Capitulo III PSS Procedimientos de Pruebas Stand Alone

CAPITULO III Pag.1 1830PSS-32/36/64

Capitulo III 1830 PSS Procedimientos de pruebas

Stand Alone


Pruebas Stand Alone

Refer to the Photonic Service Switch 36 (PSS-36) | Release 5.1.0

Installation and System Turn-up Guide PAGE

Optical Power Test 7-2

Perform Receiver Sensitivity Test 7-5

Optical Port Transmission Test (daisy chain test) 7-10

Test FLC Redundancy 7-15

Test MTX Redundancy 7-17


Equipo de prueba requerido

Quantity Description Comments

1 SDH/SONET/Ethernet Analyzer JDSU 6000 or equivalent

1

Optical power meter

Included in kit TK-0665B

Range: 35 ... +20dBm Wavelength: 850nm/1310nm/1550nm - Adaptors based on the project specs: LC, SC, ST, etc.

1

VOM Multimeter

To be used for measuring power supply voltages, grounding

tests, etc.

1

Optical Visual Inspection and

cleaning tool kit

Alcatel-Lucent tool kit. Part Number: TK-0665B

1

Adjustable optical attenuator

To be used for measuring the receiver sensitivity

- Adaptors based on the project specs: LC, SC, ST, etc.

1 Set of Fixed LC Optical

Attenuators (LBO)

To be used for optical test loops or for testing the individual

ports.

LBO size and quantity based upon the SFP, XFP specifications

and project requirements.

Be sure to take into consideration the SDH/SONET test set and

the customer fiber distribution panels for connector types

other than LC.

Be sure to exercise proper ESD and Fiber Handling procedures when

working with any equipment. Test equipment must meet calibration

requirements.


Prueba de OPTICAL POWER


Prior to performing this task, all used optical ports must be clean

Test Equipment Setup

This figure illustrates a possible test setup.

The number and type of optical interfaces

used depends on the customer

configuration.

The OP Pack could be a fixed optical port

on a module or a pluggable module such as

a SFP or XFP.

Required equipment

Prior to performing this task, the following

equipment must be available:

1. Optical power meter

Range: 35 ... +20dBm Wavelength: 1310nm/1550nm 2. ESD wrist strap.

3. TK-0665B Fiber Test/Cleaning Kit


NOTICE

Destruction of the power meter caused by a too high input power

Connecting the optical power meter with a transmit power exceeding the maximum power limit, will cause the destruction of the power meter, as the input power is then too high.

The supported maximum optical power limit of the optical power meter must be greater than the maximum mean launched power of the measured optical circuit pack to avoid damage.


Example Breakdown:

STM-64/OC-192/OTM-0.2 (I-64.1/SR-1/P1I1-2D1), 10GBASE-LR/LW

ETSI / ANSI / OTN ETSI ANSI OTN GIGE

1 = 1310nm, 2 = 1550nm


Instrucciones:

Identify the SFP and XFP modules from their part numbers and complete the chart below using the Alcatel-Lucent 1830 Photonic

Service Switch Release 5.1.0 Product Information and Planning Guide, Chapter 10, Technical Specifications, Transmission

Parameters).

OPTICAL INTERFACE TRANSMISSION PARAMETERS

PART#

OPTICAL

RATE

WAVE

LENGTH

LAUNCH (dBm) RCV (dBm) ATTENUATION

MIN MAX MIN MAX RANGE (dB)


Instrucciones Proceed as follows to check the mean launched power:

1. Clean the output port to be tested (see JDSU IBYC/IEH 610, SECTION 162).

2. Connect the optical power meter to that port.

NOTE: The optical power meter must be set to the appropriate wavelength range (refer to the Alcatel-Lucent 1830 Photonic Service Switch Release 5.1.0 Product Information

and Planning Guide, Chapter 10, Technical Specifications, Transmission Parameters).

3. Measure the mean launched power at the connected port and enter the

measured value in the table provided BELOW.

4. Check that the measured value is within the range shown in the Alcatel-Lucent

1830 Photonic Service Switch Release 5.1.0 Product Information and Planning

Guide, Chapter 10, Technical Specifications, Transmission Parameters.

