Software Status Detail. [6] Click the Yes button to begin the download process.

Transcription

1 [6] Click the Yes button to begin the download process. Note: The complete SWP of is made up of two packages: SWP to upgrade from Rel. 2.1ICS2 to Rel SWP to upgrade from Rel to Rel When the SW download starts, a screen showing the in progress operation of the download appears. The download is aborted when the Abort button is pressed. [7] Click Ok Software Status Detail [1] On the WebEML main screen, click on the SW Download dropdown menu and select SW Status. This screen shows the last two software versions details (par and par ) stored on the NE. In this example, par shows the current committed software running on the NE. par shows the standby software or previous software. 798/980 3DB18809AAAA Issue 1 Installation

2 Tab 1 Committed Software This is the current software running on the NE Tab 2 Standby Software This is the software that was downloaded above or was the previous SW version. [2] Select Tab 2 and click on the Software Management Action drop down list. [3] Select Activation from the Software Management Action drop down list. [4] Click the Apply Action button to confirm the action. Installation 3DB18809AAAA Issue 1 799/980

3 [5] Click Confirm. [6] Click OK. [7] The card will reboot automatically with the new software in Tab 2 and will display this message. Click OK. Note After the Core-E card reboots, the Tab 2 software version that was activated above will be listed under the Tab 1 SW status detail and is the committed software running the NE. The previous software will be listed under Tab 2 now. 800/980 3DB18809AAAA Issue 1 Installation

4 5 The can be performed by using: tool (refer to paragraph 5.1 on page 801) WebEML (refer to paragraph 5.2 on page 834) 5.1 by Tool The Tool allows to create and modify provisioning files Start Tool [1] Double click on the mpresuite310 icon on the Desktop (for the local copy on the PC refer to paragraph on page 782). [2] Click on MPR Tools. Figure 561. TCO Convergence (MPR Tools) 3DB18809AAAA Issue 1 801/980

5 [3] Double click on the MSS-4/MSS-8 icon. Figure 562. MSS-4/MSS-8 [4] Click on the Tool button. Start provisioning Figure 563. TCO Main Menu The Tool can be used "offline" and "online". In case of offline, it allows to prepare the provisionning in back office. Minimizing time on field and mistakes. With the online mode you can either apply the "offline" configuration or fullfil online. 802/980 3DB18809AAAA Issue 1

6 This tool is recommended for first installation. Thanks to a step by step approach this tool is easy to handle and allows to minimise time for provisioning WebEML is more flexible and mandatory to configure AUX and ATM boards (not yet supported in provisioning tool). Select: the direct connection to the NE by putting a check mark on Connect to NE. When you locally connect the PC to the NE, in the IP Address field automatically (through the autodiscovery) appears the IP Address of the NE (in the NE the default configuration of the DHCP server is enabled; for this reason your PC must be configured to obtain an IP Address automatically). Click on OK. Note 1: If the DHCP server is disabled, the IP address to be entered is the IP address of the NMS Ethernet port. or the off-line configuration by putting a check mark on Do not connect to NE and by clicking on Apply. Figure 564. Tool Connectivity Figure 565. Tool Connectivity After loading the JRE package, the screen in Figure 566 will display, if you are working off-line or the screen in Figure 567, if you are directly connected to the NE. 3DB18809AAAA Issue 1 803/980

7 Figure 566. Tool Screen (off-line working) Figure 567. Tool Screen (direct connection to the NE) If the NE does not have an empty configuration, the following screen with the following message will appear. 804/980 3DB18809AAAA Issue 1

8 Figure 568. Clear Database and Restart NE Press the Clear Database and Restart NE button and then press Create to create a new configuration or press Open to open a previously created configuration. N.B. If you don't press the Clear Database and Restart NE button at the end of the configuration you can save the file, but you cannot apply the configuration to the NE. (The Apply button will not be available at the end of the procedure). 3DB18809AAAA Issue 1 805/980

9 Configuration Screen Options The screen below is a generic one that depicts all of the pull-down options possible depending on which card is selected in the card slot. Protections options shown below are for all cards. See the screens shown below for more information. Warning: the Tool allows to configue all the units, except the EAS unit, ASAP unit and AUX unit. (The EAS unit, ASAP unit and the AUX unit must be configured with the LCT). Warning: To configure the equipment extract the ASAP and/or AUX units, if any. Note: the SDH unit is available in 2 versions: SDHACC (operation in transparent mode) SDHCHAN (operation in channalized mode) Protection options for the Core cards Protection options for Slot 3 and Slot 4 To implement the protection refer to Figure 581. Figure 569. Configuration Options Screen Warning: If from this NE remote NEs have to be reached, remember to configure properly the Routing Protocol of the TMN-RF channel, if the remote NE is connected through the radio link (refer to Figure 575. or Figure 576. or Figure 578. or Figure 580.) or of the NMS Ethernet Port, if the remote NE is connected through the Ethernet cable (refer to Figure 594.). Buttons: Restore: allows to restore in the screen the initial data without any change Prev: the procedure goes back to the previous step (the changed data may be lost after the Warning message) Next: the procedure goes on to the next step (some checks and data storage is done) 806/980 3DB18809AAAA Issue 1

10 Cancel: the procedure goes back to step 1 (Opening screen) Help: by clicking on this button the operator calls the help on line. Note: A white icon indicates that there are no cross-connections, but cross-connections can be created. A blue icon indicates the destination is full. The limits granted by the license key have been exceeded. A message is also displayed stating that no more E1 ports will be accepted. A green icon indicates that the source and destination are available and the destination can accept more E1 ports. Enable the Ethernet port by selecting Transport. Select MPT-HC or MPT- MC to connect an MPT. When checked this feature enables input and output pause features E1 Access Card Icon Ethernet Icon Check to enable auto negotiation Modem card + ODU300 icon MPT Access card + MPT-HC icon Check to allow communication at data rate in both directions at the same time Check to allow communication at data rate but in only one direction at a time Select Transport if ETH Port 4 is used to transport Ethernet data. Select MPT-HC or MPT-MC to connect an MPT. Select TMN if ETH Port 4 on the Core Card is used for SNMP data Figure 570. Core-E Configuration (Sheet 1 of 2) 3DB18809AAAA Issue 1 807/980

11 The Quality Of Service feature enables priority forwarding in the Core Card switch based on how the packets are tagged: not tagged or tagged 802.1p or DiffServ. For general traffic, the packets are not tagged and QOS can be disabled. The user has to know if the packets are tagged, and if tagged 802.1p or DiffServ in order to know which QOS function to chose. Check to enable the optical SFP plug-in Check to select the operation mode Tick to enable the SSM Check to enable the Admission Control Select Master or Slave Each packet is based on DSCP field in IP header to determine priority Priority forwarding disabled Each packet is classified based on presence of valid 802.1p user priority tag Figure 571. Core-E Configuration (Sheet 2 of 2) 808/980 3DB18809AAAA Issue 1

