Trinix NXT DIGITAL VIDEO ROUTER Installation and Service Manual Software Version 3.3.
CERTIFICATE Certificate Number: 510040.001 The Quality System of: Grass Valley USA, LLC and its Grass Valley Affiliates Headquarters: 400 Providence Mine Road Nevada City, CA 95945 United States 15655 SW Greystone Ct. Beaverton, OR 97006 United States Kapittelweg 10 4827 HG Breda The Nederlands 2300 So. Decker Lake Blvd.
Trinix NXT DIGITAL VIDEO ROUTER Installation and Service Manual Software Version 3.3.
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Contents About This Manual . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 9 Additional Documentation . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 9 Safety Terms and Symbols. . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 11 Terms in This Manual . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 11 Terms on the Product .
Contents SMS 7000 / Encore Control . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . LAN and Com Bus Connections . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . System Monitoring Applications . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . Specifications. . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . Electrical . . . . . . . . . . . . . . . . . . . . .
Contents Section 5 — Broadlinx Installation . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 259 Software Installation . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . Introduction . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . Updating Compact Flash Cards . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . Updating New Broadlinx Boards . . . . .
Contents Encore Configuration of Protected Paths . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 377 Section 11 — Analog Input Processing . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 379 TRX-VI-33100 Module . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 379 Analog Processing Control . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 379 Customizing Analog Video Processing Settings . . . . . . .
Preface About This Manual This manual provides system planning, installation and troubleshooting information specific to the Trinix Digital Video Router. The Trinix DV33XXX frames are no longer available to purchase. However, this manual covers specifics about these DV33XXX frames. The DV33XXX frames and the TRX-NXTXXX frames are similar except for minor differences, which are identified in this manual. The Trinix Digital Video Router can be controlled by the Grass Valley Jupiter or Encore Control System.
Preface 10 Trinix NXT — Installation and Service Manual
Safety Summary Read and follow the important safety information below, noting especially those instructions related to risk of fire, electric shock or injury to persons. Additional specific warnings not listed here may be found throughout the manual. WARNING Any instructions in this manual that require opening the equipment cover or enclosure are for use by qualified service personnel only.
Safety Summary Symbols on the Product The following symbols may appear on the product: Indicates that dangerous high voltage is present within the equipment enclosure that may be of sufficient magnitude to constitute a risk of electric shock. Indicates that user, operator or service technician should refer to product manual(s) for important operating, maintenance, or service instructions. This is a prompt to note fuse rating when replacing fuse(s).
Safety Summary Use proper power cord — Use only the power cord supplied or specified for this product. Ground product — Connect the grounding conductor of the power cord to earth ground. Operate only with covers and enclosure panels in place — Do not operate this product when covers or enclosure panels are removed. Use correct fuse — Use only the fuse type and rating specified for this product. Use only in dry environment — Do not operate in wet or damp conditions.
Safety Summary Ensure mains disconnect — If mains switch is not provided, the power cord(s) of this equipment provide the means of disconnection. The socket outlet must be installed near the equipment and must be easily accessible. Verify that all mains power is disconnected before installing or removing power supplies and/or options. Route cable properly — Route power cords and other cables so that they ar not likely to be damaged. Properly support heavy cable bundles to avoid connector damage.
Safety Summary Sicherheit – Überblick Lesen und befolgen Sie die wichtigen Sicherheitsinformationen dieses Abschnitts. Beachten Sie insbesondere die Anweisungen bezüglich Brand-, Stromschlag- und Verletzungsgefahren. Weitere spezifische, hier nicht aufgeführte Warnungen finden Sie im gesamten Handbuch. WARNUNG Alle Anweisungen in diesem Handbuch, die das Abnehmen der Geräteabdeckung oder des Gerätegehäuses erfordern, dürfen nur von qualifiziertem Servicepersonal ausgeführt werden.
Safety Summary Symbole am Produkt Die folgenden Symbole können sich am Produkt befinden: Weist auf eine gefährliche Hochspannung im Gerätegehäuse hin, die stark genug sein kann, um eine Stromschlaggefahr darzustellen. Weist darauf hin, dass der Benutzer, Bediener oder Servicetechniker wichtige Bedienungs-, Wartungs- oder Serviceanweisungen in den Produkthandbüchern lesen sollte. Dies ist eine Aufforderung, beim Wechsel von Sicherungen auf deren Nennwert zu achten.
Safety Summary Keine offen liegenden Leiter berühren — Berühren Sie bei eingeschalteter Strom- zufuhr keine offen liegenden Leitungen, Komponenten oder Schaltungen. Richtiges Netzkabel verwenden — Verwenden Sie nur das mitgelieferte Netzk- abel oder ein Netzkabel, das den Spezifikationen für dieses Produkt entspricht. Gerät erden — Schließen Sie den Erdleiter des Netzkabels an den Erdung- skontakt an.
Safety Summary weisungen belüftet werden. Legen Sie kein Papier unter das Gerät. Es könnte die Belüftung behindern. Platzieren Sie das Gerät auf einer ebenen Oberfläche. Antistatische Vorkehrungen treffen — Es gibt statisch empfindliche Kompo- nenten, die durch eine elektrostatische Entladung beschädigt werden können. Verwenden Sie antistatische Prozeduren, Ausrüstung und Oberflächen während der Wartung. CF-Karte nicht mit einem PC verwenden — Die CF-Karte ist speziell formatiert.
Safety Summary Consignes de sécurité Il est recommandé de lire, de bien comprendre et surtout de respecter les informations relatives à la sécurité qui sont exposées ci-après, notamment les consignes destinées à prévenir les risques d’incendie, les décharges électriques et les blessures aux personnes. Les avertissements complémentaires, qui ne sont pas nécessairement repris ci-dessous, mais présents dans toutes les sections du manuel, sont également à prendre en considération.
Safety Summary Symboles apposés sur le produit Les symboles suivants peut être apposés sur le produit: Signale la présence d’une tension élevée et dangereuse dans le boîtier de l’équipement ; cette tension peut être suffisante pour constituer un risque de décharge électrique. Signale que l’utilisateur, l’opérateur ou le technicien de maintenance doit faire référence au(x) manuel(s) pour prendre connaissance des instructions d’utilisation, de maintenance ou d’entretien.
Safety Summary Retirez tous vos bijoux — Avant de procéder à une intervention d’entretien, retirez tous vos bijoux, notamment les bagues, la montre ou tout autre objet métallique. Évitez tout contact avec les circuits exposés — Évitez tout contact avec les connex- ions, les composants ou les circuits exposés s’ils sont sous tension. Utilisez le cordon d’alimentation approprié — Utilisez exclusivement le cordon d’alimentation fourni avec ce produit ou spécifié pour ce produit.
Safety Summary Assurez une ventilation adéquate — Pour éviter toute surchauffe du produit, assurez une ventilation de l’équipement conformément aux instructions d’installation. Ne déposez aucun document sous l’appareil — ils peuvent gêner la ventilation. Placez l’appareil sur une surface plane. Utilisez des procédures antistatiques - Les composants sensibles à l’électricité statique présents dans l’équipement sont susceptibles d’être endommagés par une décharge électrostatique.
Regulatory Notices Certifications and Compliances FCC Emission Control This equipment has been tested and found to comply with the limits for a Class A digital device, pursuant to Part 15 of the FCC Rules. These limits are designed to provide reasonable protection against harmful interference when the equipment is operated in a commercial environment.
Regulatory Notices Canadian Certified Power Cords Canadian approval includes the products and power cords appropriate for use in the North America power network. All other power cords supplied are approved for the country of use. Canadian Certified AC Adapter Canadian approval includes the AC adapters appropriate for use in the North America power network. All other AC adapters supplied are approved for the country of use.
Regulatory Notices For IEC compliance: The radiant power is detected trough a 7 mm aperture at a distance of 100 mm from the source focused through a lens with a focal length of 100 mm. FCC Emission Limits This device complies with Part 15 of the FCC Rules. Operation is subject to the following two conditions: (1) This device may no cause harmful interference, and (2) this device must accept any interference received, including interference that may cause undesirable operation.
Regulatory Notices 26 Trinix NXT — Installation and Service Manual
ESD Protection Electronics today are more susceptible to electrostatic discharge (ESD) damage than older equipment. Damage to equipment can occur by ESD fields that are smaller than you can feel. Implementing the information in this section will help you protect the investment that you have made in purchasing Grass Valley equipment. This section contains Grass Valley’s recommended ESD guidelines that should be followed when handling electrostatic discharge sensitive (ESDS) items.
ESD Protection Sources of ESD and Risks The following information identifies possible sources of electrostatic discharge and can be used to help establish an ESD policy. Personnel One of the largest sources of static is personnel. The static can be released from a person’s clothing and shoes. Environment The environment includes the humidity and floors in a work area. The humidity level must be controlled and should not be allowed to fluctuate over a broad range.
ESD Protection Grounding Requirements for Personnel The information in this section is provided to assist you in selecting a grounding method. This information is taken from ANSI/ESD S20.20-2007 (Revision of ANSI/ESD S20.20-1999). Table 1. Product Qualification Personnel Grounding Technical Requirement Test Method Required Limits Wrist Strap System* ANSI/ESD S1.1 (Section 5.11) < 3.5 x 107 ohm Flooring / Footwear System – Method 1 ANSI/ESD STM97.1 < 3.
ESD Protection 30 Trinix NXT — Installation and Service Manual
Section 1 Introduction General The Trinix family of routing switchers represents a revolutionary new approach to digital signal distribution, which builds on the success of the best selling routing switcher ever, Venus. Trinix NXT is the next generation of the Trinix model routing switcher. This new model offers industry-leading cooling, signal and switching performance, as well as field-proven reliability and scalability.
Section 1 — Introduction • High density in minimal space • Each I/O board supports 32 signals • Same Crosspoint bus control as Venus, providing easy integration with Jupiter Facility Control Systems. • Mission critical components are front loading and hot swappable • Extensive alarm notification/status • Load sharing power supplies • Redundant fans • Protected path operation • High-density crosspoints in compact frames. • Fixed matrix sizes can be combined to form larger routers.
Easy to Create Very Large Routers Creating very large routers in the Trinix design is accomplished by using special circuitry for simple and cost effective expansion. For example, Using passive port expansion modules, a 1024 x 1024 router can be built using Grass Valleys 512x512 or 512x1024 Routing switchers. Using the 512x512 Routing Switcher A 1024 x 1024 router can be built using four 512 x 512 frames coupled together with the passive port expanders in four equipment racks.
Section 1 — Introduction The Trinix frame offers plenty of power to spare the: • Trinix DV-33128 runs on a 600W Power Supply Unit (PSU). • Trinix NXT-128x128 runs on a 1000W PSU. • Trinix DV-33256 and the DV-33512 both run on a 1250W PSU. • Trinix NXT-512x512 runs on a 1300W PSU. Note It is important that you refer to the Trinix rear panel’s frame markings for the correct Fuse value and Power requirements.
The VI-33100 “universal” input board uses inputs 0 - 15 are analog, SD, or HD. Inputs 16 - 31 are SD or HD. The board auto-senses and accepts 16 composite analog SD, digital SD, or digital HD signals in any combination and passes them in digital SD or digital HD form (as appropriate) to the Trinix matrix board. When analog signals are received, an extensive set of gain, phase, filtering, and other adjustments are available for each signal.
Section 1 — Introduction signal presence, reclocking settings, etc.) as well as enables the firmware updates via network connection. For Protected Path operations, the Broadlinx software can be configured to monitor router outputs that are feeding critical downstream equipment (such as a transmitter). If the “primary” output signal is interrupted, the system will automatically select the “secondary” output that is carrying the same signal and trigger a system alarm.
SNMP/NetCentral Monitoring When enabled, the Trinix SNMP (Simple Network Management Protocol) agent allows the Grass Valley NetCentral application to monitor the Trinix router. The Trinix SNMP agent is supplied with the 2.2 version (and newer versions) of the Broadlinx software. By default, the SNMP agent is disabled; a hardware address (MAC) based license key must be obtained for the agent to become active.
Section 1 — Introduction NetCentral, or by any other SNMP management application. For more information, please refer to the NetCentral User Guide. Non-NetCentral Managers For information concerning registration of Monitoring Stations (SNMP Managers) for use with non-NetCentral SMNP management applications, please refer to Configuring an SNMP Manager’s IP Address on page 303.
Section 2 Planning Guide Introduction The information in this section is an overview of the Trinix Digital Video router; as well as a guide to help understand the Trinix Routing switcher’s configuration possibilities. If you are installing the router at this time, please read this section before reading the Hardware Installation section. The details that are needed for the planning and designing of your facility with the Trinix router in mind are included in this section.
Section 2 — Planning Guide Legacy Frames • DV-33128: 128 x 128 in 8 rack units (RU). See Figure 1 and Figure 2. • DV-33256: 256 x 256 in 15 RUs. See Figure 4 • DV-33512: 512 x 512 in 32 RUs. See Figure 7 and Figure 8. Trinix NXT Frames • TRX-NXT-128x128: 128 x 128 in 8 rack units (RU). See Figure 3 on page 42. • TRX-NXT-256x256: 256 x 256 in 15 RUs. See Figure 5 on page 44. • TRX-NXT-512x512: 512 x 512 in 32 RUs. See Figure 9 on page 48.
Trinix Frames Figure 2. DV-33128 Rear Panel.
