Multiple Application Platform MAP-200

Multiple Application Platform MAP-200 MAP-200 Optical Switch, mOSW-C1 Installation and User Guide 22112369-120 R000 Standard June 2016

MAP-200 Optical Switch mOSW-C1 Installation and User Guide Standard June 2016 Document Number 22112369-120 R000 Page 2

MAP-200 Optical Switch mOSW-C1 Installation and User Guide Page 3 June 2016 Document Number: 22112369-120 R000 Status: Standard

Contents Chapter 1: Document History ............................................................................................ 8

Chapter 2: About this Guide.............................................................................................. 9

Notice ......................................................................................................................................... 9 Purpose and Scope .................................................................................................................... 9 Assumptions ............................................................................................................................... 9 Copyright .................................................................................................................................... 9 Copyright Release .................................................................................................................... 10 Trademarks ............................................................................................................................... 10 Document Ordering Information ................................................................................................ 10 Terms and conditions ................................................................................................................ 10

Chapter 3: Safety & Compliance ...................................................................................... 11

Symbols used in this manual..................................................................................................... 11 General Safety .......................................................................................................................... 12 Labels ....................................................................................................................................... 13 Regulatory Compliance ............................................................................................................. 14 Calibration................................................................................................................................. 15 WEEE Directive Compliance ..................................................................................................... 16 CE Certificate ............................................................................................................................ 17 China RoHS Certificate ............................................................................................................. 18

Chapter 4: General Information ..................................................................................... 19

Key Features ............................................................................................................................ 19 Standard Accessories ............................................................................................................... 19 Theory of Operation .................................................................................................................. 20 Configurations ........................................................................................................................... 20

1CxN Configuration ............................................................................................................... 20 2DxN Configuration ............................................................................................................... 21 2ExN Configuration ............................................................................................................... 21 2Xx2 Configuration................................................................................................................ 22 Power Trim............................................................................................................................ 22

Chapter 5: Getting Started ............................................................................................. 24

Required Software .................................................................................................................... 24 Before Initializing and Operating the Unit .................................................................................. 24

Contents


Initial Inspection ........................................................................................................................ 24 Cleaning Instructions ................................................................................................................ 25

Cleaning the Equipment ........................................................................................................ 25 Cleaning Optical Connectors ................................................................................................. 25 Cleaning Jumper Connectors ................................................................................................ 27

Installing the mOSW-C1 into a MAP-200 Chassis ..................................................................... 28

Chapter 6: The mOSW-C1 Graphical User Interface (GUI) ............................................. 30

Initial Screen ............................................................................................................................. 30 Instrument Summary ................................................................................................................. 31

Instrument Summary View .................................................................................................... 31 1x2 and 2x2 GUI ....................................................................................................................... 31

Detailed View 1x2 Switch ...................................................................................................... 32 Detailed View 2x2 Switch ...................................................................................................... 33

C-Type GUI ............................................................................................................................... 33 D-Type GUI ............................................................................................................................... 34 E-Type GUI ............................................................................................................................... 35 Simplified Views ........................................................................................................................ 36

Simplified Instrument Summary View .................................................................................... 36 Other Simplified views ........................................................................................................... 37

Naming a Cassette ................................................................................................................... 38

Chapter 7: Updating the Firmware ................................................................................. 42

Updating the MAP-200 Firmware .............................................................................................. 42 Updating the mOSW-C1 Firmware ............................................................................................ 43

Chapter 8: Remote Commands ....................................................................................... 46

Definitions ................................................................................................................................. 46 SCPI Commands Command Tables ......................................................................................... 46

Common Commands ............................................................................................................ 47 User Commands ................................................................................................................... 48

Common SCPI Commands ....................................................................................................... 49 *CLS ................................................................................................................................. 49 *ESE ................................................................................................................................. 50 *ESE? ............................................................................................................................... 52 *ESR? ............................................................................................................................... 53 *IDN? ................................................................................................................................ 55 *OPC ................................................................................................................................. 56 *OPC? ............................................................................................................................... 57 *RST ................................................................................................................................. 58 *SRE ................................................................................................................................. 59 *SRE? ............................................................................................................................... 60 *STB?................................................................................................................................ 61 *TST? ................................................................................................................................ 63 *WAI .................................................................................................................................. 64 *SAV ................................................................................................................................. 65 *RCL ................................................................................................................................. 66

Common Application Commands .............................................................................................. 67 :SYSTem:ERRor? ............................................................................................................. 67 :BUSY? ............................................................................................................................. 68

Contents


:RESet............................................................................................................................... 69 :TEST? .............................................................................................................................. 70 :CONFig? .......................................................................................................................... 71 :INFOrmation? ................................................................................................................... 73 :LOCK ............................................................................................................................... 74 :LOCK? ............................................................................................................................. 75 LOCK:RELEase ................................................................................................................ 76 :DEVice:INFOrmation? ...................................................................................................... 77 :FAULt:SLOT?................................................................................................................... 78 :FAULt:DEVice? ................................................................................................................ 79 :STATus:DEVice? ............................................................................................................. 81 :STATus:RESet ................................................................................................................. 83 :ROUTe:CLOSe ................................................................................................................ 83 :ROUTe:CLOSe? .............................................................................................................. 84 :ROUTe:TRIM ................................................................................................................... 85 :ROUTe:TRIM? ................................................................................................................. 86 :ROUTe:WAVelength ........................................................................................................ 87 :ROUTe:WAVelength? ...................................................................................................... 88 :ROUTe:CHANnel:DEScription.......................................................................................... 89 :ROUTe:CHANnel:DEScription?........................................................................................ 90 :ROUTe:MONitor? ............................................................................................................. 91

Chapter 9: Specifications ................................................................................................ 92

mOSW-C1 Parameters ............................................................................................................. 92

Chapter 10: Technical Support ........................................................................................ 98

Chapter 11: Service ........................................................................................................... 99

Storing and Shipping ................................................................................................................. 99 Claims and Repackaging ...................................................................................................... 99 Packing Guidelines With Original Packaging ......................................................................... 99 Packing Guidelines Without Original Packaging .................................................................... 99 Returning Shipments to Viavi .............................................................................................. 100

Chapter 12: Glossary ....................................................................................................... 101

Figures


Figures Figure 1: MAP-200 mOSW Cassette Label: Side Panel ...................................................................... 13 Figure 2: MAP-200 mOSW Cassette Labels: Front Panel .................................................................... 13 Figure 3: mOSW Optical Switch ........................................................................................................... 19 Figure 4: 1CxN Configuration .............................................................................................................. 20 Figure 5: 2DxN Configuration ............................................................................................................... 21 Figure 6: 2Ex2 Configuration ............................................................................................................... 21 Figure 7: 2Xx2 Configuration .............................................................................................................. 22 Figure 8: Front Panel Optical Adapter .................................................................................................. 26 Figure 9: Connector cleaning (connector type can vary) ...................................................................... 27 Figure 10: Removing a Faceplate ........................................................................................................ 28 Figure 11: Inserting an Optical Cassette .............................................................................................. 29 Figure 12: Typical PTRIM impact for 1CxN with 24 ports or less .......................................................... 95 Figure 13: Typical PTRIM impact for 1CxN with more than 24 ports .................................................... 95

Tables


Tables Table 1: Safety Symbols ...................................................................................................................... 11 Table 2: mOSW-C1 M xN, N ≥ 4 Specifications ................................................................................... 92 Table 3: mOSW-C1 [1x2] and [2x2] Parameters .................................................................................. 96


Chapter 1: Document History

Document Number / Revision

Date Comment

22112369-120 R000 June 2016

Initial release with new number. Changed branding from JDSU to Viavi. Note that diagrams are not necessarily reflective of the company name change from JDSU to Viavi.

22021771 R000 March 2013 First release


Chapter 2: About this Guide

Notice Every effort was made to ensure that the information in this manual was accurate at the time of printing. However, information is subject to change without notice, and Viavi reserves the right to provide an addendum to this manual with information not available at the time that this manual was created.

Purpose and Scope The purpose of this guide is to help you successfully use the mOSW-C1 cassette. This guide includes task-based instructions that describe how to install, configure, use, and troubleshoot the mOSW-C1. Additionally, this guide provides a complete description of Viavi warranty, services, and repair information, including terms and conditions of the licensing agreement.

Assumptions This guide is intended for novice and intermediate users who want to use the mOSW-C1 effectively and efficiently. Viavi assumes that the user is familiar with basic telecommunication concepts and terminology.