12 Note With the TDM2TDM service profile the TDM Clock source is fixed to Differential (RTP - Real Time Protocol is used); with the TDM2Eth service profile the TDM Clock source can be Differential (RTP - Real Time Protocol is used) or Adaptive (RTP is not used). In the unit it is not possible to have mixed configurations with service profiles using RTP and other service profiles not using RTP. Example: if in the unit only one E1 has service profile TDM2TDM it is possible to configure other E1 with service profile TDM2Eth only with the Differential clock source (not with the Adaptive clock source). If the Adaptive clock source is requested the E1 must be connected to another PDH unit. Figure 572. E1 Configuration 3DB18809AAAA Issue 1 809/980

13 Enable the J0, if required, by selecting one of the two modes (SixteenBytesFrame/ OneRepeatedByte) and in the Expected Receiving Value field enter the expected value. Note: byte J0 is only read, no Regeneration section Termination is done. Set the Auto Laser Shutdown: Enabled/ Disabled ForcedOn/Disabled ForcedOff. This field will appear only if the Settings tab-panel of the STM-1 unit the optical SFP has been selected. Enter the Flow ID (range: 2 to 4080). Warning: the flow id must be unique in the MPR network. Select the type: Electrical or Optical Select the Jitter Buffer Depth: High/Low Put a check mark in the Port Status box to enable the STM-1 Select the TDM Clock Source: Differential/Node Timing Enter the Expected Value Figure 573. STM-1 Configuration (SDHACC) 810/980 3DB18809AAAA Issue 1

14 Select the Port type: SFP-O (Optical) or SFE-E (Electrical) Set the Auto Laser Shutdown: Enabled/Disabled ForcedOn/Disabled ForcedOff. This field will appear only if the Settings tab-panel of the STM-1 unit the optical SFP has been selected. Enable the J0, if required, by selecting one of the two modes (SixteenBytesFrame/OneRepeatedByte) in the Expected Receiving Value field and enter the expected value and in the Sending J0 field select one of the two modes and enter the value to be transmitted. Note: byte J0 is only read, no Regeneration section Termination is done. Put a check mark in the Port Status box to enable the STM-1 Select the Clock Source In the Single Tributary Configuration area configure all the E1s to be mapped/demapped in the STM-1. The E1s are identified by a progressive number from #1 to #63. Note: all the E1s can be configured in one shot by entering the parameters in the "One Shot" tributary Configuration. Enable, if required, the E1 Node Timing Configuration. The Node Timing is the timing from the network clock as defined in G The enabling of the Node Timing is applied to all E1s of the unit. By enabling the Node Timing the E1 streams in Rx side are retimed at the output with the network element clock. Figure 574. STM-1 Configuration (SDHCHAN) 3DB18809AAAA Issue 1 811/980

15 Enter number from 1 to 255 for Receiver ID. Must match associated Receiver ID at other end of hop. Enter number from 1 to 255 for Transmitter ID. Must match associated Transmitter ID at other end of hop. Check to enable radio ID mismatch function No check mark here. Check to enable PPP RF port. The user can select: - Static routing or - OSPF Area Select the suitable reference channel spacing. Select the modulation scheme. Tick to enable the SSM Transmission over the radio channel The Revertive Restoration Criteria are available only in 1+1 configuration, if you want traffic on the protection channel to automatically switch back to the main channel when alarms clear or a switch command is release. Check to enable ATPC Enter the Tx power Select the frequency separation from drop-down list. Enter the Tx RF frequecy within the allowed range. Figure 575. Modem (without Adaptive Modulation) 812/980 3DB18809AAAA Issue 1

16 Enter number from 1 to 255 for Receiver ID. Must match associated Receiver ID at other end of hop. Enter number from 1 to 255 for Transmitter ID. Must match associated Transmitter ID at other end of hop. Check to enable radio ID mismatch function Check mark to enable the Adaptive Modulation. The only available configuration is: 1+0, 1+1 HSB. Enable PPP RF port. The user can select: - Static routing or - OSPF Area Tick to enable the SSM Transmission over the radio channel The Revertive Restoration Criteria are available only in 1+1 configuration, if you want traffic on the protection channel to automatically switch back to the main channel when alarms clear or a switch command is release. Enable the Tx RF frequency within the allowed range. Select the frequency separation from drop-down list. Enter the Tx Power. Select in the Reference Mode field the spectral efficiency class to be set as reference. Select in the Reference Channel Spacing field the suitable channel spacing. Select in the Threshold field how many db the switching thresholds have to be moved from the default value (+4 db/-2 db). The default value is approx. 6 db below the 10-6 Rx threshold. Select in the Scheme field the Modulation range (4/16 QAM or 4/16/64 QAM) to be used by the Adaptive Modulation. Figure 576. Modem (with Adaptive Modulation) 3DB18809AAAA Issue 1 813/980

17 Select the power supply type: QMA or PFoE Enable one or two of the four ports by selection the MPT type: HC or MC: Port#1 and Port#2 are electrical Ethernet ports and Port#3 and Port#4 are optical Ethernet ports. Figure 577. MPT Access configuration (1+0) N.B. The selection of the Power Supply mode to supply the MPT can be: PFoE (through 1 cable for MPT-MC or MPT-HC with the Power Extractor) or QMA (through 2 cables for MPT-HC). 814/980 3DB18809AAAA Issue 1

18 Enter number from 1 to 255 for Receiver ID. Must match associated Receiver ID at other end of hop. Enter number from 1 to 255 for Transmitter ID. Must match associated Transmitter ID at other end of hop. See Note Check to enable radio ID mismatch function No check mark here. Check to enable PPP RF port. The user can select: - Static routing or - OSPF Area Select the suitable reference channel spacing. Select the modulation scheme. Select in the ETSI mask field the spectral efficiency class to be set as reference: None, Old ETSI mask or New ETSI mask Tick to enable the SSM Transmission over the radio channel Check mark to enable the ATPC, if required Enter the Tx power Select Tx (Go) and Rx (Return) separation frequency from drop-down list. Enter the Tx RF frequecy within the allowed range. Figure 578. MPT-Access (without Adaptive Modulation) Note: This field is available only with the MPT-HC V2 with the XPIC+RPS external module installed and if in the Mode area in the Option field a mask with XPIC has been selected. The XPIC can be configured in 1+0 or 1+1 HSB (no adaptive modulation, no ATPC). N.B.: NOT ALL the channel spacings and modulation schemes can support the XPIC Configuration. To configure the XPIC go to Figure DB18809AAAA Issue 1 815/980

19 In the Polarization field select the polarization to be used by the radio channel (Vertical or Horizontal). Go in the XPIC Configuration menu Figure 579. MPT-HC V2 with XPIC 816/980 3DB18809AAAA Issue 1