Section 2 — Planning Guide Figure 3. TRX-NXT-256x256 Rear Panel.
Trinix Frames Figure 4.
Section 2 — Planning Guide Figure 5.
Trinix Frames Figure 6. TRX-NXT 256x256 Rear panel 071827609_NXT-256x256_rear.
Section 2 — Planning Guide Figure 7. DV-33512 Main frame and Associated Power Supply Unit.
Trinix Frames Figure 8. DV-33512 Main Frame and Power Supply Frame. PS IFC FAN IFC A 1 XPT BUS B A 2 B DC INPUT 2 NOT FUSED 42 - 54 VDC 30 - 24 AMPS DC IN + OP MON A DC IN - 3 B RP-33500 board.
Section 2 — Planning Guide Figure 9.
Trinix Frames Figure 10. DIP, Switch, and Monitor settings DV- 33512 and TRX NXT512x512 MONITOR FRAME 1024 0 512 1536 1415 1 2 13 3 2048 4 12 5 11 10 9 7 6 8 INPUT EXPAND OUTPUT EXPAND SYNC REDUNDANT INT XPT CNTL 60Hz ENABLE A B C 071827609_DIP, Switch, and Monitor settings- 512 LEVEL 0 SUPER 0 961121632 1415 1 2 80 13 48 3 4 64 12 64 80 5 48 11 112 9 7 16 96 10 6 32 8 ULTRA 0 Figure 11.
Section 2 — Planning Guide Figure 12. TRX-NXT-128x256 Asymmetric Frame-Back Fan modules and Exhaust vents Input and Output boards The outer four slots are Output boards See Figure 13 for detail The inner eight slots are Input boards DC Power inputs OPM Board Matrix boards SR module 071827610_128x256_rear 27612_LEVEL_MONITOR_128x256 Figure 13.
Trinix Frames Figure 14. TRX-NXT-256x512 Asymmetric Frame, Front and Back Fan modules and Exhaust vents Input and Output boards The outer four slots are Output boards The inner eight slots are Input boards DC Power inputs Matrix boards 071827609_256X512-Frame_Back-view 071827609_256X512-Frame_Front-view SR module Broadlinx boards See Figure 15 for detail Output boards Figure 15.
Section 2 — Planning Guide Figure 16.
Trinix Frames Figure 17.
Section 2 — Planning Guide Figure 18. Protected Paths, Signal Flow, and Power Supply System for TRX-NXT-512x512 Router.
Trinix Frames Power Supplies The symmetrical Trinix routing family uses an internal power supply. The 128 and 256 frames can use two power supplies. The optional (and recommended) second power supply provides redundancy and increased reliability due to load sharing; both supplies work less, creating less strain and decreasing the likelihood of failure of either unit. All power supplies are front loading, can be hot-swapped, and has its own fan for cooling.
Section 2 — Planning Guide The Asymmetrical Trinix router provides two isolated DC input power connectors only. An external AC to DC power supply provides power for these connectors or a customer may provide a 48 VDC power source. CAUTION External 48 VDC Inputs are not fused. Customers must ensure that the 48 VDC power sources, which they must provide, are properly fused.
Trinix Frames Figure 19. Airflow Openings for TRX-NXT-128x128 Frame. OUT OUT IN IN IN Right side Rear Left side Airflow openings for the 256 and 512 frames are shown in Figure 20 and Figure 21. Air is taken in from the bottom of the frame (cut-outs are located on the very bottom of the sides), and from the central area of the left and right sides.
Section 2 — Planning Guide Figure 21. Airflow Openings for TRX-NXT-512x512 Power Supply and Main Frame. Right side IN Rear OUT IN IN IN Left side IN OUT IN IN IN Using a set of central fan modules to cool the main chamber eliminates the possibility of cooling loss in one area due to failure of a single fan.The system will continue to operate if a fan does fail. Grass Valley recommends that you replace the fan and return the system to normal redundant operation as soon as possible.
Trinix Frames Figure 22. Airflow Openings for the TRX-NXT-128x256 Main Frame OUT 071827609_128x256-Cooling IN Figure 23. Airflow Openings for the TRX-NXT-256x512 Main Frame. Rear Side OUT 071827609_256X512-Frame_Cooling IN A two (2) RU space should be kept free on the bottom of the frame and fan to ensure enough airflow to prevent the routing switcher from overheating.
Section 2 — Planning Guide A two (2) RU vent option is also available to draw intake air in from the front of the frame. Figure 24. TRX-NXT-512x1024 OUT 1 RU Fans located at the top and bottom of the frame 071827612-512x1024-w-fans_r1.ai 071827612-512x1024-w-fans_r1.
Trinix Frames Sync Reference Options For synchronous vertical interval switching the same sync reference signal must be sent to the control system (for example, Jupiter CM-4000 or CM4400) and to the Trinix. (The Trinix will operate without a sync connection but switching will be non-synchronous.) Each sync input uses looping 75ohm BNC connectors. The sync signal can be NTSC or PAL black burst, or tri-level (HD) sync, and up to four sync signals can be mixed within the same frame on an outputboard basis.
Section 2 — Planning Guide available when a second NR-33000 is added; this would provide four monitor ports. • The SR-33500 Sync/OPM board, on the TRX-NXT-512x512 frames, provides four monitoring ports. • The TRX-SR Sync/OPM board, on the TRX-NXT-256x512 frames, provides four monitoring ports. • The TRX-OPM board, on the TRX-NXT-128x256 and TRX-NXT512x1024 frames, provides four monitoring ports.
Trinix Frames Figure 25. Input and Output Routing Through Matrix Board For 128 x 128 Routing Switcher.
Inputs 416-447 Inputs 384-415 Inputs 352-383 Inputs 320-351 Inputs 288-319 Inputs 256-287 0D 0C 0B 0A 09 08 JI_15 JI_14 JI_13 JI_12 JI_11 JI_10 JI_09 JI_08 0 31 0-31 JMx_40 31 0 0 14 (base) CONTROL 128-159 JMx_41 31 0 0 10 (mez) CONTROL 256-287 JMx_42 31 0 0 384-415 0 17 (base) CONTROL JMx_43 13 (mez) CONTROL 96-127 JMx_44 31 0 0 15 (base) CONTROL 224-255 JMx_45 31 0 0 11 (mez) CONTROL 352-383 JMx_46 31 0 0 16 (base) CONTROL 480-511 JMx_47
Trinix Frames Figure 27.
Section 2 — Planning Guide For a description of the various Input, Output, and Matrix boards available for Trinix, contact your Grass Valley account representative. Analog Processing Control The VI-33100 universal input module accepts analog as well as digital signals.
Trinix Frames Alarm System The operation of cooling fans, frame power supplies, on-board power supplies, and primary vs. secondary Broadlinx boards are all monitored. Any alarm for these critical items is treated as a Primary alarm. With the release of Broadlinx 3.1, the router’s system alarm has two modes, “No alarms” and “Primary alarm.” All alarms (multiple fan failure, power supply failure, etc.) are considered Primary alarms. All major components include a local alarm LED.
Section 2 — Planning Guide All of the alarm and status information is gathered by the Broadlinx technology to make it available to the user via Web pages. For more information, see Section 6-Broadlinx Software on page 285.
Duplication and Expansion Duplication and Expansion Trinix router’s inputs and outputs are designed to duplicated or expanded using passive splitter/combiner expansion panels. Unused connectors should be terminated for optimum performance. Note For Jupiter-controlled (0-based) systems, the input/output numbers in the following discussion should be decreased by one (1). For example, block 1256 should be understood as block 0-255, etc.
Section 2 — Planning Guide Figure 30. PE-33016 Used to Provide 16 Dual Outputs. 1A 1B (Terminated) Interior side 1A 1B Exterior side In the splitting application, a port expander can be used to provide dual outputs in groups of 16 outputs. Use the PE33016 Port expander for HD operations and the PE2x2-3G Port expander for 3Gp/s operations. All outputs are non-inverting.
Duplication and Expansion In this application, 16 of the PE-33016 or PE2x2-3G rear BNCs can be used for inputs (outputs from the router) and all 32 of the front BNCs can be used for outputs.1 The MK-33000 Mounting kit can have a maximum of 16 PE-33016 or PE2x23G modules mounted. The mounting kit is eight rack units high and is approximately four inches deep. Figure 32 on page 72 shows a 128 input router with a single port expander mounted in an MK-33000.
Section 2 — Planning Guide Figure 32.
Duplication and Expansion Figure 33. PE-33016 Port Expanders Provides 256 Dual outputs for 256 Input Switcher. A B C EXTERIOR 16 PE-30016 Expander Modules in MK-33000 Mounting Kit INTERIOR 3.25 in.
Section 2 — Planning Guide Output Duplication - Quad The PE-33008 Port expander can provide quad outputs in groups of 16 outputs for SD or HD options. The PE-33008 Port expander functions for data rates from 270Mb to 1.5 Gb. All outputs are non-inverting.
Duplication and Expansion to the system shown in Figure 33; this arrangement would require 16 PE33008 Port expanders. Figure 34.
Section 2 — Planning Guide Expanded Systems The PE-33016, PE-2X2 3G, and PE-33008 Port expanders can be used to combine outputs (SD and HD options) for an input expansion application. The PE-2X2 3G is required for 2X2 expansion in 3G systems, but will also work for SD and HD systems. The PE-33016 and PE-33008 will not work with 3G systems. In Figure 35 and Figure 36, a PE-33016 or PE-2X2 3G is downstream of the router.
Duplication and Expansion Possible expanded configurations include: • 1024 inputs x 512 dual outputs • 1024 inputs x 1024 dual outputs • 512 inputs x 1024 outputs • 2048 inputs x 2048 outputs (SD and HD only) • 1024 inputs x 1024 outputs Some of these configurations are shown on the following pages. Notice that the same port expander type is used for both downstream combining (for input expansion) and upstream splitting (for output expansion). All outputs are non-inverting.
Section 2 — Planning Guide Figure 36. Examples of Input and Output Expansion.
Duplication and Expansion Figure 37. 1024 x 1024 Systems.
Section 2 — Planning Guide Figure 38.
Duplication and Expansion Figure 39.
Section 2 — Planning Guide Figure 40.
Duplication and Expansion The 512x1024 Routing Switcher The 512x1024 Routing switcher can be duplicated to form the following frames: • 1024x1024 • 512x2048 • 1024x2048 • 2048x2048 Note The 2048x2048 frame can only process SD or HD signals do to the port expander that must be used (TRX-PE-33008). Examples of each of these frames can be found on the pages that follow. The 1024x1024 Frame This configuration can process SD,HD and 3Gb/s signals. Figure 41.
Section 2 — Planning Guide The 512x2048 Frame This configuration can process SD,HD and 3Gb/s signals. Figure 42.
Duplication and Expansion The 1024x2048 Frame This configuration can process SD,HD and 3Gb/s signals. Figure 43.
Section 2 — Planning Guide The 2048x2048 Frame This configuration can only process SD and HD signals. Figure 44.
Duplication and Expansion Termination for Pre-wired Expansion Frames The unused BNC connectors on the port expanders should be terminated for best performance. However, it may be desirable to install an empty or partially filled frame with associated cabling to simplify future expansion. When such cabling connects to a Port expander that is carrying active signals, special termination hardware is required.
Section 2 — Planning Guide Figure 46. 512 x 512 System Expanded to 1024 x 512 Frame 0 1 - 512 Trinix 1 - 512 512 x 512 32 PE 33016 used as combiners Future input wiring Frame 1 (unused) Trinix 512 x 512 outputs 1 - 512 Installed pre-wiring Output slots should be terminated using LD-33100 Loader boards Frame 1 contains no input or output boards, but the wiring has already been installed between Frame 1 and the PE-331016 Port expanders. Now consider Output 1 of Frame 0.
Duplication and Expansion The concepts in this example can be applied equally to both HD and SD systems with PE-33008 Port expanders. For example, they would apply to a 1024 x 1024 system that is pre-wired for expansion to 2048 x 1024 (similar to the system shown in Figure 37 on page 79, where LD-33100 Loader boards would be installed in place of output boards in Frames 4 through 7). Output Expansion The LD-33100 Loader boards may also be used for output-expandable systems.
Section 2 — Planning Guide would be a 512 x 512 pre-wired for expansion to 1024 x 1024 (similar to the system that is shown in Figure 37 on page 79). Only frame 0 would be active in the 512 x 512 router, so only the port expanders connected to Frame 0 would be in use. Frame 1’s inputs are connected to the top left PE; while Frame 2’s outputs are connected to the top right PE. Therefore Frame 1’s input slots would require LD-33100s and Frame 2’s output slots would require LD-33100s.
Duplication and Expansion Figure 50. Monitoring With Output-expanded System.
Section 2 — Planning Guide Figure 51. Expansion of two 128X256 Frames to form a 256x256 with Output Monitoring. Legend: MON outs (4) MON outs (4) (Outputs 257-260) CAS = Cascade Trinix NXT 128x256 Switcher MON = Monitor Inputs 1-128 Ins = Inputs Outputs 1-256 Frame 0 Outs = Outputs CAS ins (4) 4 75 ohm coaxial cables 16 ea. 16x2:2 COMBINERS Note: The order of the frames for the monitor cascade does not matter.