5. Repeat Step 1 to Step 4 for all optical ports.


OPTICAL PACK/PORT AID

MODULE/PORT OPTICAL

INTERFACE TYPE

WAVE LENGTH

(nm)

EXPECTED TX PWR

RANGE

MEASURED TX PWR

(dBm)


Prueba de Sensibilidad del Receptor


Test setup

This figure illustrates a possible test

setup. The number and type of optical

interfaces used depends on the customer

configuration.

Determine the A1 and A2 attenuators by

completing the Optical Specs Chart. A1

A2

OPTICAL TEST SET (SONET/ETH) OPTICAL PACK

MODEL

WAVE

LENGTH

MEASURED

TX PWR

MAX RX

PWR TYPE

WAVE

LENGTH

MEASURED

TX PWR

MAX RX

PWR

MIN RX

PWR

A1 ATTENUATOR

A2 ATTENUATOR


NOTICE

Destruction of the detector diodes caused by too high an input power

Connecting the input ports of optical circuit packs with a transmit power exceeding the maximum overload values (refer to the Alcatel-Lucent 1830 Photonic Service Switch Release 5.0 Product Information and Planning Guide) will cause the destruction of the detector diodes, as the input power is then too high.

Where an overload has been detected replace the existing LBO by an appropriate one (see appendix A, section Replacing LC-type LBOs p. A-24).


Before you begin

Prior to performing this task, you must:

Have a valid user login and password

Be connected to the subject NE

Have proper User Community Authorization Level to perform this task

Logged in to the NE

Checked that all used optical ports are clean (JDSU IBYC).

Required equipment

The following equipment is required to perform this task:

Alcatel-Lucent 1830 PSS ZIC PC (Your Laptop).

CAT5 crossover LAN cable with RJ-45/RJ-45 connectors.

Test equipment listed at the beginning of this chapter.


Instructions - This test verifies that the receiver sensitivities of all optical interfaces are within

specification.

1. Connect an SDH/SONET analyzer to a second optical port and select 2 23-1 as test pattern.

2. In the Alcatel-Lucent 1830 PSS ZIC selection tree select CrossConnection.

Then select Create Cross Connections, either by selecting Action from the main menu bar or by using the context menu

opened with the right mouse button.

Result: The Alcatel-Lucent 1830 PSS ZIC Create Cross Connections window opens.

3. Click the Wizard button.

Result: The Alcatel-Lucent 1830 PSS ZIC Connection Wizard window opens

4. In the field Connection Type select 2-Way.

5. In the facility area populate the respective fields with the needed facilities.

A transmission facility may be one of the following (both for unidirectional and bidirectional transmission):

In OTN networks:

ODU1

ODU2

Result: A confirmation window opens, stating that retrieval of cross-connection may take some time.


6. Click Apply.


7. Select the newly created cross-connection.

Result: The current data of the cross-connection are displayed.

8. In the field Display Options check the check box Protection Parameters.

Result: All protection parameters are displayed.

9. Select NORM as Output Mode in the Source to Destination and Destination to Source group boxes.

10. Type the Circuit ID, a character string of 0 to 36 characters, for the cross-connection in the Circuit Name field.

11. Click the Apply button to apply your settings and confirm the resulting message by clicking Yes.

12. Click Close.

13. Increase attenuation until a BER of 1x10-10 is displayed on the SDH/SONET analyzer for about two minutes. It saves

time to initially set the variable optical attenuator close to the MIN value of the receiver sensitivity range.


14. Measure the optical power (= receiver sensitivity) at the output port of the optical attenuator and note the value.

Important! The optical power meter must be set to the appropriate wavelength range (refer to the Alcatel-Lucent 1830 Photonic Service Switch Release 5.0 Product Information and Planning Guide).

15. Check that the measured value is within the range shown in the Alcatel-Lucent 1830 Photonic Service Switch Release

5.0 Product Information and Planning Guide.

16. In the Alcatel-Lucent 1830 PSS ZIC selection tree select CrossConnection. Then select Manage Cross Connections,

either by selecting Action from the main menu bar or by using the context menu opened with the right mouse

button.

Result: The Alcatel-Lucent 1830 PSS ZIC Manage Cross Connections window opens.