20 Enter number from 1 to 255 for Receiver ID. Must match associated Receiver ID at other end of hop. Enter number from 1 to 255 for Transmitter ID. Must match associated Transmitter ID at other end of hop. Check to enable radio ID mismatch function Check to enable PPP RF port. The user can select: - Static routing or - OSPF Area Check mark to enable the Adaptive Modulation. Tick to enable the SSM Transmission over the radio channel Enable the Tx RF frequency within the allowed range. Select the frequency separation from dropdown list. Enter the Tx Power. Select in the ETSI mask field the spectral efficiency class to be set as reference Choose in the Supported Modulation field all the modulation schemes to be used with the Adaptive Modulation. The modulation schemes (from the lowest to the highest scheme) must be contiguous. Select in the Reference Mode field the spectral efficiency class to be set as reference. Select in the Reference Channel Spacing field the suitable channel spacing. Figure 580. MPT-Access (with Adaptive Modulation) 3DB18809AAAA Issue 1 817/980

21 Enable one of the four ports for the unit on the left side and on the right side: Port#1 and Port#2 are electrical Ethernet ports and Port#3 and Port#4 are optical Ethernet ports. Select the Ports used in the protection scheme Select the protection scheme: 1+1 HSB, 1+1 FD Click on Add to enable the protection scheme Figure 581. MPT Access configuration (protection enabling: 1+1) 818/980 3DB18809AAAA Issue 1

22 Enter number from 1 to 255 for Transmitter ID. Must match associated Transmitter ID at other end of hop. Check to enable radio ID mismatch function Enter number from 1 to 255 for Receiver ID. Must match associated Receiver ID at other end of hop. See Note No check mark here. Check to enable PPP RF port. The user can select: - Static routing or - OSPF Area Select the suitable reference channel spacing. Select the modulation scheme. Select in the ETSI mask field the spectral efficiency class to be set as reference: None, Old ETSI mask or New ETSI mask Select Revertive feature if you want traffic on the protection channel to automatically switch back to the main channel when alarms clear or a switch command is released. Tick to enable the SSM Transmission over the radio channel Check mark to enable the ATPC, if required Enter the Tx power Select Tx (Go) and Rx (Return) separation frequency from dropdown list. Enter the Tx RF frequecy within the allowed range. Figure 582. MPT-Access (without Adaptive Modulation) (1+1) Note: This field is available only with the MPT-HC V2 with the XPIC+RPS external module installed and if in the Mode area in the Option field a mask with XPIC has been selected. The XPIC can be configured in 1+0 or 1+1 HSB (no adaptive modulation, no ATPC). N.B.: NOT ALL the channel spacings and modulation schemes can support the XPIC Configuration. To configure the XPIC go to Figure DB18809AAAA Issue 1 819/980

23 Enter number from 1 to 255 for Transmitter ID. Must match associated Transmitter ID at other end of hop. Check to enable radio ID mismatch function Enter number from 1 to 255 for Receiver ID. Must match associated Receiver ID at other end of hop. Check to enable PPP RF port. The user can select: - Static routing or - OSPF Area Check mark to enable the Adaptive Modulation. The available configurations are: 1+1 HSB, 1+1 FD. Select Revertive feature if you want traffic on the protection channel to automatically switch back to the main channel when alarms clear or a switch command is released. Tick to enable the SSM Transmission over the radio channel Enable the Tx RF frequency within the allowed range. Select the frequency separation from dropdown list. Enter the Tx Power. Select in the ETSI mask field the spectral efficiency class to be set as reference Select in the Reference Mode field the spectral efficiency class to be set as reference. Select in the Reference Channel Spacing field the suitable channel spacing. Choose in the Supported Modulation field all the modulation schemes to be used with the Adaptive Modulation. The modulation schemes (from the lowest to the highest scheme) must be contiguous. Select in the MSE Driving Criteria field the suitable value. In 1+1 FD and HSB configurations both the transmitters can be driven by the lowest (1) or by the highest MSE values (2) of the two remote demodulators. The Remote Switching Threshold field is not supported. Figure 583. MPT-Access (with Adaptive Modulation) (1+1) 820/980 3DB18809AAAA Issue 1

24 Secondary source: - Synch-In Port Clock from external source received on the Sync In connector on the Core card. - Any available E1 Clock from E1 source via E1 peripheral. - Any available Synch-E Clock from Giga Ethernet traffic. - Any available STM-1 port Clock from STM-1 source via STM-1 peripheral. - Free Run Local Oscillator Local oscillator on Core Card. - None No source. Restoration Criteria: - Revertive Switches sync source back to primary source after alarm on primary source clears. - Non-Revertive Does not switch back to primary source after primary alarm clears and stays on secondary sync source. Synchronization Role: Master Primary source: - Synch-In Port Clock from external source received on the Sync In connector on the Core card. - Any available E1 Clock from E1 source via E1 peripheral. - Any available Synch-E Clock from Giga Ethernet traffic. - Any available STM-1 port Clock from STM-1 source via STM-1 peripheral. - Free Run Local Oscillator Local oscillator on Core Card. This field will appear, if as Source (Primary or Secondary) has been selected the Synch-In port : MHz, MHz, 5 MHz, 10 MHz. Synch-Out Port configuration Connector that can be used to provide sync to another radio or ancillary equipment: MHz, MHz, 5 MHz, 10 MHz. This field will appear, if a Secondary Source has been selected. Select the suitable configuration. Enter the WTR time in the range 0-12 minutes at 10 second step. (Default: 5 minutes) Figure 584. Synchronization Configuration (Master) 3DB18809AAAA Issue 1 821/980

25 Secondary source: - Synch-In Port Clock from external source received on the Sync In connector on the Core card. - Any available E1 Clock from E1 source via E1 peripheral. - Any available Synch-E Clock from Giga Ethernet traffic. - Any available STM-1 port Clock from STM-1 source via STM-1 peripheral. - Rx Symbol Rate Clock extracted from the radio side. - Free Run Local Oscillator Local oscillator on Core Card. - None No source. Synchronization Role: Slave Primary source: - Synch-In Port Clock from external source received on the Sync In connector on the Core card. - Any available Synch-E Clock from Giga Ethernet traffic. - Rx Symbol Rate Clock extracted from the radio side. This field will appear, if as Primary Source has been selected the Rx Symbol Rate. Select the radio slot to be used. This field will appear, if as Source (Primary or Secondary) has been selected the Synch-In port : MHz, MHz, 5 MHz, 10 MHz. Synch-Out Port configuration Connector that can be used to provide sync to another radio or ancillary equipment: MHz, MHz, 5 MHz, 10 MHz. This field will appear, if as Secondary Source has been selected the Any available E1. Select the slot number and the E1 tributary number. Figure 585. Synchronization Configuration (Slave) 822/980 3DB18809AAAA Issue 1

26 In the XPIC Configuration will appear in GREEN only the MPT-HC V2 with a mask with XPIC (1+0 or 1+1 HSB, no Adaptive Modulation, no ATPC) configured in the Radio menu and with a suitable polarization (vertical or horizontal) To configure the XPIC refer to par where the explanation refer to the JUSM menu. The creation procedure is identical. The only difference is in pushbutton Apply, Refresh and Close: not available in the tool. Figure 586. XPIC Configuration 3DB18809AAAA Issue 1 823/980

27 To configure the Ring refer to par where the explanation refer to the JUSM menu. The creation procedure is identical. The only difference is in pushbutton Apply, Refresh and Close: not available in the tool. Figure 587. Ring Configuration 824/980 3DB18809AAAA Issue 1