Duplication and Expansion Figure 52. Expansion of two 512x1024 Frames with Output Monitoring. Legend: MON outs (4) MON outs (4) (Outputs 513-516) CAS = Cascade Trinix NXT 512x1024 Switcher MON = Monitor Inputs 1-512 Ins = Inputs Outputs 1-1024 Frame 0 Outs = Outputs CAS ins (4) X 2 4 75 ohm coaxial cables 16 ea. 16x2:2 COMBINERS Note: The order of the frames for the monitor cascade does not matter.
Section 2 — Planning Guide Figure 53. Expansion of two 256x512xFrames with Output Monitoring. Legend: MON outs (4) MON outs (4) CAS = Cascade (Outputs 513-516) Trinix NXT 256x512 Switcher MON = Monitor Inputs 1-256 Ins = Inputs Outputs 1-512 Frame 0 Outs = Outputs CAS ins (4) 4 75 ohm coaxial cables 32 ea. 16x2:2 COMBINERS Note: The order of the frames for the monitor cascade does not matter.
Protected Paths Protected Paths Overview The Protected path function is designed to monitor router outputs that are feeding critical downstream equipment and, in the event of signal loss, will automatically select the output that is carrying the same signal and trigger the system alarm. The Protected path function assumes the following: • Supported Output Boards provide the output signals that will be monitored. These boards allow individual outputs to be enabled or disabled using software controls.
Section 2 — Planning Guide the primary path and if necessary will disable the primary path output driver and enable the secondary path output driver. Notice that the two paths use independent sets of hardware. Figure 54.
Protected Paths Figure 55.
Section 2 — Planning Guide Planning The following section describes the Protected path planning process. Note The following discussion is based on a 1-based numbering scheme (Encore Control system). If you are using a zero-based numbering system (Jupiter AccuSwitch Control system), subtract 1 from all instances of input/output numbers. TRX-NXT-512x512 The recommended Protected path ranges for TRX-NXT-512x512 routers are as follows: Table 3.
Protected Paths be re-arranged in a symmetrical pattern in order to simplify Protected path configuration. Table 5. TRX-NXT-512x512Protected Paths (Example of Sequential Numbering) Primary Path Out Secondary Path In Out In Name No. Name No. Name No. Name No. AirPP 1 MCPP 1 AirSP 257 MCSP 257 Sat1PP 2 StuAPP 2 Sat1SP 258 StuASP 258 Sat2PP 3 StuBPP 3 Sat2SP 259 StuBSP 259 NetPP . . . . . . . . . . . .
Section 2 — Planning Guide TRX-NXT-256x256 Recommended Protected path ranges for TRX-NXT-256x256 routers are as follows: Table 7. Recommended Protected Path Ranges Primary Path Secondary Path Out In Out In 1-128 1-128 129-256 129-256 For example, to protect an output in the range 1-128, choose a corresponding input in the range 1-128; this will be the primary path. For the secondary (failover) path, choose an output in the range 129-256 and a corresponding input in the range 129-256.
Protected Paths number on the rear panel itself since the silk screen numbers only run from “1” to “32.”) In Jupiter-controlled systems, the Name column in these tables corresponds to the “logical input/output name.” The entries in the Number column will correspond to the physical input/output number. Figure 56.
Section 2 — Planning Guide The next example applies to existing systems where re-arrangement of cables in a sequential pattern is not practical or desirable: Table 9. TRX-NXT-256x256 Protected Paths (Example of Non-Sequential Numbering) Primary Path Out Secondary Path In Out In Name No. Name No. Name No. Name No. AirPP 21 MCPP 12 AirSP 190 MCSP 165 Sat1PP 53 StuAPP 54 Sat1SP 133 StuASP 248 Sat2PP 109 StuBPP 98 Sat2SP 189 StuBSP 129 NetPP . . . . . . . . . . .
Protected Paths The maximum number of Protected paths for a TRX-NXT-128x128 router is 64. A more detailed example is shown in Table 11. This table shows a sequential wiring scheme for a system yet to be installed or a system where cables will be re-arranged in a symmetrical pattern in order to simplify Protected path operation. Table 11. TRX-NXT-128x128 Protected Paths (Example Of Sequential Numbering) Primary Path Out Secondary Path In Out In Name No. Name No. Name No. Name No.
Section 2 — Planning Guide Asymmetrical Frames When Using the Protected Paths feature with the Asymmetrical frames, you will be able to protect half the outputs but those protected outputs cannot be greater than half the number of inputs. For example, the 128x256 router: • Outputs 0 – 127 (1-128) could protect outputs 128 - 255 (129-256) but only 64 of these outputs.
Protected Paths Worksheet for Protected Path Implementation Based on the preceding examples, specific primary and secondary paths should be identified and noted. The following worksheet is provided for this purpose. Table 16. Protected Paths Worksheet Primary Path Output Name Secondary Path Input No. Trinix NXT — Installation and Service Manual Name Output No. Name Input No. Name No.
Section 2 — Planning Guide Control Systems Jupiter Facility Control System The Jupiter control system can be used to operate the Trinix router using a VM-3000, CM-4000 or CM-4400 System Controller (Figure 57). The VM/ CM can receive switching commands from a variety of serial sources, including Jupiter control panels or an automation computer. Figure 57. Control Connections to Jupiter Facility Control System (example).
Control Systems Depending on the size of the Routing switcher, this bus may require intermediate buffering through a CB-3000 Control Buffer.
Section 2 — Planning Guide SMS 7000 / Encore Control These control systems use an Ethernet connection to the Broadlinx application, which runs on the NR-33000 Sync/NIC/OPM board. The system is operated in the Internal Crosspoint Bus Control mode, during which the Broadlinx board sends commands to the Crosspoint bus. Refer to the SMS 7000 or Encore documentation for control system planning information.
LAN and Com Bus Connections LAN and Com Bus Connections The LAN (NIC) connections use a standard 10/100BaseT twisted pair cable with RJ-45 connectors (Cat 5E Enhanced is recommended). Shielded cable is also recommended, maximum length 60 meters.1 The maximum length for a non-shielded cable is 100 meters. LAN Monitoring Only (Jupiter Control) In this arrangement, the router is under Jupiter control. The only purpose of the connection is LAN monitoring using Broadlinx web pages or SNMP. See Figure 58.
Section 2 — Planning Guide SMS Control In this arrangement, the router is under SMS control via a LAN connection. The PC is used to configure the SMS and is available for Broadlinx or SNMP monitoring. See Figure 59. Figure 59. SMS Connections to Trinix. NIC A connector 7000 SMS MCPU frame Trinix Ethernet connector NIC B connector Ethernet switch PC Another Ethernet cable must be connected from the NIC B jack to the network switch if you plan to usea secondary NR-33000 board.
LAN and Com Bus Connections Encore Control For information about the Encore control system working with Trinix, see Encore Control on page 375. Com Bus In multi-frame systems, a Com Bus” is used to loop through each frame, up to a maximum of four. The Com Bus is intended to provide Routing switcher monitoring of multiple frames using Broadlinx web pages or SNMP. The Com Bus uses a 10/100BaseT (Cat 5 twisted pair) cable with RJ45 connectors. Shielded cable is recommended, maximum length 60 meters.
Section 2 — Planning Guide System Monitoring Applications For a detailed description of Broadlinx web page monitoring using Internet Explorer, see Broadlinx / Internet Explorer Monitoring on page 311. For a brief description of system monitoring using SNMP/NetCentral, see SNMP/NetCentral Monitoring on page 37.
Specifications Specifications Electrical General Connectors: 75-ohm BNC Input boards: 32 inputs each. Output boards: 32 outputs each. Matrix boards: DM-256-3G: 256 inputs x 256 outputs DM-128-3G: 128 inputs x 128 outputs DM-128R-3G: 128 inputs x 128 outputs DM-33512: 256 inputs x 256 outputs DM-33100: 128 inputs x 128 outputs. Serial Digital Inputs Level: 800 mV p-p (+/-10%) 75-ohm terminating Return Loss: 3G: >/= 15 dB from 5 MHz to 3 GHz (20 dB typical). HD: >/=15 dB from 5 MHz to 1.
Section 2 — Planning Guide 256X512 Asymmetric Sync Inputs Level: Nominal 1 Vp-p (+/-6 dB) video or black burst Tri-level sync also accepted Video Standard: NTSC/PAL/HDTV, auto-detected Return Loss: >/= 36dB from 100 KHz to 5 MHz >/= 30dB from 5 MHz to 10 MHz >/= 20dB from 10 MHz to 30 MHz 128x256 Asymmetric Sync Inputs Level: Nominal 1 Vp-p (+/-6 dB) video or black burstTri-level sync also accepted Video Standard: NTSC/PAL/HDTV, auto-detected Return Loss: >/= 40dB from 100 KHz to 20 MHz >/= 30dB
Specifications HI-33200 Input board (SD/HD): For SD operation, equalization is automatic up to 300 meters using Belden 1694A or an equivalent coax cable. For HD operation, automatic up to 100 meters of Belden 1694A or an equivalent coax cable. SI-33110 Input board (SD): equalization is automatic up to 300 meters of Belden 1694A, 250 meters using 8281 or an equivalent coax cable for SD equalizer at 270 Mbps. Reducing to 150 meters at 540 Mbps.
Section 2 — Planning Guide Voltage Range: 100-240 VAC 50-60 Hz, universal, auto-ranging (fuses must be selected and installed as appropriate for mains voltage) For fuses F101, F105, F110- F113, F201, F205, and F210-F213 replace with fuse rated “5A 125V Fast Acting” (GV PN: 59-5053-00, LITTELFUSE PN: 39515000440) These fuses are accessible from the rear panel (underneath the two fuse covers on the rear of chassis).
Specifications 128 x 256 frame: 25.0 A 256 x 512 frame: 25.0 A 512 x1024 frame: 25.0 A Hold-up Time: Minimum 15 ms at full load Conducted Emissions: per FCC Class B, EN55022 Class B Power Supply DC Output Voltage: +48 (+/-0.5) VDC Current: 128 x 128 frame: 20 A/supply (full redundancy) 256 x 256 frame: 26 A/supply (full redundancy) 512 x 512 frame: approximately.
Section 2 — Planning Guide 42 A @ 48 VDC CASE B: A fully configured system that is operating in boosted mode. DV-33128 and NXT-128 13.2 A @ 48 VDC DV-33256 and NXT-256 26.3 A @ 48 VDC DV-33512 and NXT- 512 52.
Specifications Intake: Minimum of 2RU below the Trinix 512x1024 chassis for cool intake air. Exhaust: Minimum of 3RU above for warm exhaust air. The 3RU area requires a total exhaust area (top, sides, back or front) of 516 sq. CM (80 sq. in.). Airflow requirements for chassis: 31 cubic meters/minute (1085 cubic feet /minute). Physical Frames 128 x 128 Frames Main frame: 8 RU: 14 in. high x 19 in. wide x 17.50 in. deep (356 x 483 x 445 mm) 256 x 256 Frames Main frame: 15 RU: 26.25 in. high x 19 in.
Section 2 — Planning Guide 120 Trinix NXT — Installation and Service Manual
Configuration Configuration Quick Look Building Block Size: 32 Inputs or 32 Outputs 3G, HD, or SD rate I/O modules Options: Dual outputs (3G, HD, and SD), quad outputs (HD and SD only) Additional monitor outputs (2) Redundant sync inputs (2) Redundant monitor/status/control Redundant power supplies Standards Supported: SMPTE 259M-1997, SMPTE 292M-1998, SMPTE 424M Standard Connectors:75-Ohm BNC Output Monitor: Yes, 2 standard Sync Reference Input:Yes, 2.
Section 2 — Planning Guide Table 18. 256x256 Matrix Specifications 160 x 160 192 x 192 224 x 224 256 x 256 # of Frame 1 1 1 1 # Input Boards 5 6 7 8 # Output Boards 5 6 7 8 # of Matrix Boards 4 4 4 4 Weight in pounds (kilograms) 163 (74) 169 (77) 176 (80) 182 (83) Power Consumption* (W) ~850 ~900 ~950 ~1000 Matrix Size Table 19.
Configuration Matrix Size 160 x 160 192 x 192 224 x 224 256 x 256 Weight in pounds (kilograms) With two power supplies 163 (74) 169 (77) 176 (80) 182 (83) Power Consumption* (W) ~850 ~900 ~950 ~1000 256 x 256 256 x 512 32 32 ~1000 ~1400 Table 21. 512x512 Matrix Size Specifications (cont.
Section 2 — Planning Guide Table 23.
Section 3 Hardware Installation Summary of Installation Procedure The following list is a summary of the steps that are needed for the installation of the Trinix Routing Switcher System. 1. Pre-installation steps 2. Rack requirements 3. Connecting the Power supplies 4. Connecting and Configuring the Reference signals 5. Connecting the cables 6. Control and Monitoring Systems 7. Optional steps 8. Power up the Routing switcher Additional details may be found elsewhere in this manual as indicated.
Section 3 — Hardware Installation Customer-Supplied Rack Requirements The Routing switcher is shipped without a rack; the router should be mounted into a 19-inch wide frame or other suitable enclosure that provides power and cooling facilities for the equipment. A two (2) RU space should be kept free beneath the fan on each 512x1024 frame to ensure enough airflow to prevent the routing switcher from overheating. A two (2) RU vent option is also available to help draw air in from the front of the frame.
