012. FiMi200 Operate & Maintain.pdf

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Operate & MaintainGetting started

2.2 Connecting to FPFM200 Web-LCTBefore startBefore connecting to FPFM200 Web-LCT, make sure the IDU system is in operation.

A valid memory key is required to boot-up the system successfully, because when the system is boot up, it will first check the data in the memory key.

g The memory key can not be plugged in again in 1 minute after it was removed from the FPFM200 IDU, or the system will issue ‘Memory Key Wrong Type’ alarm.

StepsTo establish a connection to FPFM200, complete the following steps if the PC is con-nected to the OOB port of the IDU directly:

1 Connect a PC to the OOB port of the IDU which is running.For minimum PC requirement, please refer to Chapter 2.2.1.

2 Open the IE explorer in PC.

3 key in the local IP address of the IDU to be connected, e.g., http://192.168.255.100.

4 Select the user type from the User Name drop-down list and key in the correspond-ing password in text field, see Figure 2.

g For the default user types and passwords, please contact Nokia Siemens Networks technical support.

<Space bar> Switches the setting of the check box, activates the focused button, enables the radio button, or activates toolbar button.

<Enter> Activates the default button (does not require keyboard focus).

<Escape> Activates the Cancel button (does not require keyboard focus).

<F10> or <Alt> Moves focus to menu bar and posts first menu.

<Shift> + <F10> Opens the context menu for the selected object.

Keyboard operation Action

Table 4 Standard keyboard operations (Cont.)

A25000-A1000-C019-01-76P1Issue: 1 Issue date: April 2011

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Operate & Maintain Getting started

Figure 2 Login window

5 Select version2C or version3 from the SNMP Version drop-down list.

If select version2C from the drop-down list, then Authentication Protocol is fixed and there is no privacy for Privacy Protocol.If select version3 from the drop-down list, the precondition is that the security software package has been already installed and enabled. Then Authentication Protocol is fixed and there is two options for Privacy Protocol, either AES-128 or No privacy.

6 Click the button.

The GUI window of the connected IDU is opened and the connection to the IDU is estab-lished.

If the PC is not connected directly to the OOB port of the IDU but within the same subnet, follow the steps:

1 Make sure the PC’s network connection is running.

2 Open the IE explorer in PC.

3 key in the public IP address of the IDU to be connected, e.g., http://192.168.10.64.

4 Repeat steps 4, 5 and 6.

2.2.1 PC requirementWeb-LCT requires the following minimum system configuration:



2.3 Graphical User InterfaceThe LCT enables the user to perform a wide variety of operation, configuration, and maintenance tasks with the FPFM200 EP1.

The LCT GUI offers the main elements described in the following sub-chapters. The set of functions available for each operator depends on the user group of the login account, which is defined by an administrator.

2.3.1 Main windowOnce a connection is established with the NE, the main window is displayed as the root screen to access all other windows. Figure 3 provides an overview of the main window.

Computer 1 GHz or faster processor

Operating system Microsoft Windows XP only

Software environment – Java (JRE) version 1.6 or higher.It can be downloaded from www.java.com/en/download.

– Webpage browser which supports Java application, e.g., Internet Explorer (IE) 6 and higher, Mozilla Firefox 3.0 and higher, and Google Chrome.

Service supported – HTTP (port 80)– SNMP (port 161)– FTP (port 21 & 22)

Table 5 PC requirement for Web-LCT


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Figure 3 LCT Main window

2.3.2 Main window menuFigure 4 displays the LCT Main window menu. By clicking one of these menu items, the specific drop-down menu opens.

Figure 4 Main window menu

Table 6 provides a detailed description of the Main window menu items.

Menu item Description

File

Exit Exits the LCT application.

Connection

Reconnect Reconnects the LCT with a node.

Disconnect Disconnects the LCT with a node.

Help

Web LCT of FirstMile Help Opens the Help topics window.

About Web LCT of FirstMile Display the LCT application information.

Table 6 Main window menu items



Figure 5 displays the toolbar icons corresponding of Reconnect, Disconnect and Help menu items from left to right.

Figure 5 Toolbar icons

2.3.3 Equipment view of FPFM200 2.0 IDUThe “Equipment view” window displays a graphical replica of the IDU and its interfaces. The “Equipment view” window provides access to the detailed information and configu-ration windows associated with the different components in the graphic replica. See Figure 6.

Figure 6 Chassis view

g The name of local management interface is changed from Dual-IDU to OOB.

The name of in band management interface is changed from OOB to DCN.

The name of TDM port is changed from E1/T1 to E1/T1/J1.

RST is added for the reset button.

GE port 3 and 4 are changed to 3 (PWR) and 4 (PWR).

g The new names “OOB”, “DCN” and “E1/T1/J1” will be applied on new equipment after 31 March 2011. Meanwhile the old names “Dual-IDU”, “OOB” and “E1/T1” still appears in some equipment of first production (before April 2011).

g For old label marks on the front panel, please refer to Product Description Chapter 2.2.1 Interfaces for reference. All the graphics in this manual use the new label marks.

2.3.4 View barThe View bar on the left side of the LCT Main window is used to navigate between dif-ferent views and elements. All the views/tasks that are available on the View bar are also available on the View menu.

In connected mode the following buttons are available:

Icon Description

Opens the IDU device view containing the “equipment view” and “hardware view”.

Table 7 View bar


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Contains management settings: network configuration, NTP setting, configuration management, etc.

Contains general sync configuration and interface sync configuration.

Contains management VLAN, bridge configuration, xSTP and LLDP information.

Contains scheduler mode, port ingress rate limit, port egress shaping, queue egress shaping and sRED informa-tion.

Contains both Ethernet Service and CESoP Service con-figuration pages.

Contains Link protection group, Link aggregation group and E-CCM information.

Contains MD list and OAM global configuration informa-tion.

Contains performance monitoring reports for different traffic according to different standards.

Contains all the maintenance related settings, i.e. loopback testing, configuration backup, security setting and event log.

Icon Description

Table 7 View bar (Cont.)



The following part of this manual is described for each icon of the View bar.

2.3.5 Alarm areaThe alarm is displayed along the bottom of the main window, see Figure 7. All the active alarms are collected and the numbers of the alarms are listed by severity and category. By clicking the certain alarm area, the corresponding alarm window opens. The alarm area can be used to verify and analyze any kind of errors or previous actions performed in the current session with the connected IDU.

Figure 7 Alarm area

2.3.6 General function buttonsBy clicking one of the function buttons in the windows, a specific operation can be done.

Table 8 provides a detailed description of the general function buttons.

Contains all the security information: V2 user manage-ment, SNMP version and account log.

Icon Description

Table 7 View bar (Cont.)

Function button Description

To add new settings.

To confirm all the configuration changes mode.

To close the window without saving any configura-tion changes.

To close the window without saving any configura-tion changes.

To create new settings.

To delete the current settings.

To view the detailed information of the specific component.

Table 8 General function buttons


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To launch the Online Help system.

To modify the settings of a specific component.

To confirm all the configuration changes and close the window.

To print the information of a specific component.

To obtain the latest information of a specific com-ponent.

To view the detailed information of a specific com-ponent.

Function button Description

Table 8 General function buttons (Cont.)


Operate & MaintainDevice settings

3 Device settingsThe device properties view is displayed correspondingly for the selected object on equipment view.

Figure 8 Device view

3.1 System propertiesIn system properties view, there are four tabs of parameters group.

– Basic– Port List– Dry Contact– Inventory

In Basic tab, the general information of the equipment is displayed. Some information cannot be edited, e.g., System up time, Current time, Temperature, Memory key. The others are changeable to the user, e.g., System name, System location, Contact infor-mation etc. Normally these changeable items are configured when the equipment is

commissioned. See Figure 8. Click the button to get the most updated infor-

mation. And after the modification, click the button to commit the changes.

In Port List tab, it lists all the general hardware specification(Port, Name, Type, Speed)

of individual interface and its Admin Status and Operating Status. Click the button to get the most updated information. See Figure 9.


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Operate & Maintain Device settings

Figure 9 Port list tab

In Dry Contact tab, it shows exactly the same information as the dry contact button on the front panel block diagram. Please refer to 3.2 for details.

Figure 10 Dry Contact

g Since this tab works the same way as the Dry Contact tab described in chapter 3.2 Dry contact setting, modification in this tab will also take effect in the other Dry Contact tab, vice versa.

In Inventory tab, it shows all the information regarding software and hardware.

In Hardware Inventory, the following information is shown: System, Hardware Code,

Firmware Code, Modification, etc. Click the button to get the most updated information.



Figure 11 Hardware Inventory

In Software Inventory, the following information is shown: Active Loads, Stand-by

Loads, Switch Loads, etc. Click the button to get the most updated informa-tion.


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Figure 12 Software Inventory

In Memory Key, the following information is shown: Serial number, Equipment name.

Click the button to get the most updated information.

Figure 13 Memory Key

3.2 Dry contact settingClick the Dry contact button on the front panel block diagram in Figure 14 to open the dry contact settings view.



Figure 14 Alarm Output tab for dry contact

g Since this tab works the same way as the Dry Contact tab described in the previous chapter System Properties, modification in this tab will also take effect in the other Dry Contact tab, vice versa.

This interface provides Station alarms, Remote Controls and equipment Alarm Severity. Based on the users’ requirements, this interface can be connected to the LED indicator or a bell to indicate an alarm occurrence. Click the dry contact icon on the front panel block diagram to see the information.

There are two tabs of parameters group.

– Alarm Output– Alarm Input

Alarm OutputAlarm Output are the outputs commands remotely controlled by the EMS.

In the Alarm Output tab, Click the button to get the most updated informa-tion.

Modify the Alarm output


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1 Select one row and click the button to open the Modify box.

Figure 15 Modify box in Alarm Output tab

2 Fill in the Name and select the Polarity (Ground, Open), State (Normal, Active).

3 Click the button to commit the changes or click the button to withdraw the changes.

g For Alarm Output, there are two output lines, Alarm Output 1 and Alarm Output 2.

Ground means grounding indicates the alarm triggered, while Open means open-circuit indicates the alarm triggered.

Alarm InputAlarm Input are controlled by the IDU and two input alarms are carried to the EMS (e.g., over-temperature, open-door indication). A severity can be assigned to each input by the operator.

Change to the Alarm Input tab, and click the to get the most updated infor-mation.

Figure 16 Alarm Input tab for dry contact

Modify the Alarm Input



1 Select one row and click on the button to open the Modify box.

Figure 17 Modify box in Alarm Input tab

2 Fill in the Name and select the Polarity (Ground, Open).

3 Select the Severity (Critical, Major, Minor, Warning, Undefine).

4 Click the button to commit the changes or click the button to withdraw the changes.

g Ground means grounding indicates the alarm triggered, while Open means open-circuit indicates the alarm triggered.

The Alarm Severity are three output alarms indicating the Severity of the equipment. Critical/Major is one alarm output and Minor/Warning is another alarm output. While the Undefine is the undefined alarm level which can be set by the user.

3.3 OOB settingClick OOB icon on the front panel block diagram in Figure 18 to open the OOB settings view.

Figure 18 OOB port


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OOB management interface aims to connect the two IDUs for management purposes. It will configure the alignment of the protection IDU to the main IDU and exchange the alarm information, etc. Click the OOB icon on the front panel block diagram to see the information.

There are IP address and Subnet mask information shown here for the OOB port. Click

the button to get the most updated information. And they are read-only information.

3.4 DCN settingDCN interface is an Ethernet port which is designed for local management through IP packets. Click the DCN icon on the front panel block diagram in Figure 19 to open the DCN settings view.

There are IP address, Subnet mask and Default gateway information shown here for

the DCN port. Click the button to get the most updated information. And all

these fields can be modified. After the modification, click the button to commit the changes.

Figure 19 DCN port

3.5 E1/T1/J1 interface settingClick any one of the eight E1/T1/J1 interface icons on the front panel block diagram in Figure 20 to open the E1/T1/J1 settings view.



Figure 20 E1/T1/J1 interface

There are eight E1/T1/J1 interfaces to be configured here. Click on any E1/T1/J1 inter-face on the front panel block diagram, the corresponding information will be shown, such as Name, Type, etc. And users can make desired modification, such as AdminStatus, Line coding, Loopback, etc.

For the E1/T1/J1 port, there are following parameters:

Click the button to get the current status and most updated information for

this interface. And after changing the parameters, click the button to commit the changes.

Parameter Description

Name It shows the name of the port, e.g., E1 (1). Read-only.

Type It shows the type of the port, e.g., E1. Read-only.

Admin status It is the place where the desired state can be set to Up or Down.

Operational status It indicates the current operational status of the inter-face. Read-only.

Line type It indicates the variety of E1 frame type.

Line coding It describes the variety of zero code suppression used on this interface. HDB3, AMI, etc.

Line status It indicates the line status of the interface. Read-only.

Line impedance Nominal impedance. balanced 120ohms(E1), unbal-anced 75ohms(E1), 100ohm T1 and 110ohm J1.

Table 9 Properties for the E1/T1/J1 interface


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3.6 SFP module settingBasic information is shown for SFP port, such as Name, Type, etc. And the preferences for this port can be set, such as MDI Sensing, TPID, etc.

Click the SFP icon on the front panel block diagram to open the settings view.

Figure 21 SFP Properties

For the SFP Basic Properties, there are three tabs of parameters group:

– Properties– Auto Negotiation– SFP

In Properties tab, the following information is shown: Name, Type, Admin Status, Oper-ation Status, etc.


Name It shows the name of the interface, e.g., SFP1 (1) Read-only

Type It shows the type of the interface, e.g., Ethernet, Read-only

Admin status It shows the desired state of the interface. up or down.


MDI sensing It shows the MDI/MDIX autosensing enabled or dis-abled.

SSM enable It enables synchronization status messaging (SSM).

enabled - SSM messages sending and receiving is enabled.

disabled - SSM messages sending and receiving is disabled.

Table 10 Properties for the SFP module



Click the button to get the current status and information for this interface.

And after changing the parameters, click the button to commit the changes.

In Auto Negotiation tab, the following information is shown: Speed, MAU type, MAU status, etc.

Figure 22 SFP Auto Negotiation

Mode It shows the port mode, e.g., NNI.

TPID TPID is the Tag Protocol Identifier which appears in the packet segment to indicate the IEEE 802.1Q is the protocol used. And the default value is 0x8100 in Hex.

MTU It is the maximum packet size that can be sent on the interface and it is specified in octets. The range is from 64 to 9600 bytes.

Shutdown enable If the port is UNI and a service is created upon this port, then if shutdown enable is enabled, once the service is up, the port is up automatically, once the service is down, the port is down automatically. It is not applica-ble to NNI.