28 By pressing Alt+W the Segregated Port View opens (refer to the next figure). To create the Cross-Connection refer to par where the explanation refer to the JUSM menu. Note: The only difference with the Tool is in the LAG cross-connections. No LAG cross-connections can be created with the Tool. The creation procedure is identical. The only difference is in pushbutton Apply, Refresh and Close: not available in the tool. Figure 588. Cross Connections Configuration 3DB18809AAAA Issue 1 825/980

29 By pressing Alt+W the Cross Connection View opens (refer to the previous figure). To segregate the ports refer to par where the explanation refer to the JUSM menu. The procedure is identical. The only difference is in pushbutton Apply, Refresh and Close: not available in the tool. Figure 589. Segregated Port Configuration 826/980 3DB18809AAAA Issue 1

30 When the NE is configured in this mode (default configuration), the Ethernet traffic is switched according to the destination MAC address without looking the VLAN. The packets from the user Ethernet ports having the VLAN ID out the allowed range (0 and ) are dropped. The packets having a VLAN ID already used for a TDM flow are accepted. Figure D management 3DB18809AAAA Issue 1 827/980

31 VLAN 1 Management VLAN-ID 1 is automatically defined by the NE when the 802.1Q bridge type is selected. VLAN-ID 1 is shown to the operator, but it cannot be neither changed nor deleted. All the user Ethernet ports (enabled and disabled) and all the radio ports are members of the VLAN 1. In egress VLAN-ID 1 is always removed from all the ports. When the NE is configured in this mode, the management of Ethernet traffic looking the VLAN is enabled. In this mode, one VLAN will be assigned to all Ethernet frames inside the MPR network. ADD VLan: to create a new VLAN (refer to Figure VLAN management) EDIT VLan: to change the parameters of a VLAN (VLAN name, VLAN member ports, VLAN untagged ports in egress). By clicking Next the Port VLan configuration screen opens (Figure 593). DEL VLan: to delete a VLAN-ID. It is possible to remove a VLAN-ID from the VLAN-ID table even if this VLAN-ID has been already configured on one or more user ports as Port VLAN to be added in ingress to untagged frames. As consequence, the VLAN-ID=1 and PRI=0 are added to the untagged frames received on this port. Before applying this deletion, a confirmation of the operation is shown to the operator. Figure Q management 828/980 3DB18809AAAA Issue 1

32 [1] VLAN ID field: Enter the VLAN ID (the configurable values must be in the range ) N.B.: The VLAN IDs already defined to cross-connect internal flows (i.e. TDM2TDM, TDM2ETH) cannot be used. [2] VLAN Name field: Enter the VLAN Name: a text string of up to 32 characters. N.B.: There is no check on unambiguity name. [3] VLAN Ports field: Select the ports members of this VLAN by putting a check mark on the relevant check box. All the user Ethernet ports and all the Radio directions can be considered. Both enabled and disabled user Ethernet ports (radio ports when declared are implicitly enabled) can be member of a VLAN. This means that a disabled port can be configured as a member of a VLAN and a port already member of a VLAN can be disabled continuing to be a member of the same VLAN. [4] Untagged Ports field: Select, among the ports belonging to this VLAN (members), the untagged ports (in egress the VLAN will be removed from the frames). Only the user Ethernet ports, enabled and disabled, are manageable. The VLAN cannot be removed from the radio ports (with the exception of the VLAN 1). N.B.: The VLAN-ID values allowed are in the range By default, for the VLAN IDs defined, all the ports are members and the Untag flag is set to False, which means all the frames are transmitted with Tag. N.B.: Tagged frames If one tagged packet with VLAN-ID X is received on a port which is not member of the VLAN- ID X, the packet is dropped. Figure 592. VLAN Management 3DB18809AAAA Issue 1 829/980

33 The untagged frames, received on each user Ethernet port (port 1 to 4, and port 5 if the optical SFP plug-in has been installed and configured), can be Accepted or Discarded. If the untagged frames are accepted, the VLAN-ID and Priority fields must be configured. Only VLAN-ID values already defined (in the VLAN management menu) can be configured for this purpose. The Priority values allowed are in the range 0-7. The default Port VLAN-ID and Priority values are: VLAN-ID=1; Priority=0. VLAN 1 is always removed, when the frame is forwarded. Figure 593. Port VLan configuration Note The Port VLan Configuration screen opens only if in the Bridge Configuration screen the 802.1Q (Virtual Bridge) has been selected. 830/980 3DB18809AAAA Issue 1

34 Select Static Routing for manual routing. Select OSPF (Open Shortest Path First Protocol) for automatic routing. Enter local IP Address. Enter IP Address for Ethernet port. Enable the Ethernet port for management Enter the parameters for the TMN In-band management (if required) Enable the NTP Protocol. Enter the IP Address of the Main NTP server. Enter the IP Address of the Spare (standby) NTP server. Figure 594. Network Configuration 3DB18809AAAA Issue 1 831/980

35 A Trusted manager is an SNMP manager to which the NE automatically sends the TRAPS generated inside the NE. Figure 595. Trusted Managers screen 832/980 3DB18809AAAA Issue 1

36 Figure 596. Typical Report Panel By pressing the Save button an XML file is created with extension mcml. 3DB18809AAAA Issue 1 833/980

37 5.2 by WebEML Start WebEML 1) Double click on the 9500MPR-E 3.1 WebEML icon on the Desktop (for the local copy on the PC refer to paragraph on page 782). 2) Enter the IP Address or DNS name. 3) Click OK. 2 3 Figure 597. Network Element Overview 4) If the Supervision is ongoing, click Show. 5) Type your Login Name must not be more than 20 characters. Set the note at page ) Type your Password must not be less than six (6) or more than 20 characters and must be composed of full ASCII characters set (UPPER/lower case, numeric and special characters). Set the note at page ) Click on Apply. 834/980 3DB18809AAAA Issue 1

38 Figure 598. How to Login Note Profile Types there are four user profiles defined. Administrator (full access also for NMS local system security parameters). CraftPerson: person in charge for installation and the mantenance at radio site; full access to NE but not for security parameters, only for own password. Operator (person in charge to operate at the network level, not at the radio side). Viewer (view screens only). 3DB18809AAAA Issue 1 835/980

39 Note Default User Accounts at the NE installation time, two default user accounts are created on NE independently from the SNMP operating mode. Profile: administrator Username: initial Password: adminadmin Profile: craftperson Username: Craftperson Password: craftcraft To change the Default UserName and Password refer to par on page /980 3DB18809AAAA Issue 1