Copyright © Copyright June 2016 Viavi Solutions Inc. All rights reserved. Viavi and the Viavi logo are trademarks of Viavi Solutions Inc. (“Viavi”). All other trademarks and registered trademarks are the property of their respective owners. No part of this guide may be reproduced or transmitted, electronically or otherwise, without written permission of the publisher.

About this Guide Copyright Release


Copyright Release Reproduction and distribution of this guide is authorized for US Government purposes only.

Trademarks Viavi is a trademark of Viavi Solutions Inc. in the United States and other countries. Microsoft, Windows, Windows CE, Windows NT, MS-DOS, Excel, Word and Microsoft Internet Explorer are either trademarks or registered trademarks of Microsoft Corporation in the United States and/or other countries. All trademarks and registered trademarks are the property of their respective companies.

Document Ordering Information This guide is a product of Viavi's Technical Information Development Department, issued as part of the MAP-200 suite of documents. The catalog number for this guide is 22112369-120 R000. It is distributed on the MAP-200 USB drive, 21127440, shipped with MAP-200 chassis and cassettes.

Terms and conditions Specifications, terms, and conditions are subject to change without notice. The provision of hardware, services, and/or software are subject to Viavi’s standard terms and conditions, available at www.viavisolutions.com/terms.

http://www.viavisolutions.com/terms


Chapter 3: Safety & Compliance

Symbols used in this manual The following symbols and messages can be marked on the unit. Observe all safety instructions that are associated with a symbol.

Table 1: Safety Symbols

Symbol Description

CAUTION See the user manual for instructions on handling and operating the unit safely. The procedure can result in serious damage to or destruction of the unit if not carried out following instructions for proper use.

ELECTROSTATIC DISCHARGE (ESD). See the user manual for instructions on handling and operating the unit safely.

WARNING: LASER SAFETY The procedure can result in serious injury if not carried out in proper compliance with all safety instructions. Ensure that all conditions necessary for safe handling and operation are met before proceeding.

WARNING The procedure can result in serious injury or loss of life if not carried out in proper compliance with all safety instructions. Ensure that all conditions necessary for safe handling and operation are met before proceeding.

Safety & Compliance General Safety


General Safety The MAP-200 system, including functional cassettes complies with CSA/UL/IEC 61010-1.

The following safety information must be observed whenever the unit is operated, serviced, or repaired. Failure to comply with any of these instructions or with any precaution or warning contained in this user manual is in direct violation of the standards of design, manufacture, and intended use of the unit. Viavi assumes no liability for the customer's failure to comply with any of these safety requirements.

WARNING To avoid the risk of injury or death always observe the following precautions before connecting the unit to power, during initialization and during operation of the unit: • Use only the type of power cord supplied with the unit. • Do not use the unit outdoors. • To prevent potential fire or shock hazard, do not expose the unit to

any source of excessive moisture. • Do not perform any operating or maintenance procedure that not

described in this user manual. All other repairs must be done by a qualified Viavi professional.

• Do not operate the unit with its covers or panels removed.

WARNING: LASER SAFETY To avoid the risk of injury always observe the following precautions before connecting the unit to power, during initialization and during operation of the unit: • Never look into the end of an optical cable connected to an optical

output device that is operating. Laser radiation is invisible, and direct exposure can severely injure the human eye.

• Turning off the power to the device does not always block the externally supplied radiation to the connector at the output of the unit.

• Do not perform any operating or maintenance procedure that not described in this user manual. All other repairs must be done by a qualified Viavi professional.

• Do not operate the unit with its covers or panels removed.

Safety & Compliance Labels


Labels

Figure 1: MAP-200 mOSW Cassette Label: Side Panel

Figure 2: MAP-200 mOSW-C1 Cassette Labels: Front Panel

Safety & Compliance Regulatory Compliance


Regulatory Compliance • The MAP-200, including functional cassettes complies to: CE requirement

EN61010-1:2001, UL61010-1 and CAN/CSA-C22.2 No.61010-1-04 (see CE certificate of compliance).

• The MAP-200 is in Installation Category (Over voltage Category) II under IEC 664. The unit is in the Pollution Degree 2 category under IEC61010-1 Safety Requirements for Electrical Equipment for Measurement, Control, and Laboratory Use and CAN/CSA-C22.2 No. 61010-1-04 Safety Requirements for Electrical Equipment for Measurement Control, and Laboratory Use, Part I: General Requirements.

Safety & Compliance Calibration


Calibration This product is shipped with a certificate of conformance. Calibration is not required.

Safety & Compliance WEEE Directive Compliance


WEEE Directive Compliance Viavi has established processes in compliance with the Waste Electrical and Electronic Equipment (WEEE) Directive, 2002/96/EC.

This product should not be disposed of as unsorted municipal waste and should be collected separately and disposed of according to your national regulations. In the European Union, all equipment purchased from Viavi after 2005-08-13 can be returned for disposal at the end of its useful life. Viavi will ensure that all waste equipment returned is reused, recycled, or disposed of in an environmentally friendly manner, and in compliance with all applicable national and international waste legislation.

It is the responsibility of the equipment owner to return the equipment to Viavi for appropriate disposal. If the equipment was imported by a reseller whose name or logo is marked on the equipment, then the owner should return the equipment directly to the reseller. Instructions for returning waste equipment to Viavi can be found in the Environmental section of Viavi’s web site at http://www.viavisolutions.com/en-us/corporate/about-us/policies-and-standards .If you have questions concerning disposal of your equipment, contact Viavi’s WEEE Program Management team at [email protected] .

http://www.viavisolutions.com/en-us/corporate/about-us/policies-and-standards

mailto:[email protected]

Safety & Compliance CE Certificate


CE Certificate

Safety & Compliance China RoHS Certificate


China RoHS Certificate


Chapter 4: General Information The MAP-200 mOSW Optical Switch is based on Viavi expanded beam and alignment technologies and exhibits low insertion loss (IL) and high return loss (RL).

It is available in single-switch configurations from 1x2 up to 1x64 and dual independent switch configurations from 1x2 up to 1x24 and 8 by 1x2.

An important element of an optical test bed, optical switches increase throughput by enabling time-saving automation, reduce uncertainty from repeated connector mating and maximizes the use of expensive testers.

Figure 3: mOSW Optical Switch

Key Features The key features include:

• Low insertion loss ≤ 0.7 dB

• Low polarization dependent loss ≤ 0.04 dB

• Wide wavelength range

• High return loss ≥ 62 dB

Standard Accessories • USB flash drive with

General Information Theory of Operation


o MAP-200 User’s Manual

o mOSW User’s Manual

• Certificate of Conformance

• Test Report

Theory of Operation Large channel count switches use precision motors to position input and/or output channels for selection. They have one or two input channels, and multiple output channels. The switch is bidirectional and so inputs and outputs are interchangeable.

Configurations

1CxN Configuration

0

3

21

4

N

..

A

Figure 4: 1CxN Configuration

The 1CxN configuration allows a single common input to be switched to any of the N outputs.

General Information Configurations


2DxN Configuration

0A

1B1A

0B

2A

NB

..

A2B

NA

B

Figure 5: 2DxN Configuration

The 2DxN configuration allows for mass reconfiguration of optical paths. It provides simultaneous connections of a bank of inputs to outputs. “A” input connects to “A” outputs only; “B” input connects to “B” outputs only.

2ExN Configuration

0

21

0

3

N

..

A4

.

B

Figure 6: 2Ex2 Configuration

The 2ExN configuration aligns any input with any output while other inputs are aligned to adjacent outputs.



2Xx2 Configuration

A

B

1

2

Figure 7: 2Xx2 Configuration

The 2Xx2 configuration allows a straight through input to output, A => 1 and B=> 2, or a crossover input to output, A => 2 and B => 1.

Power Trim Power Trim is a new option that can be selected with single-mode 1C versions with 4 or more output channels. It brings two new capabilities that are designed to simplify integration and remote trouble shooting.

• Bidirectional Power Monitor

The optical power is reported at the common port along with an indication of the transmission direction. The bi-directional power monitor automatically senses if the common is being used as an input or an output. In-line power monitors can greatly simplify remote trouble shooting in distant factories. Due to the hardware configuration, the bi-directional power monitor can report different values even when the optical source is the same. When a signal goes in from common a port (single channel), the reported power level is the power before the switch, that is the true power going into the switch. However, when signal goes in from multiple channel side, the reported power level is the optical power after the switch, that is it is the output optical power from the switch. The switch input power would be the reported power plus the IL of the switch on that channel. If the switch is operated under trimmed power (see the next bullet — “Loss Trim”), the input optical power can be significantly higher than what was reported by the GUI. The dynamic range of power monitor is about 65dB at 1550nm: from +10 dBm to -55 dBm. A wavelength should be set on GUI for better accuracy. Please note, power monitor option is not intended to accurately report optical power, an optical power meter is recommended if an accurate power measurement is required.

