Installation and Operation Manual VF-30/VF-60. Single/Dual E1 Digital Voice Compression Modules. Megaplex-2100 Version 11 MEGAPLEX-2100 MODULES

Installation and Operation Manual VF-30/VF-60 Single/Dual E1 Digital Voice Compression Modules Megaplex-2100 Version 11 MEGAPLEX-2100 MODULES

VF-30/VF-60 Single/Dual E1 Digital Voice Compression Modules for Megaplex-2100 Version 11 Installation and Operation Manual Notice This manual contains information that is proprietary to RAD Data Communications Ltd. ("RAD"). No part of this publication may be reproduced in any form whatsoever without prior written approval by RAD Data Communications. Right, title and interest, all information, copyrights, patents, know-how, trade secrets and other intellectual property or other proprietary rights relating to this manual and to the VF-30/VF-60 and any software components contained therein are proprietary products of RAD protected under international copyright law and shall be and remain solely with RAD. VF-30/VF-60 is a registered trademark of RAD. No right, license, or interest to such trademark is granted hereunder, and you agree that no such right, license, or interest shall be asserted by you with respect to such trademark. You shall not copy, reverse compile or reverse assemble all or any portion of the Manual or the VF- 30/VF-60. You are prohibited from, and shall not, directly or indirectly, develop, market, distribute, license, or sell any product that supports substantially similar functionality as the VF-30/VF-60, based on or derived in any way from the VF-30/VF-60. Your undertaking in this paragraph shall survive the termination of this Agreement. This Agreement is effective upon your opening of the VF-30/VF-60 package and shall continue until terminated. RAD may terminate this Agreement upon the breach by you of any term hereof. Upon such termination by RAD, you agree to return to RAD the VF-30/VF-60 and all copies and portions thereof. For further information contact RAD at the address below or contact your local distributor. International Headquarters RAD Data Communications Ltd. 24 Raoul Wallenberg St. Tel Aviv 69719 Israel Tel: 972-3-6458181 Fax: 972-3-6498250 E-mail: market@rad.com North America Headquarters RAD Data Communications Inc. 900 Corporate Drive Mahwah, NJ 07430 USA Tel: (201) 529-1100, Toll free: 1-800-444-7234 Fax: (201) 529-5777 E-mail: market@radusa.com 1988 2006 RAD Data Communications Ltd. Publication No. 764-246-08/06

Quick Start Guide Installing the Jumpers If you are familiar with the VF-30 and VF-60 modules, use this guide to prepare them for operation. Refer to the figure below and set the module jumpers as required. For VF-30 modules, ignore the jumpers serving link 2. JP15 Link 1 Interface JP15, JP16, JP19, JP20 JP16 JP19 JP20 120Ω Balanced NO Link 1 Jumper JP24 Pins 3,6 of RJ-45 Connector of Link 1 not Connected to Frame Ground JP15 JP16 JP19 JP20 75Ω Unbalanced YES Pins 3,6 of RJ-45 Connector of Link 1 Connected to Frame Ground JP24 Link 1 Jumpers JP19 JP15 JP16 JP20 JP21 Link 2 Jumpers (VF-60 only) JP17 JP18 JP22 JP25 JP17 JP17 Link 2 Interface JP17, JP18, JP21, JP22 JP18 JP18 JP21 JP22 JP21 JP22 120Ω Balanced 75Ω Unbalanced NO Link 2 Jumper JP25 YES Pins 3,6 of RJ-45 Connector of Link 2 not Connected to Frame Ground Pins 3,6 of RJ-45 Connector of Link 2 Connected to Frame Ground 1

Quick Start Guide Connecting the Cables Insert the module in the assigned I/O slot, and then connect the prescribed cables to each LINK connector of the module as follows: Balanced Interface Connect the prescribed cable from the user s equipment to the LINK connector. Unbalanced Interface Configuration Procedure 1. Connect the RJ-45 connector of the adapter cable CBL-RJ45/2BNC/E1 to the prescribed LINK connector. 2. Connect the coaxial cables from the user s equipment to the two BNC connectors at the other end of the adapter cable. Pay attention to correct connection: Connect the cable from the user s equipment transmit output to the green BNC connector (VF-30/VF-60 link receive input) Connect the cable from the user s equipment receive input to the red BNC connector (VF-30/VF-60 link transmit out). You can sequentially configure all the VF-30/VF-60 parameters using the command DEF CH SS *, where SS is the VF-30/VF-60 slot number. Internal Port Parameters Configure each internal port using the command DEF CH SS CC, where SS is the VF-30/VF-60 slot number, and CC is the internal port number (IN1 to IN8). The internal port configuration parameters and the allowed range of values are listed below. Parameter Connect Rate Max Bytes in Multiplex Frame Frame Interval Voice Coding Range of Values YES NO 1 to 31 timeslots 100 to 1472 bytes 10 to 90 msec G7231 6.4 kbps G729A8 G7231 5.3 kbps G711 A-law G711 U-law Parameter Type Volume Voice Coding Echo Canceller S Tandem Modem Range of Values PTP AAL2oMPLS NONE -6 to 6 db A-Law U-Law ENABLE DISABLE DISABLE ENABLE DISABLE 2

Quick Start Guide Parameter Fax Rate Inband Management Routing Protocol Src/Dst Bundle ID Dst IP Range of Values Disable 4.8 kbps ON OFF PROPRIETARY RIP N/A 1 to 30 N/A xxx.xxx.xxx.xxx N/A 9.6 kbps 14.4 kbps Parameter MF Relay Min Pulse Width Min Power Level ML Slot ML Channel Range of Values ENABLE DISABLE 45 to 300 ms N/A 0 to -35 db N/A MP-2100: 1 to 12 MP-2104: 1 to 4 EX1 EX2 Link Parameters The links have two types of parameters: External E1 port parameters Timeslot utilization parameters. To configure the link parameters, use the command DEF CH SS CC, where SS is the VF-30/VF-60 slot number, and CC is the link number, EX1 or EX2. The external E1 port configuration parameters and the allowed range of values are listed below. Parameter Connect Frame Sig. Profile Idle Code Rx Gain OOS Signaling Range of Values YES NO G.732N G.732N-CRC4 1 to 5 00 to FF LONG HAUL SHORT HAUL FORCED BUSY FORCED IDLE G.732S G.732S-CRC4 Parameter Restoration Time Inband Management Inband Management Rate Routing Protocol Range of Values CCITT 10 SECONDS (62411) 1 SECOND (FAST) OFF DEDICATE PPP DEDICATE FR N/A 64kbps (for DEDICATE FR and DEDICATE PPP) NONE PROPRIETARY RIP RIP2 The external E1 port timeslot utilization parameters and the allowed range of values are listed below. Parameter Local Destination Timeslot Type Remote Destination Port Remote Destination Timeslot Range of Values N.C. INT01 to INT08 SS:CC:TT VOICE CCS TRANS (for SS:CC:TT only) N.C. EX1 or EX2 N.C. 1 to 31 MNG CCS 1 to CCS 8 SS7 1 to SS7 8 3