40 5.2.2 Note Changes to provisioning do not have to be made in any particular order. See Figure 599. for recommended sequence. Start Enable Plug-In Cards (par ) Provision Plug-In Cards (par ) Provision XPIC (if required) (par ) Provision Synchronization (par ) Provision NTP protocol (par ) Provision NE Time (par ) Provision VLAN (if required) (par ) Provision Cross-Connections (par ) Provision AUX Cross-Connections (if required) (par ) Provision Ethernet Ring (if required) (par ) Provision LAG (par ) Provision System (par ) Provision management parameters (par to par ) Figure 599. sequence Warning: If from this NE remote NEs have to be reached, remember to configure properly the Routing Protocol of the PPP RF channel, if the remote NE is connected through the radio link (refer to Figure 630. or Figure 633. or Figure 636.) or of the NMS Ethernet Port, if the remote NE is connected through the Ethernet cable (refer to Figure 649.). 3DB18809AAAA Issue 1 837/980

41 Enable Plug-In Cards All the cards that can be inserted in MSS4 or MSS8 chassis must be enabled in the equipment section: SFP optical plug-in Spare CORE-E (in slot 2 only) E1-PDH Access card STM-1 Access card Modem Access card (ODU300 interconnection) MPT Access card (MPT interconnection) AUX board ASAP board EAS board FAN board Enable the MSS cards by using the following procedures. See Figure 600. through Figure /980 3DB18809AAAA Issue 1

42 Enable SFP optical plug-in See Figure 600. Follow the steps to enable the optional SFP plug-in for the optical 1000 Mb/s Ethernet interface. 1 Setting tab 2 The Ethernet ports of the Core-E can be configured in 2 ways: 1. to be used as GigaEthernet interface for Ethernet traffic (Note: for port#5 and port#6 the optional SFP must be installed); 2. to be used to connect an MPT: MPT-HC or MPT-MC to port#1 to port#4; an MPT-HC only to port#5 and port# Apply the Equipment Type Figure 600. Enable SFP optical plug-in 3DB18809AAAA Issue 1 839/980

43 Enable Spare Core-E Card See Figure 601. Follow the steps to enable the Spare Core-E Card in slot 2. 1 Figure 601. Enable Spare Core-E Card 840/980 3DB18809AAAA Issue 1

44 Enable E1 Access Card See Figure 602. Follow the steps to enable the E1 Access Card(s). 1 Figure 602. Enabling E1 Access Card 1 Figure 603. Enabling E1 Access Card on the same row (to implement protected configuration) 3DB18809AAAA Issue 1 841/980

45 1 Figure 604. Enabling E1 Access Card protection 842/980 3DB18809AAAA Issue 1

46 Enable STM-1 Access Card See Figure 605. Follow the steps to enable the STM-1 Access Card(s). 1 Figure 605. Enabling STM-1 Access Card 3DB18809AAAA Issue 1 843/980

47 Select the optical SFP (SFP-O) or the electrical SFP (SFP-E) installed on the STM-1 ports (SFP#1 and/or SFP#2) and click Apply. Note: It is not possible to enable SFP #1 and SFP #2 at the same time. Figure 606. Enabling SFP for SDHACC Select the optical SFP (SFP-O) or the electrical SFP (SFP-E) installed on the STM-1 port (SFP#1) and click Apply. Figure 607. Enabling SFP for SDHCHAN 844/980 3DB18809AAAA Issue 1

48 1 Figure 608. Enabling STM-1 Access Card on the same row (to implement protected configuration) 1 Figure 609. Enabling STM-1 Access Card protection 3DB18809AAAA Issue 1 845/980

49 Enable Modem Card (to interface ODU300) See Figure 610. Follow the steps to enable the Modem Card(s). Note ODU is automatically enabled when Modem Card is enabled. 1 Figure 610. Enabling Modem Card 846/980 3DB18809AAAA Issue 1

50 1 Figure 611. Enabling Modem Card on the same row (to implement protected configuration) 1 Figure 612. Enabling Modem Card protection 3DB18809AAAA Issue 1 847/980

51 Enable MPT Access Card (to interface the MPT-HC and MPT-MC) See Figure 613. Follow the steps to enable the MPT Access Card. 1 Figure 613. Enabling MPT Access Card 5 Select as Usage MPT-HC or MPT-MC in one or two Ports. N.B. Port#1 and Port#2 are electrical Ethernet ports and Port#3 and Port#4 are optical Ethernet ports. 6 Click on Apply Figure 614. Enabling one port in the MPT Access card N.B. Two unprotected or protected MPT-HC or MPT-MC can be connected to one MPT Access unit. 848/980 3DB18809AAAA Issue 1

52 1 Figure 615. Enabling MPT Access Card Select as Usage MPT-HC or MPT-MC in one or two Ports. N.B. Port#1 and Port#2 are electrical Ethernet ports and Port#3 and Port#4 are optical Ethernet ports. 6 Click on Apply Figure 616. Enabling one port in the MPT Access card - 1 3DB18809AAAA Issue 1 849/980

53 1 To configure the protection scheme select the MPT-HC. (In the example MPT-HC#31: connected to Port#1 of the MPT Access unit in Slot#3). 4 Click on Apply 2 Settings tab. 3 Select the suitable protection scheme Figure 617. Enabling Protection configuration with MPT-HC/MPT-MC 850/980 3DB18809AAAA Issue 1

54 Enable ASAP Card See Figure 618. Follow the steps to enable the ASAP Card. 1 Figure 618. Enabling ASAP Card 3DB18809AAAA Issue 1 851/980

55 Enable EAS Card See Figure 619. Follow the steps to enable the EAS Card. 1 Figure 619. Enabling EAS Card 852/980 3DB18809AAAA Issue 1

56 Enable AUX Card See Figure 620. Follow the steps to enable the AUX Card. 1 Figure 620. Enabling AUX Card 3DB18809AAAA Issue 1 853/980

57 Enable Fan Unit See Figure 621. Follow the steps to enable the Fan Unit. 1 Figure 621. Enabling Fan Unit 854/980 3DB18809AAAA Issue 1

58 Provision Plug-In Cards See Figure 622. through Figure 634. to provision MSS plug-in card parameters after the cards have been enabled Provision Core-E Card See Figure 622. Follow the steps to provision Ethernet ports From the Ethernet traffic interfaces (configured as 1000 Mb/s) it is possible to recover the physical Rx synchronization signal or to deliver the Network Element Clock synchronization signal (in this case the Ethernet port must be set as Sync-E Master). Enable the Synch-E mode by setting Synchronous and selecting the operating mode: Master or Slave. Note: If the electrical Ethernet port has to be used as Synchronous Source, the Ethernet port must be set as Synch-E Slave. Figure 622. Core-E Card (Ethernet ports 1-4) See Figure 623. Follow the steps to provision Ethernet port 5 (available if the optional SFP plug-in has been installed and enabled in the Core-E unit). 3DB18809AAAA Issue 1 855/980

59 7 8 Click Apply button. From the Ethernet traffic interfaces (configured as 1000 Mb/s) it is possible to recover the physical Rx synchronization signal or to deliver the Network Element Clock synchronization signal (in this case the Ethernet port must be set as Sync-E Master). Enable the Synch-E mode by setting Synchronous and selecting the operating mode: Master or Slave. Note: If the electrical Ethernet port has to be used as Synchronous Source, the Ethernet port must be set as Synch-E Slave. Figure 623. Core-E Card (Ethernet port 5) 856/980 3DB18809AAAA Issue 1