• Loss Trim

Through the use of a programmable Trim Index, the insertion loss of the connected optical path may be increased by up to 20dB. The trimming function is designed to simplify applications where general power levels need to be set, but do not require exact precision. The Power Trim option offers the flexibility of adjusting the input power level without using an additional



attenuator. There are 16 adjustable steps for switches with channel counts less or equal than 24 and 32 steps for switches with channel count higher than 24. Though it is a very useful tool, it is not intended for accurate power control. An attenuator is recommended in cases where the accurate power control is required.


Chapter 5: Getting Started

Required Software The mOSW-C1 requires MAP-200 software version 2.8.x or higher on the chassis.

Before Initializing and Operating the Unit Wear an anti-static wrist strap, and work in an electrostatic discharge (ESD)

controlled area.

Inspect the unit for any signs of damage.

If the contents are incomplete or damaged, immediately inform Viavi and, if necessary, return the unit as outlined in the Service chapter.

Keep the packaging.

Read the user’s manual thoroughly, and become familiar with all safety symbols and instructions to ensure that the unit is operated and maintained safely.

Initial Inspection

WARNING To avoid electrical shock, do not initialize or operate the unit if it bears any sign of damage to any portion of its exterior surface such as the outer cover or panels.

Check that the unit and contents are complete:

1. Inspect the shipping container for any indication of excessive shock to the contents, and inspect the contents to ensure that the shipment is complete.

2. Inspect the unit for structural damage that can have occurred during shipping.

3. Keep the packaging.

Getting Started Cleaning Instructions


4. Immediately inform Viavi and, if necessary, the carrier if the contents of the shipment are incomplete, if the unit or any of its components are damaged or defective, or if the unit does not pass the initial inspection.

Cleaning Instructions

WARNING • Never clean the unit when the power is turned on.

Cleaning the Equipment

Cleaning Procedure

1. Unplug the equipment from the line power.

2. Clean the enclosure with a cloth dampened with water.

3. DO NOT plug the unit to the line power until it is completely dry.

Cleaning Optical Connectors

WARNING: LASER SAFETY • Never clean the connectors when the unit is turned on.

CAUTION • Be sure the unit’s Universal Connector Adapter (UCA) and internal optical connectors are clean and undamaged. Connecting an optical connector to the unit when contaminated/dirty can cause significant damage to the unit’s optics.

Prerequisites

The following items are required for cleaning:

• Filtered compressed air or dusting gas

• Lint-free pipe cleaners or lint-free swab

• Lint-free towels

• Optical grade isopropyl alcohol or optical grade 200° ethanol (do not use rubbing alcohol, which contains 30% water)



Cleaning Procedure

1. Remove the two adapter mounting screws with the M2 Phillips screwdriver. Removing the adapter will expose the internal optical connector that is fastened to the base plate. The internal connector and base plate are mounted at the factory and should not have to be adjusted under normal operating conditions.

Figure 8: Front Panel Optical Adapter

2. Clean the internal cavity with a pipe cleaner and alcohol (a rotating motion will yield the best results). The adapter is a critical component that can provide highly reliable mating of optical connector, if properly maintained.

3. Gently wipe the back surface of the adapter to ensure a clear mating surface to the base plate.

4. Using the dusting gas or compressed air, blow the base plate and ferrule.

5. Apply optical grade isopropyl alcohol or optical grade ethanol to a lint-free towel/tissue. Clean the unit’s optical connector by gently rubbing the ferrule. Do not apply excessive pressure while rubbing to avoid scratching and pitting.

6. Wipe the ferrule with a dry lint-free towel/tissue.

7. Using the dusting gas or compressed air, blow the end of the ferrule and base plate.

8. To insert the adapter sleeve into the base plate, align the center axis of the two parts and make sure the alignment key mates with the alignment hole on the flat surface of the base plate. Once in position, fasten the two adapter mounting screws to secure the parts together.

9. All optical jumper connectors used to mate other equipment with the MAP-200 should be cleaned thoroughly. See the Cleaning Jumper Connectors section for further details.



Cleaning Jumper Connectors

CAUTION • Connecting damaged or dirty connectors to the unit can damage

the connectors on the unit. • Never force an optical connector. Some connectors have a

ceramic ferrule that can easily be broken.

WARNING: LASER SAFETY • Never clean the connectors when the unit is turned on.

Optical connectors need to be cleaned before use with the unit.

Prerequisites

The following items are required for cleaning:

• Filtered compressed air or dusting gas

• Lint-free pipe cleaners or lint-free swab

• Lint-free towels

• Optical grade isopropyl alcohol or optical grade 200° ethanol (do not use rubbing alcohol, which contains 30% water)

Cleaning Procedure

To clean the connectors:

1. Ensure that the unit is shut down (See source shut down).

2. Blow the sleeve with filtered compressed air.

Figure 9: Connector cleaning (connector type can vary)

3. Apply optical grade isopropyl alcohol or optical grade ethanol (do not use rubbing alcohol) to a small area of a lint-free towel and rub the end of the ferrule over the wet area.

4. Wipe the ferrule on a dry area of the lint-free towel.

Getting Started Installing the mOSW-C1 into a MAP-200 Chassis


5. Using the dusting gas or compressed air, blow the end of the ferrule.

6. Apply the alcohol or ethanol to a lint-free pipe cleaner or swab and wipe off the remaining parts of the connector.

7. With the other end of the pipe cleaner or swab, dry the areas cleaned.

8. Using the dusting gas or compressed air, blow the areas cleaned.

Installing the mOSW-C1 into a MAP-200 Chassis Cassettes can be installed in a chassis at anytime regardless of whether or not the chassis is powered. MAP-200 allows for hot-swapping, so the controller detects the presence and determines the type of cassette that is being added without affecting the communication with other cassettes. Each cassette has a unique ID, serial number, hardware version, and firmware version.

The cassettes are an element of the MAP. Cassettes implement a specific functionality which is directly applicable to optical instrumentation, testing, or measurement. Different types of instrumentation cassettes can reside in a single chassis and cassettes can be added in a plug and play manner.

Installation Procedure

Perform the following steps to install a cassette:

1. Remove a blanking plate with a flat-head screwdriver by applying downward pressure to the tab at the top of the blanking plate. Store the faceplates for future use.

Figure 10: Removing a Faceplate

2. Slide the cassette into the chassis.

3. Position latch to 45° and when the cassette cannot be pushed in further, push the latch shut to make the final contact or until the cassette face plate is flush with the controller.

Getting Started Installing the mOSW-C1 into a MAP-200 Chassis


Figure 11: Inserting an Optical Cassette

CAUTION • Use minimal force when sliding in the cassette during

installation. Pushing the cassette in too fast could damage the connector on the back plane.

• An optical cassette or blanking plate MUST be present on each slot to ensure proper airflow within the unit.


Chapter 6: The mOSW-C1 Graphical User Interface (GUI)

Initial Screen To access the controls for an mOSW-C1 cassette installed in the MAP-200, press or click on “Instrument Summary” on the home screen of the MAP-200 application.

The mOSW-C1 Graphical User Interface (GUI) Instrument Summary


Instrument Summary The Instrument Summary screen provides basic information for all of the intruments installed in the MAP-200.

To access more detailed information for a particular cassette press or click on the “Detailed” view icon: this will bring up a detailed view of the cassette.

Instrument Summary View

1x2 and 2x2 GUI The screenshot below shows 8 independent 1x2 switches in different states.

The mOSW-C1 Graphical User Interface (GUI) 1x2 and 2x2 GUI


Detailed View 1x2 Switch

The mOSW-C1 Graphical User Interface (GUI) C-Type GUI


Detailed View 2x2 Switch

C-Type GUI The C-type switch is the simplest configuration of the mOSW-C1. It has one (1) input and N outputs.

C-Type Detailed View

The screenshot below shows the GUI of the switch with the Power Trim option. You can access a simplified view of the GUI by pressing the “Simplified GUI” button.

The mOSW-C1 Graphical User Interface (GUI) D-Type GUI


D-Type GUI The D-type switch is a ganged input configuration of the mOSW-C1.

It operates like a 2x[1xN] with locked channel selection. Input A connects to A outputs only and input B connects to B outputs only.

The mOSW-C1 Graphical User Interface (GUI) E-Type GUI


E-Type GUI An E-type switch aligns any input with any output while other inputs are aligned to adjacent outputs. This screenshot highlights particular features of this view.