Quick Start Guide 4

Contents Chapter 1. Introduction 1.1 Overview... 1-1 Purpose and Main Features...1-1 Main Features...1-1 1.2 Typical Applications... 1-4 Point-to-Point Applications...1-4 Point-to-Multipoint Applications...1-4 1.3 Physical Description... 1-5 1.4 Functional Description... 1-7 Functional Block Diagram...1-7 TDM Bus Interfaces...1-8 Routing Matrix on TDM Buses Side...1-8 Internal Ports Routing Matrix...1-9 DSP Subsystem...1-9 Link Interfaces...1-10 Clock Generator and Timing Subsystem...1-10 Local Management Subsystem...1-11 E1 Interface Characteristics...1-11 Handling of Signaling Information...1-12 Audio Signal Processing Capabilities...1-13 Test and Diagnostic Capabilities...1-15 1.5 Technical Characteristics... 1-16 Chapter 2. Module Installation and Operation 2.1 Introduction... 2-1 2.2 Preparation for Installation... 2-2 VF-60 Internal Settings...2-2 VF-30 Internal Settings...2-2 2.3 Installing the Module in the Chassis... 2-3 2.4 Connecting the Cables... 2-4 Connection Data...2-4 Connection Instructions...2-5 2.5 Normal Indications... 2-6 Module Status Indication...2-6 Link Status Indications...2-6 Chapter 3. Configuration Instructions 3.1 Overview... 3-1 3.2 Outline of Configuration Procedure... 3-1 3.3 VF-30/VF-60 Configuration Instructions... 3-2 Internal Port Parameters...3-2 Link Parameters...3-5 3.4 System Timing Considerations... 3-11 3.5 Displaying VF-30/VF-60 Information... 3-11 Displaying Status and Configuration Information...3-11 Displaying Signaling Information...3-11 i

Table of Contents Chapter 4. Configuring Typical Applications 4.1 Typical Application... 4-1 4.2 Configuring the Modules... 4-2 Chapter 5. Troubleshooting & Diagnostics 5.1 Introduction... 5-1 5.2 Performance Monitoring... 5-1 Overview...5-1 Internal Port Performance Parameters...5-2 5.3 Test and Diagnostic Functions... 5-3 Loopbacks and Tests on External E1 Ports...5-3 Loopbacks on Internal Ports...5-5 5.4 Troubleshooting the Modules... 5-6 Troubleshooting New Installations...5-6 General Troubleshooting Procedure...5-7 5.5 Frequently Asked Questions... 5-7 5.6 Technical Support... 5-8 ii

Chapter 1 Introduction 1.1 Overview Purpose and Main Features Note VF-30 and VF-60 are digital voice/fax compression modules with E1 interfaces for the Megaplex-2100 and Megaplex-2104 Modular Integrating Access Nodes. In this manual, the generic term Megaplex is used when the information is applicable to both the Megaplex-2100 and Megaplex-2104 chassis types. The complete designation is used only for information applicable to a specific version. The voice/fax compression modules are available in two versions that differ with respect to the number of external links (E1 interfaces) installed on the module: VF-30: module with one link, supports 30 channels VF-60: module with two independent links, supports 30 channels per link for a total of 60 channels per module. Main Features Voice Transmission VF-30/VF-60 modules connect and compress E1 voice trunks for efficient transmission over TDM or IP networks. The timeslots received from the external E1 trunks are compressed using one of the following standard algorithms: ITU-T Rec. G.723.1 at 6.4 kbps per channel. This enables transmitting up to 10 voice channels in one timeslot. ITU-T Rec. G.723.1 at 5.3 kbps per channel. This enables transmitting up to 12 voice channels in one timeslot. ITU-T Rec G.729.A at 8.0 kbps per channel. This enables transmitting up to 8 voice channels in one timeslot. Compression methods are user-selectable per bundle. Note Every six voice timeslots are handled by a single DSP. Each DSP supports one compression method at any time. Overview 1-1

Chapter 1 Introduction The module includes adaptive echo canceling for near-end hybrid echo, for delays of up to 16 msec. The echo canceller enables acceptable voice quality on voice lines with long delay, such as long-distance calls or calls over non-terrestrial (satellite) links. To ensure reliable transmission of DTMF signals, they are always transmitted through the link as digital signals (this is called DTMF relaying), and clean representations are synthesized at the receiving end. The same process is used for the call progress tones that are detected within the E1 trunk timeslots. Automatic Fax and Modem Transmission In addition to voice transmission, the VF-30/VF-60 modules also support automatic fax relaying, which allows the transmission of Group III fax (ITU-T Rec. V.17 and V.29) at rates of 2.4 to 14.4 kbps, irrespective of the digitizing rate selected for voice. The modules have automatic rate fallback capability, to automatically switch to the next lower data rate supported by both communicating faxes. Voiceband modem transmissions at all the standard rates up to 14.4 kbps (per ITU-T Rec. V.22bis and V.32bis) are also supported, and are handled in the same way as fax transmissions. Transparent Transfer of Timeslots In addition to timeslots being processed to support voice and fax, it is also possible to transparently transfer selected timeslots of the external trunks through the Megaplex links, to a remote location, thereby providing support for fractional E1 services together with compressed voice through the same E1 trunk. Another application for transparent transfer of timeslots is support for CCS signaling in any desired protocol or flavor: the timeslot carrying the CCS information can be transferred transparently together with the timeslots carrying the voice channels to the remote Megaplex equipment. This permits restoring the original E1 trunk structure, including the signaling channel, at the external link interface of the remote VF-30/VF-60 module. Inband management through dedicated timeslots is also supported. Among other options, this enables extending the inband management links, through the E1 interfaces of the module, to other equipment connected to these interfaces. Traffic Carrying Capacity The advanced digital signal processing (DSP) techniques used by the VF-30/VF-60 modules provide voice compression options that meet a wide range of user requirements and enable the transmission of high-quality compressed voice signals while requiring low bandwidth. The number of channels that can be transmitted depends on the percentage of silence the number of simultaneously active calls, and the packet parameters. The number of channels and the approximate bandwidth can be estimated using the following formula: 1-2 Overview

Chapter 1 Introduction { [(Header size x packets per second ) + (# timeslots x size of compressed G.732 packet x 1000/30 x actual transmission time (% non-silence) )] x 8 bytes per bit 1000 bits per kilobit } + rate converted to kbps You can also use for this purpose the Vmux-110/2100 Bandwidth calculator supplied on the Megaplex Technical Documentation CD. Two companding laws are supported, µ-law and A-law. In accordance with ITU-T Rec. G.711, the A-law should be used on E1 trunks and the µ-law should be used on T1 trunks. However, the user can select the desired companding law, µ-law or A-law, in accordance with the specific system requirements. Since the VF-30/VF-60 modules can compress and transmit multiple E1 trunks using minimal bandwidth, the Megaplex units can utilize the remaining bandwidth to provide other required services such as data, Ethernet LANs, ISDN and/or management, all in one platform. With regular voice encoding methods, much bandwidth is wasted during the normal periods of silence in a call. To further reduce the actual bandwidth required for voice transmission, the VF-30/VF-60 modules support voice activity detection (VAD) techniques with silence detection and suppression: When a silence interval is detected in a channel (timeslot), an indication is sent to the far end, and the transmitting side releases most of the bandwidth normally occupied by the channel traffic. The far end fills the interval with noise having characteristics similar to normal background noise (this capability is called comfort noise generation), and therefore the subjective quality of the call is not noticeably affected. This method enables using less bandwidth to transmit the same amount of voice traffic, without degrading the quality of the call. The low-rate digitized voice data packets that are the result of digital signal processing of the payload carried by the external port timeslots are routed to internal ports. The VF-30/VF-60 modules support up to 8 internal ports; each internal port can be routed to a different destination through any desired main link port, thereby supporting both point-to-point and point-to-multipoint applications. The user can therefore select the bandwidth (number of timeslots on the main link) that will be allocated per internal port in accordance with the selected compression rate. By considering the statistical distribution of speech and call traffic loads, even higher compression ratios are possible. Overview 1-3