Speed It is the physical bandwidth in bits per second, e.g., 10Mbit/s, 100Mbit/s, 1000Mbit/s.

Foreign equipment type It shows the type of the connected equipment. Other or ODU.


Table 10 Properties for the SFP module (Cont.)


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In SFP tab, the following information is shown: Module wave length, Module distance, Module vendor, etc. All this information is read-only which reads the information about the SFP module except Laser shutdown, ALS admin status and Laser status.

Figure 23 SFP


Auto negotiation admin status

It will show whether the Auto negotiation admin status is set or not. If it is set to disabled, the Auto negotiation capability advertised bits need to be set amount 10 Base-T half duplex mode, etc. If it is set to enabled, the Auto negotiation capability advertised bits will not take effect.

Auto negotiation restart If Auto negotiation admin status is enabled and this value is set to restart, two counterparts will restart the auto negotiation.

Auto negotiation capability bits

It reflects the options chosen from Auto negotiation capability advertised bit field. Read-only.

Auto negotiation capability advertised bits

If the Auto negotiation admin status is disabled, this field need to specify the rate in bits.

MAU type It shows the MAU (Medium Attachment Unit) type, e.g., 1000BaseTFD.

MAU status It shows the real status, e.g., Operational.

MAU default type It shows the default MAU (Medium Attachment Unit) type, e.g., 1000BaseTFD.

Table 11 Auto Negotiation for the SFP module


Laser shutdown If it is set to enabled, the LED will be off. If it is set to disabled, it will work together with ALS admin status.

Table 12 SFP editable fields





3.7 Electrical GE interface settingThe configuration of this port is similar to SFP port.

Basic information is shown for GE port, such as Name, Type, etc. And the preferences for this port can be set, such as MDI Sensing, TPID, etc.

Same as SFP port settings, the configuration for QoS can be set here, including egress scheduling mode (strict priority or weighted fair queuing), number of queues working in strict priority mode, number of packets to be served for each queue (totally eight queues), etc.

g Flow based priority criteria is supported in Release 2.0.

Click the GE icon on the front panel block diagram to open the settings view.

Figure 24 GE Port Properties

There are three tabs of parameters group:

ALS admin status Auto Laser Shutdown status indicates whether the LED is on or not. If it is set to enabled and Laser shutdown is disabled, then if there is no signal coming in, the LED is off.

Laser status It shows the laser status, switchedOn or switchedOff.


Table 12 SFP editable fields (Cont.)


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– Properties– Auto Negotiation

In Properties tab, the following information is shown: Name, Type, Admin Status, Oper-ation Status, etc.


Name It shows the name of the interface, e.g., GE2 Read-only

Type It shows the type of the interface, e.g., Ethernet, Read-only

Admin status It shows the desired state of the interface. up or down.


MDIsensing It shows the MDI/MDIX autosensing enabled or dis-abled.

Phy master slave selection Either master or slave can be selected.

Meas master slave status It shows the status for the NE, master or slave.

Mode It sets the port mode, e.g., NNI.

TPID TPID is the Tag Protocol Identifier which appears in the packet segment to indicate the IEEE 802.1Q is the protocol used. And the default value is 0x8100 in Hex.

MTU It is the maximum packet size that can be sent on the interface and it is specified in octets. The range is from 64 to 9600 bytes.

Shutdown enable If the port is UNI and a service is created upon this port, then if shutdown enable is enabled, once the service is up, the port is up automatically, once the service is down, the port is down automatically. It is not applica-ble to NNI.

Power supply It shows whether the GE port will support the power to the ODU or not. Only GE 3 and GE 4 have this function. So for GE1 and GE2, it is disabled by default.

Power supply status It shows the status of the power supply conditions. If GE3 and GE4 are enabled for the power supply func-tion, and ODU is connected to one of these ports, then the status will show Active. Otherwise, it shows not-Active.

Speed It is the physical bandwidth in bits per second, e.g., 10Mbit/s, 100Mbit/s, 1000Mbit/s.

Table 13 Properties for GE port





In Auto Negotiation tab, the following information is shown: Speed, MAU type, MAU status, etc.

Figure 25 GE Auto Negotiation

Foreign equipment type It shows the type of the connected equipment. Other or ODU.


Table 13 Properties for GE port (Cont.)


Auto negotiation admin status

It will show whether the Auto negotiation admin status is set or not. If it is set to disabled, the Auto negotiation capability advertised bits need to be set amount 10 Base-T half duplex mode, etc. If it is set to enabled, the Auto negotiation capability advertised bits will not take effect.

Auto negotiation restart If Auto negotiation admin status is enabled and this value is set to restart, two counterparts will restart the auto negotiation.

Auto negotiation capability bits

It reflects the option chosen from Auto negotiation capability advertised bits field.

Auto negotiation capability advertised bits

If the Auto negotiation admin status is disabled, this field need to specify the rate in bits.

Table 14 Auto Negotiation for GE port


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MAU type It shows the MAU (Medium Attachment Unit) type, e.g., 1000BaseTFD.

MAU status It shows the real status, e.g., Operational.

MAU default type It shows the default MAU (Medium Attachment Unit) type, e.g., 1000BaseTFD.


Table 14 Auto Negotiation for GE port (Cont.)


Operate & MaintainNE Management

4 NE ManagementThe NE management view shows different network related information, e.g., Network Configuration, NTP Setting, Software, License, etc. See Figure 26.

Figure 26 NE management view

There are ten tabs of parameters group:

– Network Configuration– Management VLAN– NTP Setting– Software– License– Configuration Management– Log Management– System Commands– Local Trap– Netview Trap

4.1 Network ConfigurationIn the Network Configuration tab, the network related information are displayed, e.g., DCN IP address, Subnet mask and Default gateway. See Figure 26.

Click on button to get the most recent information.

Click on any of these three fields and make corresponding changes. The color of

modified fields will be changed to blue and click on button to commit the changes.


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Operate & Maintain NE Management

4.2 Management VLANIn Management VLAN view, there are four tabs of parameters group, See Figure 27.

Figure 27 Management VLAN

– General– Management VLAN Interfaces– FDB Static Unicast Table– FDB Unicast Table

In the General tab, the M-VID , Network Rate Limit and Management VLAN Priority can be set here. See Figure 27.

Click the button to get the most recent information. Also the user can make

modifications directly on each field. And after the modification, click the button to commit the changes.

In the Management VLAN Interfaces tab, it includes the following information: Port, Ingress Rate Limit (Kbps), Egress Rate Limit (Kbps), VLAN ID and Status. See Figure 28.

Figure 28 Management VLAN Interfaces




Create a Management VLAN InterfaceHere the parameters for the management interfaces can be configured.

1 Click on the button to open the create window. And there are five param-eters can be set. See Figure 29.

Figure 29 Create a Management VLAN Interface

2 Fill in the following parameters for the new Management VLAN Interface

3 Click the button to confirm all the settings or click the button to withdraw the settings. If there is no error message showing up, the Management

Parameter Descriptions

Port It indicates the interface which need to be added into the VLAN.

Ingress rate Limit (Kbps) It is the ingress limit. If this interface is an NNI port, then this field is read-only and equals the value of Network Rate Limit. If this interface is a UNI port, then this field is read-write and the default value is 384 Kbit/s.

Egress rate Limit (Kbps) It is the egress limit. If this interface is an NNI port, then this field is read-only and equals the value of Network Rate Limit. If this interface is a UNI port, then this field is read-write and the default value is 384 Kbit/s.

VLAN ID By default it is 127.

Tag It shows two status: tagged and untagged.

Table 15 Management E-Lan Interfaces Parameters


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VLAN Interface is created successfully. Otherwise, the user has to diagnose the problem according to the error messages.

Delete a Management VLAN Interface

Figure 30 Delete a management VLAN interface

Select a Management VLAN Interface entry to be deleted, and click the button.

Then a confirmation box appears with the question “Are you sure to delete them(it)?”.

Click button to delete it, otherwise, click button to withdraw the dele-tion.

In the FDB Static Unicast Table tab, the information is shown, e.g., Static Unicast Mac Address, Port and Status. See Figure 31.

Figure 31 FDB static unicast table

Click the button to get the most recent information.

Create a FDB Static Unicast Table entry



1 Click on the button to open the create window. And there are two param-eters can be set. See Figure 32.

Figure 32 Create FDB Static Unicast

2 Fill in the following parameters for the new FDB Static Unicast Table entry.

3 Click the button to confirm all the settings or click the button to withdraw the settings. If there is no error message showing up, the FDB Static Unicast Table entry is created successfully. Otherwise, the user has to diagnose the problem according to the error messages.

Delete a FDB Static Unicast Table entry

Select a FDB Static Unicast Table entry to be deleted, and click the button.



In the FDB Unicast Table tab, the information is shown, e.g., Unicast Mac Address, port. See Figure 33.


Static unicast mac address It is the MAC address for which the entry was configured.

Port It is the bridge port corresponding to the configured interface.

Table 16 FDB Static Unicast Table parameters


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Figure 33 FDB unicast table


4.3 NTP SettingIn NTP Setting tab, the following information needs to be provided: Time server IP, Current PC time, Current GMT time, Time zone and Daylight saving enable. See Figure 34.

Figure 34 NTP (Network Timing Protocol) Setting

There are three ways to set IDU time:

1. Choose the checkbox corresponding Time server IP to enable setting of time server’s IP, then the IDU time will synchronize with the time server’s time. The time will not be lost after cold reboot.

2. Click button to use current PC time as the IDU time. The time will be lost after cold reboot.

3. Manually fill in the time in Current GMT time field. The time will be lost after cold reboot.

g When (enable/disable) checkbox is selected, the Current GMT time will be greyed out.



g If (enable/disable) checkbox is not selected and button is not clicked, the default date for IDU will be 2009-1-1.

Click on button to get the most recent information.

Click on any of these fields and make corresponding changes, and click on button to commit the changes.

4.4 SoftwareThere are four groups of information shown in the software management tab.

– Software Information– Firmware Information– Software Measurement– Software Operation Status

Figure 35 Software tab view


In Software Information group, the following information is shown:


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g The software version along with FPFM200 R2.0 panel will be the latest software version dedicated for FPFM200 R2.0. If the user still needs the old software ware for R1.0 EP1, he/she needs to download the corresponding software version from NOLS website.

In Firmware Information group, the following information is shown:

In Software Measurement group, the following information is shown:

In Software Operation Status group, the following information is shown:


Active software version The software version of active load file.

Standby software version The software version of standby load file.

Activated date (PC time zone) The date of software activation (PC time zone).

Activated date (NE time zone) The date of software activation (NE time zone).

Table 17 Software information parameters


Firmware Components The string identifying the component.

Running Version Hardware version running on the compo-nent.

Standby Version Hardware version available for the com-ponent on the standby load.

Table 18 Hardware information parameters


Active software checksum The checksum for the active load.

Standby software checksum The checksum for the standby load.

Standby software status It shows whether the standby software is valid or invalid, e.g., validLoad.

Service hitless switch Indicates whether the switch process has impact on service traffic.

Table 19 Software measurement parameters



4.4.1 Scheduled switch process

Click the button, a box Schedule Entry is open.

Figure 36 Schedule Entry box

Here it shows all the scheduled entries with Schedule Owner, Schedule Name, Time information, etc. Also the user can specify a new entry by filling in Schedule Name, Date

and Time information and then click the button to commit the creation. Also if

one entry is no longer needed, just click this entry and click the button to

delete it. Otherwise, click the button to go back to the main view.


Download status It shows the downloading, scheduled downloading, switching and align status, e.g., Copy finished!, Download Success-ful!, etc.

Self-test status It shows the self-test failed or not, e.g., Normal.

Switching allowed When Standby version is compatible with the active version, the switch command can be executed.

Table 20 Download status parameters


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4.4.2 Download process

Figure 37 Software file selection

Click the button, a box Choose the Software File to Download is open. See Figure 37. After selecting the directory where you store the latest software version,

then click the button to begin the downloading process. If it fails, ‘Download Failed!’ will be shown in the Operation status. If it succeeds, ‘Download Successful!’ will be shown in the Operation status of Software Operation Status in Figure 35. Then the latest software version is downloaded to the standby software bank of the Network Ele-ments.

g Normally, before the download process, the latest software version should be down-loaded to the PC which is running the Web-LCT.

In order to upgrade the NE between FPFM200 R1.0 EP1 to FPFM200 R2.0, follow the steps:

1. Download the latest software version for FPFM200 R2.0 to the NE2. Follow the instruction in 4.4.3 to upgrade to R2.0

The license already present on NE can still be maintained after upgrade finished. If nec-essary, new licenses can be enabled after the upgrade.

Downgrade of the NE between FPFM200 R2.0 and FPFM200 R1.0 EP1 has to be done before any other operation on the NE, i.e., before any configuration or enable any license.

In order to downgrade FPFM R2.0 to R1.0 EP1, follow the steps:

1. Download the corresponding software version for FPFM200 R1.0 EP1 to the NE.2. Follow the instruction in 4.4.3 to downgrade to R1.0 EP1



After these steps, the configuration can be set and the licenses can be enabled.

4.4.3 Immediately switch processAfter finishing the download process, there will be two software versions stored, one is the Running version, the other is the Standby version, if you want to replace the old

software version with the new software version, just click the button to begin the switch process. Once the switch process is finished, ‘Switched suc-cessfully’ will be shown in the Operation status of Software Operation Status in Figure 35.

g The software version switch takes about 10 minutes at least.

g It is not recommended to downgrade the software version from R2.0 to R1.0 EP1, because all the configuration and license keys will be cleared, and data will not be recov-ered later upgrading to version R2.0 again.

4.4.4 Align processIn order to align the software version in the active bank with the version in the standby

bank, click the button to begin the write process. ‘Copy the software to the standby file’ will be shown as the Operation status of Software Operation Status in Figure 35. Once it is successful, the software versions in both the active bank and the standby bank will be the same. The version number will be identical for Running version and Standby version in Hardware Information.

4.5 LicenseIn License tab view, the current available licenses (i.e., Feature license) with their oper-ating status are displayed, see Figure 38.

Figure 38 License view

Click to get the most updated license information.


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g For the detailed explanation of each license and license management, please refer to the Licensing of FPFM200 IDU Product Description.

g Each equipment of FPFM200 has an unique Challenge number. It is used together with License Mask, and License key (a physical dongle) to generate an upgrading license key to the user.

For details of how to generate an upgrading license key, please refer to Chapter 4.5.1.

4.5.1 CLicS License KeyThe new CLICS License Key can be generated using following steps:

1 Login to NOLS (NokiaSiemensNetworks Online Service http://online.portal.noki-asiemensnetworks.com), navigate to Care > I-CLicS.