The mOSW-C1 Graphical User Interface (GUI) Simplified Views


Simplified Views

Simplified Instrument Summary View You can change the level of detail in the summary screen by selecting the “Simplified GUI” button in the upper right-hand corner of the detail screen of any casette except the 1x2 and 2x2 cassettes. When you come back to the “Instrument Summary” screen the cassette information panel will show a simplified view of its information.

The mOSW-C1 Graphical User Interface (GUI) Simplified Views


Other Simplified views Simplified views are available for any detailed view with a “Simplfied GUI” button in the upper right-hand corner. The graphic below shows the simplified view of the C-Type switch.

The mOSW-C1 Graphical User Interface (GUI) Naming a Cassette


Naming a Cassette The screenshots below illustrate the procedure for naming a cassette.

1. Press the “Aa” button on any “Detailed View”.



A “Cassette Label” view will appear.

2. Press the typing interface icon in the “Cassette Label” view.

A typing interface will appear.

3. Type the cassette name in the typing interface



4. The cassette name appears wherever appropriate in all views.




Chapter 7: Updating the Firmware

Updating the MAP-200 Firmware Follow this procedure to update the firmware on the MAP-200 Chassis. Note that the MAP-200 firmware update may also contain a new mOSW-C1 firmware image which must be upgraded separately. After updating the MAP-200 chassis, please refer to the procedure described in the “Updating the mOSW-C1 Firmware” section.

1. Download the latest firmware for the MAP-200 to your PC. The firmware is available on the MAP-200 resource page at http://www.viavisolutions.com/en-us/products/lab-and-manufacturing-test/optical-manufacturing-test/multiple-application-platform-map-200 .

2. Insert a formatted USB memory stick into your PC. It is recommended to have the memory stick formatted with FAT format.

3. Copy the .zip file that you downloaded from the web and save it on the USB memory stick.

4. Extract the content of the .zip file to the root directory of your USB memory stick.

NOTE: The MAP-200 controller expects the folder “MAP-200” to be on the root drive of the USB memory stick.

5. Remove the USB memory stick using the appropriate procedure for your PC.

6. Plug your USB memory stick into your MAP-200 platform.

7. Navigate to the settings screen.

8. In the setting screen select the upgrade tab.

9. Press the upgrade button.

The firmware upgrade will then take place and will take about 25 minutes. The upgrade may take longer if upgrading from an older version of MAP-200

http://www.viavisolutions.com/en-us/products/lab-and-manufacturing-test/optical-manufacturing-test/multiple-application-platform-map-200



Updating the Firmware Updating the mOSW-C1 Firmware


firmware. If upgrading from a version earlier than 2.0.16 you may anticipate additional delays and reboot cycles between upgrades.

When the upgrade is completed you will be notified of the successful completion of the upgrade and the MAP-200 will request a reboot.

If the upgrade fails, please reboot the chassis and repeat upgrade procedure as described above.

10. The MAP-200 will prompt you to reboot the chassis.

11. After power-up verify that the firmware by checking the firmware version on the system screen.

Updating the mOSW-C1 Firmware A new version of mOSW-C1 firmware may be included with new releases of MAP-200 firmware. It will only be available after the chassis has been updated.

After each update of the MAP-200 chassis, follow the procedure below to check for an mOSW-C1 firmware update and perform the update if a new image file is available.

1. Go to the detailed view of an mOSW-C1 cassette.

2. Press the “Information” button. The “Cassette Information” page will be displayed.

NOTE: The “Information” button will be green when a firmware image file is available.



3. Make a note of the “Card Firmware” version.

4. Press or click on the “Firmware Update” button.

A “Firmware Image” dialog will appear.

(Procedure continued on next page.)

5. Select the correct firmware image in the “Firmware Image” dialog



NOTE: This dialog allows you to upgrade the mOSW-C1 to the current firmware version or downgrade it to a previous version. Refer to the firmware version recorded in step 4 then decide which firmware version you want to install. Normally the correct choice is the most recent firmware version. The firmware version number is included in the file name of the image file.

6. Press or click the “Unpack” icon.

The upgrade process will start and a progress indicator will appear. When the upgrade is complete the cassette will reset.

NOTE: Do not press or click any controls or add or remove any cassettes during this process.


Chapter 8: Remote Commands

Definitions

Card Refers to a removable component of the MAP shelf providing a specific functionality related to optical testing and/or measurement. The term card and cassette may be used interchangeably.

Chassis Refers to the MAP enclosure which houses cards.

CI Cassette Interface. This is a common component of all MAP cassettes.

Device The part of a card which is individually addressed and controlled to perform a particular action based on card type.

MAP200 Multiple Application Platform 200. Refers to one or more shelves which house and control modular cards to form a system.

Cassette Refers to an element, usually addressable, on a card.

SCPI Standard Commands for Programmable Instruments.

Slot The space where a card may be inserted within a MAP chassis.

PCT Passive Component Tester – refers to the MAP-200 cassette which performs IL and ORL measurements using OTDR technology (also known as the mORL cassette). This also refers to the super-application that runs this cassette.

OTDR Optical Time Domain Reflectometer

IL Insertion Loss (dB)

ORL Optical Return Loss (dB)

SCPI Commands Command Tables All the SCPI commands listed in this section can be performed through TCP/IP, through a General Purpose Interface Bus (GPIB) via the MAP-200 CMR (with extra parameter used to specify slot number) or through LXI.

Remote Commands SCPI Commands Command Tables


Common Commands The following table lists common commands of the mOSW-C1 cassette

Command Parameters Output Description

:SYSTem

:ERRor? <err id>, <description>

Extracts the first error code of the error queue

:BUSY? <state> Query the busy state of the card

:RESet Reset the cassette to its default state.

:TEST? <test result> Perform a self test.

:CONFig? <dev> <type> <maxin>…

Query configuration of all devices

:INFOrmation? <serial> <part> <firmware rev>…

Query card information

:LOCK <state>, <owner>, <ipid>

Lock the specified application for the exclusive use of the owner.

:LOCK? <state>,<owner>,<ipid>

Query the lock status of an application.

:LOCK

:RELEase Release the lock of an application

:DEVice

:INFOrmation? <dev> <dev info> Query the device description

:FAULt

:SLOT? <register> Query fault register

:DEVice? <dev> <register> Query fault register of device

:STATus

:DEVice? <dev> <register> Query status register of device

:RESet <dev> Reset status register of devicer



User Commands The following table lists user commands of the mOSW-C1 cassette.

Command Parameters Output Description

:ROUTe

:CLOSe <dev>, <input>, <output>

Set new optical connection for the selected switch device.

:CLOSe? <dev>, <input> <output> Query optical connection of selected switch device

:TRIM <dev>,<index> (0—32)

Set trim for the switch device

:TRIM? <dev> <trim> Query trim value of the device.

:MONitor? <dev> [,<dir>, <input>]

<dir>, <pow> Query power value of the switch device.

:CHANnel

:DEScription <dev>, <chnl>, <description>

Set channel description

:DEScription? <dev>, <chnl> <description> Query channel description

:WAVelength <dev>, <wavelength>

Set wavelength

:WAVelength? <dev> <wavelength> Query wavelength



Common SCPI Commands

*CLS

Description

This command will clear the following queues and registers.

• SCPI command error queue • Standard event status register (ESR) • Status byte register(STB) except MAV bit

Input Format

*CLS

Output Format

None.

Example

The following example illustrates the syntax of the CLS command.

Terminal Input:

*CLS



*ESE

Description

Sets the bits in the Standard Event Status Enable register which will determine which events are reflected in the event summary bit (ESB) of the standard status register. The numeric value is converted to a binary number. The bits of the register are set to match the bit values of the binary number.

If bits are set TRUE in the standard event status enable register and a corresponding bit is set TRUE is the standard event status register, the ESB bit (bit 5) of the status byte register will be set TRUE.

Input Format

*ESE <Register Value>

Parameter Type Value Register Numeric 0 <= value <= 255

Standard Event Status Enable Register

Bit 7 Bit 6 Bit 5 Bit 4 Bit 3 Bit 2 Bit 1 Bit 0

Power on (PON)

User request (URQ)

Command error (CME)

Execution error (EXE)

Device dependent

error (DDE)

Query error

(QYE)

Request

control (RQC)

Operation complete

(OPC)

Bit 0: operation complete Bit 1: request control – not supported Bit 2: query error. It is set when a query error occurs, for example, an attempt is made to read the output queue when the output queue is empty or when the data in the output queue is lost Bit 3: device dependent error – not supported Bit 4: execution error Bit 5: command error. it is set when a command error is detected by the system, for example, if a syntax error is detected in a program message, an incorrect command header is received, or an IEEE GET message is received in the middle of a program message. Bit 6: user request – not supported Bit 7: power on

Output Format

None.

