NDA-24318 ISSUE 1 STOCK # 200818 ® IPTRK Circuit Card System Manual NOVEMBER, 2000 NEC America, Inc.
LIABILITY DISCLAIMER NEC America, Inc. reserves the right to change the specifications, functions, or features, at any time, without notice. NEC America, Inc. has prepared this document for use by its employees and customers. The information contained herein is the property of NEC America, Inc. and shall not be reproduced without prior written approval from NEC America, Inc. NEAX® and Dterm® are registered trademarks of NEC Corporation. Cisco® is a registered trademark of Cisco Systems, Inc.
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NDA-24318 ISSUE 1 NOVEMBER, 2000 NEAX2400 IPX IPTRK Circuit Card System Manual TABLE OF CONTENTS Page CHAPTER 1 INTRODUCTION . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 1 1. GENERAL . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 1 2. SERVICE FEATURES TO BE PROVIDED . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .
LIST OF FIGURES Page Figure 1-1 Figure 1-2 Figure 1-3 Figure 1-4 Figure 1-5 Figure 2-1 Figure 2-2 Figure 2-3 Figure 2-4 Figure 2-5 Figure 2-6 Figure 2-7 Figure 2-8 Figure 3-1 Figure 3-2 Figure 3-3 Figure 3-4 Figure 3-5 Figure 3-6 Figure 3-7 Figure 3-8 Figure 3-9 Figure 3-10 Figure 3-11 Figure 3-12 Figure 3-13 Figure 3-14 Figure 3-15 Figure 3-16 Figure 3-17 Figure 3-18 Figure 3-19 Figure 4-1 Figure 4-2 Example Network Configuration via Intranet . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .
LIST OF TABLES Page Table 1-1 Table 2-1 Table 2-2 Table 2-3 Table 2-4 Table 3-1 Table 3-2 Table 3-3 Specification of IP Trunk . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . Lamp Indication Meanings . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . Switch Setting Meanings . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .
This page is for your notes.
INTRODUCTION CHAPTER 1 INTRODUCTION 1. GENERAL This manual explains the installation of the following IPTRK circuit cards, which are used to send/receive voice or FAX (G3) information via the Intranet. Although PA-8IPTB is equipped with a total of eight ports, an optional sub board (PZ-8VCTB) provides an additional eight ports, when mounted on a PA-8IPTB main board.
INTRODUCTION Table 1-1 Specification of IP Trunk (Continued) FUNCTION FAX SPECIFICATION REMARKS FAX Relay (T.30) G3 FAX (V.17, V.21, V.27ter, V.29, V.33) is available Super G3 (V.34, etc.) is not available Note 1 INTER-OFFICE SIGNAL LINK NEAX2400 IPX → NEAX2400 IPX FCCS MP CCIS MP MP: Point-to-Multipoint NEAX2400 IPX → NEAX2000 IVS2 CCIS MP Jitter Dynamic Jitter Buffer LAN Interface 10 BASE-T (100 BASE-TX) QoS (Quality of Service) WFQ by ToS Echo Canceller G.
INTRODUCTION Figure 1-3 represents a block diagram example of CCIS Networking via IP [C-163]. For more detailed information, see CHAPTER 3.
INTRODUCTION Figure 1-4 represents a block diagram example of CCIS Networking via IP [C-163] when an IPTRK circuit card in Node A is connected to the IPTRKs of Node B and C (Point-to-Multipoint connection). For more detailed information, see CHAPTER 3.
INTRODUCTION Figure 1-5 represents a block diagram example of FCCS Networking via IP [F-36]. For more detailed information, see CHAPTER 3.
INTRODUCTION 3. HOW TO FOLLOW THIS MANUAL AND RELATED REFERENCE MANUALS This manual describes only items related to the IPTRK circuit cards. Therefore, if you need details on the NEAX2400 IPX, the FCCS network, or the CCIS network, please refer to the related manual. Configuration of this manual and related reference manuals are shown below. 3.1 How to Follow This Manual • CHAPTER 1 INTRODUCTION This chapter explains the purpose of this manual.