17. Select the cross-connection.

18. Click Delete.

19. Click Close.

20. Repeat Step 2 to Step 19 for all optical ports.

End of Steps


OPTICAL PACK/PORT

AID MODULE/PORT TYPE

WAVE

LENGTH (nm)

MEASURED RX

SENSITIVITY


Prueba de transmisin de los Puertos pticos


NOTICE

Destruction of the detector diodes caused by too high an input power

Connecting the input ports of optical circuit packs with a transmit power exceeding the maximum overload values (refer to the Alcatel-Lucent 1830 Photonic Service Switch Release 5.0 Product Information and Planning Guide) will cause the destruction of the detector diodes, as the input power is then too high.

Where an overload has been detected replace the existing LBO by an appropriate one (see appendix A, section Replacing LC-type LBOs p. A-24).


Test setup

This figure illustrates a possible test setup.

The number and type of optical interfaces

used depends on the customer

configuration.

Determine the A1 and A2 attenuators by

completing the Optical Specs Chart below.

A1

A2

OPTICAL TEST SET (SONET/ETH) OPTICAL PACK (OP)

MODEL

WAVE

LENGTH

MEASURED

TX PWR

MAX RX

PWR TYPE

WAVE

LENGTH

MEASURED

TX PWR

MAX RX

PWR

MIN RX

PWR

A1 ATTENUATOR

A2 ATTENUATOR

A A A A

A Insert attenuators based upon Optical Power Tests


Note:

The above diagram shows the test set and fiber loops connected* directly to the PSS-36/64.

We will follow this setup in the lab. Customer sites will have a Fiber Distribution Panel. The test set should be connected to the FDP or LGX. Also, the fiber loops and attenuators should be connected at the FDP.

The attenuators ordered for testing should match the connector types at the FDP/LGX.

Cable run tests from the equipment to the FDP should verify that the TX and RX ports are cabled correctly.

This is accomplished by making TX measurements with a power meter at the FDP. This is different from the Optical Power Tests performed earlier. The previous test used

a known good fiber jumper with a known loss. J(DSU equipment in the TK-0665B kit has the tools to perform the proper setup.)

When we take a power measurement at the FDP, we are verifying that the cable from the equipment to the FDP/LGX is good (minimal power loss and connected to the correct

port).

When we insert the attenuator at the FDP, we want to make sure that the loop clears the LOS alarm on the correct port. Verify one port at a time.

At this time we also verify that the fiber cables are labeled correctly. * Clean all fibers, attenuators, bulkheads, etc. immediately before making any connections.


Before you begin


Have a valid user login and password

Be connected to the subject NE

Have proper User Community Authorization Level to perform this task

Logged in to the NE

Checked that all used optical ports are clean (JDSU IBYC).

Required equipment

The following equipment is required to perform this task:

Alcatel-Lucent 1830 PSS ZIC PC (Your Laptop).

CAT5 crossover LAN cable with RJ-45/RJ-45 connectors.

ESD wrist strap

Test equipment listed at the beginning of this chapter.


Procedure - Proceed as follows to perform the port transmission test:

1. Establish a test setup as shown above.

NOTE: The analyzer should be connected to a port with the lowest optical port rate (excluding the GE1SX/4, this

might be 2.5G).

2. In the Alcatel-Lucent 1830 PSS ZIC selection tree select Cross-Connection to set up the first cross-

connection..

Then select Create Cross Connections, either by selecting Action from the main menu bar or by using

the context menu opened with the right mouse button.


3. Click the Wizard button.

Result: The Alcatel-Lucent 1830 PSS ZIC Connection Wizard window opens.

4. In the field Connection Type select 1-Way.


5. In the facility area populate the respective fields with the needed facilities. A transmission facility may

be one of the following (both for unidirectional and bidirectional transmission):

In OTN networks:

ODU1

ODU2

Result: A confirmation window opens, stating that retrieval of cross-connection may take some time.

6. Click Apply.


7. Select the newly created cross-connection.

Result: The current data of the cross-connection are displayed.

8. In the field Display Options check the check box Protection Parameters.

Result: All protection parameters are displayed.

9. Select NORM as Output Mode in the Source to Destination and Destination to Source group boxes.


10. Type the Circuit ID, a character string of 0 to 36 characters, for the cross-connection in the Circuit

Name field.