Default

0 on power cycle.

Example

The following example sets standard event status enable register bits to 00100000, indicating that the COMMAND ERROR (CME) byte of the event status register

Terminal Input:



*ESE 32



*ESE?

Description

Returns the contents of the Standard Event Status Enable register as an integer that, when converted to a binary number, represents the bit values of the register.

Input Format

*ESE?

Output Format

<Register Value> (see the details in command *ESE)

Parameter Type Value Register Numeric 0 <= value <= 255

Default

0 on power cycle.

Example

The following example queries the standard event status enable register.

Terminal Input:

*ESE?

Terminal Response:

32



*ESR?

Description

Returns the contents of the Standard Event Status register as an integer that, when converted to a binary number, represents the bit values of the register.

Reading the ESR clears it.

Input Format

*ESR?

Output Format

<Register Value>

Parameter Type Value

Register Numeric 0 <= value <= 255

Standard Event Status Register Bit 7 Bit 6 Bit 5 Bit 4 Bit 3 Bit 2 Bit 1 Bit 0

Power on (PON)

User request (URQ)

Command error (CME)


Device dependent error (DDE)

Query error (QYE)

Request control (RQC)

Operation complete (OPC)

Bit 0: operation complete Bit 1: request control Bit 2: query error. it is set when a query error occurs, for example, an attempt is made to read the output queue when the output queue is empty or when the data in the output queue is lost. Bit 3: device dependent error. It is set by the system to always indicate 0. Bit 4: execution error Bit 5: command error. it is set when a command error is detected by the system, for example, if a syntax error is detected in a program message, an incorrect command header is received, or an IEEE GET message is received in the middle of a program message. Bit 6: user request Bit 7: power on

Default

0 on *CLS, *ESR? and power cycle.

Example

The following example illustrates a default value of the ESR.

Terminal Input:

*ESR?

Terminal Response:



1



*IDN?

Description

Queries for the identification.

Input Format

*IDN?

Output Format

Manufacturer,Model,ID,FW


Manufacturer String VIAVI

Model String <model name>

ID* String <ID number>

FW String <major.min>

Note: SCPI standard states that the overall length of the IDN? Response shall be less than or equal to 72 characters.

Example

The following example queries the chassis identification string:

Terminal Input:

*IDN?

Terminal Response:

JDSU,MOSW,123456789,1.00



*OPC

Description

This command starts to monitor pending operations, and sets/clears the Operation Complete (OPC) bit in the Standard Event Register as follows:

1. if there is no pending operation, sets the OPC bit to 1;

2. if there are any pending operations, sets the OPC bit to 0. The bit will be set to 1 again when all pending operations are complete;

So, *OPC command is required to enable the OPC bit. To stop monitoring pending operations (disable OPC bit), execute the *CLS command.

Input Format

*OPC

Output Format

None

Example

*OPC

Terminal Input:

*OPC



*OPC?

Description

This command will not return until all of the pending operations are complete. Once it returns, the return value will always be “1”.

Input format

*OPC?

Output format

<Status>

Parameter Type Value Status Numeric 1 = Operation Complete

Errors

Standard error messages.

Example

The following example queries the state of the

Terminal input:

*OPC?

Terminal response:

1

The response will always indicate a 1.



*RST

Description

Reset the mOSW-C1 cassette.

• The mOSW-C1 application reestablishes communication with the cassettes. • The Standard Event Status Register(ESR), Service Register(ESE), Event Status

Enable Register(SRE), STB settings and error queue settings for the application will NOT be effected.

• All the other registers and variables will be reset to their default values • All TCP/IP Connections will be maintained. • Application Locking will be maintained

Input format

*RST

Output format

None.

Example

*RST

Terminal input:

*RST



*SRE

Description

Sets the bits in the Service Request Enable register. The numeric value is converted to a binary number. The bits of the register are set to match the bit values of the binary number.

The Service Request Enable register determines which bits of the Status Byte Register are enabled. Enabled bits are ORed together, and the result is reported to the Master Summary Status.

Input format

*SRE <Register Value>


Register numeric 0 <= value <= 255

Standard Event Status Register Bit 7 Bit 6 Bit 5 Bit 4 Bit 3 Bit 2 Bit 1 Bit 0

Power on (PON)

User request (URQ)

Command error (CME)


Device dependent error (DDE)

Query error (QYE)

Request control (RQC)

Operation complete (OPC)

Bit 0: operation complete Bit 1: request control Bit 2: query error. it is set when a query error occurs, for example, an attempt is made to read the output queue when the output queue is empty or when the data in the output queue is lost. Bit 3: device dependent error. It is set by the system to always indicate 0. Bit 4: execution error Bit 5: command error. it is set when a command error is detected by the system, for example, if a syntax error is detected in a program message, an incorrect command header is received, or an IEEE GET message is received in the middle of a program message. Bit 6: user request Bit 7: power on

Output format

None.

Default

0 on *CLS and power cycle.

Example

1> The following example sets the service request enable register bits application to 11011000.

Terminal input:

*SRE 216



*SRE?

Description

Returns the contents of the service request enable register as an integer that, when converted to a binary number, represents the bit values of the register.

Input format

*SRE?

Output format

<Register Value> (see command *SRE for details)


Register Numeric 0 <= 63 | 128 <= 191

Default

00000001 on *CLS, and power cycle.

Example

The following example queries the service request enable register:

*SRE?

Terminal response:

216



*STB?

Description

Returns the contents of the SCPI status byte register as an integer that, when converted to a binary number, represents the bit values of the register. The bit value for Bit 6 of the register is the MSB bit value, not the SRQ bit value.

Input format

*STB?

Output format

<Register Value>


Register Numeric 0 <= value <= 255

Status Byte Register Bit 7 Bit 6 Bit 5 Bit 4 Bit 3 Bit 2 Bit 1 Bit 0

Not used Request for service (SRQ) or Master summary (MSS)

Event summary (ESB)

Message available (MAV)

Not used

Errors Available (EAV)

Not used Not used

Bit 0 -- 3 is not used. Bit 4: message available. it is set to 1 when a response message is available in the output queue. Bit 5: event summary bit. it is the summary bit for the standard event status structure. The ESB summary message bit is set if any bit in the standard event status register is set while its corresponding bit in the standard event status enable register is set. Bit 6: SRQ. as the service request bit, is set to 1 if a service request has been generated. The SRQ bit is set internally and is not visible to the user. Bit 6, as the master summary bit (MSS), is set when there is at least one reason for the MAP-200 unit to request service from the controller. That is, the master summary bit is set if any summary bit in the status byte register is set and if the corresponding bit in the service request enable register is also set. The MSS is returned as bit 6 when the status register is queried or the MAP-200 unit is serial polled. Bit 7 is not used.

Default

00000000 on *CLS, and power cycle.

Example

The following example queries the status byte register value.

Terminal input:

*STB?

Terminal response:

80



This response 01010000 indicates that the MSB (master summary) and the MAV (message available) bits are set.



*TST?

Description

Trigger card self test. The return value is the test result. It is equivalent to sending the :TEST? command.

Input format

*TST?

Output format

<Result>


Result Boolean 0 = PASS, 1 = FAIL

Errors


Example

The following example initiates a complete self-

Terminal input:

*TST?

Terminal response:

0

This response indicates that the self-test operation passed on all cards.



*WAI

Description

The *WAI command stops execution of any commands until the Operation Complete (OPC) bit is set to 1, which means there is no pending operation.

Input format

*WAI

Output format

None.

Errors


Example

*WAI

Terminal input:

*WAI



*SAV

Description

The *SAV command stores current status of system and all the applications with specified valid number. The status can be recalled by command *RCL <number>. The maximum of entries for user settings is 5. If user enters a number that has been set before, the settings with the old number will be overwritten.

Input format

*SAV <number>


<number>* Numeric 2 – 6 * <number> 0 is reserved for the factory default settings; <number> 1 is reserved for the power-off status; Those two numbers can’t be accessed by this command.

Output format

None.

Default

0

Errors


Example

*SAV 2

Terminal input:

*SAV 2

This example saves current system and application status as number “2”.



*RCL

Description

The *RCL command recalls the stored status of system and all the applications which is stored by *SAV command with the specified number. All the status will be recovered right after this command is issued. The interlock will be turned on during recovering and then will be restored to the state as before this command is issued.

Input format

*RCL <number>


<number>* Numeric 0 – 6 * <number> 0 is reserved for the factory default settings; <number> 1 is reserved for the power-off status; All the others can be used by the user.