CIRCUIT CARD EXPLANATIONS CHAPTER 2 CIRCUIT CARD EXPLANATIONS 1. GENERAL This chapter provides detailed explanations for the following circuit cards: • PA-8IPTB • PZ-8VCTB 2. PA-8IPTB (IPTRK Circuit Card) 2.1 General Function PA-8IPTB is a Line/Trunk circuit card that is used for providing CCIS/FCCS service via the Intranet, and to send/receive voice or FAX (G3) information over IP.
CIRCUIT CARD EXPLANATIONS 2.2 Mounting Location/Condition Mounting location/condition of this card is shown below.
CIRCUIT CARD EXPLANATIONS Ex. Slot 05 Examples of PA-8IPTB port accommodation: • Not equipped with Sub Board (PZ-8VCTB) • Equipped with one Sub Board (PZ-8VCTB) PA-8IPTB in a 32 port slot PWR PWR PIM • Ex.
CIRCUIT CARD EXPLANATIONS 2.3 Face Layout of Lamps, Switches and Connectors 1 2 3 4 5 6 7 8 1 2 3 4 5 6 7 8 MB MBR BUSY SW30 SW60 1 2 3 4 5 6 7 8 1 2 3 4 5 6 7 8 OPE SW20 SW50 1 2 3 4 5 6 7 8 SW10 SW40 1 2 3 4 5 6 7 8 The face layout of lamps, switches and connectors on this circuit card are shown below. For more detailed information, see Section 2.6 External Interfaces.
CIRCUIT CARD EXPLANATIONS Table 2-1 Lamp Indication Meanings (Continued) LAMP NAME COLOR MEANING OF INDICATION IP-LINK Green Lights when establishing a connection (physically) with the IP network. IP-TXRX Green Lights when sending/receiving data packets. IP-100M Green Lights when 100 Mbps interface is in use. IP-COL Yellow Lights when data packet collision is detected. F-LRR Green Lights when this card is used with FCCS network.
CIRCUIT CARD EXPLANATIONS Table 2-2 Switch Setting Meanings (Continued) SWITCH NAME SWITCH NUMBER 1 2 SETTING STANDARD SETTING External Ether 100 Mbps: Fixed Note 1 ON OFF × External Ether 10 Mbps: Fixed Note 1 Internal Ether 100 Mbps: Fixed Note 1 ON OFF MEANING × Internal Ether 10 Mbps: Fixed Note 1 PAD Pattern Selection SW10-3 SW10-4 SW10-5 3~5 SW10 OFF PAD PATTERN SELECTION OFF OFF Not used ON OFF OFF Not used OFF ON OFF µ-law Pattern 1 (for North America) ON ON OFF µ-law
CIRCUIT CARD EXPLANATIONS Table 2-2 Switch Setting Meanings (Continued) SWITCH NAME SWITCH NUMBER SETTING STANDARD SETTING MEANING Designation of Flexible PAD Value Note 1 SW20 -1 SW20 -2 SW20 -3 SW20 -4 SW20 -5 SW20 -6 PAD VALUE OFF OFF OFF OFF OFF OFF 16 [dB] ON OFF OFF OFF OFF OFF 15 [dB] OFF ON OFF OFF OFF OFF 14 [dB] 1~6 SW20 7 8 ON OFF × ON OFF × ON ON OFF OFF OFF OFF 13 [dB] OFF OFF ON OFF OFF OFF 12 [dB] ON OFF ON OFF OFF OFF 11 [dB] OFF
CIRCUIT CARD EXPLANATIONS Table 2-2 Switch Setting Meanings (Continued) SWITCH NAME SWITCH NUMBER 1 SETTING STANDARD SETTING ON × OFF MEANING Dynamic Controlling Static Controlling Voice Encoding/Decoding and Payload Cycle: 2~4 SW30 SW30 MEANING -2 SELECTION ORDER: HIGH TO LOW SW30 -4 SW30 -3 OFF OFF OFF Standard Setting G.729a G.723.1 G.723.1 (6.3K) (5.3K) OFF ON OFF Voice Quality Precedence Mode G.711 G.729a OFF OFF ON Band G.723.1 G.723.1 Precedence G.729a (5.3K) (6.