11. Click the Apply button to apply your settings and confirm the resulting message by clicking Yes.

12. Repeat Step 2 to Step 13 for all the other required cross-connections according to the test setup.

Important! In Step 2 use always the same cross-connection rate!

13. Before starting a signal transmission check that the optical output power of the SDH/SONET analyzer is

not too high. The allowed power input ranges for all optical circuit packs are given in the Alcatel-

Lucent 1830 Photonic Service Switch (PSS-64) Product Information and Planning Guide.

14. Start a signal transmission via the SDH/SONET analyzer for three minutes.

Result: No bit errors are present during this time.

15. Check that the measured value is within the range shown in the Alcatel-Lucent 1830 Photonic Service

Switch (PSS-64) Product Information and Planning Guide.


16. In the Alcatel-Lucent 1830 PSS ZIC selection tree select Cross-Connection. Then select Manage Cross Connections, either

by selecting Action from the main menu bar or by using the context menu opened with the right mouse button.

Result: The Alcatel-Lucent 1830 PSS ZIC Mange Cross Connections window opens.

17. Select the cross-connection.

18. Click Delete.

19. In the Alcatel-Lucent 1830 PSS ZIC System View, select Configuration Cross-Connection Delete to delete the established cross-connection.

Result: Screen 1 appears.

20. Click Finish to delete the cross-connection and confirm the resulting message by clicking Yes.

21. Repeat Step 18 to Step 22 for all the other cross-connections that have been established.

22. Click Close.

End of Steps


Ejercicio: Crear Cross Connections con Comandos TL1


Open a TL1DAT Session

Login using UID: USER05 and PID: ALCATEL+01

REMOTEIP is the IP address of your laptop.

SSH User: tl13082

IP Address of the NE

Port: 6084

Click "OK"


INPUT FORMAT

ENT-CRS-:[TID]:FROM,TO:[CTAG]::[CCT]:[CKTID=];

INPUT PARAMETERS

ODUk Value Description

{ODU0, ODU1, ODU2, ODU2E, ODU3, ODU3E2}

FROM/TO Value Description

ODUk----

ODU-1--- (Rack is always 1)

ODU0 GigE (Transparent mapping ODU0 Termination on a Multirate ANY Card)

ODU1 OC-48 (Transparent mapping ODU1 Termination on a 24XANYMR)

ODU2 OC-192 (Transparent mapping ODU2 Termination on a 10G ANY Multiport Card)

ODU2 10GigE (Transparent mapping ODU2 Termination on a 10G ANY Multiport Card)

ODU3 40G

CCT

1WAY

2WAY


TL1DAT files are stored in

D:\Documents and Settings\\TL1DAT\scripts

Script files have the file extention .cmd (example: myscript.cmd)

An Example script file to enter the 1WAY cross connections for local testing:

ENT-CRS-ODU1::ODU1-1-1-18-1&&-23,ODU1-1-1-18-2&&-24:TESTER::1WAY:;

ENT-CRS-ODU1::ODU1-1-1-18-24,ODU1-1-1-18-1:TESTER::1WAY:;

RTRV-CRS-ODU1::ALL:TESTER;

An Example script file to delete the 1WAY cross connections for local testing:

DLT-CRS-ODU1::ODU1-1-1-18-1&&-23,ODU1-1-1-18-2&&-24:TESTER::1WAY:;

DLT-CRS-ODU1::ODU1-1-1-18-24,ODU1-1-1-18-1:TESTER::1WAY:;

RTRV-CRS-ODU1::ALL:TESTER;


Prueba de la redundancia de FLC


Prueba de la redundancia de FLC When to use

Use this procedure to test the standby FLC for correct function.

You can perform this for the following 1:1 protected modules:

ECHC (Controller cards in FLC slots of PSS-64 shelves)

FLC36EA (Controller cards in FLC slots in PSS-36 shelves)

Related TL1 commands

The following TL1 commands are related to this procedure:

ALW-SWDX-EQPT

INH-SWDX-EQPT

RTRV-DX-EQPT

SW-DX-EQPT

Before you begin


Have a valid user login and password,

Be connected to the subject NE,

Have proper User Community Authorization Level to perform this task.