2 In I-CLisC home page, select link License Key Code Generation from left-hand menu.

3 Fill in following fields: NE Type Drop-down List, Target ID, License Mask.

4 Press Create button.

5 License key generated is displayed in the License Key Code field.

Figure 39 License Key Generation in CLicS

g Generated license key cannot be searched and retrieved later. So it has to be written down or printed when generated. For security reasons, do not write down on paper, but store in an encrypted laptop, e.g., in a text editor.

Enter the license key in the ClicS license key field, and click on button to update license key.



4.6 Configuration ManagementThe configuration management function provides user the protection of current config-uration of the system. The user can also restore the backuped configuration file to help diagnosing the network problem if any. See Figure 40.

Figure 40 Configuration management view

To backup the configuration, follow the steps below:

1 Click the button to select the location where the backup file to be saved.

2 Click the button to start backup. The progress is showing at the Operation Status.

3 Wait until the backup completion message shows up. The configuration backup is completed successfully.

To restore a configuration, follow the steps below:

1 Click the button to select the location where the restore file saved before.

2 Click the button to start restore. The progress is showing at the Operation Status.

3 Wait until the restore completion message shows up. The configuration restore is completed successfully.

g Before to make any operation of restoration in the NE, the operator has to check the con-figuration of the TDM interface mode.


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It is mandatory that the TDM interface mode in the backup file is the same as that on NE. For example, if the TDM interface mode in the backup file is “T1 mode”, then the TDM interface mode on NE has to be “T1 mode” as well.

If the two TDM interface modes are different, before to perform the operation of restora-tion on NE, the operator has to change the TDM interface mode accordingly with the mode in the restore file.

1. Check the TDM interface mode in the restore file and on NE2. If it is different, change the TDM interface mode on NE3. Run the restoration

4.7 Log managementIn Log mangement tab, Event Log and Log Download information can be displayed and downloaded. See Figure 41.

Figure 41 Event log

In Event Log tab, all kinds of log information can be displayed here.


In Log Download tab, logs can be downloaded from the NE. See Figure 42.



Figure 42 Log Download

To download logs, follow the steps below:

1 Click the button to select the location where the log file to be saved.

2 Click the button to start downloading. The progress is showing at the Operation Status.

3 Wait until the download completion message shows up. The memory log download-ing is completed successfully.

4.8 System CommandsIn System Commands tab, the following buttons can be used: Refresh, Reset Software (warm reboot), Reset Hardware (cold reboot) and Restore to Factory Default. Also, the user can use Restore to Factory Default to resume to the default setting. See Figure 43.


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Figure 43 System Command Setting

g Reset Software will reset the NE via software configuration without any interruption to the traffic.

Reset Hardware will re-configure the NE and the traffic will be interrupted.

Once click the button, the following message will appear. And after the waiting period, a message “Restore to factory default completed!” indi-cates the process is successful. All the configuration will be cleared except the public IP address.

Figure 44 Restore to Factory Default

4.9 Local TrapIn the Local Trap tab, it includes the following information: Trap Destination IP Address, UDP Port, Erase Time Second (0..14400) and Row Status. See Figure 45.

Figure 45 Local Trap


Create a Local Trap entry



1 Click on the button to open the create window. And there are three parameters can be set. See Figure 46.

Figure 46 Create Local Trap

2 Fill in the following parameters for the new Local Trap entry.

3 Click the button to confirm all the settings or click the button to withdraw the settings. If there is no error message showing up, the static trap is created successfully. Otherwise, the user has to diagnose the problem according to the error messages.

Delete a Local Trap entry

Select a Local Trap entry to be deleted, and click the button.



4.10 Netview TrapIn the Netview Trap tab, it includes the following information: Trap Destination IP Address, Udp Port, Snmp Version, Erase Time Second (0..14400) and Status. See Figure 47.


Trap destination IP address It is the IP address for which the trap will be sent to.

UDP Port (162 .. 65535) It is the UDP port set for this static trap.

Erase time second (0..14400) It is the time the static trap exists. After this time duration, the static trap will be deleted.

Table 21 FDB Static Unicast Table parameters


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Figure 47 Netview Trap


Create a Netview Trap entry

1 Click the button to open the create window. And there are three param-eters can be set. See Figure 48.

Figure 48 Create Netview Trap

2 Fill in the following parameters for the new Netview Trap entry.


Trap destination IP address It is the IP address for which the trap will be sent to.

Community string A community to which the destination address belongs.

Erase time second (0..14400) It is the time the dynamic trap exists. After this time duration, the dynamic trap will be deleted.

Table 22 FDB Dynamic Unicast Table parameters



3 Click the button to confirm all the settings or click the button to withdraw the settings. If there is no error message showing up, the dynamic trap is created successfully. Otherwise, the user has to diagnose the problem according to the error messages.

Delete a Netview Trap entry

Select a Netview Trap entry to be deleted, and click the button.



g Netview traps can only exist for a duration which is defined by the user. After that dura-tion, the Netview traps will disappear automatically.


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Operate & Maintain Clock Sync settings

5 Clock Sync settingsFigure 49 lists all the synchronization sources of the system (in the Sync Normal/SSM Source List section). The user can create, modify, or delete a synchronization source.

g It is allowed a maximum of two synchronization sources which can be E1 or Ethernet interface; one as primary source, and the other as secondary source. When the primary source is not available, the system automatically uses the secondary one.

Figure 49 Synchronization settings overview

There are three tabs of synchronization parameters group:

– General Sync Configuration– Transmit clock source for E1/T1/J1– SSM configuration for Ethernet port

g For the detailed information of FPFM200 synchronization feature, please refer to Syn-chronization over Packet network in Product Description manual.

5.1 General Sync ConfigurationIn General tab (see Figure 49), there are two views showing Sync Mode and Sync Source List.


Operate & MaintainClock Sync settings

5.1.1 Sync mode settingsUnder Sync Mode view, Clock Mode can be selected as Internal/External. See Figure 49.

If External is selected, External Clock Mode can be selected as Normal/SSM, the views will be different as follows:

– External Clock Mode-Normal • If one E1 or one Ethernet interface is selected as synchronization source, when

the source fails the system goes to internal source (freerun state). • While two synchronization interfaces are selected, one as primary source and

the other as secondary, when the primary source is not available, the system automatically uses the secondary one. Once the primary source is recovered, the system comes back to the primary source if the revertive mode is set, or stay on the secondary source if the non-revertive mode is configured.

Figure 50 External Clock Mode-Normal view

– External Clock Mode-SSMthe system selects the best synchronization source based on following criteria stated in the Synchronization State Message (SSM) received, e.g., signal fail, signal received quality level, or priority. The synchronization state is freerun(no clock source is chosen), holdover and Locked.

g Only if the SSM enable is enabled, then in General Sync Configuration tab, External Clock Mode can be set to SSM. Otherwise, the setting to SSM for External Clock Mode will not take effect.


65


g If no synchronization source exists in the Sync Source List in Figure 49, no SSM will be sent out.

Figure 51 Clock Mode-SSM view

The parameters in Sync Mode view are listed in Table 23:




Clock Mode External or Internal

Synchronization state When configured in Internal Reference mode the system shall foresee only one synchronization state, the freeRun(1).

When configured in External Reference mode the system shall foresee the fol-lowing states:– freeRun(1): this is the state selected

after startup or after a synchroniza-tion reset command.

– locked(2): this is the state selected after the PLL has locked and no syn-chronization alarms are present, i.e. a qualified reference source is avail-able at the selected interface.

– holdover(3): this is the state selected when the reference source has been disqualified due to some problems.

External Clock Mode Can be set between Normal and SSM

HoleoffTime(ms) The clock hold over time: the time in milli seconds that the clock has to stay in failure state before reporting on the failure.

Applicable values (in milli seconds):– Minimum value - 300 milli seconds.– Maximum value - 1800 milli

seconds.– Default value - 300 milli seconds.

WTR Time(s) Enables the revertive mode and repre-sents the time after which an input, back to fault free, can be considered as avail-able by the selection process.

Applicable values (in seconds): Minimum value - 0 second; Maximum value - 720 seconds.

To disable the revertive mode, and therefore select the nonRevertive option, the special value 3600 is used. Configuration granularity: 60 seconds. Default value - 300 seconds.

Table 23 Sync configuration input settings


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Modify any fields under Sync Mode and click the button to confirm the set-tings.

5.1.2 Sync Normal/SSM source list settingSync Normal Source List The existed general synchronization configuration are listed in Sync Normal Source List view with the parameters in Table 24 if Normal mode is selected for external clock mode. See Figure 50.

Create a synchronization source To create a new synchronization source interface, follow the steps below:

SSM System Clock Threshold SSM System Clock Threshold. Setting it to notApplicable will disable the thresh-old. And other choices define the corre-sponding clock threshold in order to select the proper clock source.

Clock Mode Measurement When the Clock mode is selected, reports if all configurations are ok or if any configuration is missing or is not correct.


Table 23 Sync configuration input settings (Cont.)


Priority 1 as primary and 2 as secondary.

Source id – If the clock source type is line, the clock source is from E1/T1 port.

– If the clock source type is ethPort, the clock source is from Ethernet port.

Table 24 Synchronization Normal Source List



1 Click the button to open the creating window, see Figure 52:

Figure 52 Create a synchronization source window

2 Select the synchronization clock Source id.

3 Click the button to confirm the settings. The new synchronization source is created.

Delete a synchronization source

Select an entry of the synchronization source list to be deleted, click the button.

Modify a synchronization sourceTo modify a existing synchronization source interface, follow the steps below:

1 Click the button to open the modify window, see Figure 53:

Figure 53 Modify a synchronization source window


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2 Modify the synchronization clock Source id.

3 Click the button to confirm the settings or click the button to withdraw the settings.

Sync SSM Source ListThe existed general synchronization configuration are listed in Sync SSM Source List view with the parameters in Table 25 if SSM mode is selected for external clock mode. See Figure 51.

Create a synchronization source To create a new synchronization source interface, follow the steps below:


Priority 1 as primary and 2 as secondary.

Type – line applies to the TDM synchronization input.– ethPort applies to an Ethernet interface configured in

slave clock mode.– internal applies to the internal oscillator.

Clock source – If the clock source type is line, the clock source is from E1/T1 port.

– If the clock source type is ethPort, the clock source is from Ethernet port.

Configured QL Configured Quality Level (QL) of SSM.

Table 25 Synchronization SSM Source List




Figure 54 Create a synchronization source window

2 Select the synchronization source Type, Clock Source (interface) and Configured QL.

3 Click the button to confirm the settings. The new synchronization source is created.

Delete a synchronization source

Select an entry of the synchronization source list to be deleted, click the button.

Modify a synchronization sourceTo modify a existing synchronization source interface, follow the steps below:


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1 Click the button to open the modify window, see Figure 55:

Figure 55 Modify a synchronization source window

2 Modify the synchronization clock Type, Clock source and Configured QL.

3 Click the button to confirm the settings or click the button to withdraw the settings.

5.2 Transmit clock source for E1/T1/J1

Figure 56 Transmit clock source for E1/T1/J1 tab

Port Index and Output Index Type will be displayed for different ports.



Modify a interface synchronization configuration for E1/T1/J1 portTo modify a existing interface synchronization configuration, follow the steps below:

1. Select one existing interface synchronization entry and click button to open the modify box. See Figure 57.

Figure 57 Modify interface synchronization entry (E1/T1/J1)2. Select the Output clock type: Loopback, System, PW Recovered, TDM Sync.

3. Click the button to confirm the settings or click the button to withdraw the modification.

5.3 SSM configuration for Ethernet port

Figure 58 SSM configuration for Ethernet port tab

Modify a interface synchronization configuration for the Ethernet portTo modify a existing interface synchronization configuration, follow the steps below:

1. Select one existing interface synchronization entry and click button to open the modify box. See Figure 59.


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Figure 59 Modify interface synchronization entry (Ethernet port)2. Select the SSM enable to disabled or enabled.

g Only if the SSM enable is enabled, then in General Sync Configuration tab, External Clock Mode can be set to SSM. Otherwise, the setting to SSM for External Clock Mode will not take effect.

3. Click the button to confirm the settings or click the button to withdraw the modification.


Operate & MaintainEthernet Configuration

6 Ethernet ConfigurationTwo SFP interfaces and four GE interfaces can also be configured here to be the man-agement interfaces to send and receive the management packets.

The Ethernet configurations is displayed as in Figure 60.

Figure 60 Ethernet configuration settings view

And there are three types of Ethernet configurations.

– General configuration– xSTP– LLDP

Click on one setting, the corresponding view is displayed.

6.1 General ConfigurationIn the General Configuration tab, it includes the following information: Aging Time Dis-abled, Aging Time (10...1000000 seconds), Mac Cache Disabled and Mac Cache Size Limit (10...8192). See Figure 60.


Also, the user can make modifications directly on each field. After the changes, click

button to commit the changes.

6.2 xSTPIn RSTP/MSTP view, there are three tabs of parameter groups. See Figure 61.

– Configuration


Aging time Indicates how long the automatically assigned MAC address is available.

Mac cache size limit Indicates the size of the learned MAC address occupied.

Table 26 Aging time parameters


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Operate & Maintain Ethernet Configuration

– CIST– CIST Advanced– MST

In the Configuration tab, the xSTP Enable and 100ms Clock Unit Enable can be set here. See Figure 61.

Figure 61 Configuration

g During the re-enabling of the xSTP, there will be a temp loop.

Click the button to get the most updated information. Also the user can make modifications directly on those two fields. And after the modification, click the

button to commit the changes.

In the CIST tab, the CIST Bridge Information and CIST Port Properties can be set here. See Figure 62.


xSTP Enable Used to enable or disable the RSTP/MSTP.

100ms Clock Unit Enable Used to enable or disable the clock unit of 100ms

Table 27 xSTP Enable



Figure 62 CIST


Bridge MAC MAC address of the bridge.

Priority The value of the editable portion of the Bridge ID (i.e., the first two octets of the (8 octet long) Bridge ID). Permissible values are 0-61440, in steps of 4096.

Scheme Indicates whether the MSTP or RSTP will be used.

Table 28 CIST Bridge Information


ID The identifier of the port.

Port Name of the port.

Priority The priority field for the Port Identifier for the Port. Permissible values are 0-240.

Port State The current state of the Port.

xSTP Enabled Status Indicate whether the xSTP is enabled or not on this port.

Protocol Migration The current value of the mcheck variable for the Port.

Admin Edge Port Status In a Bridge that supports the identifica-tion of edge ports, the status of the Port's Admin Edge Port.

Table 29 CIST Port Properties


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Click the button to get the current status and information. Click the

button to modify existing row. See Figure 63.