60 Provision PDH Access Card (TDM2TDM) See Figure 624. Follow the steps to provision E1 lines (ports) Double Left Click See details in Figure Flow ID number required to transport E1 data. 4 7 Choose TDM2TDM if radio is being used to transport E1 data only (no Ethernet). Flow ID number is system unique and must not be repeated in radio network. Loss of E1 data can occur. Figure 624. PDH Access Card (TDM2TDM) 3DB18809AAAA Issue 1 857/980

61 Provision PDH Access Card (TDM2ETH) See Figure 625. Follow the steps to provision E1 lines (ports) Double Left Click See details in Figure Flow ID number required to transport E1 data Flow ID number is system unique and must not be repeated in radio network. Loss of E1 data can occur. Figure 625. PDH Access Card (TDM2ETH) 858/980 3DB18809AAAA Issue 1

62 Signal Mode. Configures line format. Allows user to choose if line is dropped and inserted (by selecting Framed/ Unframed) or passed through or not used (by selecting Disabled) Select Disabled if port (E1 line) is not: being used as a source or destination (typical choice for a line not being used at a terminal or not being dropped and inserted at a repeater); being dropped or inserted (typical choice for a line being passed through at a through repeater and not being dropped and inserted at a drop and insert repeater). Select Framed: to be able to collect the performances at the input in Tx side and at the output in Rx side. Select Unframed: being used as a source or destination (typical choice for a line being used at a terminal); being dropped or inserted (typical choice for a line being dropped and inserted at a drop and insert repeater) 4 Figure 626. PDH Access Card Details 3DB18809AAAA Issue 1 859/980

63 Provision SDH Access Card (SDHACC) See Figure 627. Follow the steps to provision STM-1 ports #1 and #2. Double Left Click Flow ID number is system unique and must not be repeated in radio network. Loss of STM-1 data can occur. Figure 627. SDH Access Card (SDHACC) 860/980 3DB18809AAAA Issue 1

64 [2] Put a check mark in the Port Status box to enable the STM-1. [3] Click on Apply. [4] Set the Auto Laser Shutdown: Enabled/Disabled ForcedOn/Disabled ForcedOff. This field will appear only if the Settings tab-panel of the STM-1 unit the optical SFP has been selected. [5] Enable the J0, if required, by selecting one of the two modes (SixteenBytesFrame/OneRepeated Byte) and in the Expected Receiving Value field enter the expected value. Note: byte J0 is only read, no Regeneration section Termination is done. [6] Click on Apply on the left part. [7 Enter the Flow ID (range: 2 to 4080). Warning: the flow id must be unique in the MPR network. [8] Select the Jitter Buffer Depth: High/Low. [9] Select the TDM Clock Source: Differential/Node Timing. [10] Click on Apply on the right part. 3DB18809AAAA Issue 1 861/980

65 Provision SDH Access Card (SDHCHAN) See Figure 628. and Figure 629. Follow the steps to provision STM-1 ports #1 and #2. Double Left Click Go to the next page Figure 628. SDH Access Card (SDHCHAN) 862/980 3DB18809AAAA Issue 1

66 Figure 629. SDH Access Card (SDHCHAN) [2] Put a check mark in the Port Status box to enable the STM-1. [3] Set the Auto Laser Shutdown: Enabled/Disabled ForcedOn/Disabled ForcedOff. This field will appear only if the Settings tab-panel of the STM-1 unit the optical SFP has been selected. [4] Select the Clock Source. [5] Enable the J0, if required, by selecting one of the two modes (SixteenBytesFrame/OneRepeated Byte) in the Expected Receiving Value field and enter the expected value and in the Sending J0 field select one of the two modes and enter the value to be transmitted. Note: byte J0 is only read, no Regeneration section Termination is done. [6] Click on Apply. [7] Enable, if required, the E1 Node Timing Configuration. The Node Timing is the timing from the network clock as defined in G The enabling of the Node Timing is applied to all E1s of the unit. By enabling the Node Timing the E1 streams in Rx side are retimed at the output with the network element clock. [8] Configure all the E1s to be mapped/demapped in the STM-1. The E1s are identified by a progressive number from #1 to #63, but also by the standard SDH identification (x-y-z). The E1 tab-panel performs all available functions for the tributary. To define the involved ports, the interface selection in the tree view is first required; therefore the selection of the desired tributary port in the tabular view enables the «Resource Detail list» to show the available functions for the single one resource. 3DB18809AAAA Issue 1 863/980

67 [9] Select Settings. [10] Signal Mode: The possible values are: Unframed for the unframed received signal Framed for the collection of the performances at the input in Tx side and at the output in Rx side Disabled [11] Click on Apply. [12] Service Profile: The possible profiles are: TDM2TDM TDM2Eth [13] Flow Id: To implement cross-connections between line side and radio side each E1 tributary must be associated to an identifier. Enter the Flow identifier value in the relevant field (possible values: 2 to 4080) and press Apply. [14] Fields ECID Tx, ECID Rx, Payload Size and TDM Clock Source can be written only if the Service Profile is TDM2Eth. Note: The service profile must be the same for all the E1s. [15] Alarm profile: Not implemented now. [16] Click on Apply. 864/980 3DB18809AAAA Issue 1

68 Provision Modem Card See Figure 630. and follow the steps to provision the Modem Card for Presetting Mode. See Figure 632. and follow the steps to provision the Modem Card for Adaptive Modulation mode. Tick on Enable to enable the transmission of the SSM message over the radio channel Figure 630. Modem Card, Presetting Mode (Sheet 1 of 2) 3DB18809AAAA Issue 1 865/980

69 By clicking on the icon the Alarm Severity Profile menu opens, which allows to associate to the radio channel a specific alarm profile. Select one Alarm Profile in the Profile Name list (4 alarm profiles are listed) and click Apply. Tick the Show details check box to see the severity associated to each alarm. Figure 631. Modem Card, Presetting Mode (Sheet 2 of 2) Warning When the Mode is changed from Presetting to Adaptive Modulation, the radio defaults to 14 MHz bandwidth at 4 QAM. If the capacity of the radio (number of E1 lines cross connected) exceeds the available capacity of a 14 MHz Channel at 4 QAM, Adaptive Modulation will not enable. It may be necessary to perform one of the following provisioning changes: 1. Reduce the quantity of E1 lines being transported to meet the required capacity. 2. Increase Reference Channel Spacing. 866/980 3DB18809AAAA Issue 1

70 Figure 632. Modem Card, Adaptive Modulation Mode (Sheet 1 of 3) 3DB18809AAAA Issue 1 867/980

71 Figure 633. Modem Card, Adaptive Modulation Mode (Sheet 2 of 3) 868/980 3DB18809AAAA Issue 1

72 By clicking on the icon the Alarm Severity Profile menu opens, which allows to associate to the radio channel a specific alarm profile. Select one Alarm Profile in the Profile Name list (4 alarm profiles are listed) and click Apply. Tick the Show details check box to see the severity associated to each alarm. Figure 634. Modem Card, Adaptive Modulation Mode (Sheet 3 of 3) 3DB18809AAAA Issue 1 869/980