Output format

None.

Default

0

Errors


Example

*RCL <number>

Terminal input:

*RCL 0

This example restores the factory settings.

Remote Commands Common Application Commands


Common Application Commands

:SYSTem:ERRor?

Description

Extracts the first error code written to the error queue. The error queue is used exclusively to indicate SCPI command errors. Command’s error from multiple interfaces will be written to the same error queue.

If no errors are present in the error queue, the value 0 will be returned. The error queue size is 128 bytes. If the system writes more than 128 errors to the error queue then the last error queue number is –350 and all subsequent errors are discarded until –350 is read.

When this command is issued to a specific application, the error queue for the application will be extracted.

Input Format

:SYSTem:ERRor?

Output Format

<Error>, “Description”


Error Numeric -16384 to 16384

Description String 8 – 50 chars

Errors


Example

The following example queries the first error in the error queue.

Terminal Input:

:SYST:ERR?

Terminal Response:

-100,”Command error”



:BUSY?

Busy Status

N/A

Description

Queries the selected card to determine if any devices are busy. Response is determined by the busy state.

In optical switching applications, BUSY only indicates completion of a command operation. Optical settings may not have completed to specification and additional time should be allowed.

Input Format

:BUSY?

Output Format

<State>


State Boolean 1 = Busy, 0 = Available

Example

The following example quarries the BUSY state of a specific to determine when the operation is complete so another command may be sent.

Terminal Input:

:BUSY?

Terminal Response:

1

The response indicates that the device queried is busy (i.e. still performing the switch operation).



:RESet

Description

Reset cassette to its default state. Perform the same reset as *RST.

Card reset commands simulates a hot-swap or card power-up event. The card may briefly appear to have disappeared from the system. This is normal until the system acquires and configures the card.

Input Format

:RESet

Output Format

None.

Errors


Example

The following example resets all devices on the specific card.

Terminal Input:

:RES



:TEST?

Description

Performs a self-test and the same as *TST? command

Input Format

:TEST?

Output Format

<Result>


Result Boolean 0 = PASS, 1 = FAIL

Errors


Example

The following example returns result of the self-test performed on the selected card.

Terminal Input:

:TEST?

Terminal Response:

0

The above response indicates a successful test.



:CONFig?

Description

Query configuration of all devices.

Input Format

:CONFig?

Output Format

<Device> <Type> <Maxin> <Maxout> <Latching>

<max Trim Level> <Opm> <Fiber Mode> <Fiber Core Size> <Connector Type>


Device Numeric 1 to 8

Type String OSW

MaxIn Numeric 1 to 2

MaxOut Numeric 1 to 64

Latching Boolean YES / NO

Max Trim Level Numeric 0 to 32

OPM Boolean YES / NO

Fiber Mode Numeric

0 : Single Mode 1 : Multi Mode OMI 62.5 µm 2 : Multi Mode OM3 50.0 µm

Fiber Core Size Float 5.5um – 100um

Connector Type String

Examples

The following examples illustrate typical responses for the CONFig?

Terminal Input:

:CONF?

Example

Terminal Response:



1 OSW 1 8 YES NO NO 0 50.00 FC/APC,2 OSW 1 8 YES 0 NO 0 50.00 FC/APC

The response illustrates the two 1x8 OSW latching switches without trim and OPM.



:INFOrmation?

Description

Query card information.

Input format

:INFOrmation?

Output format

<Serial Number>,<Part Number>,<Card Firmware Rev>,

<OSW Module Firmware Rev>,<OPM Module firmware Rev>,

<HW Rev>,<Assembly Date>,<Description>


Serial Number String max. 18 characters

Part Number String max. 24 characters

Card Firmware Rev String max. 4 characters

OSW Module Firmware Rev String max. 4 characters

OPM Module Firmware Rev String max. 4 characters

HW Rev String max. 4 characters

Assembly Date (YYYYMMDD) String max. 8 characters

Description String max. 32 characters

Example

The following example illustrates typical response

Terminal Input :

:INFO?

Terminal Response :

29374743,OSC-A1 1234 ,2.00,3.00,3.00,3.00, 20010815,Custom for IE MRR



:LOCK

Description

Lock the specified application for the exclusive use of the owner. Once the application is locked, only the owner can access it; for all the other users access will be blocked except the command LOCK? query the lock status will always return the current lock status.

Input Format

:LOCK <STATE>,<OWNER_NAME>,<IP_ID>


<STATE> Boolean 0:unlock; 1:lock;

<OWNER_NAME> String up to 20 char

<IP_ID> String can be IP address or string “LOCAL” which indicate the source is from local chassis

up to 20 char

Output Format

None.

Example

The following example sets the lock state.

Terminal Input:

:LOCK 1,”LXI”,”LOCAL”



:LOCK?

Description

Query the lock status of an application.

Input Format

:LOCK?

Output Format

<STATE>,<LOCK_NAME >,<IP_ID> if it is locked; <STATE> if it is not locked.


<STATE> Boolean 0:unlock; 1:lock;

<LOCK_NAME> String 1 -20 char

<IP_ID> String can be IP address or string LOCAL which indicates the source is from local

chassis. Up to 20 char

Example

The following example queries the lock status.

Terminal Input:

:LOCK?

Terminal Response:

1,“LXI”,“LOCAL”

The response indicates that the application is locked by LXI from local chassis.



LOCK:RELEase

Busy Status

Busy Test Required? Causes Card Busy?

Description

Unlock a locked application no matter the application is locked by anyone else.

Input Format

:LOCK:RELEase

Output Format

None.

Errors

Standard Error Messages

Example

The following example unlocks the application.

Terminal Input:

LOCK:RELE



:DEVice:INFOrmation?

Description

Query the device OSW cassette description.

Input Format

:DEVice:INFOrmation? <D>

Output Format

<switch serial number>,<switch model number>


Switch Serial Number String 15 characters

Switch Model Number String 31 characters

Example

The following example illustrates response of the mOSW-C1 cassette.

Terminal Input:

:DEVice:INFO? 1

Terminal Response:

123456677,OSW5205



:FAULt:SLOT?

Description

Returns an integer which, when translated to binary, indicates the state of all bits in the slot fault register for the slot address specified. A bit set as 1 indicates a TRUE condition. The Slot fault register contains a bit for all lower-level device fault register.

Input Format

:FAULt:SLOT?

Output Format

<Register>


Register Integer 0 <= value <= 255

mSRC Slot Fault Register Bit 7 Bit 6 Bit 5 Bit 4 Bit 3 Bit 2 Bit 1 Bit 0

RSVD RSVD RSVD RSVD RSVD RSVD Device Fault RSVD

Bit 0 -- Reserved. Bit 1 -- (Device Fault) is set when there is at least one bit that set in the device fault register. Bit 2 – Bit 7 Reserved.

Default

0

Examples

The following examples illustrate typical responses for the slot fault register query.

Terminal Input:

:FAULt:SLOT?

Terminal Response:

2

The binary pattern for integer response 2 is 00000010 which indicates the card has a device fault. Device fault register should be queried to determine exact fault.



:FAULt:DEVice?

Description

Returns an integer which, when translated to binary, indicates the state of all bits in the device fault register for the device specified. A bit set as 1 indicates a TRUE condition.

If a bit of any device fault register is TRUE, the device fault bit of associated Slot fault register will have corresponding bit set TRUE.

Important:

• Reserved (unused) bits are returned with value 0. • Device without a fault register will return a value 0.

Input Format

:FAULt:DEVice? <D>

Output Format

<Register>



Device Fault Register Bit 7 Bit 6 Bit 5 Bit 4 Bit 3 Bit 2 Bit 1 Bit 0

RSVD RSVD RSVD RSVD OPM_ERR OSW_ERR No OPM No OSW Bit 0 (No OSW) is that OSW cassette can not be found in a device which is configured with an OSW cassette Bit 1 (No OPM) is that OPM cassette can not be found in a device which is configured with an OPM cassette Bit 2 (OSW ERR) is set when OSW cassette has an error. Bit 3 (OPM ERR) is set when OPM cassette has an error. Bit 4 – Bit 7 Reserved.

Default

0

Example

The following examples illustrate typical responses for the device fault register query for device 2.

Terminal Input:

:FAULt:DEV? 2

Tls Example

Terminal Response:



2

The binary pattern for integer response 2 is 00000100 which indicates the Dev2 has a OSW cassette error.



:STATus:DEVice?

Description

Returns an integer which, when translated to binary, indicates the state of all bits in the device status register for the device specified. A bit set as 1 indicates a TRUE condition.

Important: Reserved (unused) bits are returned with value 0.