Figure 63 Modify CIST Port Properties

Oper Edge Port Status In a Bridge that supports the identifica-tion of edge ports, the status of the Port's operational Edge Port.

External Port Path Cost CIST path cost from all bridges to the CIST Root. Permissible values are 0-200000000.

Internal Port Path Cost IST path cost from the transmitting Bridge to the IST Regional Root. Per-missible values are 0-200000000.

Cist Port Role The current Port Role for the Port.

Admin P2P Indicate whether the port is connected to a point-to-point LAN or not.

Oper P2P It’s the real value of the “Admin P2P”. Indicate whether the port is connected to a point-to-point LAN or not.


Table 29 CIST Port Properties (Cont.)




Click the button to manually re-check the appropriate BPDU format to send on the selected interfaces.

In the CIST Advanced tab, the CIST Bridge Information, CIST Bridge Timing and Local Bridge Timing can be set here. See Figure 64.

Figure 64 CIST Advanced


CIST Root ID the Bridge Identifier of the current CIST Root.

External Root Path Cost CIST path cost from all bridges to the CIST Regional Root. Permissible values are 0-200000000.

CIST Regional Root ID the Bridge Identifier of the current CIST Regional Root.

Table 30 CIST Bridge Information


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Internal Root Path Cost IST path cost from the transmitting Bridge to the IST Regional Root. Per-missible values are 0-200000000.

Root Port ID The identifier of the port that offers the lowest cost path from this bridge to the root bridge.


Hello Time(s) The amount of time between the trans-mission of Configuration bridge PDUs by this node on any port when it is the root of the spanning tree, or trying to become so, in units of one second. Per-missible values are 100-1000.

Forward Delay(s) This time value, measured in units of one second, controls how fast a port changes its spanning state when moving towards the Forwarding state. Permissible values are 0-65535.

Max Age(s) The maximum age of Spanning Tree Protocol information learned from the network on any port before it is dis-carded, in units of one second. Permis-sible values are 0-65535.

Max Hops MaxHops parameter. The range of the parameter is 6 to 40.

Table 31 CIST Bridge Timing


Hello Time(s) The value that all bridges use for Hello-Time when this bridge is acting as the root. Permissible values are 0.1, 0.2, ... 10.

Forward Delay(s) The value that all bridges use for For-wardDelay when this bridge is acting as the root. Permissible values are 4-30.

Max Age(s) The value that all bridges use for MaxAge when this bridge is acting as the root. Permissible values are 6-40

Table 32 Local Bridge Timing


Table 30 CIST Bridge Information (Cont.)



Click the button to get the current status and information. And after

changing the parameters, click the button to commit the changes.

In the MST tab, the MST Region Properties, MST Instance, MSTI Regional Root, MSTI Root Path Cost and VLANs Mapped can be set here. See Figure 65.

g In order to create the MST instance, xSTP Enable need to be enabled in the Configu-ration tab in Figure 61.

Figure 65 MST

Max Hops MaxHops parameter. The range of the parameter is 6 to 40.


Table 32 Local Bridge Timing (Cont.)


Bridge ID (Priority, MAC) Bridge Identifier.

Region Name Name of the Region.

Revision Level Revision Level in the MST Configura-tion Identifier. Permissible values are 0-65535.

Configuration ID The configuration digest in the MST, Configuration Identifier.

Table 33 MST Region Properties


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Click the button to get the current status and information. Click the

button to create MSTI, see Figure 66.

Figure 66 Create MSTI

Click the button to modify the existing row, see Figure 67.


Instance MST instance. Value range from 1 to 8.

MSTI Regional Root Regional Root of MST instance.

MSTI Root Path Cost Path Cost of MSTI Root. Permissible values are 0-200000000.

VLANs Mapped VLAN mapped to the instance. Permis-sible values are 51-4094.

Table 34 MST Instance List



Figure 67 Modify MSTI

Select one row in the Port MSTI Properties, and click the button to modify, see Figure 68.

Figure 68 Modify port MSTI properties



83


g CIST can be used by both MSTP and RSTP, but MST can only be used by MSTP.

6.3 LLDPIn LLDP view, there are five tabs of parameter groups. See Figure 69.

– Configuration– Local System– Remote System– Remote Management– Counter

In the Configuration tab, the Tx Message Rate and other parameters can be set here. See Figure 69.

Figure 69 Configuration


Tx Message Rate (5-32768 seconds) The interval at which LLDP frames are transmitted on behalf of this LLDP agent.

Time To Leave Multiplier (2-10) A multiplier used to multiply Tx Message Rate to get a TTL value.

Tx Delay (1-8192) Indicates the delay (in units of seconds) between successive LLDP frame trans-missions initiated by value/status changes in the LLDP local systems MIB.

Notification Enable Indicates whether or not the notification from agent is enabled.

Table 35 Configuration Parameters



Click the button to get the current status and information. For those fields

can be modified directly, click the button to commit the changes.

In order to modify fields Port Num and Admin Status, follow the steps below:

1. select one existing row and click the button to open the modify box in.

Figure 70 Modify box in Configuration tab2. Modify the Admin Status to TX, RX, TX & RX or disabled.

3. Click the button to commit the changes or click the button to withdraw the modification.

In the Local System tab, the Local System Data, Local Management Address and LLDP Local Port can be set here. See Figure 71.

Port Num The index value used to identify the port component (contained in the local chassis with the LLDP agent) associ-ated with this entry.

Admin Status The administratively desired status of the local LLDP agent.


Table 35 Configuration Parameters (Cont.)


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Figure 71 Local System


Chassis ID SubType The type of encoding used to identify the chassis associated with the local system.

Chassis ID The string value used to identify the chassis component associated with the local system.

Table 36 Local System Data


Management Address Subtype The type of management address iden-tifier encoding used in the associated 'Management Address' object.

Management Address The string value used to identify the management address component asso-ciated with the local system.

Management Address Length The total length of the management address subtype and the management address fields in LLDPDUs transmitted by the local LLDP agent.

Table 37 Local Management Address



Click the button to get the current status and information.

In the Remote System tab, the Local Port, Chassis Id Subtype, Chassis Id, Remote Port Id Subtype and Remote Port Id can be seen here. See Figure 72.

Figure 72 Remote System


Port The index value used to identify the port component (contained in the local chassis with the LLDP agent) associ-ated with this entry.

Port Sub Type The type of port identifier encoding used in the associated 'Port Id' object.

Port ID The string value used to identify the port component associated with a given port in the local system.

Table 38 LLDP Local Port


Local Port Identifies the port on which the remote system information is received.

Chassis ID Subtype The type of encoding used to identify the chassis associated with the remote system.

Table 39 Remote System Parameters


87



In the Remote Management tab, the Local Port, Management Address Subtype, and Management Address can be seen here. See Figure 73.

Figure 73 Remote Management

Chassis ID The string value used to identify the chassis component associated with the remote system.

Remote Port ID Subtype The type of port identifier encoding used in the associated 'Remote Port Id' object.

Remote Port ID The string value used to identify the port component associated with the remote system.


Table 39 Remote System Parameters (Cont.)


Local Port Identifies the port on which the remote management information is received.

Management Address Subtype The type of management address iden-tifier encoding used in the associated 'Management Address' object.

Management Address The string value used to identify the management address component asso-ciated with the remote system.

Table 40 Remote Management Parameters




In the Counter tab, the Last Change Time, Inserts, deletes and ageouts can be seen here. See Figure 73.

Figure 74 Counter


Last Change Time The value of sysUpTime object at the time an entry is created, modified, or deleted in the tables associated with the Remote Systems Data objects and all LLDP extension objects associated with remote systems.

Inserts The number of times the complete set of information advertised by a particular MSAP has been inserted into tables contained in Remote Systems Data and Extensions objects.

Deletes The number of times the complete set of information advertised by a particular MSAP has been deleted from tables contained in Remote Systems Data and Extensions objects.

Ageouts The number of times the complete set of information advertised by a particular MSAP has been deleted from tables contained in Remote Systems Data and Extensions objects because the infor-mation timeliness interval has expired.

Table 41 Counter Parameters


89



Port The index value used to identify the port component (contained in the local chassis with the LLDP agent) associ-ated with this entry.

Tx Frames The number of LLDP frames transmit-ted by this LLDP agent on the indicated port.

Rx Discarded Frames The number of LLDP frames received by this LLDP agent on the indicated port, and then discarded for any reason.

Rx Error Frames The number of invalid LLDP frames received by this LLDP agent on the indi-cated port, while this LLDP agent is enabled.

Rx Frames The number of valid LLDP frames received by this LLDP agent on the indi-cated port, while this LLDP agent is enabled.

Rx Ageouts The counter that represents the number of age-outs that occurred on a given port.


Table 41 Counter Parameters (Cont.)


Operate & MaintainService management

7 Service managementIn Service Management view (see Figure 75), there are two types of service settings:

– Ethernet service– CES service

Figure 75 Service management view

7.1 Ethernet serviceIn Ethernet service view, there are five tabs of parameter group.

– Service view– Bandwidth profile– Static unicast FDB– Dynamic unicast FDB– Mapping rule

7.1.1 Service viewIn Service View tab (see Figure 76), parameters of Ethernet service are displayed, see Table 42.

Figure 76 Service view


Service index Locally unique index of the service.

Service global ID Network-wide unique index of the service. Used to correlate all objects across the network related to a specific service.

Table 42 Ethernet service parameters


91

Operate & Maintain Service management

Name Locally unique name of the service.

Service type Two types of service to be chosen:

– E-LAN– E-Line

This field is mandatory when creating a row in this table. This field is not modifiable after creation.

S-VLAN ID Service VLAN ID, S-VLAN is used to identify man-agement traffic. The value range is between 51 and 4094.

Admin state The service's administrative status. It can be set to enable only after the service has been activated (RowStatus set to active(1)).

enable(1) - The service have been set to work from administration point of view.

disabled(2) - The service is not allowed to work.

Operation state The Service operational status.

For E-Line, it can have one of the following values:

– up(1) - The service has connectivity with its peer.

– down(2) - The service has no connectivity with its peer.

– off(3) - The service AdminState is disable(2).– unknown(4) - There is not enough information.– na(5) - not-applicable.

For E-LAN, it can have one of the following values:

– up(1) - The service has full end-to-end connec-tivity.

– down(2) - The service has no end-to-end con-nectivity.

– off(3) - The service AdminState is disable(2).– unknown(4) - There is not enough information.– na(5) - the service has no AC.– partial(6) - The service has EtE connectivity to

part of its remote peers.


Table 42 Ethernet service parameters (Cont.)



Click the button to get the latest updated information.

In Service View, there are six operations can be applied to an Ethernet service: Create, Delete, View, Modify, Enable Service and Disable Service.

Create an Ethernet serviceTo create a new Ethernet service, follow the steps below:

Sub type This field defines the sub-type of the service.

The following values are applicable only to service of type eline(2):

– local(1) - the service is an E-Line connecting two UNI ports on this device. The E-Line, in this case, starts and ends in this device.

– p2p(2) - The service is an edge end point of a Point to Point EtE service. In this case the service starts at this device and ends at another.

– n2n(3) - The service is an intermediate Cross Connect in an EtE E-Line service or in a spoke of an E-LAN service. In this case the service is an E-Line connecting two NNI ports on this device.

The following values are applicable only to service of type elan(1):

– mp2mp(5) - The service supplies Multi Point to Multi Point connectivity from/to all its ACs.

This field is mandatory at creation and cannot be modified after creation.

Description The service’s description.

Last error Error of last failed operation performed on the service (including sub-components (SI, SII).

Last error time Time of last failed operation performed on the service (including sub-components (SI, SII).

Service priority The service's PSC. Applicable values are:

– pscAf3(2) - AF3 - Normal– pscAf2(3) - AF2 - Business Critical– pscEf1(6) - EF1 - CES– pscEf2(7) - EF2 - Delay-sensitive– multi(11) - the service is multi-PSC service.


Table 42 Ethernet service parameters (Cont.)


93


1 Click the button in Figure 76 to open the Create Ethernet Service window, there are six tabs on the left side of the window (see Figure 77) to indicate the steps of the configuration.

Figure 77 Create-select interface window

2 Select two desired Ethernet interfaces listed in Figure 77.

g If the service type is E-LAN, more than two ports can be selected.

Click the button to open the Assign General Information window.

If select Basic Mode, refer to Figure 78;

If select Advanced Mode, refer to Figure 79.

Figure 78 Create-assign general information window-basic mode



Figure 79 Create-assign general information window-advanced mode

If the Service Mode is set to Transparent, the window is as Figure 80.

If the Service Mode is set to Translation, the window is as Figure 81.

g The translation service mode only applies on UNI ports with E-LAN service type.

Figure 80 Create-assign general information window-transparent mode


95


Figure 81 Create-assign general information window-translation mode

3 In the Assign General Information window (see Figure 79), the general information of a new service is listed as in Table 43.

4 Enter the value of parameters and click the button to open the Assign Service Mapping Rules window, see Figure 82.

g This step is not available for the Basic mode.


Service Name A name given by the user.

Global ID An unique ID defined by the user, and to be referred by a CESoP service.

Service type Two types of service to be chosen:

– E-LAN– E-Line

g For detailed information of E-LAN and E-Line, please refer to Ethernet processing in Product Description manual.

Service VLAN ID Service VLAN ID, S-VLAN is used to identify manage-ment traffic. The value range is between 51 and 4094.

Multi CoS Multi CoS is possible on E-Line / E-LAN for UNI-to-NNI or UNI-to-UNI connections. Multi CoS classification is based on VLAN-pri or DSCP for both untagged traffic and tagged traffic.

Service mode Transparent

Translation

Table 43 Ethernet Service parameters



Figure 82 Create-assign service mapping rules window

The purpose of mapping is to classify incoming packets according to packet’s protocol field and source / destination port. It is a method to differentiate services and flows.

The mapping fields supported on UNI port and NNI port are different. For different service type, E-LAN or E-Line, the mapping fields are also different. These mapping fields are illustrated below.

– Mapping fields on UNI port for E-LAN service are as follows:– Source MAC Address– VLAN ID (C-tag)– Source IP Address

g The limitations of the mapping rule for E-LAN service on UNI port:1 Source MAC Address / Source IP Address are per system based.2 For a single mapping rule, only one field can be used for classification.3 Priority of these fields is fixed: VLAN ID -> Source MAC Address -> Source

IP Address -> untagged traffic (all traffic).

– Mapping fields on UNI port for E-Line service are as follows:– Dest MAC Address– Source MAC Address– C-Priority– VLAN ID (C-tag)– Ether Type– Dscp Value– IP Protocol– Source IP Address– Dest IP Address– Source UDP Port– Dest UDP Port


97


g More than one mapping fields are supported for E-Line service.