Chapter 1 Introduction 1.2 Typical Applications Point-to-Point Applications Figure 1-1 shows a typical point-to-point application for VF-30/VF-60 modules. In this application, a single PBX trunk is connected to a VF-30 module, and the resulting data stream is routed by means of a single internal port, allocated the desired number of timeslots, to a main link port. The compressed voice data stream is transported through the TDM network to the far end, where it is restored and connected to another PBX. The PBX trunks can use any desired signaling protocol: For CAS (G.732S), no special arrangements are needed, as this signaling protocol is processed and transferred by the VF-30 module within the compressed voice data stream. For other signaling protocols, for example, protocols using CCS, the timeslots carrying the signaling information can be transparently transferred to the far end in other main link timeslots, and made available to the equipment connected to the far end module. A single Megaplex-2100 unit can be equipped with up to 10 VF-60 modules, and therefore can support up to 20 E1 trunks (600 digital voice channels). After compression, this payload can be transmitted using only two E1 links, enabling very efficient utilization of the E1 links. Megaplex-2104 units can be equipped with 4 VF-60 modules to support up to 8 E1 trunks. Figure 1-1. Typical Point-to-Point Application for VF-30/VF-60 Modules Point-to-Multipoint Applications Point-to-multipoint applications use the multiple internal ports (up to 8) supported by the VF-30/VF-60 modules. Each internal port can operate at a different voice encoding rate and/or fax rate. Each internal port can be routed to a different destination by routing it to a different main link port or IP destination. Figure 1-2 shows a typical point-to-multipoint application for VF-30/VF-60 modules. In this application, two PBX trunks are connected to a VF-60 module, and the resulting data stream is routed by means of three internal ports, allocated the desired number of timeslots, to a ML-IP module. The ML-IP module provides independent links to the desired destinations through the IP network. 1-4 Typical Applications

Chapter 1 Introduction Figure 1-2. Typical Point-to-Multipoint Application for VF-30/VF-60 Modules 1.3 Physical Description VF-30/VF-60 are 4U-high modules that occupy one slot in the Megaplex chassis. All the module parameters are configurable by software, except for the selection of the link interface type (balanced or unbalanced). The VF-30/VF-60 module panels are shown in Figure 1-3. The panels include an RJ-45 connector and a group of status indicators for each link, and a module alarm indicator. Table 1-1 explains the functions of the components located on the module panels. Physical Description 1-5

Chapter 1 Introduction Component Description ALARM indicator ON LINE indicator LOC S. LOSS indicator REM S. LOSS indicator Table 1-1. VF-30/VF-60 Panels Lights when a fault has been detected in the module Lights steadily when the corresponding link is operating properly and is active (i.e., some of its timeslots are connected to an internal port or bypassed). Off when the corresponding link is defective, or none of its timeslots is connected to an internal port or bypassed Lights when the corresponding local link has lost frame synchronization Lights when a loss-of-frame synchronization indication is received by the corresponding link from the equipment connected to that link TST indicator Lights when a test is being performed on the corresponding link LINK connector RJ-45 connector for connection to the corresponding link interface VF-30 E1 ALARM ON TST LINE LOC REM S. LOSS L I N K TST LOC VF-60 E1 ALARM S. LOSS ON LINE REM L I N K 1 L I N K 2 ON TST LINE LOC REM S. LOSS VF-30 VF-60 Figure 1-3. VF-30/VF-60 Module Panels 1-6 Physical Description

Chapter 1 Introduction Functional Block Diagram 1.4 Functional Description Figure 1-4 shows the functional block diagram of the VF-30 and VF-60 modules. Internal Ports VF-30/VF-60 1 Voice Processing DSP 1 2 3 Link Interface (Port EX1) Link 1 Routing Matrix and TDM Bus Interfaces 4 5 Internal Ports Routing Matrix Signaling DSP VF-60 Only TDM Bus A TDM Bus B TDM Bus C TDM Bus D 6 7 Voice Processing DSP 2 Link Interface (Port EX2) Link 2 8 Control To Link Interfaces Management Channel Local Management To CL Module Nodal Timing Main Clock Fallback Clock Clock Generator Internal Clock & Timing Signals Receive Clock from Link Interfaces Clock Selection Figure 1-4. VF-30/VF-60, Functional Block Diagram The VF-30/VF-60 modules include the following subsystems: Routing matrix and TDM bus interfaces Internal ports routing matrix Functional Description 1-7

Chapter 1 Introduction DSP subsystem Link interfaces Clock generator and timing subsystem Local management subsystem. TDM Bus Interfaces The VF-30/VF-60 module has four independent TDM bus interfaces, one for each Megaplex TDM bus. Each TDM bus interface is used to connect timeslots from the corresponding bus to the routing matrix of the VF-30/VF-60 module, in accordance with the commands received from the CL module. Routing Matrix on TDM Buses Side Overview of Internal Routing Method To understand the payload routing method used within the VF-30/VF-60 module, it is necessary to consider three entities: Chassis TDM buses. The flow of payload on these buses is organized in timeslots (31 timeslots per bus). The CL module automatically assigns timeslots on the TDM buses to each connected I/O channel or internal port of the modules installed in the chassis. External ports. The external port, which has an E1 interface, provides the connection to the local user s equipment. VF-60 modules have two independent external ports. An external port has a capacity of 31 timeslots. However, since signaling information must always be transmitted, only 30 timeslots can carry voice (one timeslot is always assigned either to CAS or CCS signaling). Internal ports. On the TDM buses side, the timeslots that carry voice and fax payload directed for transmission through the VF-30/VF-60 module are formally connected to entities designated internal ports. The VF-30/VF-60 modules can be configured to use up to 8 internal ports. On the external ports side, the internal ports receive frames containing digitized voice and the associated signaling from the DSP subsystem. An internal port provides a convenient way to indicate which payload is to be routed to a certain destination, and enables the user to specify associated parameters. For flexibility in routing, the internal ports are located between two routing matrices: the TDM bus side routing matrix, and the internal ports routing matrix. 1-8 Functional Description

Chapter 1 Introduction Note In addition to packetized payload, it is also necessary to transparently bypass timeslots to a main link port. Bypassing of timeslots is needed to support fractional E1 service through the module links; it may also be used to transparently transfer the common channel signaling (CCS) information received from the user s equipment connected to the external port to the remote end of the compressed voice link, where the original frame structure and signaling can be restored. The timeslot carrying inband management traffic may also have to be bypassed. Routing Matrix Functions The routing of the TDM bus side matrix is user-programmable, under the control of the CL module, and enables connecting any timeslot between of its ports. As a result, the matrix can be used to perform the following functions: Connect timeslots between main link ports of modules installed in the Megaplex and the internal ports of the VF-30/VF-60 module. This is performed by connecting the desired timeslots from the TDM buses to the prescribed internal port. Bypass timeslots between the external ports of the VF-30/VF-60 module and main link ports (through the internal ports of the VF-30/VF-60 module). Note It is not possible to bypass timeslots directly between two VF-30/VF-60 modules. Internal Ports Routing Matrix DSP Subsystem The internal ports routing matrix is used to route the packetized voice traffic to timeslots that are then connected by the TDM side routing matrix to the TDM buses. The internal ports routing matrix is also used to bypass timeslots between the external ports of the VF-30/VF-60 module and main link ports. The DSP subsystem includes two groups of DSPs: Voice processing DSPs Signaling DSP. Voice Processing DSP Subsystem The voice processing DSP subsystem includes five DSPs for each external port. Each DSP processes six timeslots out of the 30 payload timeslots that may be carried by an external port. The timeslots processed by each DSP are identified in Table 1-2. Since the DSP performs the same operations on all of the processed timeslots, the six timeslots must use the same voice coding standard and fax rate. The resulting voice packets are sent to the internal ports routing matrix. Functional Description 1-9