Input Format

:STATus:DEVice? <D>

Output Format

<Register>



mOSW-C1 - Status Register Bit 7 Bit 6 Bit 5 Bit 4 Bit 3 Bit 2 Bit 1 Bit 0

RSVD RSVD RSVD OSC RSVD UTEMP OTEMP EPV Bit 0 (EPV) -- EEPROM error. Bit 1 (OTEMP) – Over temperature Bit 2 (UTEMP) – Under temperature Bit 3 – Reserved Bit 4 (OSC) – Oscillator’s not the same as calibrated value Bit 5 – Reserved Bit 6 – Reserved. Bit 7 – Reserved

Default

0

Example

The following examples illustrate typical responses for the device status register query for device 1.

Terminal Input:

:STAT:DEV? 1

TLS Example

Terminal Response:

1



The binary pattern for integer response 1 is 00000001 which indicates the EEPROM error.



:STATus:RESet

Description

Clears the device status register.

Input Format

:STATus:RESet <D>

Output Format

None.

User Commands

:ROUTe:CLOSe

Description

Set new optical connection for selected switch device.

Input Format

:ROUTe:CLOSe <D>,<Input>,<Output>


Input Integer 1* -- max input channel

Output Integer 0** -- max output channel *See CONFig? query command description. **Not all switches may have a 0 (off) channel.

Output Format

None

Default

0

Example

The following example sets input 1 to output 20 for device 1.

Terminal Input:

:ROUT:CLOS 1,1,20



:ROUTe:CLOSe?

Description

Query optical connection of selected switch device.

Input Format

:ROUTe:CLOSe? <D>,<Input>

Output Format

<Power>


Input Integer 1 -- MaxIn* *See CONFig? query command description.

Output Format

<Output>


Output Integer MaxOut* *See CONFig? query command description.

Example

The following example returns output connected to input channel 1 on device 1:

Terminal Input:

:ROUTe:CLOSe? 1,1

Terminal Response:

20



:ROUTe:TRIM

Description

Set trim for the switch device. The command only works for the switch device that has trim capability. The trim level is reset, when the switch position is moved.

Input Format

:ROUTe:TRIM <D>,<level>


Level Integer 0 – MAX level

Output Format

None

Default

0

Example

The following example sets trim for the device 1 to level 10.

Terminal Input:

:ROUT:TRIM 1,10



:ROUTe:TRIM?

Description

Query trim value of the specified device. The command only works for the switch device that has trim capability

Input Format

:ROUTe:TRIM? <D>

Output Format

<level>


Level Integer 0 – 32

Default

0

Example

The following example queries the trim value of the switch device 1.

Terminal Input:

:ROUT:TRIM? 1

Terminal Response:

10

The above response indicates the trim value of the switch device 1 is 10 dB



:ROUTe:WAVelength

Description

Set wavelength for the switch device. The command only works for the switch device that has optical power monitor.

Input Format

:ROUTe:WAVelength <D>,<wavelength>


wavelength Float min wavelength – max wavelength

Output Format

None

Default

0

Example

The following example sets wavelength for the device 1 to 1550 nm.

Terminal Input:

:ROUT:WAV 1,1550



:ROUTe:WAVelength?

Description

Query wavelength value of the specified device. The command only works for the switch device that has optical power monitor

Input Format

:ROUTe:WAVelength? <D>

Output Format

<wavelength>


Wavelength Float min wavelength – max wavelength

Default

0

Example

The following example queries the wavelength value of the switch device 1.

Terminal Input:

:ROUT:WAV? 1

Terminal Response:

1550

The above response indicates the wavelength value of the switch device 1 is 1550nm



:ROUTe:CHANnel:DEScription

Description

Set channel description. The channel description will be stored in flash memory after it is set.

If dev num <= 2 max chnl =(dev -1)*64 + chan - 1

If 2 < dev num <= 4 max chnl =(dev -1)*32 + chan -1

If 4 < dev num <= 8 max chnl = (dev -1) *16 + chan -1

Max channel must be smaller than 128

Input Format

:ROUTe:CHANnel:DEScription <dev>,<chan>,<des>


<dev> Integer device (1 – 8)

<chan> Integer output channel(1 –128)

<des> String description (length < 64)

Output Format

None

Default

0

Example

The following example sets channel description “TEST channel” for channel 1 of device 1.

Terminal Input:

:ROUT:CHAN:DES 1,1,TEST channel



:ROUTe:CHANnel:DEScription?

Description

Query channel description. The channel description will be stored in flash memory after it is set.

If dev num <= 2 max chnl =(dev -1)*64 + chan - 1

If 2 < dev num <= 4 max chnl =(dev -1)*32 + chan -1

If 4 < dev num <= 8 max chnl = (dev -1) *16 + chan -1

Max channel must be smaller than 128

Input Format

:ROUTe:CHANnel:DEScription? <dev>,<chan>

Output Format

<description>


<dev> Integer (1 – 8)

<chan> Integer (1 –128)

<des> String < 64

Example

The following example queries channel description from channel 1 of device 1

Terminal Input:

:ROUT:CHAN:DES? 1,1

Terminal Response:

Test description

Channel description from channel 1 of device 1 if Test description.



:ROUTe:MONitor?

Description

Query the optical power value of switch device. The command only works for the switch device that has optical power meter capability.

If dir is not set, optical direction is decided by firmware.

If input = 1 and device does not have the opm channel 1 & channel 2, system will have systax error. The device must have opm channel 3 and channel 4 for input 2

Input Format

:ROUTe:MONitor? <D>, [dir, input]


Dir Integer Common Output 1: Output Commo

Input Integer

input line of switch 1xN switch input = 1 2XN switch input = 1 or 2 Default: input = 1

Output Format

<dir>,<power>


Dir Integer 0: common N (Output) 1: N (Output) comm

Power Float -100 to 30

Example

The following example queries the optical power monitor values on switch device 1.

Terminal Input:

:ROUTe:MON? 1

Terminal Response:

0, -8.000

The above response indicates the power direction is from input to output and power value is -8.000dbm.


Chapter 9: Specifications

mOSW-C1 Parameters The following specifications describe the warranted characteristics of the instrument.

Table 2: mOSW-C1 M xN, N ≥ 4 Specifications

Parameter 1 1C Configuration 2D Configuration

2E Configuration

Wavelength Range

Single Mode 2 (SM) 1250 nm – 1650 nm

Multi Mode 3 (MM) 760 nm – 1360 nm

Insertion Loss (IL) 4

Single Mode (SM) 0.7 dB 0.7 dB 0.9 dB

Multi Mode (MM) 0.9 dB 0.9 dB 1.0 dB

Return Loss (RL) 5

Single Mode (SM) 62 dB 62 dB 60 dB

Multi Mode (MM), OM1 (62.µm)

30 dB 30 dB 25 dB

Multi Mode (MM), OM3 (50 µm) 40 dB 40 dB 35 dB

1 All optical measurements, excluding connectors, taken after temperature has been stabilized for minimum of one hour at ambient room temperature between 20-30°C and variation less than ±3°C. 2 For IEC 60793-2-50 Type B1.3/ ISO 11801 OS2 compliant fiber, that is Corning SMF-28e. 3 For fiber type of OM1 and OM3 fiber compliant with ISO/IEC 11801. 4 Excluding connectors. Tested at 1310nm and 1650nm for SM and 850nm and 1300nm for MM with EF compliant with IEC 62614 ED1.0 2010. 5 RL excluding connectors with 1m pigtail length. Tested at 1310nm/1625nm for SM and 850nm/1300nm for MM with EF compliant with IEC 62614 ED1.0 2010.

Specifications mOSW-C1 Parameters



2E Configuration

Polarization Dependent Loss (PDL) 6

Single Mode (SM) 0.04 dB 0.05 dB 0.07 dB

Repeatability 7

Sequential switching ±0.005 dB ±0.01 dB ±0.01 dB

Random switching ±0.025 dB ±0.04 dB ±0.04 dB

IL stability 8 (maximum)

Single Mode (SM) ±0.025 dB

Crosstalk (maximum)

Single Mode (SM) -80 dB

Multi Mode (MM) -60 dB

Optical Power

Max input power (optical) 300 mW

Lifetime

Lifetime 100 million

Switching time ≤ 24 ports >24 ports

Electro-Mechanical (break to make) 20+10*(N-1) ms 55+30*(N-1) ms

Settling time to 90% final IL 60 ms 70 ms

Settling time for 99% final IL 90 ms 120 ms

Environment

Operation temperature 0 – 50 °C,

Operation humidity 15 to 80% RH, 0 to 40 °C non condensing

Storage temperature -30 to 60 °C

6 PDL tested at 1310nm and 1650nm. 7 Measured between two consecutive readings over 100 cycles. 8 Drift of any channel relative to reference channel at ±3°C deviation of ambient temperature over a 7-day period (168 hours).