CIRCUIT CARD EXPLANATIONS Table 2-3 PAD Values of µ-law Pattern 1 / Pattern 2 PAD NO. Note: PATTERN 1 SEND PATTERN 2 RECEIVE SEND RECEIVE 7 or 15 0 [dB] 0 [dB] 1 2 [dB] 3 [dB] 2 4 [dB] 3 [dB] 3 6 [dB] 6 [dB] 4 8 [dB] or Flexible PAD Note 9 [dB] or Flexible PAD Note 5 0 [dB] 0 [dB] Flexible PAD is used when SW10-7 is set ON. For details on Flexible PAD values, refer to SW20-1~SW206. 2.
CIRCUIT CARD EXPLANATIONS When using an IPTRK circuit card for FCCS Networking via IP [F-36] (Point-to-Multipoint Connection), connect an Ethernet cable from the IPCON connector to the router. Next, connect another Ethernet cable from FCON connector to LANI card (CPR, PCI slot 00/03) via HUB. The following figure is an example when connecting the IPTRK circuit card to the LANI of CPU0, PCI slot 0.
CIRCUIT CARD EXPLANATIONS ATTENTION Contents Static Sensitive Handling Precautions Required To "SUB3B" Connector To "SUB3A" Connector Sub Board (PZ-8VCTB) Main Board (PA-8IPTB) Figure 2-7 Attachment of Sub Board (PZ-8VCTB) onto IPTRK Circuit Card NDA-24318 CHAPTER 2 Page 17 Issue 1
CIRCUIT CARD EXPLANATIONS 2.7 Switch Setting Sheet Table 2-4 Switch Setting Sheet MODULE SLOT NO. SWITCH NAME SWITCH SHAPE REMARKS ON MB ON MBR MODE SW10 1 2 34 56 78 ON 12 3 4 56 78 ON 1 2 3 4 56 78 ON 1 2 3 4 56 78 ON 1 2 3 4 56 78 ON 1 2 3 4 56 78 ON SW20 PIM SW30 SW40 SW50 SW60 3. PZ-8VCTB (Sub Board) 3.
OFFICE DATA PROGRAMMING CHAPTER 3 OFFICE DATA PROGRAMMING 1.
OFFICE DATA PROGRAMMING 2.1 Required Hardware This feature is available using the following hardware. As shown, both signal and speech paths can be provided by connection of IPTRK circuit cards between the nodes.
OFFICE DATA PROGRAMMING 2.2 Required Hardware (Point-to-Multipoint Connection) This feature (allowing IPTRK circuit cards for both speech and CCIS signal channels) is available by using the following hardware. Once this feature is set, each IPTRK circuit card can make a Point-to-Multipoint connection with IPTRK circuit cards of multiple nodes.
OFFICE DATA PROGRAMMING 2.3 Service Conditions 1. 2. 3. 4. 5. To send/receive speech and CCIS signals, each node will use an IPTRK circuit card. At this time, the IPTRK circuit cards in the self-node and each of its connected node can be in either 1-to-1 ratio, or in 1to-n (n=2 or more) relations. This is referred to as Point-to-Multipoint connection. A maximum number of two IPTRK circuit cards per UNIT are allowed. Accordingly, a total of 16 IPTRK circuit cards can be accommodated per IMG.
OFFICE DATA PROGRAMMING 6. 7. 8. 9. 10. Tandem Path through function is not provided. This feature supports QoS (Quality of Service) function. When a system message indicates “TCP link failure” due to data congestion on the router or IP network, a call cannot be made via an IPTRK circuit card. When a call is attempted despite this, the caller hears busy tone.
OFFICE DATA PROGRAMMING 11. This feature does not support Broad Band Services H0/H1. Therefore, when assigning the IPTRK circuit card routes by the ARTD command, enter BOB = 0. This feature can use link re-connection function. Service conditions are the same as those for the normal CCIS network. PAD can be provided for RECEIVE control only. On a conference call via IPTRK, Echo Canceller cannot be activated when using certain kinds of telephone sets (generally analog telephones).