Note For more information about Power Supply connections with Asymmetric frames, see Trinix Asymmetrical Power Supply Configurations on page 227. Grass Valley strongly recommends, whenever possible, using the AC high line to reduce line currents and heat within the power supplies. The following items should be considered during the installation process. Fuse Differences Make sure that you use the correct fuse when you change from 120Vac to 220Vac.
Section 3 — Hardware Installation Install the supplied “IFC” cables: 1. Connect the long cable from the FRAME IFC connection on the power supply frame to the PS IFC connection on the main frame. • The FRAME IFC connection is located in the lower right side of the power supply frame (Figure 68 on page 141). 2. Connect the short cable from the FAN IFC connection on the center right side of the main frame to the FAN IFC connection in the fan module section, which is above the Input and Output connectors.
Summary of Installation Procedure Note The 512x1024 uses the NR-33000 NIC/Sync/OPM boards exclusively for sync reference. Video standard operation (that is, NTSC, PAL, or HDTV) is detected automatically by the system. The sync signal can be video, black burst, 2 V composite sync, 4 V composite, or tri-level. Tri-level reference should be used with HD. Note Each sync input uses looping-75-ohm BNC connectors; if a loop through is not used, the loop BNC should have a 75-ohm terminator. 2.
Section 3 — Hardware Installation 4. On High Definition and 3G Routing switchers: a. The Signal reclocking mode can be set for each output on an output board. Auto is the factory default setting. • This setting means that properly-formed standard data-rate signals will be reclocked. Other signals will be bypassed or not reclocked. See Output Reclocker Bypass Settings on page 197 for details. This reclocking feature is not included with SD Routing switchers do not include the reclocking feature.
Summary of Installation Procedure Connecting the Cables 1. Make sure all boards and cards are seated in their backplane sockets. This step is generally not a problem since the boards and cards are held in place with locking extractors. As previously described in Duplication and Expansion on page 69, either the PE-33016 or PE-2X2-3G Port expanders can be used to provide dual outputs in blocks of 16. The PE-33008 Port expander can be used to provide quad outputs in blocks of 16. 2.
Section 3 — Hardware Installation 2. Connect and configure the LAN and Com Bus for the Broadlinx board (NR-33000 NIC/Sync/OPM board). • These Configuration steps are covered in the specific control systems. The Broadlinx software can be configured to monitor router outputs that are feeding critical downstream equipment (such as a transmitter) for Protected path operations.
Summary of Installation Procedure Note All alarms are now reported as primary alarms. For example, a single fan failure, which would be a secondary alarm in the past, will now be reported as a primary alarm. Powering Up the Routing Switcher Connect the AC power cords to power up the system. • If the LED on the front panel turns to green after the first few seconds of operation, the system is operating properly.
Section 3 — Hardware Installation Figure 61. Installation of Rack Spacers INSTALL RACK SPACERS ONLY WHEN MOUNTING HOLES ARE RECESSED MORE THAN 0.6 INCH (15.2 MM) FROM FRONT SURFACE OF RACK (DIMENSION ). SPACERS WILL POSITION SWITCHER CHASSIS SO THAT ACCESS DOOR CAN BE OPENED FAR ENOUGH TO PERMIT REMOVAL OF RIGHT-HAND COMPONENTS. EACH SPACER IS SECURED WITH 2 RACK SCREWS (SUPPLIED). RACK SPACERS FOR DV-33128 CHASSIS (KIT NO. 44-052989-001) RACK SPACERS FOR DV-33256 CHASSIS (KIT NO.
Summary of Installation Procedure Figure 62. TRX-NXT-128x128 and 256x512 Front View (door removed).
Section 3 — Hardware Installation Figure 63.
Summary of Installation Procedure Figure 64. TRX-NXT-256 X 256 Front View (door removed).
Section 3 — Hardware Installation Figure 65.
Summary of Installation Procedure Figure 66. TRX-NXT-256x256 Rear Panel.
Section 3 — Hardware Installation FAN A FAN B FAN C FAN D FAN ALARM FAN ALARM FAN ALARM FAN ALARM Fan modules FAN ALARM FAN ALARM Figure 67.
Summary of Installation Procedure Figure 68. DV-512 main frame and power supply frame connections.
Section 3 — Hardware Installation Figure 69.
Summary of Installation Procedure Figure 70.
Section 3 — Hardware Installation Figure 71.
Summary of Installation Procedure Figure 72. TRX-NXT-256x512 Asymmetric Frame, Front and Back Fan modules and Exhaust vents Input and Output boards The outer four slots are Output boards The inner eight slots are Input boards DC Power inputs Matrix boards 071827609_256X512-Frame_Back-view 071827609_256X512-Frame_Front-view SR module Broadlinx boards See Figure 73 for detail Output boards Figure 73.
Section 3 — Hardware Installation Figure 74.
Summary of Installation Procedure Figure 75.
Section 3 — Hardware Installation Setting the Rear Panel Dip Switch OPEN CLOSED INPUT EXPAND OUTPUT EXPAND SYNC REDUNDANT INT XPT CNTL 60Hz ENABLE A B C The above figure is an example of a DIP switch that is located on the rear panel of the routing switcher. The different settings on this switch are explained in the sections below Input/Output Expand See Duplication and Expansion on page 186. Sync Redundant Note This switch may be labeled “VIT Redundant” on some units.
Setting the Rear Panel Dip Switch tion is changed, the board must be rebooted. This switch is used in multiple frame systems when there are multiple active NR boards that are connected to the Com Bus. For example, if two 128 or 256 size frames are used in a fully redundant protected path system. Note If the “A” switch is closed when the NR33000 board is installed in the frame, it will not drive the Com Bus.
Section 3 — Hardware Installation Control Connector This connector is reserved for future use.
Power Supply Notes Power Supply Notes Power supply specifications are shown in AC Power Input on page 115. Ventilation is critical for the Trinix power supplies. The power supplies should not be run when the fan is not working. The power supply will shut down automatically to prevent damage if the supply begins to overheat. Note Grass Valley strongly recommends that you use redundant power supplies. The back panel of the frame provides a separate AC connector for each supply.
Section 3 — Hardware Installation Figure 77. Fuse Location for the 256x512 Router 071827611_fuse-loc_256x512 Location of Fuses The 512x1024 Asymmetrical Frame The fuse locations for the 512x1024 Asymmetric frame is similar to the 256x512 frame, except there are two fuse covers, one in the upper section and one in the lower section. The upper fuses are for the fan modules, both the upper (F110-F113) and lower fans (F210-F213). These fuses have LEDs to indicate the presence of a blown fan fuse.
Power Supply Notes Contact Grass Valley's Technical support for replacement fuse information (see Contacting Grass Valley on page 4). Installing the TRX-NXT-128x128 and TRX-NXT-256x256 Frames AC Applications Power supplies are factory-installed and designed to be hot swappable. Note Fuses must be selected and installed as appropriate for mains voltage.
Section 3 — Hardware Installation CAUTION Do NOT cross these cables. Output 1 MUST go to Input 1 and Output 2 to Input 2 in order for the alarm system to operate correctly. The pinouts are shown on Table 26 on page 170. An illustration of the power connectors is shown on Figure 68 on page 141. The power supply modules are factory-installed and designed to be hotswappable. Note Fuses must be selected and installed as appropriate for mains voltage.
Power Supply Notes Power supply connector (Ground) Cable description Yellow/green (Ground) Plain black Main frame connector (Ground) (Ground) DC Out + (left) 1 (red) DC In + (left) DC Out + (right) 2 (blue) DC In + (right) DC Out - (left) 3 (white) DC In - (left) DC Out - (right) 4 (yellow) DC In - (right) TRX-NXT-128x256 and TRX-NXT-256x512 The 128x256 and 256x512Trinix Asymmetrical frames provide two DC input connectors.
Section 3 — Hardware Installation 2. Connect the power IFC cable to the PMBUS B connector on the back of the main frame. DC Applications Connect the DC source to the DC Input A and DC Input B connectors of the main frame. Note 156 For DC applications, fusing must be provided externally in accordance with local electrical regulations. DC input specifications and characteristics for the Trinix are shown in the DC Power Input section.
Sync Reference Connections Sync Reference Connections For synchronous vertical interval switching, the same sync reference signal must be sent to the control system and to the Trinix. (Trinix will operate without a sync connection but switching will be non-synchronous.) For SMS 7000 and Encore systems, sync must be connected to the Sync 1 input. Note Some TRX-NXT-512x512 power supply units are not labeled correctly. See Figure 68 on page 141 for correct REF IN connector labeling.
Section 3 — Hardware Installation Figure 79. Single Sync Reference Options SMS MCPU or Encore SCB Sync 1 Sync 1 OR Jupiter Sync 1 *Sync Redundant switch = Off T 2 Primary NR-33000 1 All output boards Sync Line Frames with Dual-Sync References In the example shown in Figure 80 on page 159, the Dual-Sync reference is sent to the Encore and Jupiter control system and to two connections on the Trinix router.
Sync Reference Connections Figure 80. Dual Sync Reference Options SMS MCPU or Encore SCB Sync 1 Sync 1 OR Jupiter Sync 1 Sync Redundant switch = Off Sync 2 T T 2 Primary NR-33000 1 Output board(s) on SL1 Output board(s) on SL2 Sync Lines Two independent sync signals can be connected to the Trinix. They may be different standards (for example, SD and HD) or different phases of the same standard (for example, NTSC and delayed NTSC).
Section 3 — Hardware Installation Frames with Multi-Sync References The Multi-sync reference arrangement is similar to what is described in Frames with Dual-Sync References on page 158, except that all four possible sync references are used. This is an option with the TRX-NXT-128x128, TRX-NXT-256x256, TRX-NXT-128x256, TRX-NXT-256x512, and the TRXNXT-512x1024 Routing switchers. Figure 81.
Sync Reference Connections For a discussion concerning which sync reference should be connected to the control system, see Sync Connection to Control System on page 159.
Section 3 — Hardware Installation Frames with Sync Redundant NR Operation This is an option with the TRX-NXT-128x128, TRX-NXT-256x256, TRXNXT-128x256, TRX-NXT-256x512, and the TRX-NXT-512x1024 Routing switchers. Figure 82.
Sync Reference Connections For a discussion concerning which of the two sync references should be connected to the control system, see Sync Connection to Control System on page 159.
Section 3 — Hardware Installation TRX-NXT-512x512 with Multi Sync References Figure 83.
Sync Reference Connections TRX-NXT-512x512 with Single Sync Reference and Single/Dual NR-33000 The example shown in Figure 84, is a TRX-NXT-512x512 with Single Sync Reference and Single/Dual NR-33000. See Sync Reference Connections on page 157 for more information about Sync Reference. Figure 84.
Section 3 — Hardware Installation TRX-NXT-512x512 with Dual Sync References and Single/Dual NR-33000 Figure 85. SMS MCPU or Encore SCB Sync 1 Sync 1 OR Jupiter Sync 1 Sync 2 SR-33500 Sync Redundant switch = Off “C” switch = Off 1 2 3 4 T T 1 Primary NR-33000 2 See Note Some TRX-NXT-512x512 power supply units are not labeled correctly. See Figure 68 on page 141 for correct REF IN connector labelling.
Sync Reference Connections TRX-NXT-512x512 with Dual Sync References and Redundant NR Operation Figure 86. SMS MCPU or Encore SCB Sync 1 Sync 1 OR Jupiter Sync 1 SR-33500 Sync Redundant switch = On “C” switch = On 1 2 Sync 2 3 4 2 1 Primary NR-33000 4 3 Secondary NR-33000 T T Output board(s) on SL1 Some TRX-NXT-512x512 power supply units are not labeled correctly. See drawing on Figure 68 on page 141 for correct REF IN connector labelling.
Section 3 — Hardware Installation Broadlinx operation is also redundant. See Sync Connection to Control System on page 159 for information concerning which of the two sync references should be connected to the control system. TRX-NXT-512x512 with Multi Sync References and Dual NR-33000 Figure 87.
Sync Reference Connections board in the Primary slot will feed Sync Lines 1 and 2; the NR board in the Secondary slot will feed Sync Lines 3 and 4. • If the Primary NR is removed, Sync Lines 1 and 2 will automatically switch to the SR-33500. • If the Secondary NR is removed, the SR will feed Sync Lines 3 and 4. See Sync Connection to Control System on page 159 for information concerning which of the four sync references should be connected to the control system.
Section 3 — Hardware Installation NR/SR-33000 / SR-33500/ TRX-SR V-Phasing A V-phasing feature, available with the NR-33000, SR-33000 with Rev B FPGA Software Update, and SR-33500 allows the user to adjust the switch point from the -1 line to +2.5 lines relative to the nominal switch point for the video standard being used.
NR/SR-33000 / SR-33500/ TRX-SR V-Phasing +1.0 line On On Off +1.5 line Off On Off +2.0 line On Off Off +2.5 line Off Off Off Table 28 shows the switches providing adjustment relative to SR-33500 Reference 3. Table 28. Switch Point Shift For Signals Referenced to Ref 3. Switch point relative to Ref. 3 SR-33500: S102-1 SR-33500: S102-2 SR-33500: S102-3 -1.0 line On On On -0.5 line Off On On Coincident (default) On Off On +0.5 line Off Off On +1.0 line On On Off +1.