Instrucciones

1. If both FLCs are equipped, wait until the standby FLC is aligned to the active one. On

a new installation, this could take up to 60 minutes depending of the system

configuration.

Additional information Usually FLC_A is the active one and FLC_B is the standby one.

This can be visually observed by the EPS LED:

solid green: active

solid amber: standby.

2. In the Alcatel-Lucent 1830 PSS ZIC selection tree select the part of equipment for

which you want to perform the switch via Equipment Rack 1 Shelf 1:PSSxx

3. Then select Switching Switch, either by selecting Action from the main menu bar or by using the context menu opened with the right mouse button.

Result: The Switch Duplex dialogue box is displayed.


4. Click Switch.

Result: A confirmation window opens.

5. Click Yes.

Result: Now an equipment protection switch from the currently active FLC to the standby FLC takes place. As a result, the formerly standby unit becomes active, and the formerly active unit becomes standby.

Important! If you perform a manual equipment protection switch for FLCs, the Alcatel-Lucent 1830 PSS ZIC will exit, and you will have to re-launch it once the equipment protection switch is complete.

Login with the ZIC to the new active FLC will be possible at least after 5 minutes.

No unexpected additional alarms must remain active.

END OF STEPS


Prueba de redundancia de la Matriz


Prueba de redundancia de la Matriz When to use

Use this procedure to test the standby MTX for correct function.

You can perform this for the following 1:1 protected modules:

MT1T9 (Matrix cards in MTX slots in PSS-64 shelves)

MT960C (Matrix cards in MTX slots in PSS-36 shelves)

Related TL1 commands

The following TL1 commands are related to this procedure:

ALW-SWDX-EQPT

INH-SWDX-EQPT

RTRV-DX-EQPT

SW-DX-EQPT

Before you begin


Have a valid user login and password,

Be connected to the subject NE,

Have proper User Community Authorization Level to perform this task.


Instructions

1. As precondition, both MT modules must be equipped. The protection group is created

automatically after the shelf is created.

Note: After first plug in of the standby MT, it could take up to 30 minute until the standby CRU is tracking the active CRU.

Additional information Usually MTX_A is the active one and MTX_B is the standby one.

This can be visually observed by the EPS LED:

solid green: active

solid amber: standby.

2. In the Alcatel-Lucent 1830 PSS ZIC selection tree select the part of equipment for

which you want to perform the switch via Equipment Rack 1 Shelf 1:PSSxx

3. Then select Switching Switch, either by selecting Action from the main menu bar or by using the context menu opened with the right mouse button.

Result: The Switch Duplex dialogue box is displayed.


4. Under Command Mode you can choose between NORM and FORCED.

5. Click Switch.

Result: A confirmation window opens.

6. Click Yes.

Result: Now an equipment protection switch from the currently active MTX to the standby MTX takes place. As a result, the formerly standby MTX becomes

active, and the formerly active MTX becomes standby.

The interruption time of TDM, OTN and Data is less than 5ms.

No unexpected additional alarms must remain active.

END OF STEPS


Restauracin de la Base de Datos del 1830 PSS


Restauracin de la Base de Datos del OCS

Upload DB from RFSDB to STBYDB

Use this procedure to upload a DB from a RFS to the Standby database of the NE.

NOTE: During the Backup, if the NE supports GMRE (GMPLS Routing Engine),

the GMRE configuration parameters are also invoked.

Redundant Systems (systems with redundant FLCs):

Due to the redundant system control, there is no interruption on the active FLC during the download, While the download procedure is running, the passive FLC is not available.

Stand-alone Systems (systems with a single FLC):

The FLC is not available while the download procedure is running, The NE cannot be controlled or managed during this time.



NOTE: For Command-Mode:

Forced In this mode:

Mismatch between the Primary and Secondary system parameters is ignored; Database restore is performed regardless

of backup Date and Time; Restore will proceed even if Secondary (Standby) FLC is in OOS-AU or OOS AUMA state.

Normal In this mode, the command is denied if:

Mismatch between the Primary and Secondary system parameters is present; Secondary FLC is in OOS-AU or OOS

AUMA state.