OFFICE DATA PROGRAMMING Port accommodation for the IPTRK circuit card is shown below. All the available time slots on the controlling IPTRK circuit card can be assigned as the B-channel.
OFFICE DATA PROGRAMMING Perform the following data assignment using the ACSC/ACIC2 commands.
OFFICE DATA PROGRAMMING Note: • In Point-to-Multipoint connection, because it cannot be determined which destination node is to be called until the call is originated, all of the CCIS related data is assigned for the self-node. As to the ACIC1 command, the data must be assigned to all the destination nodes and also to the self-node.
OFFICE DATA PROGRAMMING Data assignment at Node A Data assignment at Node A PIM IPTK_IP bbb.bbb.bbb.b 23 19 15 (1) To Node B PIM (2) To Node C 22 18 14 21 17 13 06 04 02 00 10 08 06 04 02 00 20 16 12 06 04 02 00 20 16 12 o LENS Assign the 1st LEN of the IPTRK HW block 21 17 13 10 08 06 04 02 00 LENS Assign the 1st LEN of the IPTRK HW block )T (2 DST_IP ddd.ddd.ddd.d 22 18 14 PWR DST_IP ccc.ccc.ccc.c 09 07 05 03 01 11 09 07 05 03 01 DG_IP xxx.xxx.xxx.
OFFICE DATA PROGRAMMING 3. FCCS NETWORKING VIA IP [F-36] This feature allows the system to exchange both speech and FCCS signals via the Intranet. It is not necessary to use an FCH circuit card. To establish/release a call, the following connection patterns can be selected: For both speech and FCCS signal channels, an IPTRK circuit card is used. At this time, the IPTRK circuit cards in the self-node and each of its connected node(s) must be in 1-to-1 ratio. See Section 2.4 Data Programming.
OFFICE DATA PROGRAMMING 3.1 Required Hardware This feature is available by using the following hardware. As shown, both speech and FCCS signal channels between the nodes must be provided by IPTRK circuit cards with 10 BASE-T cables.
OFFICE DATA PROGRAMMING 3.2 Required Hardware (Point-to-Multipoint Connection) This feature (allowing IPTRK circuit card for both speech and FCCS signal channels) is available by using the following hardware. Once this feature is set, each IPTRK circuit card can make a Point-to-Multipoint Connection with IPTRK circuit cards of multiple nodes.
OFFICE DATA PROGRAMMING 3.3 Service Conditions 1. 2. 3. 4. 5. To send/receive voice information, each node will use an IPTRK circuit card. At this time, the IPTRK circuit cards in the self-node and its connected node(s) can be either in 1-to-1 ratio, respectively, or in 1to-n (n=2 or more) relations (referred to as Point-to-Multipoint connection). Be sure to use a router for connections between IP network and IPTRK circuit card. A maximum of two IPTRK circuit cards per UNIT are allowed.
OFFICE DATA PROGRAMMING 7. For Point-to-Multipoint connection, one IPTRK circuit card (assigned as FCCS signal controlling card by the AFCH command), can control the B-channels of the same card, and also a maximum of 15 other IPTRK circuit cards. It is not necessary to assign the trunk data for a time slot as a controlling channel.See the following figure. When the connection is Point-to-Multipoint, port accommodation for the IPTRK circuit card is shown below.
OFFICE DATA PROGRAMMING 13. When all lines of an IPTRK circuit card are busy, alternate routing to C.O. line or Tie line is available. Details on alternate routing patterns are shown in the table below: Table 3-2 Alternate Routing to be Provided/Not Provided (FCCS Networking via IP [F-36]) FROM FCCS NETWORKING VIA IP (POINT-TO-MULTIPOINT) TO FCCS NETWORKING VIA IP (POINT-TO-MULTIPOINT) Analog C.O.
OFFICE DATA PROGRAMMING STEP 2: ACRD - Assign Route Class Data of speech routes. It is not required to assign the signal route data. IPTRK circuit card assigned by the AFCH command is used as the FCCS signal channel controlling card. An example data assignment is shown in the following figure.