Section 3 — Hardware Installation TRX-SR V Phase and Source Information Table 30 shows the switches providing adjustment for TRX-SR, S2. Table 30. Switch Point Shift for TRX-SR, S2 TRX-SR, S2:1-3 Reference 1 TRX-SR, S2:4-6 Reference 2 -1.0 line On, On, On, On, On, On, -0.5 line Off, On, On Off, On, On Coincident (default) On, Off, On On, Off, On +0.5 line Off, Off, On Off, Off, On +1.0 line On, On, Off On, On, Off +1.5 line Off, On, Off Off, On, Off +2.
NR/SR-33000 / SR-33500/ TRX-SR V-Phasing Table 32.
Section 3 — Hardware Installation Figure 88. NR-33000 NIC/Sync/OPM board AC and dual power systems DC and single power systems Power Input Select Jumper JN2 The NR-33000 PS alarms are ignored for all Asymmetrical frames. Secondary alarms are no longer supported. Always set this jumper to the "Suppress SALARM" position. SMPTE Alarm Jumper JN1 Report SALARM Supress SALARM Location of Lithium-Ion battery Switch S3.
NR/SR-33000 / SR-33500/ TRX-SR V-Phasing Figure 89. SR-33000 Sync/OPM reference card Monitor expansion jumpers JN3 and JN4. DC and single power supply systems: set JN2 to “DC.” AC and Dual power supply systems: set JN2 to “AC.” Switch S2.
Section 3 — Hardware Installation Figure 90. SR-33500 Sync/OPM reference card Switches S101 and S102. DIP switches S103, S104, and S610 are reserved for future use. The default setting for these switches is “Open.
NR/SR-33000 / SR-33500/ TRX-SR V-Phasing Figure 91. TRX-SR DIP Switches DIP Switches S1-S4 071827609_TRX-SR The TRX-SR Board LEDs The TRX-SR uses the following LED colors for status (see Table 34). Table 34. TRX-SR Status LEDs LED Color Definition MSTR ALARM Red A standard Trinix Board Alarm indicating that something is wrong on this board. IN USE Yellow An output is being monitored by this module. P2V1 Green The +2.1V supply is OK. P3V3 Green The +3.3V supply is OK.
Section 3 — Hardware Installation Figure 93. TRX-OPM Switch DIP Switche S1 Used for sync selection configuration monitor on the 128x256 and 512x1024 frames only 071827612_TRX-OPM_r1 Table 35.
NR/SR-33000 / SR-33500/ TRX-SR V-Phasing Figure 94. RP-33500 512 x 512 Rear Panel board DC and single power supply systems: set JN1 to “DC.” AC and Dual power supply systems: set to “AC.
Section 3 — Hardware Installation Figure 95. 3G Input Base and Mezzanine Boards TRX-HI-3G Input Mezzanine, which is also used in the HI1024 071827608-3g-mez-input TRX-HI-3G 071827608-3G-baseboard.
NR/SR-33000 / SR-33500/ TRX-SR V-Phasing Figure 96.
Section 3 — Hardware Installation Figure 97.
NR/SR-33000 / SR-33500/ TRX-SR V-Phasing Figure 98.
Section 3 — Hardware Installation Figure 99.
Output Board Configuration Output Board Configuration This adjustment applies to systems with more than one sync reference. Each output board provides a block of 32 outputs and by factory default, each block is assigned to sync reference 1. If additional references are used, DIP switch S5 on each output board is used to assign the board to one of four possible sync lines. Figure 100. Sync Reference CLOSED OPEN SYNC SEL A SYNC SEL B AUTO RCLK Table 36.
Section 3 — Hardware Installation Duplication and Expansion Trinix routing switchers are designed to duplicate/expand inputs and outputs using passive splitter/combiner expansion panels. Whenever an expansion panel is connected, signal gain must be increased to compensate for the added circuitry. In addition, unused connectors should be terminated for optimum performance. Note For Jupiter-controlled (0-based) systems, the input/output numbers should be decreased by one (1).
Duplication and Expansion The necessary gain increase is accomplished by 1. Closing the rear-panel Input Expand DIP switch. For the location of this switch, see: • Figure 63 on page 136 [128 x 128] • Figure 4 on page 43 [256 x 256] • Figure 8 on page 47 [512 x 512] • Figure 12 on page 50 [128 x 256] • Figure 14 on page 51 [256 x 512] 2. Setting the output board jumpers (or DIP switches) to the Expand Enable position (as shown on Figure 105).
Section 3 — Hardware Installation In this example: • For SO-33110/33011, HO-3G, and HO-33110/33011 output boards, the gain for outputs 1-16 would be boosted by closing the rear-panel Input Expand DIP switch and verifying that the on-board jumper for that set of outputs is in the Expand Enable position. The gain for outputs 17-256 must be held at unity by setting the on-board jumpers for that set of outputs to the Force Normal position; this overrides the rear-panel DIP switch setting for those outputs.
Duplication and Expansion Note Use the PE33016 Port expander for HD operations and the PE2x2-3G Port expander for 3G operations. The necessary gain increase is accomplished by one of the following: 1. Closing the rear-panel Input Expand DIP switch. For the location of this switch, see: • Figure 63 on page 136 [128 x 128] • Figure 4 on page 43 [256 x 256] • Figure 8 on page 47 [512 x 512] • Figure 14 on page 51 [256x512] 2.
Section 3 — Hardware Installation In this example: 190 • For SO-33110/33011, HO-3G, and HO-33110/33011 output boards, the gain for outputs 17-512 would be boosted by closing the rear-panel Input Expand DIP switches on both frames and verifying that the on-board jumpers for that set of outputs are in the Expand Enable position. The location of the boost jumper on these output boards is shown on Figure 105.
Duplication and Expansion Figure 105. Location of gain jumpers on SO-33110/33011, HO-3G, and HO-33110/33011 output boards.
Section 3 — Hardware Installation Figure 106. Location of gain switches for HO-33120 Universal Output base board, TRX-HO-3G, and HO-33121 Universal Output mezzanine board. DIP switch S5 Table 37. HO-33120 and TRX-HO-3G DIP switch S5 settings. Refer to example on Figure 105.
Duplication and Expansion Full Frame Output Expansion The Full Frame Output expansion configuration, all inputs are split and must therefore be boosted. For example, in the system shown in Figure 107, Input 1would be split (duplicated) and sent to both frames, etc. Figure 107.
Section 3 — Hardware Installation shown in Figure 108, inputs 1-16 are not split (and therefore are restricted to outputs 1-512). Figure 108. 1 - 16 Frame 0 1 - 512 17 - 512 Trinix 512 x 512 17 - 512 Outputs expanded to 1024 (restricted) 32 PE 33016 used as splitters Frame 2 513 - 1024 17 - 512 Trinix 512 x 512 Note Use the PE33016 Port expander for HD operations and the PE2x2-3G Port expander for 3G operations.
Duplication and Expansion Figure 109. Location of gain jumpers on SI-33110, and HI-33110. Note labelling error: Some "Base" jumpers have reversed silkscreening. In all cases, "Expand Enable" requires a jumper between pins 1 and 2.
Section 3 — Hardware Installation Figure 110. Front-edge switches on VI-33100 base board.
Output Reclocker Bypass Settings Output Reclocker Bypass Settings The following discussion applies to units equipped with the HO-33110 HD or the HO-33120 SD/HD/3G Output Boards. Front edge dual in-line package (DIP) switches S5-8 and S1 through S4 on these output boards are used to control reclocking. Figure 111.
Section 3 — Hardware Installation A list of supported data rates for the HO-33110 and HO-33120 Output Boards is shown in the Data Reclocking specifications on page 115. Sync Selection Switch S5 See the table on page 185.
Input Equalization Settings Input Equalization Settings (TRX-NXT-512x512 and TRX-NXT-256x512 Models Only) Recent versions of the DM-33512 Digital Matrix boards used in TRX-NXT512x512 routers have additional input equalization for improved HD performance; these boards are identified with “Pre-emphasis Added” stickers on the J421 headers used to connect the two halves of the board. If these stickers are present, and you are operating with Broadlinx 2.
Section 3 — Hardware Installation Output Monitoring Output monitoring allows verification of Routing switcher performance without interrupting normal operations. A separate internal switching system is used to switch the Monitor Output to any output of the Routing switcher. Using a control panel, the operator picks an output as usual—in this case, the Monitor Output. The operator then selects an input, but this input is actually one of the Routing switcher outputs.
Output Monitoring Figure 113. Example of Output Monitor Connection for the 128 x 128 all-NTSC Routing switcher SECONDARY PRIMARY OUTPUT MONITOR REF IN 4 3 COM BUS 4 OUTPUT MONITOR REF IN 3 2 1 NICB 2 COM BUS CONSOLE B CROSSPOINT BUS CONTROL 1 NICA CROSSPOINT BUS CONSOLE A (Terminate) QC STATION JUPITER CONTROL SYSTEM SWITCHER CONTROL PANEL Figure 114. Example of the Output Monitor Connection for the 256 x 256 all-NTSC switcher.
Section 3 — Hardware Installation Figure 115. Example of the Output Monitor Connection for the 256 x 512 all-NTSC switcher. 071827609_TRX-SR Output Monitoring Connection Output Monitor Connection Figure 116. Example of the Output Monitor Connection for the 512 x 512 all-NTSC switcher.
Output Monitoring Setting the Output Monitor Address The Monitor rotary switch on the back panel is used to set the control address for the available monitor outputs. For example, with a 128 x 128 Routing switcher equipped with redundant NR-33000 boards, the quality control monitor could be connected to output monitor connector 1 and the monitor switch set to 128; the control system would then select Output 129* for monitoring purposes. See Table 40.
Section 3 — Hardware Installation Table 40. TRX-NXT-128x128 Monitor Switch Information TRX-NXT-128x128 Monitor Switch Output Number and Address 1 2 3 4 128 129* 130* 131* 132* 256 257* 258* 259* 260* 384 385* 386* 387* 388* 512 513* 514* 515* 516* 2048 2049* 2050* 2051* 2052* Table 41.
Output Monitoring Asymmetrical Frames Monitor Switch Information Table 43. TRX-NXT-128x256 Monitor Switch Information TRX-NXT-128x256 Monitor Switch Output Number and Address 1 2 3 4 256 257* 258* 259* 260* 512 513* 514* 515* 516* 768 769* 770* 771* 772* 1024 1025* 1026* 1027* 1028* Table 44.
Section 3 — Hardware Installation Output Monitor Reclock / Force Bypass Settings TRX-NXT-128x128 and TRX-NXT-256x256 For these models, “Auto detect on” means the signal will be checked to see if it is HD or SD. If HD, the signal will be reclocked. If the signal is SD, it will be bypassed. NR-33000 Monitor Output switches “Bypass B” S3-7 and “Bypass A” S3-8 select the “auto detect on” or “force bypass” settings for the Monitor outputs. “Auto Detect” (“ON”) is the default setting. DIP switch S3.
Output Monitoring Trinix Asymmetric Frames TRX-SR board The TRX-SR board does not have individual Reclocker/Bypass switches. Switch S3- 7 will bypass reclocking signals globally for the four monitor outputs. Switch S2- 8 is the Mezz Boost Override switch, which is only used for Grass Valley testing. This switch should be set to OFF at all times. All other switches are defined in the tables under TRX-SR V Phase and Source Information on page 172.
Section 3 — Hardware Installation Figure 118. Monitoring with Output-expanded System.
Output Monitoring Figure 119.
Section 3 — Hardware Installation In systems controlled by SR-33000 boards, Monitor Expansion jumpers JN3 and JN4 on the SR-33000 boards must be set to “Exp.” Note Output monitoring is not available for input-expanded systems controlled by an SR-33000 Sync/OPM board. Trinix Asymmetrical Frames In expanded systems, output monitors are cascaded from expanded frames to the main frame via the TRX-SR for the 256x512 and the TRX-OPM for the 128x256, and 512x1024 output monitor inputs.
Output Monitoring Figure 121. Expanded Trinix 256x512 Asymmetrical Frames with Output Monitoring Legend: MON outs (4) MON outs (4) (Outputs 513-516) CAS = Cascade Trinix NXT 256x512 Switcher MON = Inputs 1-256 Monitor Outputs 1-512 Frame 0 Ins = Inputs Outs = Outputs CAS ins (4) 4 75 ohm coaxial cables 32 ea. 16x2:2 COMBINERS Note: The order of the frames for the monitor cascade does not matter.
Section 3 — Hardware Installation Frame Number Settings Setting the Frame for Input or Output Blocks Figure 123. FRAME 0 14 15 13 12 11 10 1 2 3 4 5 9 6 7 8 Up to 16 Trinix frames can be configured to operate as a single router. The FRAME rotary switch on the rear panel is used to indicate the relative position of each individual frame to the input-output matrix. The FRAME bits (4) are decoded to determine which inputs and outputs correspond to the frames.
Frame Number Settings Table 48. Frame Numbering (cont.) TRX-NXT-512x512 and 256x512* FRAME NUMBER INPUTS 1537-2048* 5 7 13 15 1025-1536* 4 6 12 14 513-1024* 1 3 9 11 1-512* 0 2 8 10 OUTPUTS 1-512* 513-1024* 1025-1536* 1537-2048* The 256X512 router is a subset of the 512X512router and it operates as a partially stuffed 512X512 system. Table 49. Frame Numbering (cont.