Chapter 1 Introduction Note that the rate at which the DSP exchanges data on the external port side must be locked to the external port timing, whereas the packet data rate on the TDM buses side must be locked to the Megaplex nodal timing. These two rates need not be synchronized, because it is not necessary to lock the packet timing to the external port timing. Table 1-2. Timeslots Processed by Individual DSPs DSP Processed Timeslots 1 1, 2, 3, 4, 5, 6 2 7, 8, 9, 10, 11, 12 3 13, 14, 15, 17, 18, 19 4 20, 21, 22, 23, 24, 25 5 26, 27, 28, 29, 30, 31 Link Interfaces Signaling DSP Subsystem The signaling DSP subsystem includes a single DSP that can serve both external ports of a VF-60 module. In the transmit-to-far end direction, the signaling DSP processes the signaling information received from the external E1 port in timeslot 16 (by means of the ABCD signaling bits), so that it can be incorporated in the signaling packets transmitted by each internal port. The reverse operation is performed for the receive direction. The DSP can also perform signaling translations, independently for each external port, in accordance with the user-specified profile. The VF-30 module has one link interface, and the VF-60 module has two independent link interfaces. Each link interface performs the following functions: The transmit path of each interface generates the E1 frames in accordance with the framing mode selected by the user, and prepares the resulting data stream for transmission. The receive path recovers the receive signal and the associated clock. In addition, the link interface can collect performance diagnostic data (CRC-4 block error data) in accordance with the applicable standards. Clock Generator and Timing Subsystem Link Timing The link receive path always uses the clock signal recovered from the received line signal. The timing of the link transmit path is always derived from the Megaplex nodal timing. 1-10 Functional Description

Chapter 1 Introduction Therefore, the user s equipment must operate with loopback timing, i.e., it must be configured to lock its transmit timing to the clock signal recovered from the VF-30/VF-60 transmit signal. System Timing The VF-30/VF-60 clock generator and timing subsystem provides the clock signals needed by the local module circuits. In addition, this subsystem can also provide Megaplex nodal main and fallback clock signals, derived from the clock signals recovered from the received line signals by each link interface. Therefore, the Megaplex nodal timing can be locked to the clock signal recovered from the desired E1 receive signal. This mode is used when the E1 link timing must be determined by the user s equipment connected to the VF-30/VF-60 interface. This option is necessary only when timeslots are bypassed from the module links to main link ports, and the user s equipment cannot be configured to lock its transmit timing to the clock signal recovered from the VF-30/VF-60 transmit signal. Local Management Subsystem The local management subsystem of the VF-30/VF-60 module controls the operation of all the module circuits, under the control of the CL module. The management subsystem can also provide an interface between the Megaplex CL module and the external links, to support inband management through a dedicated timeslot when this option is enabled by the user: In the receive-from-link direction, the management traffic is extracted from the user-specified timeslot and transferred to the CL module via the Megaplex chassis buses. In the transmit to-link direction, the management traffic received from the CL module is inserted in the user-specified timeslot of the link interface, for transmission to the user s equipment (when it can be managed using one of the protocols supported by Megaplex equipment). The management traffic can use the PPP or Frame Relay protocols, in addition to the RAD proprietary routing protocol. E1 Interface Characteristics The E1 interfaces of the VF-30/VF-60 module meet the requirements of ITU-T Rec. G.703, G.704, and G.732. The line code is HDB3. Jitter performance complies with the requirements of ITU-T Rec. G.823. Each link can be configured by means of internal jumpers to use either of the following types of interfaces: 120Ω balanced line interface. The nominal balanced interface transmit level is ±3V. 75Ω unbalanced interface. The nominal unbalanced interface transmit level is Functional Description 1-11

Chapter 1 Introduction ±2.37V. You can select the maximum line attenuation that can be compensated without degrading the BER performance: 12 db (similar to a DSU) or 36 db (as required of an LTU). Each link can be configured to use its own framing mode. The following framing modes are supported: G732S (16 frames per multiframe), intended for use with channel-associated signaling (CAS). In most applications, the required signaling mode is CAS: this mode is compatible with the signaling mode used by PBXs. G732N (2 frames per multiframe), intended for use with common-channel signaling (CCS) protocols. These protocols exchange the signaling information through a dedicated timeslot and therefore require transparent transmission of the CCS timeslot through the link. You can configure each interface to operate with or without the CRC-4 option. The use of the CRC-4 option allows monitoring the E1 connection to the user s equipment. Handling of Signaling Information Handling of CAS Signaling In the CAS mode, the signaling information of all the channels is multiplexed within timeslot 16 of the E1 frames. Each timeslot (channel) is allocated four signaling bits, designated A, B, C, and D. The signaling information of a channel represents, as a minimum, the state of the equipment connected to the channel (on-hook/off-hook). The signaling information of each channel is processed and transferred in the packets transferred through the internal port serving the corresponding voice channels. In case the link to the remote VF-30/VF-60 module is out-of-service, the user can select the state of the signaling information sent in all the channels during the out-of-service period: FORCED BUSY FORCED IDLE The signaling information is forced to the busy state during out-of-service periods. The signaling information is forced to the idle state during out-of-service periods. Handling of CCS Signaling In addition to CAS signaling, the VF-30/VF-60 modules can also support equipment using common-channel signaling (CCS) protocols. These protocols exchange the signaling information through a dedicated channel timeslot and therefore require transparent transmission of the CCS timeslot through the module. The CCS timeslots can be compressed and transmitted to the destination ports in up to 8 logical groups, CCS<1> to CCS<8>. Timeslots are assigned to logical 1-12 Functional Description

Chapter 1 Introduction groups manually be the user. Handling of SS7 Signaling Handling of SS7 signaling timeslots is similar to that of CCS. Audio Signal Processing Capabilities This section explains the audio processing capabilities of VF-30/VF-60 modules. The audio processing capabilities, which are performed by the digital signal processors (DSPs), include: Voice processing Processing of DTMF and call progress tones Processing of fax and voiceband modem signals. Each DSP processes its group of timeslots (see Table 1-2) independently of the other DSPs, in accordance with the parameters selected by the user for that group. However, within each group, the DSP detects the signal type (voice, DTMF, fax, etc.) carried in each timeslot (channel), and automatically selects the appropriate processing method. Handling of Voice Signals Voice is digitized and compressed using one of the processing algorithms supported by the VF-30/VF-60. The low bit rate voice compression options and data rates supported by VF-30/VF-60 are as follows: Voice compression using multiple-pulse, maximum likelihood code-excited linear prediction (MP-MLQ) per ITU-T Rec. G.723.1, at a channel data rate of 6.4 kbps. When using this option, up to 10 voice channels can be carried by each timeslot sent to the Megaplex TDM buses. Voice compression using conjugate structure-algebraic-code-excited linear prediction (CS-ACELP) per Annex A of ITU-T Rec. G.729A, at a channel data rate of 8 kbps. When using this option, up to 8 voice channels can be carried by each timeslot sent to the Megaplex TDM buses. To further reduce the bandwidth needed to transmit the voice, the VF-30/VF-60 DSP recognizes silence intervals and replaces them with special silence packets, that require much less bandwidth than regular voice packets. When silence packets are received, the comfort noise generator (CNG) of the remote channel generates background noise to fill the silence intervals and give the remote subscriber the impression of a live line. The resulting channel data stream is packetized for transmission through the network. The user can select two parameters: The maximum number of bytes included in each voice coder frame (100 to 450 bytes). This limits the size of packets sent to the network. The maximum interval between consecutive frames: if this interval expires, the Functional Description 1-13