OFFICE DATA PROGRAMMING STEP 3: ACTK - Assign the connection trunk data of IPTRK circuit card. It is not required to assign the trunk data for D-channel. An example data assignment is shown in the following figure. When IPTRK circuit cards are mounted in the following slots with the specified RT numbers, data setting is as follows: IPTRK (C_RT2 [speech]) 0 0 0 4 0 Note 3 0 0 0 0 4 1 1 3 0 0 0 0 4 2 1 4 0 0 0 0 4 3 ..... ...... .....
OFFICE DATA PROGRAMMING STEP 5: AFCH - Assign FCH number (FCHN) to each IPTRK circuit card which is used as the FCCS signal controlling card. In this example, FCHN = 1 is assigned to the IPTRK circuit card controlling FCCS signal. Node A C_RT2 (Speech and FCCS Signal) IPTRK IPTRK Router FCHN = 1 FCHEN = 000040 C_RT1 (speech and FCCS Signal) AFCH command display FCHN HUB 1 FCHEN 000040 Note to CPU Figure 3-11 Example Assignment of FCHN Note: This setting is an example.
OFFICE DATA PROGRAMMING STEP 6: AETH - Assign the following data: FPC (Fusion Point Code): FPC number (1-253) of the Destination Node FCHN (FCH Number): FCH Number, specified in Step 5 C_RT (Connection Route): Connection Route Number of speech channel (1-1023) DST_IP (Destination IP Address): IPTRK IP address of the Destination Node NEXT_IP (Next IP Address): IPTRK IP address of the Destination Node Example data assignment is shown in the following figure, and the Example Data Sheets (Figure 3-15 through
OFFICE DATA PROGRAMMING STEP 7: STEP 8: ACAN - Assign the Fusion Connection Index Code (FCIC) to Self node FPC: FPC (Fusion Point Code): FPC number (1 - 253) of the Self node FCIC (Fusion Connection Index Code): Unique Fusion CICs in Self node C_LENS (Connection_LENS): IPTRK LENS data (speech channel data) specified in Step 3 Example data assignment is shown in Figure 3-13. AFRT - Set Connection Route Numbers of the speech channels for the FCHN, which was assigned in Step 5.
OFFICE DATA PROGRAMMING STEP 9: AGIP - Assign IP addresses of IPTRK circuit card and its connected route.
OFFICE DATA PROGRAMMING Data Assignment at Node A Data Assignment at Node A IPTK_IP 09 07 05 03 01 22 18 14 PWR 06 04 02 00 IPTEN Assign the 1st LEN of the IPTRK HW block 21 17 13 06 04 02 00 10 08 06 04 02 00 20 16 12 21 17 13 10 08 06 04 02 00 20 16 12 IPTEN Assign the 1st LEN of the IPTRK HW block 11 09 07 05 03 01 MULT Point to Mult 22 18 14 PWR MULT Point to Mult 09 07 05 03 01 11 09 07 05 03 01 DG_IP xxx.xxx.xxx.x rrr.rrr.rrr.r DG_IP xxx.xxx.xxx.x 23 19 15 IPTK_IP qqq.qqq.qqq.
OFFICE DATA PROGRAMMING 3.4.1 FCCS Routing Example Data Sheets This figure represent example data for FCCS Networking via IP [F-36] (Point-to-Multipoint). NEAX2400 IPX FPC 2 C_RT: 100 IP Address: 10.40.221.20 FCHN: 10 IP Address: 10.40.222.254 NEAX2400 IPX FPC 1 IPTRK Router POWER IPTRK IP Address: 10.40.221.254 Router Intranet C_RT: 100 IP Address: 10.40.222.20 FCHN: 20 POWER IPTRK C_RT: 100 IP Address: 10.40.221.