Section 3 — Hardware Installation Jupiter Control Figure 124. Control connections to Jupiter Facility Control System (example). Trinix routing switcher(s) Jupiter file server T Crosspoint bus terminator Ethernet switch 10/100BaseT LAN Crosspoint bus Jupiter control panels CM-4000 System Controller MPK bus The Jupiter Facility Control system can be used to control the Trinix router using a VM-3000 System Controller.
Jupiter Control nector) is looped out in order to connect the bus to the next item under cross point control. This bus may require intermediate buffering through a CB-3000 Control Buffer depending on the size of the Routing switcher . A CB-3000 is required in the following cases: TRX-NXT-128x128 - eight or more frames TRX-NXT-256x256 - four or more frames TRX-NXT-512x512 - two or more frames TRX-NXT-128 x 256 - four or more frames TRX-NXT-256x512 - two or more frames TRX-NXT-512x1024 - More than one frame.
Section 3 — Hardware Installation Figure 125. CC-2010 wiring. Reference: Assembly, CC-2010 Matrix Cable,” Grass Valley drawing no. 01-032707-TAB Twisted pairs Reset 9 Data 10 Clock 11 Take 12 Confirm 13 1 2 Shield Red Red Black Black 9 Yellow Yellow Black Black 3 10 Green Green Black Black 4 5 11 Blue Blue Black Black 12 White White Black Black 13 1 2 3 4 5 Shield (drain) Ground 8 8 P1 DB15P (male) Ferrite core Ferrite core 50 ft ( 15.
Jupiter Control Figure 127. INT XPT CNTL” Rear-Panel DIP Switch OPEN CLOSED INPUT EXPAND OUTPUT EXPAND SYNC REDUNDANT INT XPT CNTL 60Hz ENABLE A B C This will cause the Broadlinx board to release control of the Trinix internal Crosspoint bus. Switch commands arriving at the Crosspoint bus connector on the rear of the frame will be executed. 3. Set Level switches: Two back-panel rotary switches are used to set the level address of the router.
Section 3 — Hardware Installation Note 218 Newer-model Trinix units have “1-based” input/output connector numbering; i.e., there is no connector “0.” However, Jupiter tables are always 0-based. When controlling such units, references to Physical Input/Output connectors in Jupiter tables refer to that connector number plus 1. For example, Physical Input 10 in the Jupiter Switcher Input table would correspond to connector number 11 on the Trinix rear panel.
SMS 7000 / Encore Control SMS 7000 / Encore Control These control systems use an Ethernet connection to the Broadlinx option (NR-33000 Sync/NIC/OPM board). 1. Set the Trinix INT XPT CNTL rear-panel DIP switch to On (switch closed). See Figure 129. Figure 129. OPEN CLOSED INPUT EXPAND OUTPUT EXPAND SYNC REDUNDANT INT XPT CNTL 60Hz ENABLE A B C In the internal-Crosspoint bus control mode, the Broadlinx board sends commands to the Crosspoint bus. 2.
Section 3 — Hardware Installation 3. On TRX-NXT-512x512 units only, a Crosspoint bus cable must be installed between the power supply frame and the main frame. If there is more than one TRX-NXT-512x512 in the system, the Crosspoint bus must be daisy-chained between units. The Crosspoint bus must be terminated at the farthest point from the controlling Broadlinx board. This connection is shown on Figure 68. The Crosspoint bus cable is described on Figure 124. 4.
LAN and Com Bus Connections LAN and Com Bus Connections The LAN (NIC) connections use a standard 10/100BaseT twisted pair cable with RJ-45 connectors (Cat 5E Enhanced is recommended). Shielded cable is also recommended, maximum length 60 meters.1 Maximum length for a non-shielded cable is 100 meters. LAN Monitoring Only (External XPT Control) In this arrangement, the router is under external Jupiter control and the only purpose of the connection is LAN monitoring using Broadlinx web pages or SNMP.
Section 3 — Hardware Installation SMS Control In this arrangement, the router is under SMS control via a LAN connection. The PC is used to configure the SMS and is available for Broadlinx or SNMP monitoring. See Figure 132. Figure 132. SMS connections to Trinix. NIC A connector 7000 SMS MCPU frame Trinix Ethernet connector NIC B connector Ethernet switch PC If you plan to use a secondary NR-33000 board connect another Ethernet cable from the NIC B jack to the network switch.
LAN and Com Bus Connections Encore Control In this arrangement, the router is under Encore control via a LAN connection. The PC is to configure the Encore and is available for Broadlinx or SNMP monitoring. The recommended connections for the system when equipped with redundant NR-33000 boards and redundant Encore controllers is shown in Figure 133. For more Information about Encore control of Trinix, see Encore Control on page 375. Figure 133.
Section 3 — Hardware Installation Com Bus In multi-frame systems, a “Com Bus” is used to loop through each frame, up to a maximum of four. The Com Bus is intended to provide Routing switcher monitoring of multiple frames using Broadlinx web pages or SNMP. The Com Bus uses a 10/100BaseT (Cat 5 twisted pair) cable with RJ45 connectors. Shielded cable is recommended, maximum length 60 meters.1 Maximum length for a non-shielded cable is 100 meters. Figure 134.
LAN and Com Bus Connections If SNMP/NetCentral monitoring is to be used, the Trinix SNMP agent residing on the NR-33000 board must be enabled (that is, licensed). For more information, see SNMP/NetCentral Monitoring on page 300.
Section 3 — Hardware Installation Replacing Trinix Boards When replacing Trinix boards, you should keep in mind that there was a change in the VIT timing. This change was made to accommodate the additional processing delay of 10.3us in the new 3G matrix cards. The VIT signals generated from the NR and SR cards were advanced by 10.3us. All of the legacy matrix/output cards VIT timing will be delayed by a similar amount.
Section 4 Trinix Asymmetrical Power Supply Configurations Introduction The Trinix Asymmetrical routers use external power supply modules, which reside in a 1 RU power supply frame. Each of these frames can house up to four power supply modules. The power supply modules are monitored by means of I2C links. The number of power supply frames, power supply modules, and I2C links can vary depending on the model of the asymmetrical router that is used and the redundancy configuration.
Section 4 — Trinix Asymmetrical Power Supply Configurations Using the I2C Interface to Monitor the Power Supplies The power supply frames provide a single I2C interface to status and monitor the four power supply modules. The I2C link-up provides the ability to monitor up to eight power supply modules. A single I2C link-up can monitor two power supply frames (Figure 136). The power supply frames that are connected to a single I2C link must be connected to the same power distribution bus. Figure 136.
The External Power Supply Frame Displaying the Status of the Power Supply Module There are four LEDs on the front panel of the power supply module that display the status for the AC input, DC input, Temperature, and non-specific faults. For more information, see Asymmetrical Frames in the Troubleshooting section on page 394.
Section 4 — Trinix Asymmetrical Power Supply Configurations Basic Configuration for the Lineage Power Supply Frame The basic power supply frame’s configuration (Figure 137) consists of the following: • A Power Supply frame. • A 10 ft. (3.05 meters) Trinix Power Supply cable. • A 10 ft. (3.05 meters) Trinix Power Supply interface cable. The GV part # for the basic configuration assembly is 751-0326-00. Figure 137.
Trinix Asymmetrical Frames be configured, by means of Dual In-line Package (DIP) switches, to match the power supply configuration of each system. Figure 138. TRX-SC Board Configuration DIP Switches The configuration DIP switches are located on the left side of the back of the TRX-SC board (Figure 139). Note The DIP switches will be highlighted in red in the following TRX-SC board examples in this appendix. Figure 139.
Section 4 — Trinix Asymmetrical Power Supply Configurations The BUS x ENABLE switches control the number of power busses to monitor. Both power busses will be disabled if the frame is powered directly from a customer’s power distribution. The BUS x EXPANSION ENABLE switches control the number of external power supply frames that are connected to the respective power supply bus.
The 128X256 Trinix Asymmetrical Frame The 128X256 Trinix Asymmetrical Frame The 128X256 Asymmetrical frames are designed to support a maximum load of 1400 Watts. Each frame provides two isolated power inputs and a TRX-SC board. These connections are identified below in Figure 141 below. This connectivity supports up to two external power supply frames and eight power supply modules. Figure 141.
Section 4 — Trinix Asymmetrical Power Supply Configurations Figure 142.
The 128X256 Trinix Asymmetrical Frame The 128X256 Redundant Power Supply Configurations - A and B Option The A and B configuration options for the redundant power supply includes the Trinix default power supply configuration and one or two additional power supply modules (see Figure 144 on page 235 and Figure 145 on page 236). The power is connected to the DC INPUT A connector on the router frame. The power supply’s interface cable is connected to the PMBUS A connector on the router frame. Figure 144.
Section 4 — Trinix Asymmetrical Power Supply Configurations Figure 145.
The 128X256 Trinix Asymmetrical Frame The 128X256 Redundant Power Supply Configuration-Option C The C configuration option for the redundant power supply includes two Trinix power supply frames with four power supply modules (see Figure 147 on page 238). The first Trinix power supply rack is connected to the DC INPUT A connector on the router frame. The power supply’s interface cable from this power supply rack is connected to the PMBUS A connector on the router frame.
Section 4 — Trinix Asymmetrical Power Supply Configurations Figure 147.
The 128X256 Trinix Asymmetrical Frame The 128X256 Redundant Power Supply Configurations - Options D and E The D and E configuration options for the redundant power supply includes two Trinix power supply frames and either six or eight power supply modules (see Figure 149 on page 240 and Figure 150 on page 241). The first Trinix power supply rack is connected to the DC INPUT A connector of the router frame. The power supply’s interface cable is connected to the PMBUS A connector of the router frame.
Section 4 — Trinix Asymmetrical Power Supply Configurations Figure 149.
The 128X256 Trinix Asymmetrical Frame Figure 150.
Section 4 — Trinix Asymmetrical Power Supply Configurations 242 O N 1 2 3 4 5 6 7 8 1827609_TRX-SC DIP Switch settings for 128X256 O Figure 151.
The 256X512 Trinix Asymmetrical Frame The 256X512 Trinix Asymmetrical Frame The 256X512 Asymmetrical frames are designed to support a maximum load of 2100 Watts. Each frame provides two isolated power inputs and a TRX-SC board. These connections are identified below in Figure 152 on page 243 below. This connectivity supports up to two external power supply frames and eight power supply modules. Figure 152.
Section 4 — Trinix Asymmetrical Power Supply Configurations 256X512 Default Power Supply Configurations The default configuration for the 256x512’s power supply includes one Trinix power supply frame and two power supply modules. The power is connected to the DC INPUT A connector of the router frame. The power supply’s interface cable is connected to the PMBUS A connector on the router frame. Figure 153.
The 256X512 Trinix Asymmetrical Frame The corresponding TRX-SC DIP switch setting is shown in Figure 154 on page 245. Figure 154. TRX-SC DIP Switch Settings for 256X512 Default Configuration 256X512 Redundant Power Supply Configurations Options A and B The A and B configuration options for the redundant power supply includes the Trinix default power supply configuration and one or two additional power supply modules (see Figure 155 on page 246 and Figure 156 on page 247).
Section 4 — Trinix Asymmetrical Power Supply Configurations Figure 155.
The 256X512 Trinix Asymmetrical Frame Figure 156.
Section 4 — Trinix Asymmetrical Power Supply Configurations The 256X512 Redundant Power Supply Configuration - Option C The C configuration option for the redundant power supply includes two Trinix power supply frames and four power supply modules. One of the Trinix power supply racks is connected to the DC INPUT A connector of the router frame. The power supply’s interface cable from this Trinix power supply rack is connected to the PMBUS A connector of the router frame.
The 256X512 Trinix Asymmetrical Frame The corresponding TRX-SC DIP switch setting for the 256X512 redundant power supply configurations, option C, is shown in Figure 159 on page 249. Figure 159.
Section 4 — Trinix Asymmetrical Power Supply Configurations Figure 160.
The 256X512 Trinix Asymmetrical Frame Figure 161.
Section 4 — Trinix Asymmetrical Power Supply Configurations The 512X1024 Trinix Asymmetrical Frame The 512X1024 Asymmetrical frame is designed to support a maximum load of 5400 Watts. The frame provides four isolated power inputs and two TRXSC boards. This connectivity supports up to four external power supply frames and sixteen power supply modules (Figure 163). Grass Valley recommends that the power supplies are installed to the side of the 512X1024 Asymmetrical frame.
The 512X1024 Trinix Asymmetrical Frame Figure 163.
Section 4 — Trinix Asymmetrical Power Supply Configurations 512X1024 Default Power Supply Configuration The default power supply configuration includes two Trinix power supply frames and eight power supply modules. One of the Trinix power supply racks is connected to the DC INPUT A connector of the router frame. The power supply’s interface cable from this Trinix power supply rack is connected to the PMBUS A connector of the router frame.
The 512X1024 Trinix Asymmetrical Frame Figure 164.
Section 4 — Trinix Asymmetrical Power Supply Configurations Note Do NOT place anything on top or on the bottom of the 512x1024 routing switcher; doing so will block the airflow and may cause the routing switcher to overheat. For the 512X1024 default power supply configuration the two TRX-SC boards in the frame are configured with the corresponding DIP switch setting as shown in Figure 165. Figure 165.
The 512X1024 Trinix Asymmetrical Frame 512X1024 Redundant Power Supply Configurations, Option A The redundant power supply configuration, option A, include the default power supply configuration and two additional Trinix power supply frames with eight additional power supply modules. The additional power supply racks are connected to the DC INPUT B connectors of the router frame. The additional power supply’s interface cables are connected to the PMBUS B connectors of the router frame (Figure 166).