2E Configuration

Physical

Dimensions (W x H x D) 4.1 x 13.3 x 37.0 cm (single slot) 8.1 x 13.3 x 37.0 cm (dual slots)

Weight 1.75 kg (single slot with pigtails) 3.1 kg (dual slot with pigtails)

Power Trim Option for Single Mode 1CxN 9

Additional IL 0.6 dB

Return Loss 55 dB

Additional through path PDL 0.02 dB

Power Measurement Range +10 to -55 dBm (1550nm)

Power Trim Range 20 dB (typical)

Power Trim Index 0 to 16 (≤ 24 ports) 0 to 32 (>24 ports)

(typical trim resolution shown below)

9 Typical power trim curve is characterized at 1550nm and is for reference purposes only. The actual performance may vary based on the channel and wavelength being operated.



Figure 12: Typical PTRIM impact for 1CxN with 24 ports or less

Figure 13: Typical PTRIM impact for 1CxN with more than 24 ports



Table 3: mOSW-C1 [1x2] and [2x2] Parameters

Parameter 10 1x2 2x2

Wavelength Range

Single Mode 11 (SM) 1290nm to 1330 and 1520 to 1650nm

Multi Mode 12 (MM) 760nm – 1360nm

Insertion Loss (IL) 13

Single Mode (SM) 0.7 dB 1.2 dB

Multi Mode (MM) 0.9 dB 1.2 dB

Return Loss (RL) 14

Single Mode (SM) 50 dB 50 dB

Multi Mode (MM), OM1 (62.5 µm) 30 dB 25 dB

Multi Mode (MM), OM3 (50 µm) 40 dB 35 dB

Polarization Dependent Loss (PDL) 15

Single Mode 0.07 dB 0.08 dB

Repeatability 16

SM and MM ±0.02 dB ±0.03 dB

Insertion Loss

IL Stability 17(maximum) ±0.025 dB

Crosstalk (maximum)

Single Mode (SM) -55 dB

10 All optical measurements, excluding connectors, taken after temperature has been stabilized for minimum of one hour, at ambient room temperature between 20-30°C and variation less than ±3°C. 11 For IEC 60793-2-50 Type B1.3/ ISO 11801 OS2 compliant fiber, that is Corning SMF-28e. 12 For fiber type of OM1 and OM3 fiber compliant with ISO/IEC 11801. 13 Excluding connectors. Tested at 1310nm and 1650nm for SM and 850nm and 1300nm for MM. EF compliant with IEC 62614 ED1.0 2010. 14 RL excluding the connectors with 1m pigtail length. Tested at 1310nm/1625nm for SM and 850nm/1300nm for MM. EF compliant with IEC 62614 ED1.0 2010. 15 PDL tested at 1310nm and 1650nm. 16 Measured between two consecutive readings over 100 cycles. 17 Drift of any channel relative to reference channel at ±3°C deviation of ambient temperature over a 7-day period (168 hours).



Parameter 10 1x2 2x2

Multi Mode (MM) -55 dB

Optical Power

Max input power (optical) 300 mW

Lifetime

Lifetime 100 million

Switching time Single Mode Multimode

Electro-Mechanical (break to make)

4 ms 210 ms



Environment

Operation temperature 0 – 50 °C,

Operation humidity 15 to 80% RH, 0 to 40 °C non condensing

Storage temperature & Humidity -30 to 60 °C, non condensing

Physical

Dimensions (W x H x D) 4.1 x 13.3 x 37.0 cm

Weight 1.75 kg (with single slot pigtails)


Chapter 10: Technical Support Visit this site on the web, http://www.viavisolutions.com/en/services-and-support/support/technical-assistance, select your country and then select “FOPLT” or “MAP-200” to find the MAP-200 technical assistance phone number for your region.

http://www.viavisolutions.com/en/services-and-support/support/technical-assistance

http://www.viavisolutions.com/en/services-and-support/support/technical-assistance


Chapter 11: Service

Storing and Shipping To maintain optimum operating reliability, do not store the unit in locations where the temperature falls below -30 °C or rises above 60 °C. Avoid any environmental condition that can result in internal condensation. Ensure that these temperature and humidity requirements can also be met whenever the unit is shipped.

Claims and Repackaging Immediately inform Viavi and, if necessary, the carrier, if

• The contents of the shipment are incomplete

• The unit or any of its components are damaged or defective

• The unit does not pass the initial inspection

In the event of carrier responsibility, Viavi will allow for the repair or replacement of the unit while a claim against the carrier is being processed.

Packing Guidelines With Original Packaging • Ensure foam is properly placed

• Use the L-Shaped cardboard piece to hold controller in place

• Do not ship with the display mounted on the chassis, ensure it is packaged separately

• Do not ship with MTLS and MTBF populated in the chassis

Packing Guidelines Without Original Packaging • Do not ship with any modules populated in the chassis

• Do not ship with the display mounted on the chassis, ensure it is packaged separately

• Ensure the bottom of the chassis is supported

• Ensure sufficient cushioning is provided for all modules, chassis and display being shipped

Service Storing and Shipping


Returning Shipments to Viavi Viavi only accepts returns for which an approved Return Material Authorization (RMA) has been issued by Viavi. This number must be obtained prior to shipping any material to Viavi. The owner’s name and address, the model number and full serial number of the unit, the RMA number, and an itemized statement of claimed defects must be included with the return material.

Return shipments to Viavi in the original shipping container and packing material. If these are not available, packaging guidelines are as follows:

1. Cover the front panel with a strip of foam.

2. Wrap the unit in anti-static packaging.

3. Pack the unit in a reliable shipping container.

4. Use enough shock-absorbing material (10 to 15 cm or 4 to 6 in on all sides) to cushion the unit and prevent it from moving inside the container. Pink poly anti-static foam is the recommended material.

5. Seal the shipping container securely.

6. Clearly mark FRAGILE on its surface.

7. Always provide the model and serial number of the unit and the RMA number on any accompanying documentation.

Please contact the RMA department, using the contact information under Technical Support on page 98 to provide an RMA number and a shipping address.


Chapter 12: Glossary

Term Definition

CE European Community

Chassis Refers to the mechanical MAP enclosure that houses cassettes and cards.

CI Card Cassette Interface PCB. This is a common component of all MAP cassettes.

Controller MAP controller card

CSA Canadian Standards Association

Device The part of a card that is individually addressed and controlled to perform a particular action based on card type. For example, a switch card contains switch devices that can be controlled to connect specific input channels to specific output channels.

DWDM Dense Wavelength Division Multiplexer

ESD Electrostatic Discharge

FC Fiber Coupler

FC/APC Ferrule Connector/Angled Polished Connector

FC/PC Ferrule Connector/Polished Connector

FP laser Fabry–Pérot laser

GPIB General Purpose Interface Bus

IEC International Electrotechnical Commission

IEEE Institute of Electronic and Electrical Engineers

IL Insertion Loss

ISO International Standards Organization

VIAVI JDS Uniphase Corporation

LXI LAN-based eXtensions for Instrumentation

MAP Multiple Application Platform. Refers to one or more shelves that house and control modular cards to form a system.

MM Multi Mode

Glossary Storing and Shipping


Module Refers to a functional element on a MAP cassette.

OPM Optical Power Meter. A card containing one or more optical power detectors. Detectors may be internally integrated within the card or consist of a detector ‘head’ connected via cable to the card.

PCB Printed Circuit Board

PDL Polarization Dependent Loss

RMA Return Material Authorization

SCPI Standard Commands for Programmable Instruments.

SLED or SLD Superluminescent Light Emitting Diode.

Slot One of eight physical areas where a card may be inserted within a MAP chassis. Mechanical guides specify where cards may be inserted.

SM Single Mode

SMF Single Mode Fiber

TEC ThermoElectrically Cooled

UCA Universal Connector Adapter

UL Underwriters Laboratory

USB Universal System Bus

WDM Wavelength Division Multiplexer

Viavi Solutions

North America (Toll Free) 1-844-GO-VIAVI / 1-844-468-4284

Latin America +52 55 5543 6644

EMEA +49 7121 862273

APAC +1 512 201 6534

All other regions www.viavisolutions/contacts

Email [email protected]

MAP-200 Optical Switch mOSW-C1

Installation and User Guide

22112369-120 R000

Standard

June 2016

English

Documents

Multiple Application Platform MAP-200