OFFICE DATA PROGRAMMING This figure represent example data for FCCS Networking via IP [F-36]. NEAX2400 IPX FPC 2 C_RT: 100 IP Address: 10.40.221.20 FCHN: 10 IP Address: 10.40.222.254 NEAX2400 IPX FPC 1 IPTRK Router POWER Point-to-Multipoint IPTRK IP Address: 10.40.221.254 Router Intranet C_RT: 150 IP Address: 10.40.222.20 FCHN: 20 POWER IPTRK Point-to-Multipoint C_RT: 101 IP Address: 10.40.221.21 FCHN: 11 NEAX2400 IPX FPC 3 IP Address: 10.40.223.
OFFICE DATA PROGRAMMING This figure represent example data when ASPC and AETH commands are required for an identical FPC at the tandem node. NEAX2400 IPX FPC 1 C_RT: 50 C_RT: 60 DTI FCH FCH FCHN: 1 IPTRK FCHN: 2 Router C_RT: 70 FCH NEAX2400 IPX FPC 3 DTI FCHN: 3 IPTRK FCHN: 4 Router POWER POWER C_RT: 100 IP Address: 10.40.221.20 FCHN: 10 C_RT: 80 DTI Tandem Node DTI NEAX2400 IPX FPC 2 C_RT: 150 IP Address: 10.40.222.20 FCHN: 20 Router FCH IPTRK POWER C_RT: 200 IP Address: 10.
OFFICE DATA PROGRAMMING This figure represent example data when FCCS routing data is not assigned by using the AFPC command. Be sure to assign the following dummy data when using this configuration. Use different FCHN for passing through the node C_RT: 150 IP Address: 10.40.222.20 FCHN: 20 POWER IPTRK IPTRK Tandem Node Router NEAX2400 IPX FPC 1 NEAX2400 IPX FPC 2 C_RT: 151 IP Address: 10.40.222.
OFFICE DATA PROGRAMMING This figure represent example data when AFPC and AETH commands are required for an identical FPC at the tandem node. C_RT: 70 C_RT: 80 NEAX2400 IPX FPC 2 DTI Tandem Node NEAX2400 IPX FPC 1 NEAX2400 IPX FPC 3 DTI FCHN: 4 FCH FCH FCHN: 3 IPTRK Router POWER IPTRK Router C_RT: 150 IP Address: 10.40.222.20 FCHN: 20 POWER C_RT: 100 IP Address: 10.40.221.
OPERATION TESTS AFTER INSTALLATION CHAPTER 4 OPERATION TESTS AFTER INSTALLATION 1. GENERAL This chapter explains the procedure to verify the normal operation of the IPTRK circuit card, when installation and necessary data setting have been completed. This chapter also explains the procedures to test and correct possible IPTRK circuit card-related faults. ATTENTION Contents Static Sensitive Handling Precautions Required 2. CCIS NETWORKING VIA IP [C-163]/VOICE OVER IP (H.323) When using the H.
OPERATION TESTS AFTER INSTALLATION 1. Note: Test of IP-LINK lamp on IPTRK circuit card: Note H.323 Handler (PA-8IPTB-A). a.) See if the IP-LINK lamp on the IPTRK circuit card Note is lighting green. This lamp will light if the circuit card is physically connected to the IP network. Note: 2. Note: H.323 Handler (PA-8IPTB-A). ATTENTION Contents Static Sensitive Handling Precautions Required b.
OPERATION TESTS AFTER INSTALLATION 3. FCCS NETWORKING VIA IP [F-36] When using the IPTRK circuit card for FCCS Networking via IP [F-36] (Point-toMultipoint Connection), perform the following circuit card operation tests. If necessary, perform fault repairs. Handling Precautions Required Caution:Some LSIs on this circuit card may be hot. Handle with care. 1. 2. ATTENTION Contents Static Sensitive Test of OPE lamp on IPTRK circuit card: a.
OPERATION TESTS AFTER INSTALLATION 3. 4. 5. 6. 7. 8. 9. Test of IP-LINK lamp on IPTRK circuit card: a.) See if the IP-LINK lamp on the IPTRK circuit card is lighting green. This lamp will light if the circuit card is physically connected to the IP network. b.) When the IP-LINK lamp is OFF, make sure that the Ethernet cable is securely ATTENTION Contents connected to the IPCON connector. Make sure that neither the Ethernet cable Static Sensitive Handling nor the router are faulty.