Section 4 — Trinix Asymmetrical Power Supply Configurations Note Do NOT place anything on top or on the bottom of the 512x1024 routing switcher; doing so will block the airflow and may cause the routing switcher to overheat. For the 512X1024 redundant power supply configuration, option A, the two TRX-SC boards in the frame are configured with the corresponding DIP switch setting as shown in Figure 167. Figure 167.
Section 5 Broadlinx Installation This document provides the software installation instructions for the Broadlinx software. Interoperability Requirements • Any Encore system that is newer than the 1.7.3 version. • Any Jupiter system. • The 2.0.13 version of NetConfig or newer. Note Do not use Broadlinx with either the Dynex DX-ESW8, 10/100M Fast Ethernet Switch or the Zonet Model ZFS3124.
Section 5 — Broadlinx Installation Software Installation CAUTION Installation of this upgrade will interrupt video signals passing through the system. The length of this interruption will vary depending on system size and specific procedures used. Users of this equipment should consult with Grass Valley Technical Support personnel before proceeding. Introduction The Broadlinx firmware is installed and updated using Compact Flash cards.
Software Installation Caveats Before starting the Installation process, please read the following: • All frames with TRX-DM256-3G matrix cards MUST be updated to the 3.3.0 (or later) release of Broadlinx. For example, the 256x512, 512x512, and the 512x1024. • Web tools such as NetConfig cannot be used to install versions prior to the 3.2.0 version of Broadlinx. • Protected paths are not monitored during firmware updates.
Section 5 — Broadlinx Installation Copying the Broadlinx Software to the CF Using a CF Reader This process assumes that a Compact Flash (CF) card reader has been connected to the workstation. If not, see the Installation instructions that came with the CF card reader. Note Grass Valley recommends that you format your CF card to the FAT16 format. For more information, see Formatting the Compact Flash Card with the FAT16 Format on page 279.
Software Installation You MUST do the following options when you are adding a new HD board to a Trinix router that is running Broadlinx 2.4.2 or older: Note • This option will insure that switches occur at the correct timing position. Update the Trinix router to Broadlinx 3.0.1 or newer. CAUTION Grass Valley strongly recommends that customers keep all software updated to the latest released version. New boards are NOT guaranteed to be compatible with older versions of software.
Section 5 — Broadlinx Installation Figure 168. Battery location on the NR-33000. Battery terminal location 071828316-BATTERY CONNECTION 2. Insert the Compact Flash card into the slot on the Broadlinx board and then insert the Broadlinx board into the frame. Broadlinx will then inventory the boards that are in the frame. Figure 169. NR-33000 (Broadlinx board) Controls.
Software Installation The Broadlinx Firmware Management page displays the following: • The possible types of PC boards • The version of the Broadlinx software that is presently associated with each type of board that is installed • The versions of top-level software packages that are present in the Broadlinx board • The compatibility Status of these software elements. An example of this table is shown in the figure below (Figure 170).
Section 5 — Broadlinx Installation Write down the time displayed for reference. 2. Click the OK button. The Broadlinx: Updating firmware status window will then appear: Figure 172. The Broadlinx: Updating Firmware Status Window The new software will then be copied from the NR-33000 (Broadlinx board) to each board that requires an update. This process can take several hours. • When updating systems with two NR boards, the NR performing the update will not install the software onto itself.
Software Installation Figure 173. The Broadlinx: Updating Firmware Status Window - Update Completed Click this button The Broadlinx web page will then indicate “Post Completed.” 4. Navigate to the Firmware Management page. The Restart button will now appear near the bottom of the page. (The display may vary from the example that is shown in Figure 174.) Figure 174. The Restart Button on the Firmware Management Screen The cards must be restarted to use the new firmware. 5.
Section 5 — Broadlinx Installation Figure 175. The Restart Caution Popup CAUTION Clicking the OK button will cause a momentary interruption to video passing through the Routing switcher. Clicking the Cancel button, while not advised, will stop the restart process allowing you to restart the board during a scheduled service time. However, the new software will not be applied until the boards are restarted. 6. Click the OK button. The Post Complete window will then reappear. 7.
Software Installation Updating Systems with Two Broadlinx Boards This section describes the steps for updating existing Broadlinx boards. The Installation process uses the Broadlinx Firmware Management Web page. These steps are described below. Follow these steps to update all the boards within the frame (except an active NR-33000 board): 1. Remove the Broadlinx boards from the chassis and remove the existing compact Flash card by pressing the Eject button (Figure 178 on page 270).
Section 5 — Broadlinx Installation Figure 178. NR-33000 (Broadlinx board) Controls. NR board left ejector lever Flash module Reset button Flash module ejector button Activate button and "Active" LED Using the Web Page Navigate to the Broadlinx Web page to complete updating the firmware. Note Using Telnet or a Console session during an firmware update can cause the update to fail.
Software Installation Figure 179. The Firmware Management Screen Older firmware The installed version of Broadlinx Some of the Status lights, in the Status column, will be red following an installation using a Compact Flash card (Figure 179). This indicates that the software that is currently running in the module is different (or older) than the software that was just installed. The new software should be activated by following the instructions provided below. Activating Software 1.
Section 5 — Broadlinx Installation Figure 181. The Broadlinx: Updating Firmware Status Window The new software will then be copied from the NR-33000 (Broadlinx board) to each board that requires an update. This process can take up to several hours. • When updating systems with two NR boards, the NR performing the update will not install the software onto itself.
Software Installation Figure 182. The Broadlinx: Updating Firmware Status Window - Update Completed Click this button The Broadlinx web page will then indicate “Post Completed.” 4. Navigate to the Firmware Management page. The Restart button will now appear near the bottom of the page. Figure 183. The Restart Button on the Firmware Management Screen The cards must be restarted to use the new firmware. 5. Click the Restart button, which is shown above in Figure 183.
Section 5 — Broadlinx Installation Figure 184. The Restart Caution Popup CAUTION Clicking the OK button will cause a momentary interruption to video passing through the Routing switcher. Clicking the Cancel button, while not advised, will stop the restart process allowing you to restart the board during a scheduled service time. However, the new software will not be applied until the boards are restarted. 6. Click the OK button. The Post Complete window will then reappear.
Software Installation Figure 185. The Firmware Management Screen Broadlinx Status is Red 3. Click the Activate button in the lower right side. The board will be updated similar to the process described when updating the first board. 4. Navigate to the Firmware Management page. The Restart button will now appear near the bottom of the page. (The display may vary from the example that is shown in Figure 186.) Figure 186.
Section 5 — Broadlinx Installation Figure 187. The Restart Caution Popup CAUTION Clicking the OK button will cause a momentary interruption to video passing through the Routing switcher. Clicking the Cancel button, while not advised, will stop the restart process allowing you to restart the board during a scheduled service time. However, the new software will not be applied until the boards are restarted. 6. Click the OK button. The Post Complete window will then reappear. 7.
Software Installation Licensing SNMP on Both Broadlinx Boards SNMP is licensed for a frame type using the hardware Ethernet address (MAC Address) of the Broadlinx or NR33000 processor. To license SNMP use the Enter License Key option from the Configuration web page on both boards with the specific key for each board. An alternative to licensing both boards is to enable inter-board communications to save the license key from the active board that has been licensed to the standby board.
Section 5 — Broadlinx Installation Figure 189. Example The SNMP Keys status Ensure that the SNMP key and the master SNMP key values are the same. The value for the SNMP keys shown in this example are for the frame type rather than the encrypted key number that was entered on the Web page. If zero is shown, no SNMP key has been set.
Software Installation Formatting the Compact Flash Card with the FAT16 Format These steps describe the steps needed to reformat your Compact Flash (CF) card to the FAT16 format, which will decrease the time it takes to ”boot” or start up. The FAT16 format will check all the file entries in less time than the FAT32 format. When you format the CF, a warning will appear that indicates that the format may not be compatible with older versions of Windows because of the large allocation size.
Section 5 — Broadlinx Installation Figure 191. The Format Option The Format dialog will then appear (Figure 192). Figure 192. The Format Dialog 5. Enter a preferred name in the Volume label field. 6. Select FAT from the File system drop-down list. 7. Select Default from the Allocation unit size drop-down list. 8. Click the OK button. A popup will appear (Figure 193). Figure 193. Format Warning Click the OK button.
Software Installation Alternate methods for Updating a Compact Flash Cards Uploading the Broadlinx Software Using NetConfig Note For more information about the NetConfig application see the NetConfig Instruction Manual. The 3.3.1 version of Broadlinx may be copied to the Compact Flash cards using the 2.0.13 version of NetConfig.
Section 5 — Broadlinx Installation Updating Broadlinx Using NetConfig Pre-Installation Steps Note Please read the Requirements on page 281 before proceeding. Before Starting the update using NetConfig: • Place the latest broadlinx.tar file in the Trinix directory of the Matrices folder (….\Encore\Matrices\Trinix). • Place the trinix.xml file in the Netconfig directory. Note If Encore was installed in directories other than the default, you will need to edit the element in the trinix.
Software Installation Installation FAQ The installation process seems to have stopped If no activity is being shown on the Progress bar, and the time has exceeded the estimated time by 20%, check the LED on the door of the frame on which the installation is being preformed. • If the LED is green, Restart Web browser. • If the LED is red, Open the door and see which board has a red LED. Then start a Telnet session to check the alarm conditions on the board.
Section 5 — Broadlinx Installation 284 Trinix NXT — Installation and Service Manual
Section 6 Broadlinx Software The Broadlinx option, which consists of Broadlinx software running on the NR-33000 Sync/NIC/OPM board, allows SMS 7000 or Encore control using Grass Valley CPL (Control Point Language) through an Ethernet connection.
Section 6 — Broadlinx Software Simple Network Settings A Simple network is when there is only a monitor PC and a Broadlinx board in an isolated network environment. You will need to change the monitor PC network address to be compatible with the Broadlinx board’s default setting. You must then browse to and configure the board to work in your facility. Configuring the PC’s Network Settings The PC’s Network Settings must be compatible with the Broadlinx board’s default values.
Figure 196. The Internet Protocol (TCP/IP) Properties Dialog 5. Click the Use the following IP address radio button. You must have administrator privileges to change Internet settings. a. Enter “192.168.253.XXX”in the IP address field (where “XXX” is a three number combination that identifies the Monitor PC on the network) and then “255.255.255.0” into the subnet mask field. All other TCP/IP network settings are irrelevant at this point. b. Reboot the PC to apply the changes.
Section 6 — Broadlinx Software Note If you connect to the Internet via a Proxy, you must turn off the Explorer Proxy settings. To check the Proxy setting, open Microsoft Internet Explorer’s LAN Settings (Menu bar> Tool > Internet Options> Connections> LAN Settings). 2. Enter the factory default URL in the address field (This URL is the IP address for the Broadlinx board): http://192.168.253.200 The Broadlinx web page will then appear. Figure 197. Broadlinx Web Page 3.
Figure 198. Configuration Web Page The Configure Network Interface button 2. Click the Configure Network Interface button (the blue box with a white arrow in it, at the bottom of the section, see Figure 198) to navigate to the Network Configuration page. The Configure Network Interface page (Figure 199) will then be displayed. Figure 199. The Configure Network Interface Screen 3. Enter the information that is needed to connect to your network in the respective fields.
Section 6 — Broadlinx Software Note If you don't know what values to enter, consult your network administrator. Your parameters will differ from those in the example shown in Figure 199. The SNMP Device ID is the MAC address of the NR-33000. This information is used when obtaining license for SNMP/NetCentral monitoring. For more information, see SNMP/NetCentral Monitoring on page 37. • You will lose the connection if you change the Broadlinx board to another network.
Encore Controlled Routers Once the newly inserted board has booted, run the Re-Sync Comms and Re-Sync Router from the Encore System Configure window (Encore User Interface> System Configure window).
Section 6 — Broadlinx Software Configuration This Configuration section describes the steps that are needed to deploy Broadlinx to meet your business needs. Each section title of the Configuration page is described. Opening the Configuration Page 1. Connect to the Routing switcher following the procedure described in the Simple Network Settings section on 286. 2. Click the Configure button at the bottom of the Main Broadlinx page.
Configuration Figure 201. The Current Time section of the Configuration Page Click the Time Management arrow Figure 202. The Time Management The clock displayed on the page will synchronize automatically to a VITC signal on line 141 of the sync reference input. Follow these steps to set the time setting: 1. Click the Use Daylight Savings Time check box. The Daylight Savings Time box MUST be checked or unchecked manually at the appropriate time of year. 2.
Section 6 — Broadlinx Software Figure 203. Manually Setting the Time Follow these steps to manually set the time: 1. Click the Set Time Manually radio button. The dialog will then expand to display the Time drop-down lists. 2. Enter the appropriate values. System Description This is the source of the system name that appears on the left side of the toplevel Broadlinx page. Follow these steps to change the description: Figure 204.
Configuration 4. The System description that you entered will now appear below the Reload button. Figure 206. System Description Network Interface The Configure Network Interface page is where you enter the information that is needed to access the Router network. Follow these steps to configure the network settings: Figure 207. The Configure Network Interface “Arrow” Click the Configure Network Interface arrow 1. Click the Configure Network Interface arrow button.