Chapter 1 Introduction frame is closed and sent, even if the specified maximum number of bytes has not yet been collected. This parameter ensures that the end-to-end delay is not excessive, for example, the additional delay needed to collect timeslots to fill a frame from an internal port that carries a single channel (timeslot), even for the minimum frame length (100 bytes) is approx. 12.5 msec. Note Because the DSP sends only data packets toward the Megaplex TDM buses, and packets can be read and transmitted independently of the rate of the incoming E1 stream, in general it is not necessary to lock the timing of the link interface to the Megaplex timing. The timing must be locked only when the module transfers (bypasses) timeslots transparently. To improve the perceived link quality, the DSPs also implement adaptive echo canceling for near-end reflections (echo delay less than 16 milliseconds). The echo canceling performance complies with ITU-T Rec. G.168 requirements. DTMF Processing The waveform of the DTMF signals is very different from speech waveforms, therefore most compression algorithms distort DTMF signals to the point that errors occur in the detection of the dialed digits when the DTMF signals are transmitted as analog signals through a compressed voice channel. To enable reliable transmission of DTMF signals, the VF-30/VF-60 module uses DTMF relaying. For this purpose, each DSP detects incoming DTMF signals, independently for each timeslot, and identifies the dialed digits. The digits detected by the receiving end are digitally transmitted through the link to the remote end, where clean digital representations of DTMF signals are synthesized and inserted into the data stream sent in the corresponding timeslot. While DTMF information is received, the voice path is disconnected, to prevent interference by signals transmitted through the regular processing path. The method used for DTMF relaying is also used to transfer transparently call progress tones. Automatic Fax Processing The processing of audio signals by low bit rate voice compression methods does not enable analog transmission of fax signals. Therefore, when it is possible that fax machines may be connected to an VF-30/VF-60 voice channel, it is necessary to enable the automatic fax relaying function on that channel. When automatic fax relaying is enabled, a VF-30/VF-60 channel will automatically recognize and transmit fax messages at the standard rates in the range of 2.4 to 14.4 kbps, complying with ITU-T Rec. V.17 and V.29. The maximum fax rate can be selected by the user. The VF-30/VF-60 supports automatic fallback capability, that is, it will automatically switch to the next lower data rate supported by both communicating faxes. The whole fax transmission process is handled as a data transmission, with the corresponding DSP providing the fax signal modulation/demodulation functions 1-14 Functional Description

Chapter 1 Introduction and the detection and generation of the fax connection set up tones (in digital format), to enable the handshaking necessary to implement the standard fax communication protocol. Fax transmission over the digital network improves transmission quality, while greatly reducing long distance telephone costs and the time needed for freeing the fax machine. To set up a fax connection, the DSP processing the local timeslot (channel) emulates the remote fax machine toward the local machine, and the remote DSP emulates the local fax toward the remote machine. After the fax connection is established, the fax data stream is transmitted as a packetized data stream through the link. This means that the link must have enough free bandwidth to enable sustained transmission of a data stream at the fax data rate (and the additional connection supervision signals). This process enables any standard Group III fax machine to transmit over the link. The only limitation is that the round-trip transmission delay through the link cannot exceed the time-out intervals specified by the fax communication protocol (about 700 msec); otherwise, the handshaking needed to establish a fax connection will fail. Since each VF-30/VF-60 channel automatically switches between the fax relay mode and the voice mode in accordance with the type of signal being detected, VF-30/VF-60 modules can serve PBX tie lines or channels serving a combined phone/fax machine. Handling of Voiceband Modem Signals The DSPs can also handle voiceband modem signals, in accordance with ITU-T Rec. V.22bis and V.32bis. The processing method is similar, except that the DSP emulates a voiceband modem instead of a fax modem. Test and Diagnostic Capabilities The VF-30/VF-60 supports the following user-initiated loopback functions: External E1 ports. The loopback functions available at the external E1 port level include: Local loopback toward the Megaplex TDM buses Remote loopback toward the user s equipment connected to the port. Internal ports. The internal ports support the local loopback toward the Megaplex TDM buses. Functional Description 1-15

Chapter 1 Introduction General 1.5 Technical Characteristics Number of External Ports VF-30 VF-60 Number of Internal Ports Voice Encoding Voice Digitizing Technique One E1 port Two E1 ports Eight MP-MLQ per ITU-T Rec. G.723.1, at a channel data rate of 6.4 kbps or 5.3 kbps Conjugate structure-algebraic-code-excited linear prediction (CS-ACELP) per Annex A of ITU-T Rec. G.729A, at a channel data rate of 8 kbps Fax Support Fax Data Rates 4.8, 9.6 and 14.4 kbps, selectable per internal port E1 Interface Characteristics Number of Ports VF-30: 1 Voice Channels Supported Format VF-60: 2 Up to 30 (per port) E1, 2.048 Mbps Standard Compliance ITU-T Rec. G.703, G.704, G.732 Framing Interface Line Code Signal Levels G.732N G.732N with CRC-4 G.732S G.732S with CRC-4 120Ω, 4-wire balanced 75Ω, coaxial unbalanced HDB3 Transmit Balanced : ±3V ±10% Receive Unbalanced: ±2.73V ±10% Jitter Performance Per ITU-T Rec. G.823 0 to -12 db for short-haul applications (DSU) 0 to -36 db for long-haul applications (LTU) 1-16 Technical Characteristics

Timing Mode Connectors Chapter 1 Introduction Transmit clock derived from Megaplex nodal clock Receive clock recovered from the receive signal, can be selected as timing reference for Megaplex nodal clock Balanced: 8-pin RJ-45 Bandwidth Allocation on Trunk Channel Bit Error Rate Adaptive Echo Canceller Unbalanced: Two BNC coaxial connectors, via adapter cable Selectable, according to the programmed voice encoding rate 1 x 10-3 or better Echo path length Echo return loss enhancement (ERLE) Maximum 16 msec Better than 30 db Convergence speed Better than ITU-T Rec. G.168 Diagnostics Module Level Automatic self-test upon power-up and continuous monitoring during normal operation Each E1 Interface Each Internal Port Indicators Per Module Alarm Configuration Per E1 Interface Local loopback toward Megaplex TDM buses Remote loopback toward the user s equipment connected to the port Local loopback towards Megaplex TDM buses On-line Local sync loss Remote sync loss Test Programmable via the Megaplex management system Technical Characteristics 1-17

Chapter 1 Introduction 1-18 Technical Characteristics

Chapter 2 Module Installation and Operation 2.1 Introduction This Chapter provides installation and operation instructions for the VF-30/VF-60 modules. The information presented in this Chapter supplements the Megaplex-2100 installation, configuration and operation instructions contained in the Megaplex-2100 Installation and Operation Manual. Warning Before performing any internal settings, adjustment, maintenance, or repairs, first disconnect all the cables from the module, and then remove the module from the Megaplex enclosure. No internal settings, adjustment, maintenance, and repairs may be performed by either the operator or the user; such activities may be performed only by a skilled technician who is aware of the hazards involved. Always observe standard safety precautions during installation, operation, and maintenance of this product. Caution The VF-30/VF-60 modules contain components sensitive to electrostatic discharge (ESD). To prevent ESD damage, always hold the module by its sides, and do not touch the module components or connectors. Introduction 2-1

Chapter 2 Module Installation and Operation VF-60 Internal Settings 2.2 Preparation for Installation The operating mode of the VF-30/VF-60 module is controlled by software. In addition, there are several jumpers that select the hardware operating mode, and these may have to be set before installing a module in the Megaplex enclosure. Figure 2-1 shows the location of the internal jumpers located on the VF-60 module. Table 2-1 describes the jumper functions, and lists the factory (default) settings. If the current settings meet your specific requirements, you may skip this section and proceed with the installation of the module in the equipment enclosure, as explained in Section 2.3. In addition to the user-selectable jumpers, the VF-60 module includes additional jumpers that are preset by the manufacturer and must not be moved. Table 2-1. VF-60 Module Internal Jumpers Jumper Link Interfaces Link 1: JP15, JP16, JP19, JP20 Link 2: JP17, JP18, JP21, JP22 Link 1: JP24 Link 2: JP25 Function Each group of jumpers selects the corresponding main link interface: BAL 120Ω balanced interface. UNBAL 75Ω unbalanced interface. When using this interface, you may use the CBL-RJ45/2BNC/E1 adapter cable available from RAD to convert the RJ-45 connector to two BNC connectors. Default setting: BAL Controls the connection of the frame ground to pins 3, 6 in the corresponding RJ-45 link connector: YES NO Connected. Not connected. Default setting: YES VF-30 Internal Settings The VF-30 module includes only one link, therefore use the information given above for the VF-60 module but ignore the link 2 settings. 2-2 Preparation for Installation