– Mapping fields on NNI port are only source port and SVID.

5 Table 44 explains all the parameters of mapping rule.

6 To create a new rule, configure all the parameters in the Assign Service Mapping

Rules window and click the button.

To modify a mapping rule, select the mapping rule entry in the Assign Service

Mapping Rules window, update the parameters and click the button to confirm the modification.

g Modify button is not available for Multi CoS.


Precedence Contains the precedence of this rule within the Interface Index to which this rule applies.

CVlan Indicates a matching condition of a frame C-VID value.

CPriority Indicates a matching condition between a frame C-Tag priority value and the Service AC SII.

Ether type The Ethernet type.

Source IP address The source IP Address. When not applicable, the value should be: 0.0.0.0.

Source IP mask The source subnet mask associated with the IP address of this entry. When not applicable, the value should be: 0.0.0.0.

Dest IP address The destination IP Address. When not applicable, the value should be: 0.0.0.0.

Dest net mask The destination subnet mask associated with the IP address of this entry. When not applicable, the value should be: 0.0.0.0.

IP protocol IP protocol type- the protocol type byte that appears in the IP header.

Dscp value Indicates a matching condition between a frame IP DSCP and the Service AC SII. Values: 0..63 (decimal values).

Source Mac address The physical address of the source.

Dest Mac address The physical address of the destination.

Source UDP port Source UDP port.

Dest UDP port Destination UDP port.

Table 44 Service mapping rule parameters



To delete a mapping rule, select the mapping rule entry in the Assign Service

Mapping Rules window, click the button to delete.

7 If the Ethernet service is Multi CoS, click the button to open the Assign Qos Mapping Rules window (see Figure 83).

Figure 83 Create-assign Qos mapping rules window

Table 45 explains the service parameters in the Assign Qos Mapping Rules window.


Dscp value Indicates a matching condition of a frame IP DSCP.

Queue priority Used to define the classifier PSC (PHB Scheduling Class). Applicable values from lowest to highest priorities are:

– pscBe(0) - Best Effort– pscAfCtrl(1) - AF Control– pscAf3(2) - Normal– pscAf2(3) - Business Critical– pscAf1(4) - AF1– pscEfCtrl(5) - EF Control– pscEf1(6) - CES– pscEf2(7) - Delay-sensitive

gMulti-PSC service is selected in case of multi-CoS configuration.

Table 45 Service parameters


99


If the Ethernet service is not Multi CoS, click the button to open the Assign SLA Policy window (see Figure 84).

Figure 84 Create-assign SLA policy window

Table 46 explains the service parameters in the Assign SLA Policy window.

g SLA defines acceptable levels of delay, data loss and bandwidth availability, among other performance measurements, for particular groups of traffic. SLA parameters can be assigned symmetrically or asymmetrically, by assigning the same or different value to each direction of the service.

SLA profile The Service Level Agreement Profile. SLA can provide a means of measuring and guaranteeing Quality of Service.


Service SLA The Service Level Agreement Profile. SLA can provide a means of measuring and guaranteeing Quality of Service.

Service priority Used to define the classifier PSC (PHB Scheduling Class). Applicable values from lowest to highest priorities are:

– pscBe(0) - Best Effort– pscAfCtrl(1) - AF Control– pscAf3(2) - Normal– pscAf2(3) - Business Critical– pscAf1(4) - AF1– pscEfCtrl(5) - EF Control– pscEf1(6) - CES– pscEf2(7) - Delay-sensitive

g Multi-PSC service is selected in case of multi-CoS configuration.

Table 46 Service parameters


Table 45 Service parameters (Cont.)



To create a new SLA, click the button in Figure 83 / Figure 84, a window pops up, see Figure 85.

Figure 85 Create new SLA

Select the values of parameters listed in Table 47. Click the button to create the new SLA.

Select the value of parameter Service Priority.

8 Click the button to open the Assign Unicast FDB window (see Figure 86).

g This step is not available for the Basic mode.


CIR Committed information rate (CIR), refers to bandwidth that is guaranteed available at all times to a specific service. Values: 1..1000000.

CBS Committed burst size (CBS), the value configured by the user is rounded to the higher valid value. The valid value is dependent also on the CIR value. Values: 0 or 16..16384.

PIR Peak information rate (PIR), must >=CIR. It is a burstable rate set on routers and/or switches that allows throughput overhead. Values: 1..1000000.

PBS Peak burst size (PBS), values: 0 or 16..16384.

Table 47 SLA profile parameters


101


Figure 86 Create-assign unicast FDB window

Key in the value of Static unicast Mac address and select the Port interface for the service.

Click the button to add the defined Unicast FDB entry; OR

Click the button to delete an entry of Unicast FDB.

9 Click the button to go to the Finish page (see Figure 87).

Click the button to confirm all the settings. If there is no error message showing up, the service interface is created successfully. Otherwise, the user has to diagnose the problem according to the error messages.


Static unicast Mac address The destination MAC address in a frame to which this entry's filtering infor-mation applies. This object must take the value of a unicast address.

Port The port number of the port from which a frame must be received in order for this entry's filtering information to apply.

Table 48 Unicast FDB parameters



Figure 87 Ethernet service finishing page

Delete an Ethernet serviceTo delete an Ethernet service, select the Ethernet service profile entry in Figure 76, click

button. A confirmation message ‘Are you sure to delete them (it)?’ will be

seen and click button to delete.

g If select more than one Ethernet service profile entries by Ctrl , the selected entries will be deleted together.

View an Ethernet serviceTo view an Ethernet service profile, select the Ethernet service profile entry in Figure 76,

click button, see in Figure 88.

Figure 88 Select interface window

Click the button, see in Figure 89.


103


Figure 89 Assign general information window


Figure 90 Assign mapping rules window


Figure 91 Assign SLA policy window




Figure 92 Assign Unicast FDB window

Click the button to close the View Ethernet Service window.

Modify an Ethernet serviceTo modify an Ethernet service, select the Ethernet Service entry in Figure 76, and click

the button. Modify the settings in the pop-up Modify Ethernet Service window, see in Figure 93.

Figure 93 Modify-select interface window

g when the Ethernet service is in use, the modify function can not work. There is a warning message ’Service can not be modified, service index: xx name: xx which is used by

CESoP Service index: x.' when click the button.



105


Figure 94 Modify-assign general information


Figure 95 Modify-assign mapping rules


Figure 96 Modify-assign SLA policy




Figure 97 Modify-assign unicast FDB


Figure 98 Modify-finish

Click the button to apply the modification, and click the button to close the window.

Enable an Ethernet serviceTo enable an Ethernet service, select the Ethernet Service entry in Figure 76, and click

the button. The Admin State is updated to enable.

Disable an Ethernet serviceTo disable an Ethernet service, select the Ethernet Service entry in Figure 76, and click

the button. The Admin State is updated to disable.

7.1.2 Bandwidth profileIn the Bandwidth Profile tab (see Figure 99), the general information of SLA Bandwidth Configuration are displayed, e.g., ID, CIR (Kbps), CBS (Kbytes), etc.



107


Figure 99 Bandwidth Profile View

Create a bandwidth profileTo Create a new SLA Bandwidth Configuration, follow the steps below:

1 Click the button in Figure 99 to open the Create window, there are four parameters to be configured (see Figure 100).

Figure 100 Create a Bandwidth Profile window

In Create a Bandwidth Profile step, configure the following parameters:


CIR Committed information rate (CIR), refers to bandwidth that is guaranteed available at all times to a specific service. Values: 1..1000000.

CBS Committed burst size (CBS), the value configured by the user is rounded to the higher valid value. The valid value is dependent also on the CIR value. Values: 0 or 16……16384.

PIR Peak information rate (PIR), must >=CIR. It is a burstable rate set on routers and/or switches that allows throughput overhead. Values: 1..1000000.

Table 49 SLA profile parameters



2 Key in the SLA Bandwidth CIR, CBS, PIR, and PBS in the corresponding text fields.

3 Click the button to confirm the creation. The created bandwidth profile displays on the Bandwidth Profile view.

Delete a bandwidth profileTo delete a Bandwidth Profile, select the bandwidth profile entry in Figure 99, and click

the button. A confirmation message ‘Are you sure to delete them (it)?’ pops

up, click the button to confirm the deletion.

Modify a bandwidth profileTo modify a Bandwidth Profile, select the bandwidth profile entry in Figure 99, and click

the button. Modify the settings in the pop-up modify window, see in Figure 101.

Click the button to confirm all the settings.

Figure 101 Modify bandwidth profile window

g The CIR (Kbps) value should be less than the PIR (kbps) value.

7.1.3 Static unicast FDBIn the Static Unicast FDB tab (see Figure 102), the Static Unicast Forwarding DataBase (FDB) is listed. For a service with an unique Service ID, if the destination address of a receiving packet of this service matches the corresponding Static Unicast

PBS Peak burst size (PBS), values: 0 or 16……16384.


Table 49 SLA profile parameters (Cont.)


109


MAC Address in the FDB, the packet will be forwarded to the corresponding Static Unicast SI Number, otherwise it will be broadcast to all other ports.


Figure 102 Static Unicast FDB view

7.1.3.1 Create a static unicast FDB entryTo create a new entry, follow the steps below:

1 Click the button in Figure 102 to open the creating window, see Figure 103:

Figure 103 Creating a Static Unicast FDB entry window



2 Fill in the parameters, and click . The new entry will be added to the FDB if the data settings are correct.

7.1.3.2 Delete a static unicast FDB entryTo delete a Static Unicast FDB entry, select the FDB entry in Figure 102, and click the

button. A confirmation message ’Are you sure to delete them (it)?’ pops up,

click the button to confirm the deletion.

7.1.4 Dynamic unicast FDBIn the Dynamic Unicast FDB tab (see Figure 104), all the forwarding data is determined by the system and not editable to the user.

Figure 104 Dynamic Unicast FDB view

Click the button to get the latest updated data.

Click the button to open the Flush FDB window as in Figure 105.

Figure 105 Flush FDB window


111


Click the button to open the confirmation window as in Figure 106.

Figure 106 Flush FDB confirmation window

Click the button to close the window.

7.1.5 Mapping ruleIn the Mapping Rule tab, all the mapping rules created for each interfaces are listed together with the detailed parameters, see Figure 107.

Figure 107 Ethernet service mapping rules

The parameter description of mapping rule is listed as in Table 44.


Select the desired interface from the Interface drop-down list to see its responding mapping rules.

Select a row of mapping rule and click the / button to increase/decrease its Precedence level.

g Ethernet services need to be disabled before making any changes to the mapping rules.



7.2 CES serviceCES service offers TDM trunking over a packet network. In FPFM200, a CES service can be created by mapping the TDM traffic from a specific E1/T1/J1 port with selected N x DS0 level signals into an already established Ethernet service.

g For the detailed information of TDM over Packet, please refer to Product Description manual.

In the CES Service, there are five tabs of parameter group:

– CES service– CES interface– CES profile– CES IWF– CES bandwidth

Figure 108 CES service view

7.2.1 CES serviceIn CES Service tab (see Figure 108), all the existed CES Service are listed with the fol-lowing parameters:


Index The index of the CES profile to be applied.

Service type CESoP or SAToP.

Destination IP address The destination IP address.

Remote / local UDP port

Remote / local UDP port number, [49152 ~ 65535].

Name A name given by the user.

Admin status Two options:

– Up– Down

g When first time created, the AdminStatus is by-default as Down.

Table 50 CES service parameters


113


CES services can be created, deleted, viewed and modified using buttons at the bottom of the view (see Figure 108).

Create a CES serviceTo create a new CES service, follow the steps below:

1 Click on to open the Create CES Service window.

If select Advanced Mode, refer to Figure 109;

If select Basic Mode, refer to Figure 110.

Operation status The state of operation.

PDH port PDH interface.

Profile index The index of the CES profile to be applied.

C-VLAN ID (tagged) CES VLAN ID.

NextHop Mac address Static MAC address of the next hop if the Mac Address Learning Mode is set as manual.

Mac address learning mode

automatic or manual.

Global ServiceID A Service ID that identified as either an E-Line or an E-LAN service. Each service is further associated with 2 or more service interface (SIs), representing the attachment circuits (ACs) and PWs, or NVIs. A service can be thought of as a virtual switching instance in the sense that it forwards traffic between ACs and NVIs.

Clock Recovery mode Timestamps generation modes:

– adaptive: the PSN-bound IWF sets timestamps using the clock recovered from the incoming TDM ACs.

– differential: Both IWFs have access to a common higher quality timing source, and this source is used for timestamp generation.

g The Clock Recovery mode setting is meaningful only when the corresponding E1 port output synchronization mode is set as Recovered.


Table 50 CES service parameters (Cont.)



Figure 109 Creating a CES service window-advanced mode

Figure 110 Creating a CES service window-basic mode

Select a TDM interface port (E1 0/1 ~ E1 0/8), select the Service Type in the drop-down menu (CESoP / SAToP). There are totally 31 time slots in the E1 frame, 24 time slots in the T1/J1 frame.

g By default, all the Time Slots are ticked.

2 Click the button to go the Select Traffic Profile window, see Figure 111.

g This step is not available in basic mode.


115


Figure 111 Selecting traffic profile for CES service

Set the Number of Frames, RTP header used, Jitter buffer size to a profile, and

give a Name to it in the corresponding text field. Click the button to add the defined profile.

3 Click the button to open the Select Ethernet Service window, see Figure 112.

Figure 112 Selecting Ethernet service for CES service

Select an desired Ethernet service to be mapped in the available Ethernet service list.

4 Click the button to go the Assign Service Attribute window.

If select basic mode, refer to Figure 113;

If select advanced mode, refer to Figure 114.



Figure 113 Assign service attribute-basic mode

Figure 114 Assign service attribute-advanced mode

Configure the required parameters in the window.

5 Click the button to go the Finish window, see Figure 115.


117


Figure 115 Finishing creating a CES service

Click the button to confirm the settings, the CES service is created suc-cessfully.

Delete a CES serviceTo delete a CES service entry, select the CES service entry in Figure 108, and click the

button. A confirmation message ’Are you sure to delete them (it)?’ pops up,

click the button to confirm the deletion.

View a CES serviceTo view a CES service profile, select the CES service profile entry in Figure 108, click

the button, see in Figure 116.

Figure 116 Select TDM port window




Figure 117 Select traffic profile window


Figure 118 Select Ethernet service window



119


Figure 119 Assign service attribute window

Click the button to close the View CES Service window.

Modify a CES serviceTo modify a CES service, select the Ethernet Service entry in Figure 108, and click on

. Modify the settings in the pop-up Modify CES Service window, see in Figure 120.