Forced In this mode:

Mismatch between the Primary and Secondary system parameters is ignored; Database restore is

performed regardless of backup Date and Time; Restore will proceed even if Secondary (Standby) FLC

is in OOS-AU or OOS AUMA state.

Normal In this mode, the command is denied if:

Mismatch between the Primary and Secondary system parameters is present; Secondary FLC is in OOS-

AU or OOS AUMA state.


Facilidades del 1830 PSS y Loopbacks del terminal


Facilidad OCH y loopback Terminal Loopback definition

A loopback is a troubleshooting test in which a signal is transmitted through a port unit to a set destination and then returned to the originating port unit. The transmitted and received signals are measured and evaluated by the user to

ensure that the received signal is accurate and complete when compared to the original signal. Information described

here about loopback operations is consistent for both OCS and WDM compounds, except where noted specifically for one

or the other.

Note that a loopback is a disruptive operation. It is normally employed as a diagnostic on a failed facility which must be taken out of service. Therefore it is not expected that an entity in loopback will function correctly as a member of a

protection group. Signal and overhead monitoring will be affected by an inserted signal (for example, AIS). In the case

of a terminal loopback, ingress monitoring is compromised for both transparent and nontransparent overhead modes

since the ingress signal is overwritten by the looped back signal at the interface.

Controlling loopbacks

Loopbacks can be enabled and disabled using Alcatel-Lucent 1350 OMS or Alcatel-Lucent 1830 PSS ZIC. See the

Alcatel-Lucent 1830 PSS User Provisioning Guide or the respective management system

documentation.

Loopbacks are possible on the following facility types:

OTN (OTU2, OTU2e, OTU3, OTU3e2)

SDH (STM-1, STM-4, STM-16, STM-64)

SONET (OC-3, OC-12, OC-48, OC-192)

Ethernet (1 Gb/s, 10 Gb/s)


Facilidad OCH y loopback Terminal Facility Loopback

Facility loopback is used to test the correct connection (fibering) between NEs including the involved interface ports. Facility loopbacks are supported for OTH, SDH/SONET, and Ethernet signals.

Facility loopbacks can be set up as follows:

Transparent: the signal transmitted in the downstream direction is not changed.

Forced AIS (Alarm Indication Signal) insertion (for OTH/SDH/SONET).

CSF (Client Signal Fail) insertion (for Ethernet).

Shut off the transmitter.

The incoming signal in the upstream direction is terminated during the loopback and an AIS is created.


Facilidad OCH y loopback Terminal Terminal loopbacks

In a terminal loopback, the signal that is about to be transmitted is connected to the associated incoming receiver. These loopbacks can be used to test signal paths through a network element. Depending upong card, terminal loopbacks

are supported for SDH/SONET, OTH (except uplink cards), and Ethernet signals.

Terminal loopbacks can be set up as follows:

Transparent, that means, the signal transmitted in the downstream direction is not changed.

Force AIS insertion (for SDH/SONET and OTH).

Insertion of a replacement signal (for Ethernet).

Unused signals in the incoming direction of transmission are automatically terminated.

Depending on the configuration of consequent actions, an appropriate consequent action signal is inserted into unused

signals in the outgoing direction of transmission, or the looped signal is continued in the outgoing direction of transmission.


CROSS-CONNECT GBE THROUGH A 40G


1830 PSS-36/64 CROSS-CONNECT GBE THROUGH a 40G

TS GBEODU0T-

1-1-3-1

ODU3TODU0-

1-1-71-1-1

ODU3T-

1-1-71-1

ODU3TODU3-

1-1-47-1

ODUPOOL GBE 40G

1) From tree, select the 2xANY 40G in slot 47.

2) DC on 01 (1-1-47-1) 3) DC on OTU3-1-1-47-1

4) RC on OTU3ODU3-1-1-47-1

Connect To ODUPOOL

Unprotected

5) AID: OTU3ODU3-1-1-47-1

XCTYPE: 2WAY

CIRCUIT ID:

CLICK Apply 6) From the tree select:

ODUPOOL

ODU3T

ODU3TLP-1-1-71-1..64

ODU3T-1-1-71-1

7) RC TIMESLOT#1 (ODU3TODU0-1-1-71-1-1

GoTo

Create Cross Connection

8) Create Cross Connection Screen

To Facility

Click the icon (Facility Browser)

9) Facility Browser Screen

Drill down to GBEODU0T-1-1-3-1

Click Apply 10) In the Cross Connection Screen, Click Apply

The ODUPOOL is used to make cross connections

from one Facility Line Rate to another through the

backplane.