73 Provision MPT Access Card See Figure 635. to Figure 639. and follow the steps to provision the MPT Access Card. Mode 1 - QMA (only with MPT-HC) In this mode the MPT-HC V1 is power supplied with a dedicated coaxial cable connected on the QMA connector on the front panel of the MPT Access unit. Mode 2 - PFoE (Power Fixed on Ethernet) In this mode the MPT-HC or MPT-MC are power supplied by using the electrical Ethernet cable. Note: To implement this mode with MPT- HC the Power Extractor must be installed, near the MPT-HC, to separate the Ethernet traffic and the power supply. Figure 635. Power Source configuration Note: To unprovision an MPT: perform a Tx Mute; unprovision the MPT; remove the power supply. 870/980 3DB18809AAAA Issue 1

74 Mode. Select Presetting from dropdown list. Reference Channel Spacing. Displays reference channel spacing based on capacity and modulation. Select from dropdown list. Modulation. Displays modulation scheme based on reference channel spacing and capacity. Select from dropdown list. Capacity. Read Only Field. See Note. PPP RF. Check to enable PPP RF port. When not checked (disable) user command change: - Routing IP Protocol - OSPF Area - Remote Address Click to enable Open Shortest Path First protocol then select area name that has OSPF protocol. Select from dropdown list. Alarm Profile. Not supported. Check to enable radio ID mismatch function. Enter number from 1 to 255 for receiver ID. Must match transmitter ID at other end of hop. Enter number from 1 to 255 for transmitter ID. Must match associated receiver ID at other end of hop. Tick on Enable to enable the transmission of the SSM message over the radio channel Figure 636. MPT Access Card, Presetting Mode (Sheet 1 of 2) Note: This field is available only with the MPT-HC V2 with the XPIC+RPS external module installed and if in the Mode area in the Option field a mask with XPIC has been selected. The XPIC can be configured in 1+0 or 1+1 HSB (no adaptive modulation, no ATPC). N.B.: NOT ALL the channel spacings and modulation schemes can support the XPIC Configuration. Select the suitable Polarization: Vertical or Horizontal. 3DB18809AAAA Issue 1 871/980

75 Shifter. Select the frequency separation from the Shifter Data Help list. Range. Displays range of Tx RF frequencies that may be entered. Tx RF Frequency is automatically entered by ODU when ODU is connected to MSS. If the ODU is not connected to the MSS, enter the Tx RF Frequency, whitin allowed range. Read Only Field. Displays Rx RF Frequency. Result of calculation: Rx Freq - X Freq = Shifter Freq. Tx Mute. Read Only Field. Status of Local Tx Mute function. By clicking on the icon the Alarm Severity Profile menu opens, which allows to associate to the radio channel a specific alarm profile. Select one Alarm Profile in the Profile Name list (4 alarm profiles are listed) and click Apply. Tick the Show details check box to see the severity associated to each alarm. ATPC. Check to enable ATPC. ATPC Power Range. Remote ATPC Tx Threshold. Default value is -55 dbm. Select in the RSL Driving Criteria field the suitable valueonly for MPT-HC. In 1+1 FD and HSB configurations both the transmitters can be driven by the lowest or by the highest RLS values of the two remote demodulators. Figure 637. MPT Access Card, Presetting Mode (Sheet 2 of 2) 872/980 3DB18809AAAA Issue 1

76 Mode. Select from the dropdown list. Reference Channel Spacing. Displays reference channel spacing based on the modulation mode and the modulation range. Select from the dropdown list. Modulation. Select the lowest modulation scheme. Manual Operation. When checked, allowed user to select and test a specific modulation scheme. Current Modulation. Read Only Field. Displays modulation scheme the radio is currently using. Forced Modulation. Select modulation scheme (one from the Modulation Range selected) to test. When activated by the Apply button, radio is forced to operate using selected modulation scheme. PPP RF. Check to enable PPP RF port. When not checked (disabled) user cannot change: - Routing IP Protocol - OSPF Area - Remote Address Select the spectral efficiency class to be set as reference: None, Old ETSI mask or New ETSI mask. Choose in the Supported Modulation field all the modulation schemes to be used with the Adaptive Modulation. The modulation schemes (from the lowest to the highest scheme) must be contiguous. Note: With MPT-MC max. scheme is 128 QAM. The Remote Switching Threshold field is not supported. Not supported in Adaptive Modulation mode Link Identifier Confguration. Check to enable radio ID mismatch function. Expected Identifier. Enter number from 1 to 255 for receiver ID. Must match transmitter ID at other end of hop. Sent Identifier. Enter number from 1 to 255 for transmitter ID. Must match associated receiver ID at other end of hop. Figure 638. MPT Access Card, Adaptive Modulation Mode (Sheet 1 of 2) 3DB18809AAAA Issue 1 873/980

77 Select the frequency separation from the dropdown list. Displays range of Tx RF frequencies that may be entered. The Tx Power function allows the operator to select the transmitter output power of each modulation scheme. The default level is the expected output power. The minimum and maximum range of each modulation scheme is shown in parenthesis (min XX- max YY). Tx RF Frequency is automatically entered by ODU when ODU is connected to MSS. If the ODU is not connected to the MSS, enter the Tx RF frequency, within allowed range. Read Only Field. Displays Rx RF frequency. Result of calculation: Rx Freq - Tx Freq = Shifter Freq. Select in the RSL Driving Criteria field the suitable value. In 1+1 FD and HSB configurations both the transmitters can be driven by the lowest or by the highest RLS values of the two remote demodulators. By clicking on the icon the Alarm Severity Profile menu opens, which allows to associate to the radio channel a specific alarm profile. Select one Alarm Profile in the Profile Name list (4 alarm profiles are listed) and click Apply. Tick the Show details check box to see the severity associated to each alarm. Check to enable the Tx output power out of ODU. Read Only Field. Status of Local Tx Mute function. Figure 639. MPT Access Card, Adaptive Modulation Mode (Sheet 2 of 2) 874/980 3DB18809AAAA Issue 1

78 Provision ASAP Card See Figure 640. and follow the steps to provision the ASAP Card. Figure 640. ASAP Card The configuration of the ASAP unit is divided in four tab-panels: E1 Layer IMA Layer ATM Layer ATM PW Layer For the configuration of the tab-panels refer to paragraph 3.18 on page DB18809AAAA Issue 1 875/980

79 Provision EAS Card See Figure 641. and follow the steps to provision the EAS Card. Setting tab Port #5 to #8 can be configured to accept an optical SFP. Apply the Equipment Type Figure 641. EAS Card Configuration the Ethernet ports as explained in paragraph 3.14 on page /980 3DB18809AAAA Issue 1

80 Provision AUX Card See Figure 642. and follow the steps to provision the AUX Card. Figure 642. AUX Card The configuration of the AUX unit is divided in two tab-panels: Settings External Points For the configuration of the tab-panels refer to paragraph 3.20 on page DB18809AAAA Issue 1 877/980