Figure 120 Modify-select TDM port



Click on , see in Figure 121.

Figure 121 Modify-select traffic profile


Figure 122 Modify-select Ethernet service



121


Figure 123 Modify-assign service attribute


Figure 124 Modify-finish


Figure 125 Modify-finish applied



Click on to close the window.

Enable a CES serviceTo enable a CES service, select the CES Service entry in Figure 108, and click on

. The Admin State is updated to Up.

Disable a CES serviceTo disable a CES service, select the CES Service entry in Figure 108, and click on

. The Admin State is updated to disable.

7.2.2 CES interfaceIn CES Interface tab (see Figure 126), all the CES interfaces are listed with Port number. The channels are converted into 31-bit from T1 to T31 for E1 interface or 24-bit from T1 to T24 for T1/J1 interface.

There are total 32 channels of a E1 interface, channel 0 is reserved for control traffic, while T1 ~ T31 can be used for data. Those bits which are set to 1 of T1 ~ T31 indicate the corresponding channels are selected for the CES service.

For example, if a CES service channel number is set as 0x8F (10001111), it means channel T1 ~ T4 and T8 are selected for this CES service.

Click on to get the latest updated data.

Figure 126 CES interface view

7.2.3 CES profileIn CES Profile tab (see Figure 127), a list of the CES service rules defined by the user is displayed with the parameters as in Table 51.


123


Figure 127 CES profile view


g There can be more than one CES Profile, each is identified with an index, which is applied to a CES service. It means different CES services can have different CES Pro-files.

Create a CES profileTo create a new CES profile, follow the steps below:


Index Identification of a CES Profile.

Number of frames The TDM frame number contained in a packet.

RTP header used True or False.

If set to False: an RTP header is not pre-pended to the TDM packet.

Jitter buffer size Size of jitter buffer, 1 ~ 16 ms.

Name A descriptive string, preferably a unique name, to an entry in this table.

Table 51 CES profile parameters



1 Click on to open the Create window, see Figure 128:

Figure 128 Creating a CES profile window

2 Set proper parameters, and click on to confirm the settings. The new CES profile will be added to the list if it is created successfully.

Delete a CES profileTo delete a CES profile, select the CES profile entry in Figure 127, and click on

. A confirmation message ’Are you sure to delete them (it)?’ pops up, click on

to confirm the deletion.

g CES Profile A/B/C is the default system-defined profile, and can not be deleted.

7.2.4 CES IWFIn CES IWF tab (see Figure 129), all the Interworking functions (IWF) are listed with the parameters as in Table 52.

Figure 129 CES IWF view


125



Modify a CES IWF

To modify a CES IWF, select the CES IWF entry in Figure 129, and click on , see Figure 130:

Figure 130 Modifying a CES IWF window


IfIndex Identification of a CES IWF.

IP address IWF IP address defined by the user.

Net Mask Net Mask given by the user.

Default gateway Default gateway IP address.

MAC address MAC address of the IWF.

g IWF and OOB interface share the same MAC address.

ARP refresh interval 0 means that the functionality is disabled. Disabled means that the ARP request is sent only on need: after PW setup (creation), after equipment startup, during connection outage (in any of the two directions).

When connection is fully operational no need of ARP contin-uous requests.The parameter is expressed in seconds. Defined range is between 60 and 1200 (1 to 20 minutes).

Table 52 CES IWF parameter



In the Modify window, type in the value of the parameters and click the button to modify the CES IWF.

g The modification of CES IWF only take effect after the reset of the CES service.

7.2.5 CES bandwidthIn the CES Bandwidth tab (see Figure 131), the bandwidth used by each CES service is listed with detailed information, e.g., Packet Size, Bit Rate, etc.

Figure 131 CES Bandwidth view



Index Identification of a CES bandwidth.

Name A name given by the user.

Packet size The packet size in bytes.

Packet rate The packet rate in packet/s.

Bit rate The bit rate in bit/s.

Table 53 CES bandwidth parameters


127

Operate & Maintain Advanced QoS settings

8 Advanced QoS settingsFPFM 200 supports the QoS mechanism and user can select the policy for each flow going through this port. And all these settings for QoS can be configured here, including but not limited to the following:

• egress scheduling mode (strict priority or weighted fair queuing) • number of queues working in strict priority mode • number of egress packets on a port to be served for each queue (totally eight

queues)

For the Qos, there are five tabs of parameters group, see Figure 132:

– Scheduler Mode– Port Ingress Rate Limit– Port Egress Shaping– Queue Egress Shaping– sRED

8.1 Scheduler ModeIn Scheduler Mode tab, the following information is shown: Port list, Scheduler fair queue mode, Strict priority queue number, WFQ scheduler q8 weight ... WFQ scheduler q1 weight.

Port list shows all the ports that can be set for QoS including four GE ports, two SFP ports and the logic port LPG as well.

Figure 132 Scheduler Mode


Schedule fair queue mode It is the egress scheduling weighted fair queueing mode, Weighted Round Robin or Weighted Deficit Round Robin.

Table 54 Scheduler Mode for QoS


Operate & MaintainAdvanced QoS settings



8.2 Port Ingress Rate LimitIn Port Ingress Rate Limit tab, the following information is shown: Whole traffic policer enable, Whole traffic policer value, Broadcast traffic policer enable, Multicast traffic policer value, etc.

Figure 133 Port Ingress Rate Limit

Strict priority queue number It shows the number of queues working in Strict Priority scheduling mode. The range is between 0 and 8. And 0 means no queue in strict priority. 1 means queue 8 in Strict Priority with the resulting scheduled Weighted Deficit Round Robin. 2 means queue 8 and 7 in Strict Priority with the resulting scheduled Round Robin among queues 6 to 1, and so on.

When value is 8 (all queues in Strict Priority), the node SchedulerFairQueueMode is not affecting the system behavior.

WFQSchedulerQ8Weight, ...

WFQSchedulerQ1Weight

This number represents the number of egress packets on a port to be served before moving on to the next CoS queue, in a range from 1 to 127.


Table 54 Scheduler Mode for QoS (Cont.)


Whole traffic policer enable It indicates whether whole traffic policer is enable or disabled.

Table 55 Port Ingress Rate Limit


129




8.3 Port Egress ShapingIn Port Egress shaping tab, the following information is shown: Port egress shaping value and Port egress shaping enable.

Figure 134 Port Egress Shaping

Whole traffic policer value It is the per-port policing parameter and admit 64kbps granularity settings.

Broadcast traffic policer enable

It indicates whether broadcast traffic policer is enable or disabled.

Broadcast traffic policer value

It is the per-port policing parameter and admit 64kbps granularity settings.

Multicast traffic policer enable

It indicates whether multicast traffic policer is enable or disabled.

Multicast traffic policer value It is the per-port policing parameter and admit 64kbps granularity settings.

Unicast unknown traffic policer enable

It indicates whether unicast unknown traffic policer is enable or disabled.

Unicast unknown traffic policer value

It is the per-port policing parameter and admit 64kbps granularity settings.

Port SLA profile It describes the per-port SLA (service level agree-ment).


Table 55 Port Ingress Rate Limit (Cont.)



Click the button to get the current status and information. And after


8.4 Queue Egress ShapingIn Queue Egress shaping tab, the following information is shown: Queue Rate Shaper Index, Queue Rate Shaper Min Value and Queue Rate Shaper Max Value.

Figure 135 Queue Egress Shaping


Port egress shaping value This object provides the absolute shaped bandwidth of the port in kbps with 64kbps steps.

Port egress shaping enable This object indicates the port egress shaping is enabled or disabled.

Table 56 Port Egress Shaping for QoS


Queue Rate Shaper Index The queue identifier index, sequential number from 1 to 8.

Queue Rate Shaper Min Value

This provides the strict minimum bandwidth guaran-tees for the relevant queue. The value ranges between 64kbps and Port rate limiter value with 64kbps steps.

Queue Rate Shaper Max Value

This provides the strict maximum bandwidth guaran-tees for the relevant queue. The value ranges between 64kbps and Port rate limiter value with 64kbps steps.

Table 57 Queue Egress Shaping for QoS


131



Select one row and click the button to open Modify box. See Figure 136. Change Queue Rate Shaper Min and Queue Rate Shaper Max parameters. And after


Figure 136 Modify Queue Egress Shaping

8.5 sREDIn sRED tab, the following information is shown: Queue Index, Color, Enable, Min Threshold Value, Max Threshold Value and Drop Fraction.

Figure 137 sRED


Queue Index The queue identifier index, sequential number from 1 to 8.

Color The sRED color. In SVR 2.0 fixed to yellow.

Enable Enable sRED for the relevant CoS queue.

Table 58 Queue Egress Shaping for QoS




Select one row and click the button to open Modify box. See Figure 138. Change SRED Enable, SRED Min Threshold, SRED Max Threshold and SRED Drop

Fraction parameters. And after changing the parameters, click the button to commit the changes.

Figure 138 Modify sRED

Min Threshold Value The minimal queue depth threshold of the CoS queue: sRED begins to drop packets. Below this value no packets will be dropped.When queue depth is above this level, YELLOW packets are dropped with a proba-bility increasing as queue depth grows. The range is between 0 and 128.

Max Threshold Value The maximum queue depth threshold of the CoS queue: sRED may begin to drop all packets. Above this value all the packets will be dropped. The value is fixed to 128.

Drop Fraction The SRED fraction of packets to be dropped when the queue depth is above Min Threshold Value but below Max Threshold Value. The range is between 0 and 7.

0: 100% cliff drop; 1: 12.5%; 2: 6.25%; 3: 3.125%; 4: 1.5625%; 5: 0.78125%; 6: 0.390625%; 7: 0.1953125%


Table 58 Queue Egress Shaping for QoS (Cont.)


133

Operate & Maintain Protection settings

9 Protection settingsFPFM200 supports Link Protection Group (LPG). There are three tabs of parameters group.

– Link Protection Group– Link Aggregation Group– E-CCM

Figure 139 Protection view

9.1 Link Protection GroupIn Link Protection Group tab (see Figure 139), there are two views showing LPG Con-figuration and LPG Properties.

9.1.1 LPG configuration


The parameters of LPG Configuration are listed in Table 59:


Index The interface index for an LPG.

Group name There are two possibilities of LPG group name, i.e., LPG1(701) and LPG2(702). LPG1(701) is the group of GE electrical port 1 & 2, while LPG2(702) is the group of GE electrical port 3 & 4.

GE port 3 & 4 support power feeding to the connected ODUs.

P-CCM VLAN ID The VLAN-ID (VID) of the LPG protection check continuity message (PCCM) between ODUs.

Port 1 First port name of corresponding group.

Port 1 radio link status Link state of this ODU port.

Port 1 meas master slave status

Master / slave resolution.

Port 2 Second port name of corresponding group.

Port 2 radio link status Link state of this ODU port.

Table 59 LPG configuration parameters


Operate & MaintainProtection settings

Create a LPG configurationTo create a new LPG configuration, follow the steps below:

1 Click the button in Figure 139 to open the creating window, see Figure 140.

Figure 140 Create a new LPG configuration window

2 Choose the LPG group from the drop-down menu and fill in P-CCM VID(16..50).

3 Click the button to confirm the setting, and the new LPG configuration is added to the LPG list.

Delete a LPG configurationTo delete a LPG configuration, select the LPG configuration entry in Figure 139, click



Port 2 meas master slave status

Master / slave resolution.

PCCM admin status The state of PCCM.

Operational status Operational status of corresponding LPG.


Table 59 LPG configuration parameters (Cont.)


135


g If select more than one LPG configuration entries by Ctrl , the selected entries will be deleted together.

9.1.2 LPG propertiesClick on the LPG Properties sub-tab, the LPG Properties view shows as in Figure 141.

Figure 141 LPG properties view


The parameters of LPG Property are listed in Table 60:


Port The LPG group port number.


– Up– Down

Operational status The operational state.

Mode The port mode.

– notApplicable - not applicable– userEdge - UNI– networkEdge - NNI– networkCore - E-NNI– management - Management port– ipUserEdge - able of forwarding user

IP traffic.

TPID The Tag Protocol Identifier which appears in the packet segment to indicate the IEEE 802.1Q is the protocol used. And the default value is 0x8100 in Hex.

MTU The maximum packet size that can be sent on the interface and it is specified in octets. The range is from 64 to 9600 bytes.

MAU default type The default administrative baseband MAU type.

Table 60 LPG property parameters



Modify LPG properties

To modify LPG properties, select the LPG entry in Figure 141, and click the button. Modify the settings in the pop-up LPG properties window, see in Figure 142.

Click the button to confirm the settings.

Figure 142 Modify LPG properties window

9.2 Link Aggregation GroupIn Link Aggregation Group tab (see Figure 143), there are two views showing LAG Configuration and LAG Properties.

Figure 143 LAG view

9.2.1 LAG configurationIn LAG Configuration view (see Figure 143), Port List shows all the ports for each LAG index.


137



Create a LAG configurationTo create a new LAG configuration, follow the steps below:

1 Click the button in Figure 143 to open the creating window, see Figure 144:

Figure 144 Create a new LAG configuration window

2 Tick to select ports for the new LAG configuration.

3 Click the button to confirm the setting, and the new LAG is added to the LAG list.

Delete a LAG configurationTo delete a LAG configuration, select the LAG configuration entry in Figure 143, click



g If select more than one LAG configuration entries by Ctrl , the selected entries will be deleted together.

Modify a LAG configurationTo modify a LAG configuration, select the LPG configuration entry in Figure 143, and

click the button. Modify the settings in the pop-up LAG configuration window,

see in Figure 145. Click the button to confirm the settings.



Figure 145 Modify LAG configuration window

9.2.2 LAG propertiesClick on the LAG Properties sub-tab, the LAG Properties view shows as in Figure 146.

Figure 146 LAG properties view


The parameters of LAG Property are listed in Table 61:


Port The LAG group port number.


– Up– Down

Operational status The operational state.

Table 61 LAG property parameters


139


Modify LAG properties

Mode The port mode.

– notApplicable - not applicable– userEdge - UNI– networkEdge - NNI– networkCore - E-NNI– management - Management port– ipUserEdge - able of forwarding user

IP traffic.

TPID The Tag Protocol Identifier which appears in the packet segment to indicate the IEEE 802.1Q is the protocol used. And the default value is 0x8100 in Hex.

MTU The maximum packet size that can be sent on the interface and it is specified in octets. The range is from 64 to 9600 bytes.

Shutdown enable If the port is UNI and a service is created upon this port, then if shutdown enable is enabled, once the service is up, the port is up automatically, once the service is down, the port is down automatically. It is not applicable to NNI.