Chapter 2 Module Installation and Operation JP15 Link 1 Interface JP15, JP16, JP19, JP20 JP16 JP19 JP20 120Ω Balanced NO Link 1 Jumper JP24 Pins 3,6 of RJ-45 Connector of Link 1 not Connected to Frame Ground JP15 JP16 JP19 JP20 75Ω Unbalanced YES Pins 3,6 of RJ-45 Connector of Link 1 Connected to Frame Ground JP24 Link 1 Jumpers JP19 JP15 JP16 JP20 JP21 Link 2 Jumpers (VF-60 only) JP17 JP18 JP22 JP25 JP17 JP17 Link 2 Interface JP17, JP18, JP21, JP22 JP18 JP18 JP21 JP22 JP21 JP22 120Ω Balanced 75Ω Unbalanced NO Link 2 Jumper JP25 YES Pins 3,6 of RJ-45 Connector of Link 2 not Connected to Frame Ground Pins 3,6 of RJ-45 Connector of Link 2 Connected to Frame Ground Figure 2-1. VF-30/VF-60 Modules, Internal Jumpers 2.3 Installing the Module in the Chassis The VF-30/VF-60 modules can be installed in an operating chassis (hot insertion). For general installation procedures and safety instructions, refer to the Megaplex-2100 Installation and Operation Manual. Insert the VF-30/VF-60 module in the prescribed I/O slot and fasten it with its two screws. Installing the Module in the Chassis 2-3

Chapter 2 Module Installation and Operation Connection Data 2.4 Connecting the Cables This section provides connection data for the VF-30/VF-60 modules. Connector Data Each link interface of a VF-30/VF-60 module is terminated in a shielded RJ-45 connector wired in accordance with Table 2-2. Table 2-2. Link Interface Connector, Pin Functions Pin Function 1 Receive pair ring 2 Receive pair tip 3 Frame ground (connection controlled by internal jumper) 4 Transmit pair ring 5 Transmit pair tip 6 Frame ground (connection controlled by internal jumper) 7, 8 Not connected E1 Adapter Cable, CBL-RJ45/2BNC/E1 When the VF-30/VF-60 uses unbalanced E1 interfaces, it is necessary to convert each VF-30/VF-60 RJ-45 connector to the standard pair of BNC female connectors used by unbalanced E1 interfaces. For this purpose, RAD offers a 15-cm long adapter cable, CBL-RJ45/2BNC/E1, which has one RJ-45 plug for connection to a VF-30/VF-60 LINK connector and two BNC female connectors at the other end. Cable wiring is given in Figure 2-2. 2-4 Connecting the Cables

Chapter 2 Module Installation and Operation Receive (Green) RJ-45 Transmit (Red) BNC Female RX Ring 1 RX Tip NC 2 3. Receive (Green BNC) TX Ring 4 TX Tip NC 5 6. Transmit (Red BNC) NC 7 NC 8 Shielded RJ-45 Figure 2-2. E1 Adapter Cable, CBL-RJ45/2BNC/E1, Wiring Diagram Connection Instructions Before starting, refer to the installation plan to determine the cables intended for connection to this VF-30/VF-60 module. To connect the balanced interface: Connect the user s equipment to the prescribed VF-30/VF-60 RJ-45 connectors marked LINK1 and LINK2. When connecting a VF-30/VF-60 link connector to equipment having an unbalanced interface, it is necessary to use an adapter cable terminated in two BNC connectors. You may use for this purpose the CBL-RJ45/2BNC/E1 cable, offered by RAD. To connect the unbalanced interface: 1. Connect the RJ-45 connector of the adapter cable CBL-RJ45/2BNC/E1 to the prescribed LINK connector. 2. Connect the coaxial cables from the user s equipment to the two BNC connectors at the other end of the adapter cable. Pay attention to correct connection: Connect the cable from the user s equipment transmit output to the green BNC connector (VF-30/VF-60 link receive input) Connect the cable from the user s equipment receive input to the red BNC connector (VF-30/VF-60 link transmit output). Connecting the Cables 2-5

Chapter 2 Module Installation and Operation Module Status Indication Link Status Indications 2.5 Normal Indications When an VF-30/VF-60 main link interface is operational, its ALARM indicator must be off. The status of each VF-30/VF-60 link is indicated by a separate set of indicators. The normal indications for an operational link interface are as follows: The ON-LINE indicator of an active link must light steadily. The TST indicator must be off, but may turn on when a test loop is activated on the corresponding link interface. If the other communication equipment on the link is not yet operative, the corresponding LOC S. LOSS and/or REM S. LOSS indicator may light. These indicators must turn off as soon as the link with the remote equipment is established. 2-6 Normal Indications

Chapter 3 Configuration Instructions 3.1 Overview This chapter provides specific configuration information for VF-30/VF-60 modules. The procedures used to select these parameters depend on the management system used to control the Megaplex unit. The instructions appearing in this chapter assume that you are familiar with the management system being used: Supervision terminal or Telnet (covered by the Megaplex-2100 Installation and Operation Manual). Network management system, e.g., the RADview network management system (refer to the RADview User's Manual for instructions). This Chapter covers only the configuration activities specific to VF-30/VF-60 modules. For general instructions and additional configuration procedures, refer to Chapter 5, Chapter 7 and Appendix F of the Megaplex-2100 Installation and Operation Manual. 3.2 Outline of Configuration Procedure The configuration procedure of a new VF-30/VF-60 module includes the following main steps: Inclusion of a VF-30 or VF-60 module not yet installed in the Megaplex into the database. This allows preprogramming the module parameters, so that when the module is installed in the enclosure, it will immediately start operating in the desired mode. This function is performed by means of the DEF SYS command. Note You may also have to use the DEF SYS command to configure the system timing when the new module is supposed to provide the timing reference. Configuration of module parameters use the DEF CH SS * command. The VF-30/VF-60 modules have three types of configuration parameters: Internal port parameters External port parameters for each link Timeslot utilization for each link. Before configuring the VF-30/VF-60 module, it is necessary to define the appropriate signaling profiles, using the DEF PROFILE command. Outline of Configuration Procedure 3-1

Chapter 3 Configuration Instructions 3.3 VF-30/VF-60 Configuration Instructions Internal Port Parameters The VF-30/VF-60 module has 8 internal ports, identified as IN1, IN2,, IN8. Each internal TDM port can be independently configured in accordance with the system requirements. To define the parameters of the desired internal port, type: DEF CH SS CC where SS is the VF-30/VF-60 slot number, and CC is the desired internal port number (IN1 to IN8). Table 3-1 lists the internal port parameters. Table 3-1. Internal Port Parameters Parameter Function Values Connect Determines whether this port is connected to the internal TDM buses of the Megaplex chassis YES NO The internal TDM port is connected. The internal TDM port is disconnected. You can still program the desired parameters, so the port will be ready to operate when needed. Rate Specifies the number of timeslots to be assigned to this port on the Megaplex TDM buses. The required number depends on the payload rate carried by this port Default: NO The allowed range is 1 to 31 timeslots. Default: 1 Max Bytes in Multiplex Frame Specifies the total number of bytes to be inserted in each packet sent through this internal port. When the internal port is connected to an ML-IP module, the total number of bytes includes the IP header bytes added by the module before sending the packet to the IP network The allowed range is 100 to 1472 bytes. Default: 450 MF Relay Enables/disables MF tone relay Enable The MF Relay is enabled. Disable The MF Relay is disabled. Default: Disable Min Pulse Width Sets the minimum pulse width of the MF tone to be detected and relayed From 45 to 300 msec N/A if MF Relay is disabled 3-2 VF-30/VF-60 Configuration Instructions