81 Provision XPIC The XPIC configuration can be implemented only with the MPT-HC V2. For the configuration refer to paragraph 3.16 on page Provision Synchronization All the NEs radios in the network must be synchronized to the same clock. One radio in the network is provisioned Master. All other radios in the network must be provisioned Slave. The slave radios all sync to the clock provided by the master. For the Synchronization configuration refer to par on page Provision NTP protocol This menu allows to enable the NTP (Network Time Protocol). Figure 643. NTP protocol Put a check mark in the NTP protocol field to enable the protocol and write in the Main Server address field the IP address of the server, which is in charge to distribute the time to all the NEs in the network. In the Spare Server address field write the IP address of the Spare Server, if any. The Server reachability field is a read-only field, which shows the reachability of the NTP servers. The following information can appear: "Main server reachable" "Spare server reachable" "None servers reachable" "Both servers reachable" Click on Apply to send to the NE the NTP Configuration. Refresh push-button can be used to update the screen. 878/980 3DB18809AAAA Issue 1

82 Provision NE Time The user can synchronize the NE time from either the PC/laptop or Network Time Protocol (NTP) servers. Time and date provisioning is accomplished using the NE Time Configuration screens. See Figure 644. and follow the steps to provision Network Equipment Time. Click to display pop-up dialog for NE Time configuration. If NPT Protocol is disabled, when checked, enables function to synchronize Operating System and Network Equipment Times. 3 4 Figure 644. NE Time 3DB18809AAAA Issue 1 879/980

83 Provision VLAN (if required) To provision the VLAN management, if required, refer to paragraph 3.22 on page Provision Cross-Connections The available cross-connections are listed in the next paragraphs: To create the TDM cross-connections refer to paragraph on page 253. To create the SDH cross-connections with SDHACC - Transparent mode refer to paragraph on page 262. To create the SDH cross-connections with SDHCHAN - Channalized mode refer to paragraph on page 266. To create the ATM Cross-connections refer to paragraph on page 270. To create the LAG-LAG Cross-connections refer to paragraph on page 280. To create the Ring Cross-connections refer to paragraph on page /980 3DB18809AAAA Issue 1

84 Provision AUX Cross-Connections From the Configuration menu select AUX Cross-Connections. Valid Cross Connections: Local User Service Cross-Connection Pass-through User Service Cross-Connection Figure 645. Auxiliary Cross Connections menu Provision Ethernet Ring Refer to paragraph 3.15 on page DB18809AAAA Issue 1 881/980

85 Provision LAG See Figure 646. Follow the steps to provision the LAG. For the LAG creation refer to par Figure 646. LAG creation 882/980 3DB18809AAAA Issue 1

86 Provision System See Figure 647. Follow the steps to provision the system parameters as explained in par on page 240. Figure 647. System Setting 3DB18809AAAA Issue 1 883/980

87 Provision Local NE IP Address See Figure 648. Follow the steps to enter the NE IP address, allowing the network to communicate with the NE. Click to display pop-up dialog for the IP configuration. Enter NE IP Address. 4 Apply the IP Address. 5 Note After IP address change, the NE restarts. Figure 648. Local Configuration 884/980 3DB18809AAAA Issue 1

88 Provision TMN Ethernet Port See Figure 649. Follow the steps to provision TMN Ethernet Port on the Core-E unit. 4 Enable TMN Ethernet Enter IP address Select Static Routing for manual routing. Select OSPF (Open Shortest Path First protocol) for automatic routing. 6 8 Enter IP Mask and click on Apply Click on the Alarm Profile icon to open the Alarm Severity Profile menu to associate to the TMN Ethernet port a specific alarm profile. Select one Alarm Profile in the Profile Name list (4 alarm profiles are listed). Tick the Show details check box to see the severity associated to each alarm. 7 Figure 649. TMN Ethernet Port Configuration 3DB18809AAAA Issue 1 885/980

89 Provision Ethernet Port 4 for TMN (if required) See Figure 650. Follow the steps to provision Ethernet Port 4 for TMN on the Core-E unit to carry SNMP data. 2 3 Enable the TMN Port 4 Enter IP address 5 4 Select Static Routing for manual routing. Select OSPF (Open Shortest Path First protocol) for automatic routing. 6 8 Enter IP Mask and click on Apply Click on the Alarm Profile icon to open the Alarm Severity Profile menu to associate to the TMN Ethernet port a specific alarm profile. Select one Alarm Profile in the Profile Name list (4 alarm profiles are listed). Tick the Show details check box to see the severity associated to each alarm. 7 Figure 650. Ethernet Port 4 Configuration 886/980 3DB18809AAAA Issue 1

90 Provision TMN in-band See Figure 651. Follow the steps to provision TMN In-band Figure 651. TMN In-band Configuration [3] Enable. [4] IP address and subnet: default /24 for interface #1 and /24 for interface #2 [5] VLAN ID: default 1000 for interface #1 and 1001 for interface #2 [6] List of User Ethernet interfaces where transmit/receive TMN In-Band traffic: default None (multiple selection with the mouse can be done) [7] OSPF enable/disable: default disabled for both interfaces [8] Area ID in case of OSPF protocol enabled: default DB18809AAAA Issue 1 887/980

91 Provision IP Static Routing See Figure 652. Follow the steps to provision. Click now to display pop-up dialog for the IP Static Routing Configuration. Route to specific IP address 5 Input IP Address. 6 7 IP Mask. IP interface to a host or network. Typically used to a spur to interface a host over the RF path. In this scenario, the Default Gateway IP Address is and the IP Mask (greyed out) is Also typically used at an end terminal in a radio link for interface with the network. 8 9 List of RF path directions. Click to view drop down list. 10 Create new or change existing IP static routes. Figure 652. IP Static Routing 888/980 3DB18809AAAA Issue 1

92 Provision OSPF Static Routing See Figure 653. Follow the steps to provision Open Shortest Path First (OSPF) protocol static (automatic) routing. Figure 653. OSPF Static Routing 3DB18809AAAA Issue 1 889/980

93 890/980 3DB18809AAAA Issue 1

94 6 Maintenance and Trouble-clearing 6.1 Introduction This section contains information and procedures to aid in restoring the equipment to its proper operating condition after it has been determined that a problem exists. The following warnings and cautions apply while operating, performance testing, troubleshooting, or repairing the 9500 MPR-E series radios. Short circuits in low-voltage, low-impedance dc circuits can cause severe arcing that may result in burns or eye injury. Remove rings, watches, and other metal jewelry while working with primary circuits. Exercise caution to avoid shorting power input terminals. Units with the electrostatic-sensitive (ESS) symbol contain ESS devices. Store these units in an antistatic container when not in use, and anyone handling a unit should observe antistatic precautions. Refer to the Special Precautions pages in the front of the instruction book for detailed handling information. Note Ensure that all antennas are properly aligned and waveguide is in good physical condition. Note Before performing procedures that might in any way affect transmission, it is recommended that the person performing the procedure understand the Rules and Regulations pertaining to the equipment and be properly authorized to operate the equipment. Maintenance and Trouble-clearing 3DB18809AAAA Issue 1 891/980