HashMode noHash = 0 as hashing value.

mode1=hash criteria SA, VLAN, ETherType, source module, port Id.

mode2=hash criteria DA, VLAN, ETherType, source module, port Id.

mode3=hash criteria SA_XOR_DA,VLAN, ETherType, source module,port Id.

mode4=hash criteria SIP, source source TCP/UDP port.

mode5=hash criteria DIP, destination source TCP/UDP port.

mode6=hash criteria SIP_XOR_DIP, source and destination TCP/UDP port.

mode7=hash based load balancing.

MAU default type The default administrative baseband MAU type.


Table 61 LAG property parameters (Cont.)



To modify LAG properties, select the LAG entry in Figure 146, and click the button. Modify the settings in the pop-up LAG properties window, see in Figure 147.

Click the button to confirm the settings.

Figure 147 Modify LAG properties window


9.3 E-CCM settingsE-CCM is the management communication message between IDU and ODU. The user can configure the properties of the E-CCM message in groups of six tabs, see Figure 148:

Figure 148 E-CCM configuration


141


Each parameters are explained in details in table for six tabs.

General:

Maintenance Domain (MD):Maintenance domain is a network or part of a network that faults in connectivity are managed. It is a domain confined by the associated Maintenance Endpoints (MEP).

Figure 149 Maintenance Domain view



E-CCM enable Enable or Disable the E-CCM communication.

E-CCM VID VLAN ID for E-CCM channel, range from 1 ~ 15.

Available TX resources Measurement of available transmission resources in term of number of frames per 10 seconds.

Available RX resources Measurement of available receiving resources in term of number of frames per 10 seconds.

Start delay interval The time interval in which even though the IDU does not send any message to ODU, but ODU still think IDU is alive, range from 2 ~100 seconds.

Suspend interval Possible values for the suspend interval.

Table 62 E-CCM general parameters


MD index MD index number.

MD format The format of MD, read-only.

MD name MD identification.

Table 63 E-CCM maintenance domain parameters



Maintenance Association (MA): Maintenance association is an association of Domain Service Access Points (DoSAP) configured to verify the integrity of a specific service. MA is composed of MEPs.

For FPFM 200, there are totally 6 MAs, including 2 SFP and 4 GE electrical endpoints.

Figure 150 Maintenance Association view


The MA CCM interval value can be changed with the steps below:

1 Select the row of MA to be modified.

2 Click the button to open the modifying window, see Figure 151.

MD level The area of MD covered, from lowest 0 to highest 7.

MD next index Contains an unused value for MD index, 0 indicates that no one exist.


MA index MA index number. It is predefined from 1101 ~ 1106.

MA format The format of MA, read-only.

MA name MA identification.

MA CCM interval The CCM sending interval in 1 s/100 ms from MEP.

Table 64 E-CCM maintenance association parameters


Table 63 E-CCM maintenance domain parameters (Cont.)


143


Figure 151 Maintenance association CCM interval

3 Select the desired interval, i.e., 1 s or 100 ms form the drop-down list of MA CCM interval.

4 Click to confirm the setting.

Maintenance Association End Point (MEP):

Figure 152 Maintenance Association End Point view



MEP identifier A small integer that is unique among all the MEPs in the same MA. MEP identifier is also known as the MEPID.

MEP ifindex The interface index of the interface either a bridge port, or an aggregated IEEE 802.1 link within a bridge port, to which the MEP is attached.

Table 65 E-CCM maintenance association Endpoint parameters



The MEP CCM generation can be enabled or disabled with the steps below:

1 Select the row of MEP to be modified.


Figure 153 Maintenance endpoint Cci enable

3 Select enabled or disabled form the drop-down list of Cci Enabled.


Remote MEP Database:It shows derived information sent from ODU to IDU in E-CCM message.

Figure 154 Remote MEP Database view


MEP direction The direction in which the MEP faces on the Bridge port.

MEP active Administrative state of the MEP.

MEP Cci enabled If set to true, the MEP will generate CCM messages.


Table 65 E-CCM maintenance association Endpoint parameters (Cont.)


145


Mep CC loss Threshold:

Figure 155 Mep CC loss Threshold view


The MEP CC Loss Threshold value can be modified with the steps below:

1 Select the row of MEP to be modified.



Remote MEP identifier Maintenance association End Point Iden-tifier of a remote MEP whose information from the MEP Database is to be returned.

Remote MEP state The operational state of the remote MEP.

RDI state Remote Defect Indication (RDI) status

Port / Interface status TLV Port / Interface status Type Length Value (TLV)

MEP radio link status The status of the Radio Link for MEPs in the MA service type E-CCM.

Table 66 E-CCM remote maintenance association Endpoint parameters


Index Index number.

Loss threshold Number of missed CCMs that cause some CCM defects.

Table 67 E-CCM Mep CC loss threshold parameters



Figure 156 Maintenance endpoint CCMs loss threshold

3 Key in a number in Loss threshold text field.



179

Operate & Maintain Performance

11 PerformanceIn Performance tab (see Figure 188), there are different views showing parameters of Statistics and Performance:

– Statistics– Ethernet Port– SLA

– Performance– G.826– Ethernet Port– Ethernet Service

– Switch– Ethernet Service Performance

– PW– Switch– PW Performance– TDMoP Performance

– OAM– Switch– OAM Performance

Figure 188 Performance measurement overview

11.1 Statistics

11.1.1 Ethernet PortClick the Ethernet Port tab to view the values of the Ethernet counters at each ingress / egress radio port. The following Ethernet counters are shown:


Port The name of the port being monitored.

Drop events The total number of events in which packets were dropped by the probe due to lack of resources.

Table 86 Ethernet port counters


Operate & MaintainPerformance

Pkts The total number of packets (including bad packets, broadcast packets, and multicast packets) received.

Broadcast pkts The total number of good packets received that were directed to the broadcast address. Note that this does not include multicast packets.

Multicast pkts The total number of good packets received that were directed to a multicast address. Note that this number does not include packets directed to the broadcast address.

CRC align errors The total number of packets received that have a length (excluding framing bits, but including FCS octets) between 64 and 1518 octets and have a bad Frame Check Sequence (FCS) with either an integral number of octets (FCS Error) or a non-integral number of octets (Alignment Error).

Undersize pkts The total number of packets received that are less than 64 octets long (excluding framing bits, but including FCS octets) and well formed.

Oversize pkts The total number of packets received that were longer than 1518 octets (excluding framing bits, but including FCS octets) and were otherwise well formed.

Fragments The total number of packets received that are less than 64 octets in length (excluding framing bits but including FCS octets) and have a bad Frame Check Sequence (FCS) with either an integral number of octets (FCS Error) or a non-integral number of octets (Alignment Error).

Jabbers The total number of packets received that were longer than 1518 octets (excluding framing bits, but including FCS octets), and had either a bad Frame Check Sequence (FCS) with an integral number of octets (FCS Error) or a bad FCS with a non-integral number of octets (Alignment Error).

Collisions The best estimate of the total number of collisions on this Ethernet segment.

Pkts 64 octets The total number of packets (including bad packets) received that were 64 octets in length (excluding framing bits but including FCS octets).


Table 86 Ethernet port counters (Cont.)


181


Pkts 65 to 127 octets The total number of packets (including bad packets) received that were between 65 and 127 octets in length inclusive (excluding framing bits but including FCS octets).





In octets The total number of octets received on the inter-face, including framing characters.

In ucast pkts The number of packets, delivered by this sub-layer to a higher (sub-)layer, which were not addressed to a multicast or broadcast address at this sub-layer.

In discards pkts The number of inbound packets which are chosen to be discarded to prevent being delivered to a higher-layer protocol even though no errors have been detected.

In errored pkts For packet-oriented interfaces, the number of inbound packets that contain errors preventing them from being delivered to a higher-layer proto-col. For character-oriented or fixed-length inter-faces, the number of inbound transmission units that contain errors preventing them from being delivered to a higher-layer protocol.





In unknown protos For packet-oriented interfaces, the number of packets received via the interface which are dis-carded because of an unknown or unsupported protocol. For character-oriented or fixed-length interfaces that support protocol multiplexing, the number of transmission units received via the interface which are discarded because of an unknown or unsupported protocol. For any inter-face that does not support protocol multiplexing, this counter will always be 0.

Out octets The total number of octets transmitted out of the interface, including framing characters.

Out ucast pkts The total number of packets that higher-level pro-tocols requested be transmitted, and which were not addressed to a multicast or broadcast address at this sub-layer, including those that were dis-carded or not sent.

Out discards pkts The number of outbound packets which are chosen to be discarded to prevent being transmit-ted even though no errors have been detected. One possible reason for discarding such a packet could be to free up buffer space.

Out errored pkts For packet-oriented interfaces, the number of outbound packets that contain errors at this sub-layer.

In multicast pkts The number of packets, delivered by this sub-layer to a higher (sub-)layer, which are addressed to a multicast address at this sub-layer.

In broadcast pkts The number of packets, delivered by this sub-layer to a higher (sub-)layer, which are addressed to a broadcast address at this sub-layer.

Out multicast pkts The total number of packets that higher-level pro-tocols request to be transmitted, and these packets are addressed to a multicast address at this sub-layer, including those that are discarded or not sent.

Out broadcast pkts The total number of packets that higher-level pro-tocols request to be transmitted, and these packets are addressed to a broadcast address at this sub-layer, including those that are discarded or not sent.

HC in octets The total number of octets received on the inter-face, including framing characters. A 64-bit object.




183


HC in ucast pkts The number of packets, delivered by this sub-layer to a higher (sub-)layer, which were not addressed to a multicast or broadcast address at this sub-layer.

HC in multicast pkts The number of packets, delivered by this sub-layer to a higher (sub-)layer, which were addressed to a multicast address at this sub-layer. For a MAC layer protocol, this includes both Group and Func-tional addresses.

HC in broadcast pkts The number of packets, delivered by this sub-layer to a higher (sub-)layer, which were addressed to a broadcast address at this sub-layer.

HC out octets The total number of octets transmitted out of the interface, including framing characters. A 64-bit object.

HC out ucast pkts The total number of packets that higher-level pro-tocols requested be transmitted, and which were not addressed to a multicast or broadcast address at this sub-layer, including those that were dis-carded or not sent.

HC out multicast pkts The total number of packets that higher-level pro-tocols requested be transmitted, and which were addressed to a multicast address at this sub-layer, including those that were discarded or not sent. For a MAC layer protocol, this includes both Group and Functional addresses.

HC out broadcast pkts The total number of packets that higher-level pro-tocols requested be transmitted, and which were addressed to a broadcast address at this sub-layer, including those that were discarded or not sent.

High speed An estimate of the interface's current bandwidth in units of 1,000,000 bits per second.

Promiscuous mode This object has a value of false if this interface only accepts packets/frames that are addressed to this station.This object has a value of true when the station accepts all packets/frames transmitted on the media.

Alignment errors A count of frames received on a particular inter-face that are not an integral number of octets in length and do not pass the FCS check.





FCS errors A count of frames received on a particular inter-face that are an integral number of octets in length but do not pass the FCS check. This count does not include frames received with frame-too-long or frame-too-short error.

Single collision frames A count of frames that are involved in a single col-lision, and are subsequently transmitted success-fully.

Multiple collision frames A count of frames that are involved in more than one collision and are subsequently transmitted successfully.

SQE test errors A count of times that the SQE test errors is received on a particular interface.

Deferred transmissions A count of frames for which the first transmission attempt on a particular interface is delayed because the medium is busy.

Late collisions The number of times that a collision is detected on a particular interface later than one slotTime into the transmission of a packet.

Excessive collisions A count of frames for which transmission on a par-ticular interface fails due to excessive collisions.

Internal MAC transmit errors A count of frames for which transmission on a par-ticular interface fails due to an internal MAC sub-layer transmit error.

Carrier sense errors The number of times that the carrier sense condi-tion was lost or never asserted when attempting to transmit a frame on a particular interface.

Frame toolongs A count of frames received on a particular inter-face that exceed the maximum permitted frame size.

Internal MAC receive errors A count of frames for which reception on a partic-ular interface fails due to an internal MAC sub-layer receive error.

Symbol errors For an interface operating at 100 Mb/s, the number of times there was an invalid data symbol when a valid carrier was present.

Duplex status The current mode of operation of the MAC entity. Unknown indicates that the current duplex mode could not be determined.




185


Click the button to get the latest updated measurement.

Click the button to open the filter window as Figure 189. Select / unselect the counters by tick / untick the select boxes, the unticked counters are not shown in the Ethernet Port view.

Figure 189 Filter window

Select one entry of the measurement and click the button to reset all the counters of this entry.

Rate control ability True for interfaces operating at speeds above 1000 Mb/s that support Rate Control through lowering the average data rate of the MAC sub-layer, with frame granularity, and false otherwise.

Rate control status The current Rate Control mode of operation of the MAC sub-layer of this interface.

InBadPkts It is the sum of all bad ethernet frames received at this interface.

Filtered It is the sum of lengths of all filtered Ethernet frames at this port.





Click the button to reset all the counters of all the entries.

11.1.2 SLAClick the SLA tab to view the values of the SLA counters at each Service ID (see Figure 190).

Figure 190 SLA view

Click to get the latest updated measurements.

Select one entry of the measurement and click the button to clear the entry.

11.2 Performance

11.2.1 G.826Click the G.826 tab to view the performance statistics related to E1/T1/J1 signal, the monitoring time interval includes 15-minute and 24-hour.

Figure 191 - G.826 15mins current view.


Service index An unique ID defined by the user, and to be referred by a CESoP service.

Service number Locally unique index of the SI.

Green pkts Number of packets below CIR.

Total pkts Total number of packets.

Table 87 SLA counters


187


Figure 191 G.826 15 mins current view

Figure 192 - G.826 24 hours current view.

Figure 192 G.826 24 hours current view

Figure 193 - G.826 16x15 mins history view.

Figure 193 G.826 16x15 mins history view

Figure 194 - G.826 1x24 hours history view.



Figure 194 G.826 1x24 hours history view

The following parameters are measured in G.826 tab.


11.2.2 Ethernet PortClick the Ethernet Port tab to view the performance measurements of the Ethernet ports, the monitoring time interval includes 15-minute and 24-hour.


Port The interface number.

Interval number For 16 * 15mins history, a number between 1 and 16, where 1 is the most recently completed 15-minute interval and 16 is the 15-minute interval completed 3 hours and 45 minutes prior to interval 1. For 1 * 24 Hours, the number is 1.

Elapsed seconds The time of monitoring.

Valid data This variable indicates if the data for this interval is valid.

ESs The number of Errored Seconds.

SESs The number of Severely Errored Seconds.

SEFSs The number of Severely Errored Framing Seconds.