It is also used to convert from one ODU type to

another (i.e. combine two DSU0 to one DSU1.

Like type Line Rates do not need to use the ODUPOOL.

The example to the right is showing the steps to cross

connect a GBE to one of the ports on a 40G card.

It starts by making a cross connect to the ODUPOOL

from port 01 on the 40G card in slot 47.

This connection creates 64 ODU3TODU0 connection

points to which a GBE (which is an ODU0) can be

connected.

In this example we are using the Facility Browser to

search for available facilities. In the next example, we

will demonstrate the Wizard to select a facility.

The diagram above shows the desired results.


CROSS-CONNECT STM-1 THROUGH A 10G


TS OC48ODU1T-

1-1-4-9

ODU2TODU1-

1-1-71-1-1

ODU2T-

1-1-71-1

OTU2ODU2-

1-1-46-5

ODUPOOL 24xANY 10xANY 10G

1) From tree, select the 10xANY 10G in slot 46.

2) DC on OTU2-1-1-46.

3) DC on OTU2-1-1-46-5.

4) RC on OTU2ODU2-1-1-46-5

Connect To ODUPOOL

Unprotected.

5) AID: OTU2ODU2-1-1-46-5

XCTYPE: 2WAY

CIRCUIT ID:

CLICK Apply 6) From the tree select:

ODUPOOL

ODU2T

ODU2TLP-1-1-71-1..64

ODU2T-1-1-71-1

7) Select TIMESLOT#1 and TIMESLOT#2

8) RC TIMESLOT#1 (ODU2TODU0-1-1-71-1-1

Assign

ODU1

9) RC TIMESLOT#1&2 (ODU2TODU1-1-1-71-1-1

GoTo

Create Cross Connection

10) Create Cross Connection Screen

Click the Wizard Button

11) Click the Button for the To Facility 12) Facility Browser Screen

Drill down to OC48ODU1T-1-1-4-9

Click Apply 13) In the Cross Connection Screen Click Apply

The example to the right is showing the steps to cross

connect an OC48 to one of the ports on a 10G card.

It starts by making a cross connect to the ODUPOOL

from port 5 on the 10G card in slot 46.

This connection creates 8 ODU2TODU0 TIMESLOTS.

We combine the two ODU2TODU0 in TIMESLOT#1 and

TIMESLOT#2 to one DSU1 which ends up as

TIMESLOT#1&2 (ODU2TODU1-1-1-71-1-1).

We then make a cross connection from the new

TIMESLOT#1&2 to the OC48 on port 9 in slot 4 24xANY,

(OC48ODU1T-1-1-4-9).

In this example, we will demonstrate the Wizard to

select a facility.

The diagram above shows the desired results.

TIMESLOT#1

TIMESLOT#2

1830 PSS-36/64 CROSS-CONNECT STM-1 THROUGH a 10G


1830 PSS-36/64 CROSS-CONNECT OC-48 THROUGH a 10G


1830 PSS Cambiando ODU POOL Port types


1830 PSS-36/64 tipos de puertos ODUPOOL Port Type 21 creates ODU0 Port Rates for the Timeslots.

This is the default action.

Port Type 20 creates ODU1 Port Rates and reduces the number of Timeslots.


1830 PSS-36/64 tipos de puertos ODUPOOL Port Type 21 creates ODU0 Port Rates for the Timeslots.


1830 PSS-36/64 tipos de puertos ODUPOOL Port Type 20 created ODU1 Port Rates for the Timeslots.

Notice that the number of Timeslots changed from 8 to 4.


Ejercicio: Crear Cross Connections con el ZIC


Ejercicio

Usando lo visto anteriormente, crear distintos tipos de Crossconexiones.

Capitulo III PSS Procedimientos de Pruebas Stand Alone

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Transcript of Capitulo III PSS Procedimientos de Pruebas Stand Alone