Chapter 3 Configuration Instructions Table 3-1. Internal Port Parameters (Cont.) Parameter Function Values Min Power Level Frame Interval Voice Coding Type Volume Sets the minimum power level of the MF tone to be detected and relayed Specifies the maximum time to wait before sending an outgoing packet through this internal port. When the specified interval expires, the current packet is immediately transmitted, even if the specified maximum number of bytes has not yet been reached Selects the coder used by this internal port, and the resulting digitized voice data rate. See also the considerations presented in the Timeslot Utilization Parameters section below Enables/disables operating with RAD s Vmux-110 and Vmux-2100 devices Sets the volume gain transmitted from the DSPs towards the PBX. For example, if the gain received from the remote voice switch/pbx is very low, you may set the volume to +3 db, thereby amplifying the TX voice volume without the need to change the configuration of the voice switch. From 0 to 35 dbm N/A if MF Relay is disabled The allowed range is 10 to 90 msec in 10 msec steps. Default: 30 msec G7231 6.4 kbps Coder complying with ITU-T Rec. G.723.1, operating at a data rate of 6.4 kbps. G7231/5.3 kbps Coder complying with ITU-T Rec. G.723.1, operating at a data rate of 5.3 kbps. G729A8 Coder complying with ITU-T Rec G.729.A, operating at a data rate of 8.0 kbps G711 A-law Coder complying with ITU-T Rec. G.711, A-law. G711 U-law Coder complying with ITU-T Rec. G.711, μ-law. Default: G7231 6.4 kbps PTP Point-to-point mode, set for operating opposite VF-24/48 or VF-30/60 modules AAL2oMPLS Uses the AAL2oMPLS protocol to transmit the voice and data over the network, set for operating opposite Vmux-110 or Vmux-2100 Default: PTP NONE No volume gain From -6 db to +6 db in steps of 1 db. Default: NONE VF-30/VF-60 Configuration Instructions 3-3

Chapter 3 Configuration Instructions Table 3-1. Internal Port Parameters (Cont.) Parameter Function Values Coding Law Sets the coding used by your PBX A-Law A-Law coding U-Law μ-law coding Default: A-Law Echo Canceller Modem S Tandem Fax Rate Inband Management Routing Protocol Enables/disables the built-in echo canceller, which supports up to a 32 msec delay. If you have an external echo canceller on your telephone network, disable the built-in DSP echo canceller. Enables/disables modem transmission Enables/disables Vmux Super Tandem mechanism Determines the maximum fax transmission rate (all the other standard rates lower than the selected maximum are also supported). See also the considerations presented in the Timeslot Utilization Parameters section below Controls the transfer of inband management traffic through this internal port. Controls the inband management protocol. Enable Disable Default: Disable Enable Disable The built-in canceller is enabled. The built-in canceller is disabled. Modem transmission is enabled. Modem transmission is disabled. Default: Disable Disable Currently only this value is possible. Default: Disable Disable Fax transmission disabled. 4.8 kbps Maximum fax rate of 4.8 kbps. 9.6 kbps Maximum fax rate of 9.6 kbps. 14.4 kbps Maximum fax rate of 14.4 kbps. Default: Disable OFF The transfer of management traffic is disabled. ON The transfer of management traffic is enabled. Default: OFF PROPRIETARY RIP RAD proprietary routing protocol (set up automatically when inband management is enabled) N/A Displayed automatically when inband management is disabled. Default: OFF 3-4 VF-30/VF-60 Configuration Instructions

Chapter 3 Configuration Instructions Table 3-1. Internal Port Parameters (Cont.) Parameter Function Values Dst IP Sets IP address of the destination Vmux-110 device or Vmux-2100 group Src/Dst Bundle ID Sets the number of the destination bundle of the group with the IP address specified by Dst IP parameter ML Slot ML Channel Specifies the main link module to which this internal port is connected Specifies the external port of the main link module to which this internal port is connected When operating opposite a Vmux device (Type must be set to AAL2oMPLS), set the IP address in the format xxx.xxx.xxx.xxx. When operating opposite a VF module (Type set to PTP), N/A is displayed The allowed range is 1 to 30 when operating opposite a Vmux device (Type must be set to AAL2oMPLS) When operating opposite a VF module (Type set to PTP), N/A is displayed The allowed range is 1 to 12 for Megaplex-2100, and 1 to 4 for Megaplex-2104. Default: 1 The allowed range is 1 and 2, in accordance with the number of external ports on the main link module. Default: 1 Link Parameters To define the parameters of the desired VF-30/VF-60 link, type: DEF CH SS:CC where SS is the VF-30/VF-60 slot number, and CC is the desired link number, 1 or 2 (you may also use EX1 and EX2). The link parameters include two types of parameters: External E1 port parameters Timeslot utilization parameters, displayed immediately after the external E1 port parameters. Note To enable correct configuration of timeslot utilization, first it is necessary to configure the internal port parameters. The two types of parameters are described below. External Port Parameters Table 3-2 lists the external E1 port parameters. VF-30/VF-60 Configuration Instructions 3-5

Chapter 3 Configuration Instructions Table 3-2. External E1 Port Parameters Parameter Function Values Connect Frame Sig. Profile Determines whether the E1 port is connected to the internal signal processing circuits Determines the framing mode for this E1 port. Whenever possible, select a framing mode that supports the CRC-4 function. This enables the collection of performance diagnostic data Selects the signaling profile that specifies the interpretation of the signaling information transmitted and received by the corresponding link. When the profile has been assigned a name, the number of the profile appears in brackets, after the profile name. The signaling profiles and their names are defined by means of the DEF PROFILE command. This parameter is not relevant when using the G.732N or G.732N-CRC4 frame YES NO Default: NO G.732N E1 port is connected. E1 port is disconnected. You can still program the desired parameters, so the E1 port will be ready to operate when needed. 256N multiframe per ITU-T Rec. G.704 (2 frames per multiframe), CRC-4 function disabled. G.732N-CRC4 256N multiframe per ITU-T Rec. G.704 (2 frames per multiframe), CRC-4 function enabled. G.732S G.732S-CRC4 Default: G.732S 256S multiframe per ITU-T Rec. G.704 (16 frames per multiframe), CRC-4 function disabled. 256S multiframe per ITU-T Rec. G.704 (16 frames per multiframe), CRC-4 function enabled. The available range is 1 through 5. Default: 1 3-6 VF-30/VF-60 Configuration Instructions

Chapter 3 Configuration Instructions Table 3-2. External E1 Port Parameters (Cont.) Parameter Function Values Idle Code Selects the code transmitted to fill idle (unused) timeslots in the frames transmitted through this link toward user s equipment The available selections are 00 to FF (hexa). Default: FF Rx Gain Determines the maximum attenuation of the receive signal that can be compensated for by the port receive path, to obtain the BER performance required by the standards LONG HAUL SHORT HAUL Maximum attenuation of 30 db, relative to the nominal transmit level (0 db). Maximum attenuation of 12 db, relative to the nominal transmit level (0 db). The lower attenuation may actually improve the performance when operating over relatively short line sections, especially when operating over multi-pair cables. In such cables, significant interference is generated by the signals carried by other pairs, and therefore a weak desired signal may be masked by the interference. OOS Signaling Restoration Time Determines the state of the signaling bits during out-of-service periods. This parameter is not relevant when using the G.732N or G.732N-CRC4 frame Used to change the frame synchronization algorithm, to reduce the time required for the E1 port to return to normal operation after local loss of synchronization Default: SHORT HAUL FORCED BUSY The signaling bits are forced to the busy state during out-of-service periods. FORCED IDLE The signaling bits are forced to the idle state during out-of-service periods. Default: FORCED IDLE CCITT Complies with ITU-T Rec. G.732. 10 SECONDS Similar to the requirements of AT&T (62411) TR-62411 (after 10 seconds). 1 SECOND After 1 second. (FAST) Default: 1 SECOND (FAST) VF-30/VF-60 Configuration Instructions 3-7

