to the "Switch to Peripheral Mode" message with either DTMF ‘B’ if the

peripheral is available or DTMF ‘A’ if the peripheral is unavailable.

7. After completion of dx_TxIottData( ), the dx_getdig( ) function retrieves the DTMF ACK

sequence from the CPE device. Set the DV_TPT tp_termno parameter to DX_DIGTYPE to

receive the DTMF string "adxb," where "x" is the message count acknowledgment digit (1-5).

When the DTMF string is received, additional messages can be sent and received between the

server and the CPE peripheral.