UASs The number of Unavailable Seconds.

EB The number of Errored Block.

BBE The number of Background Block Error.

ESR The rate of Errored Seconds.

SESR The rate of Severely Errored Seconds.

BBER The rate of Background Block Error.

Table 88 G.826 15min current counters


189


Figure 195 - PM 15 mins current view.

Figure 195 PM 15 mins current view

Figure 196 - PM 24 hours current view.

Figure 196 PM 24 hours current view

Figure 197 - PM 16x15 mins history view.

Figure 197 PM 16x15 mins history view

Figure 198 - PM 4x24 hours history view.

Figure 198 PM 4x24 hours history view



The following statistics are measured in Ethernet Port tab.


11.2.3 Ethernet Service

Figure 199 Ethernet Service view

11.2.3.1 SwitchClick the Switch tab to view the PM enable / disable setting for each Ethernet Service ID, see Figure 199.


Port The interface number.

Valid data This variable indicates if the data for this interval is valid.



In dropped pkts Sum of CRC Align Errors, Fragments, In Errors, In Unknown Protos, Undersize Pkts, Oversize Pkts.

Out dropped pkts Sum of Out Errors, Out Discards.

In good pkts Sum of In Ucast Pkts, In Broadcast Pkts, In Multi-cast Pkts.

Out good pkts Sum of Out Ucast Pkts, Out Broadcast Pkts, Out Multicast Pkts.

In octets The total number of octets received on the inter-face, including framing characters.

Out octets The total number of octets transmitted out of the interface, including framing characters.

Table 89 Ethernet Port current counters


191


Click button to get the latest updated measurements.

To enable a PM for a certain service ID, select the service entry, click button to enable the PM statistics of the service.

To disable a PM for a certain service ID, select the service entry, click button to disable the PM statistics of the service.

11.2.3.2 Ethernet Service PerformanceClick the Ethernet Service Performance tab (see Figure 200) to view the performance measurements of the Ethernet services. Only the services which the Service PM Enable are set to enabled in Switch view are showing in this view.

Figure 200 Ethernet service performance view

The following statistics are measured in Ethernet Service Performance tab.


Service index An unique ID defined by the user, and to be referred by a CESoP service.


Interval number For 16 * 15mins history, a number between 1 and 16, where 1 is the most recently completed 15-minute interval and 16 is the 15-minute interval completed 3 hours and 45 minutes prior to interval 1. For 4 * 24 Hours, a number between 1 and 4, where 1 is the most recently completed 24 hours interval and 4 is the 4 hours interval completed 72 hours prior to interval 1.

Valid data This variable indicates whether the data for this interval is valid.


StatIng pkts The number of total frame.

StatIng pkts green The number of green frame.

Table 90 Ethernet service counters




11.2.4 PW

Figure 201 PW overview

11.2.4.1 SwitchClick the Switch tab to view the PM enable / disable setting for each PW, see Figure 201.


To enable a PM for a certain PW, select the service entry, click button to enable the PM statistics of the PW.

To disable a PM for a certain PW, select the service entry, click button to disable the PM statistics of the PW.

11.2.4.2 PW PerformanceClick the PW Performance tab to view the performance measurements of the pseudo wires (see Figure 202), the monitoring time interval includes 15-minute and 24-hour.

StatIng bytes The number of total octet.

StatIng bytes green The number of green octet.


Table 90 Ethernet service counters (Cont.)


193


Figure 202 PW performance view

The following statistics are measured in PM 15mins Current / PM 24 Hours Current and PM 16x15 mins History / PM 1x24 Hours History tabs.


11.2.4.3 TDMoP PerformanceClick the TDMoP Performance tab to view the performance measurements of the TDMoP (see Figure 203), the monitoring time interval includes 15-minute and 24-hour.


PW index The pseudo wire index.




Received pkts High-capacity counter for number of packets received by the PW (from the PSN) during the interval.

Received bytes High-capacity counter for number of bytes received by the PW (from the PSN) during the interval.

Transmitted pkts High-capacity counter for number of packets for-warded by the PW (from the PSN) during the inter-val.

Transmitted bytes High-capacity counter for number of bytes for-warded by the PW (from the PSN) during the inter-val.

Table 91 PW performance counters



Figure 203 TDMoP performance view

The following statistics are measured in TDM And CET 15mins Current / TDM And CET 24 Hours Current and TDM And CET 16x15mins History / TDM And CET 1x24 Hours History tabs.




Elapsed seconds The duration of a particular interval in seconds.

Lost pkts The number of missing packets.

ReOrdered pkts The number of packets detected out of sequence but successfully reordered.

Buffer underruns The number of times a packet needed to be played out and the jitter buffer was empty.

Out of sequence pkts The number of packets detected out of order that could not be re-ordered or could not fit in the jitter buffer.

Malformed pkts The number of packets detected with unexpected size or bad headers' stack.

Stray pkts The number of stray packets.

Multiple pkts The number of multiple packets.

ESs The number of Errored Seconds.

SESs The number of Severely Errored Seconds.

UASs The number of Unavailable Seconds.

Buffer Overruns This counter is incremented every time the jitter buffer overruns its capacity.

Table 92 TDMoP performance counters


195



g When there are two IDUs consisting of dual-IDU configuration, all the port related per-formance information will display the statistics of two IDUs, where the main IDU with the name of IDU-A, protection with the name of IDU-B.

11.2.5 OAM

Figure 204 OAM overview

11.2.5.1 SwitchClick the Switch tab to view the PM enable / disable setting for each OAM service, see Figure 204.


To enable a PM for a certain OAM service, select the service entry, click button to open the window as Figure 205. Set the parameters MD Id, MA Id and MEP

Id, click the button to enable the PM statistics.

Figure 205 OAM service PM enable window



To disable a PM for a certain OAM service, select the service entry, click button to disable the PM statistics.

11.2.5.2 OAM PerformanceClick the PW Performance tab to view the performance measurements of the OAM services (see Figure 206), the monitoring time interval includes 15-minute and 24-hour.

Figure 206 OAM performance view

The following statistics are measured in OAM PM 15mins Current / OAM PM 24 Hours Current and OAM PM 16x15 mins History / OAM PM 4x24 Hours History tabs.


Service index The OAM service index.


MD index Index of the MD.

MA index Index of the MA.

MEP id OAM MEP identifier.




Pkts loss near end This object contains the near-end frame-loss value.

Pkts loss far end This object contains the far-end frame-loss value.

Delay TM min This object contains the minimum value of frame-delay.

Delay TM max This object contains the maximum value of frame-delay.

Table 93 OAM performance counters


197



Delay avg Average delay measured for a two-way delay measurement transaction.


Table 93 OAM performance counters (Cont.)


Operate & MaintainMaintenance

12 MaintenanceThe Loopback Testing function is available to the users for daily operation mainte-nance of the network (see Figure 207).

Figure 207 Maintenance overview

12.1 Loopback testingLoopback is used to test the network connection and diagnose the network problem. For FPFM200, the pseudo-wire circuits and all the physical interfaces, i.e, TDM, SFP, GE ports, can be set as the loopback interfaces.

For TDM connection testing, there are two types of loopback to be used for the user:

– TDM local loopback– TDM remote loopback

For Ethernet connection testing, only the local loopback is possible.

Click to get the latest updated information.

Create a LoopbackTo create a new loopback line, follow the steps below:


Figure 208 Create a loopback window


199

Operate & Maintain Maintenance

There are two options in Loopback type:

– TDM local self test LIU - When enabled, the ingress E1/T1/J1 data stream is regenerated, re-timed and looped back to the egress.

– TDM remote loopback LIU - When enabled, the E1/T1/J1 data stream recovered from the CESoP receiver function is forwarded to the LIU; the stream is HDB3 coded and sent to the pulse shaper; then the signal is looped back (analog loop), regenerated, re-timed and forwarded back to the CESoP transmitter function.

For Release Time(s), if it is set to a value from 1100 (11 seconds) onwards the new time duration is used.

2 Select the loopback Interface, Loopback type and set the Release time in seconds.

3 Click to confirm the settings. The new loopback is created successfully.

Delete a LoopbackTo delete an existing loopback line, follow the steps below:

1 Select the loopback line entry to be deleted in Figure 207.

2 Click the button, then a confirmation message ‘Are you sure to delete them (it)?’ pops up.

3 Click the button to delete it, or click the button to withdraw the dele-tion.


Operate & MaintainSecurity

13 SecurityThe Security interface is different between the SNMP version 2C and SNMP version 3. Security interface in SNMP version 2C and Security interface in SNMP version 3 are descripted respectively in this section.

13.1 Security interface in SNMP version 2CIn Security tab (see Figure 209), there are three tabs of parameter group.

– V2 user management– SNMP version– Account log

Figure 209 Security overview

13.1.1 V2 user managementThree different user accounts can be created in V2 User Management setting:

– admin– readonly– readwrite

Figure 210 Security setting

g For the default User/Password settings, please contact Nokia Siemens Networks Tech-nical Support.

To reset the password, follow the steps below:


201

Operate & Maintain Security

1 Select the type of user account from the drop-down list, i.e., Admin, ReadOnly, or ReadWrite.

2 Key in the New Password, make sure it is between 6 to 12 characters.

3 Re-key in the new password to Confirm New Password.

4 Click the to apply the changes.

g Only admin user has the privilege to modify password.

When updating the password for admin user, the message ‘Your password has been changed, you need to relogin the system, system will exit!’ pops up. Admin user needs to relogin the system with the new password.

13.1.2 SNMP versionIn SNMP Version view, the SNMP version is shown as in Figure 211. The current SNMP version is SNMP v2C, it can be upgraded to SNMPv3.

Figure 211 SNMP version view


Upgrade to SNMP V3

Figure 212 SNMPv3 view



g SNMPv3 upgrade should be done with proper license.

To upgrade the SNMP version to SNMPv3, follow the steps below:

1 Select SNMP version as versionv3, the view is changed to Figure 212.

2 Select the SNMP mode as Light / Strong.

g Light Mode: SNMPv2C / SNMPv3 are available, Telnet / Ftp / Http / SSH / SFTP are supported.

Strong Mode: only SNMPv3 is available, only SSH / SFTP are supported.

3 Click the button to open the Choose Security Pack File window as in Figure 213.

Figure 213 Choose security pack file window

4 Select the Security Pack file and click the button to upgrade.

5 The confirmation message ‘This operation will cause FirstMile cold reboot and

WebLCT relogin. Are you sure to continue?’ pops up. Click the button.

6 The message ‘Please wait for a moment while upgrading SNMP’ pops up.

7 The message ‘Upgrade SNMP to v3 completed! Your SNMP version has been changed, you need to relogin the system and system will exit!’ pops up. Click the

button.

For the Security interface in SNMPv3, refer to Security interface in SNMP version 3.


203


13.1.3 Account logIn Account Log view (see Figure 214), there are two tabs of parameter group:

– Account log threshold– Account log

Figure 214 Account log overview

– Account log thresholdIn Account Log Threshold view (see Figure 214), the parameters of account log threshold are displayed as in Table 94.

Click to get the latest updated information.To update the settings, fill in the values of First alarm threshold / Max records and

Second alarm threshold / Max records, and click the button to apply the updates.

– Account logIn Account Log view (see Figure 215), the properties of account log are listed in Table 95.


Max records number The maximum account log size which is set default to 120.

First alarm threshold / Max records The first threshold for the notification alarms to be sent out when the log dimension exceeds it. The default value is 70%.

Second alarm threshold / Max records

The second threshold for the notification alarms to be sent out when the log dimension exceeds it. The default value is 70%.

Table 94 Account log threshold parameters



Figure 215 Account log view


To clear the account log, click the button to clear the entries.

To export the account log, click the button to open the Save window as Figure 216. The account log can be saved in .xml file.


User name User name of the successful log action.

IP address IP address of the user.

Action Log action type (either login, logout or change password).

Access flavour Protocol type.

Date & Time Date and time of the log action.

Table 95 Account log parameters


205


Figure 216 Save file window

13.2 Security interface in SNMP version 3In Security tab (see Figure 217), there are three tabs of parameter group.

– SNMPv3 user management– SNMP version– Account log

Figure 217 Security overview

13.2.1 SNMPv3 user managementIn SNMPv3 User Management tab (see Figure 217), there are three operations can be applied to user accounts: Create, Delete and Modify.




– Create

Click the button to open the new account creation window as Figure 218.

Figure 218 Add user window

To add a new user, enty the User Name, Password and select the Group type from

admin / readonly / readwrite. And click the button to apply the creation.

– DeleteTo delete a user account, select the user account entry in the view, click on

button, there is a warning message ‘Are you sure to delete them (it)?’

pops up, click on button to proceed the deletion.

– Modify

To modify a user account setting, select the user account entry, click on button to open the Modify User window as


207


Figure 219 Modify user window

To reset the password or group type, follow the steps below:1 Select the type of user account from the drop-down list, i.e., Admin, ReadOnly,

or ReadWrite.2 Key in the new Password, make sure it is between 6 to 12 characters.3 Re-key in the new password to Confirm password.

4 Click the to apply the changes.

13.2.2 SNMP versionIn SNMP Version view, the SNMP version is shown as in Figure 220. The current SNMP version is SNMPv3, can not do any upgrade action.

Figure 220 SNMP version view




g Light mode: This mode is compatiable, both support SNMPv2C and SNMPv3.

Strong mode: This mode only supports SNMPv3.

13.2.3 Account logIn Account Log view (see Figure 221), there are two tabs of parameter group:

– Account log threshold– Account log

Figure 221 Account log overview

– Account log thresholdIn Account Log Threshold view (see Figure 221), the parameters of account log threshold are displayed as in Table 96.


209


Click to get the latest updated information.To update the settings, fill in the values of First alarm threshold / Max records and

Second alarm threshold / Max records, and click the button to apply the updates.

– Account logIn Account Log view (see Figure 222), the properties of account log are listed in Table 97.

Figure 222 Account log view


Max records number The maximum account log size which is set default to 120.

First alarm threshold / Max records The first threshold for the notification alarms to be sent out when the log dimension exceeds it. The default value is 70%.

Second alarm threshold / Max records

The second threshold for the notification alarms to be sent out when the log dimension exceeds it. The default value is 70%.

Table 96 Account log threshold parameters




To clear the account log, click the button to clear the entries.

To export the account log, click the button to open the Save window as Figure 223. The account log can be saved in .xml file.

Figure 223 Save file window


User name User name of the successful log action.

IP address IP address of the user.

Action Log action type (either login, logout or change password).

Access flavour Protocol type.

Date & Time Date and time of the log action.Table 97 Account log parameters

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012. FiMi200 Operate & Maintain.pdf