Chapter 3 Configuration Instructions Table 3-2. External E1 Port Parameters (Cont.) Parameter Function Values Inband Management Inband Management Rate Routing Protocol Controls the transfer of inband management traffic through this port. Any selection except OFF requires transparent transmission of the management timeslot from the selected external port (link) to the Megaplex TDM buses through this internal port, and therefore it is necessary to lock the timing of the external port and the timing of the external equipment, as explained in Section 3.4 When the transfer of inband management traffic is enabled, selects the data rate Controls the transmission of RIP2 routing tables, to enable the use of the RIP2 routing protocol for management traffic carried through this link OFF The transfer of management traffic is disabled. DEDICATE PPP The transfer of management traffic is enabled. The management traffic is transferred in a dedicated timeslot, using synchronous PPP HDLC encapsulation. DEDICATE FR The transfer of management traffic is enabled. The management traffic is transferred in a dedicated timeslot, using Frame Relay encapsulation (under DLCI 100) in accordance with RFC 1490. Default: OFF When inband management is enabled (DEDICATE PPP or DEDICATE FR), the data rate is automatically set to 64 kbps (one timeslot). If inband management is OFF, this field shows N/A and cannot be changed The selections available when the inband management mode is DEDICATE PPP or DEDICATE FR are as follows: NONE Routing is not supported. PROPRIETARY RIP Supports only the RAD proprietary routing protocol. RIP2 Supports the RAD proprietary protocol and in addition transmits management routing tables in the format required by the RIP2 protocol. If inband management is OFF, this field shows N/A and cannot be changed. Default: NONE Timeslot Utilization Parameters The parameters that control the utilization of each timeslot carried by the external port are described in Table 3-4. The utilization parameters can be independently selected for each timeslot, provided the following configuration guidelines are taken into consideration: When using G.732S or G.732S-CRC4 framing, timeslot 16 cannot be assigned to traffic. 3-8 VF-30/VF-60 Configuration Instructions

Chapter 3 Configuration Instructions The voice timeslots of each external E1 port are processed in groups of 6 consecutive timeslots (skipping timeslot 16), as listed in Table 3-3. Therefore, when selecting timeslots for connection to an internal port, make sure that all the timeslots included in any given group are configured to the same Voice Coding and Fax Rate values. When inband management is enabled for the external E1 port being configured (DEDICATE PPP or DEDICATE FR), you must also assign a timeslot to the inband management traffic. When bypassing a timeslot for transparent transmission through a main link port, you can select as local destination only one of the free timeslots on a main link port that has already been configured and connected. The information regarding the remote destination (remote VF-30/VF-60 port and timeslot) specified by you must match the configuration defined on the remote VF-30/VF-60 module. Table 3-3. Timeslot Groups with Respect to Voice Coding and Fax Rate Parameters External E1 Port Group Timeslots 1 1, 2, 3, 4, 5, 6 1 2 7, 8, 9, 10, 11, 12 3 13, 14, 15, 17, 18, 19 4 20, 21, 22, 23, 24, 25 5 26, 27, 28, 29, 30, 31 6 1, 2, 3, 4, 5, 6 2 (VF-60 only) 7 7, 8, 9, 10, 11, 12 8 13, 14, 15, 17, 18, 19 9 20, 21, 22, 23, 24, 25 10 26, 27, 28, 29, 30, 31 VF-30/VF-60 Configuration Instructions 3-9

Chapter 3 Configuration Instructions Table 3-4. External E1 Port Timeslot Utilization Parameters Parameter Function Values Local Destination Determines the internal routing of the corresponding timeslot. The timeslot may be connected either to an internal port, or bypassed to a selected main link port. When the timeslot is bypassed, it is necessary to lock the timing of the external VF-30/VF-60 port and the timing of the external equipment, as explained in Section 3.4 Timeslot Type Determines the handling of the corresponding timeslot Remote Destination Port Remote Destination Timeslot Specifies the external E1 port of the remote VF-30/VF-60 module to which the payload carried by the corresponding timeslot is to be routed. The remote destination port and timeslot parameters determine the structure of the voice packets sent to the remote module Specifies the remote E1 port timeslot to which the payload carried by the corresponding timeslot is to be routed. The remote destination port and timeslot parameters determine the structure of the voice packets sent to the remote module N.C. INT01 to INT08 SS:CC:TT Default: N.C. VOICE TRANS MNG CCS<x> SS7<x> Default: VOICE N.C. EX1 or EX2 Default: N.C. N.C. The timeslot is not connected. In this case, the VF-30/VF-60 module sends the selected idle code in this timeslot. The timeslot is connected to the selected internal port. The timeslot is bypassed transparently to a selected main link timeslot. SS stands for the main link module slot, CC stands for the external port and TT stands for the timeslot number of the selected external port of the main link port. The timeslot payload is processed by the voice DSP in accordance with the selected Voice Coding parameter. The timeslot payload is transparently transferred. This selection is automatically displayed when the timeslot is bypassed and cannot be changed. The timeslot carries inband management. This option is available only when inband management is enabled. The timeslot carries CCS signaling data belonging to logical group x, x=1,,8. The timeslot carries SS7 signaling data belonging to logical group x, x=1,,8. The timeslot is not connected. This selection is acceptable only when the local destination is also N.C. The timeslot is connected to the specified external E1 port of the remote module. EX2 is acceptable only when the remote module is a VF-60 module. The timeslot is not connected. This selection is acceptable only when the local destination is also N.C. 1 to 31 Number of timeslot at the remote destination external port. Default: Same timeslot 3-10 VF-30/VF-60 Configuration Instructions

Chapter 3 Configuration Instructions 3.4 System Timing Considerations Two options are available: Lock the timing of the user s equipment to the Megaplex nodal timing, by configuring the equipment to use loopback timing (that is, lock its transmit timing to the clock signal recovered from the signal received from the external VF-30/VF-60 port. Lock the Megaplex nodal timing to the clock signal recovered from the signal received from the user s equipment connected to an external VF-30/VF-60 port. This option is configured by means of the DEF SYS command. For a general description of this command, refer to Appendix F of the Megaplex-2100 Installation and Operation Manual. 3.5 Displaying VF-30/VF-60 Information In addition to the configuration functions listed above, you can display status information and performance statistics on the module external and internal ports defined on the VF-30/VF-60 module, as well as information on the signaling transmitted and received by a specific voice channel carried by one of the module links. Displaying Status and Configuration Information You can read the VF-30/VF-60 status and configuration information using the DSP ST CH SS command. For a general description of this command, refer to Appendix F of the Megaplex-2100 Installation and Operation Manual. After entering the DSP ST CH SS command, you will see a data form similar to that displayed by the DEF ST CH SS command that displays the current module configuration and status data. For a description of the displayed parameters, refer to Table 3-1 and Table 3-2. Displaying Signaling Information The user can display the signaling information associated with a selected external port timeslot of the VF-30/VF-60 using the DSP SIG TS SS:CC:TT command. For a general description of this command, refer to Appendix F of the Megaplex-2100 Installation and Operation Manual. Displaying VF-30/VF-60 Information 3-11

Chapter 3 Configuration Instructions 3-12 Displaying VF-30/VF-60 Information

Chapter 4 Configuring Typical Applications This Chapter provides a typical configuration example that illustrates the procedures used to configure the VF-30/VF-60 modules. The configuration activities presented in this Chapter assume that the Megaplex unit is configured using a standard ASCII terminal. However, the same configuration activities can also be performed by means of a Telnet host, or an SNMP network management station. Chapter 3 presents the VF-30/VF-60 configuration parameters together with configuration guidelines. For general information regarding the supervision language syntax, usage and commands, refer to the Megaplex-2100 Installation and Operation Manual. 4.1 Typical Application The application in Figure 4-1 shows a typical point-to-point application for VF-30/VF-60 modules. In this application, a single PBX trunk (30 timeslots) is connected to an external port of the VF-30 module, allocated the 3 timeslots on a single internal port and the resulting data stream is routed to an ML-2E1 main link module port. The compressed voice data stream is transported through the TDM network to the far end, where it is restored and connected to another PBX. VF-30 ML-2E1 ML-2E1 VF-30 TDM Network Megaplex Megaplex PBX PBX Figure 4-1. Typical VF-30/VF-60 Application Typical Application 4-1