Section 6 — Broadlinx Software The secondary board will automatically be given the same IP address as the primary board, plus 1. Subnet Mask: This field assigns the Subnet mask that is usually 255.255.255.0 (Class C net with no sub-netting). Target Name (SMS control only): This field assigns the name used by SMS 7000 control system for router. This name can be up to eight characters, but the last character must be a “1.
Configuration 4. Click the Submit button. The pop-up window will then change to display the text shown in Figure 211. Figure 211. The License Key is Valid Note If the number is not valid, check the number entered. If the number is still not valid contact Tech support (see Contacting Grass Valley on page 4). 5. Click the OK button. The SNMP License window will then close and return you to the Configuration page. The word “enabled” will appear for SNMP Services. Figure 212.
Section 6 — Broadlinx Software Figure 213. The Firmware Management Page The firmware used in the Trinix system consists of a collection of programs operating within the various PC boards. These programs are identified either by a sub-level revision number from 1 to 255 or by a date. Since these programs must be compatible with each other, they are managed as a package with a top-level revision number.
Configuration NR Broadlinx board (Sync/NIC/OPM board) SR Sync/OPM board RP interface board (used only on TRX-NXT512x512 chassis) VxWorks operating system (used only on NR board) Web Interface software used to communicate with the PC (used only on NR board) Table 52.
Section 6 — Broadlinx Software For the microcontroller, 2 digits will be shown. For example, 6:4. The first digit represents the firmware version. The second digit represents the loader version. This means mismatched versions between the firmware and the loader can be shown as 6... : 4, 6 : 4..., or 6... : 4.... The sub-level programs in the selected package are identified in the “FPGA Pending” column and the “uControl Pending” column.
Configuration Table 54. Network Information Item Description IP Address The IP address of the Trinix matrix. Subnet Mask The Subnet address of the Trinix matrix. Gateway Address The Gateway address of the Trinix matrix. Table 55. Power Supply Information Item Description PS Name The name of the Power supply such as Power Supply A, Power Supply B etc PS Status The status of Power Supply such as active/faulty etc.
Section 6 — Broadlinx Software Item Description Signal State The state of the signal. For example, Detected or Not Detected and so forth. Signal Last Changed The time at which signal state was changed. Signal Specific This is an OID and can be used to extend the signal information to another table.
Configuration Notification Description Board Error A board error message is sent to the manager if any error occurs in board (Input / output / fabric) status. This error trap is cleared once the board is restored to the correct state Over temperature Error An over temp error trap message is sent to the manager if any of the boards present in matrix frame crosses its normal operating temperature range. This error trap is cleared once the board is restored to the normal operating temperature range.
Section 6 — Broadlinx Software Figure 214. The SNMP Section of the Configuration Web Page The Configure SNMP Manager IP Address page will then appear. 2. Enter the Appropriate IP Addresses and Community names in the respective fields. The IP Addresses shown in Figure 215 are for demonstration purposes only. 3. Click the Submit button to save and apply the changes (Figure 215). The IP address shown is for example only. Figure 215.
Configuration SNMP license installed on the matrix. The Signal-Loss settings can be accessed from two places: • From the Individual Input Board Web Page. • From the Frame Level Signal Web Page. Both of these pages are explained in detail below. From the Individual Input Board Web Page You can use Grass Valley’s NetConfig application to access each Input board. Follow these steps to configure the Input Signal Loss notification feature using the Individual Input board’s Web Page: 1.
Section 6 — Broadlinx Software From the Frame Level Signal Web Page The Signal Alarm information can be accessed from the Frame Level Signal Web page. Follow these steps to configure the Input Signal Loss notification feature using the Frame level signal’s Web Page: 1. Click the Signal button to open the Frame Info tab (Figure 219). 2. Select the Signal alarms for each connector. Figure 219. The Signal Alarm Configuration Page 3.
Configuration Both of these processes are explained in detail below. From the Individual Output Board Web Page Follow these steps to configure Output Signal Loss notifications using the Individual Output board’s Web Page: 1. Click the Signal button to open the Signal Alarm Configuration page (Figure 221). 2. Select the Signal alarms for each connector. Figure 221. The Output Signal Alarm Configuration Page 3. Save the configuration by clicking the Save Signal Alarm Config button (Figure 222). Figure 222.
Section 6 — Broadlinx Software Figure 223. The Signal Alarm Configuration Page 3. Save the configuration by clicking the Save Signal Alarm Config button (Figure 224). Figure 224.
Configuration Licensing SNMP on Both Broadlinx Boards SNMP is licensed for a frame type using the hardware Ethernet address of the Broadlinx or NR33300 processor. (MAC Address)To license a newly added standby board either in the primary or secondary slot type setSnmpCommunicationsEnable and wait for the SNMP license set message then reboot the board.
Section 6 — Broadlinx Software Figure 225. Example The SNMP Keys status Ensure that the SNMP key and the master SNMP key values are the same. The value for the SNMP keys shown in this example are for the frame type rather than the encrypted key number that was entered on the Web page. If zero is shown, no SNMP key has been set.
Configuration Broadlinx / Internet Explorer Monitoring Normal Connection Procedure Following Network Address Configuration 1. Launch Internet Explorer. Microsoft Internet Explorer 5.0 or newer is required; version 6 or newer is recommended for best performance. 2. Enter the URL for the Broadlinx board installed in the system to be monitored. When a connection is established, you will see the Broadlinx main web page (similar to the example that is shown in Figure 226). Figure 226.
Section 6 — Broadlinx Software Checking Hardware Status Follow these steps to check the hardware’s status: 1. Connect to the Routing switcher following the procedure described in the Normal Connection Procedure Following Network Address Configuration section. 2. Click on the graphic of the Routing switcher front panel. A line drawing of the Trinix frame will then appear (similar to the example shown in Figure 228). Figure 227.
Configuration Figure 228. The Trinix 512x512 or “512 Squared” Frame In this example, all installed and active modules and boards show a green dot meaning that operation is normal. Modules that are not active or installed are grayed out. 3. Select a module or board to check its condition by ether clicking the name of the board or module in the list or the graphic in the drawing (Figure 229 on page 314). The selected board and its information will then appear (Figure 230 on page 315).
Section 6 — Broadlinx Software Figure 229. Frame and Device Tree or click one of these Click one of these • 314 In this example, the HI-33300-3G board has been selected.
Configuration Figure 230. Example of Web Page for Specific Board For TRX-NXT-512x512 Routing switchers, the SR-33500 Sync Reference board and the RP-33500 Rear Panel must be selected from the list (because these boards on located on the rear panel). Note To find the name of a board or module, you can mouse over the graphic and a tool-tip text alert with the name and status will appear (Figure 231). Figure 231.
Section 6 — Broadlinx Software TRX-NXT-512x512 Routing switchers 1. Connect to the Routing switcher following the procedure described on page 311. 2. Click on the graphic of the Routing switcher front panel. 3. Click “Signals” A menu similar to Figure 232 will then appear. Figure 232. Monitor Window (TRX-NXT-512x512). The Monitor tab displays the following: Chassis: This column lists the monitor output ports labeled “1” through “4” on the back of the frame.
Configuration Reclocker: (TRX-NXT-512x512): This column lists the following: • “L” = The monitor output board is locked to (and is reclocking) the signal. • “B” = The monitor output board is bypassing (and not reclocking) this signal. For more information about output monitor reclocking, see Output Monitor Reclock / Force Bypass Settings on page 206. For more information about output monitoring, refer to the manual supplied with the control system.
Section 6 — Broadlinx Software Figure 234. Outputs Tab Firmware Update For firmware update instructions, refer to the Release Notes document that is supplied with the firmware; also see Updating Systems with a Single Broadlinx Board on page 263.
Configuration Trinix Matrix Identification from the NetConfig Software Trinix matrices now support identification from the NetConfig tool. The ID function is used to identify the physical location of the Trinix Matrix. This feature is helpful in a facility with many matrices scattered across the facility. Follow these steps to identify a matrix: 1. Open the NetConfig application. 2. Right-click the preferred Trinix matrix listed on the tree view in the left pane. 3.
Section 6 — Broadlinx Software Figure 236. The Broadlinx card’s LED 0718277609__Broadlinx-ID-LEDs The time that the LEDs will “blink” can be configured using the NetConfig option in the Configure menu of NetConfig. For more information about the Broadlinx LEDs, see NR-33000 NIC/Sync/OPM board on page 406. Follow these steps to configure various options in Broadlinx: 1. Select the NetConfig option in the Configure menu (Configure> NetConfig option). Figure 237.
Configuration Figure 238. The NetConfig Options Menu 2. Make the appropriate changes. a. The Blink interval can be changed by entering the time in milliseconds in the Interval box. b. The Blink duration can be changed by entering the time in seconds in the Duration box. 3. Click the OK button to apply and save the changes.
Section 6 — Broadlinx Software Updating the FPGAs Firmware on Multiple Boards at the Same Time The steps needed to update the FPGAs Firmware are: 1. Installing the latest version of the Broadlinx software. 2. Updating the FPGAs firmware for a group of boards. 3. Restarting the updated boards Each of these steps is described in detail below.
Configuration Selecting the Board Type You need to know the board type ID to update that board. 1. Enter deviceListShow At the command prompt. The device list will then appear. The available boards and information about the frame will be displayed. 2. Select the board type that you want to update. The 3G Input board (HI33300-3G HD/SD Input - 3G) is type 26. This is the board type that will be used in the rest of the examples.
Section 6 — Broadlinx Software Updating the FPGA Firmware for a Group 1. Type updateFpgaGroup 26 At the Command prompt. The following will then occur: • The lights on the selected boards will then go red. • The update process will then look for and then report the selected board types in the different slots. For example: value = 0 = 0x0 Trinix1 > 20000528.000111: FPGA update requested for frame 0 slot 32 (class 2, type 26). (deviceMaster.
Configuration 20000528.001749: FPGA update succeeded for frame 0 slot 33, new version is 2. Card must be re-powered to use new version. (deviceMa) 20000528.001749: FPGA update succeeded for frame 0 slot 34, new version is 2. Card must be re-powered to use new version. (deviceMa) 20000528.001749: FPGA update succeeded for frame 0 slot 35, new version is 2. Card must be re-powered to use new version. (deviceMa) 20000528.001749: Updated: 4 FPGA(s) for group 8582 (passed 4, failed 0). (deviceMaster.
Section 6 — Broadlinx Software Verifying that the Update was Successful You can verify that an update was successful by using the deviceListShowcommand. 1. Type deviceListShow At the command prompt. The device list will then appear. All updated boards will have an asterisk by the version number. See the example below: 2. Restart the boards. Restarting the Updated Boards The updated boards must be restarted for the firmware to be activated. Follow these steps to restart the recently updated boards: 1.
Configuration The system will then respond with the following console message: value = 0 = 0x0 Trinix1 > 20000528.001933: Restart FPGA in frame 0 slot 32 (class 2, type 26). (slaveDevice.cc:640) 20000528.001934: Restart FPGA in frame 0 slot 33 (class 2, type 26). (slaveDevice.cc:640) 20000528.001935: Restart FPGA in frame 0 slot 34 (class 2, type 26). (slaveDevice.cc:640) 20000528.001935: Restart FPGA in frame 0 slot 35 (class 2, type 26). (slaveDevice.cc:640) The FPGAs have been updated.
Section 6 — Broadlinx Software For example: Type Trinix1 > updateFpgaGroup at the command prompt. The following text will be displayed. Forcing an Update Entering a coma and then the number “1” after the updateFpgaGroup command will force all boards for the selected type to update regardless of the FPGA version. For example: updateFpgaGroup 26 ,1 The process will be similar to what is described in Updating the FPGAs Firmware for a Group of Boards on page 322.
Section 7 Broadlinx Console Commands The following commands can be used when you are connected to the Trinix NR-33000 (Broadlinx) board through a console session on a PC using either a serial connection to the Console A port or an Ethernet/ Telnet connection. Each of these commands is explained in the tables below. You can quickly access the commands by clicking the first letter of the command below. [A] [C] [D] [E] [F] [H] [I] [L] [M] [N] [O] [P] [R] [S] [T] [U] [V] Table 60.
Section 7 — Broadlinx Console Commands Table 61. C Command Arguments Detailed Description comBusStart () Starts com bus polling (or any other com bus activity) by releasing the bus. Do not do this unless you acquired the com bus. comBusStop () Stops com bus polling (and any other com bus activity) by acquiring the bus. No EsTributary activity can proceed till the com bus is released.
Table 64. F Command Arguments Detailed Description far (char *fileName) Archives firmware. fileName is the name of a firmware archive. This will display the contents of the archive file with some file information. finger () Find out who is on the bus (shows frame, slot, type, and version) frameTempShow () No Help Text (frameTemp.cc) fwDownload (int frame, int slot, char *fileName) Download a file to a microcontroller.
Section 7 — Broadlinx Console Commands Table 68. M Command moduleIdShow Arguments (int verbose) Detailed Description Prints information about all known devices. Table 69. N Command Arguments Detailed Description netConfigShow () No Help Text (netConfig.cc) nrUpTime (void) Displays the total time the system has been alive. Table 70. O Command Arguments Detailed Description outputMonitorShow (int verbose) Show output monitor status. verbose can be 1 or 2 for more or still more verbosity.
Table 71. P Command Arguments Detailed Description protectedPathsReset (void) Diagnostic use only. Sets the ForceFileReadFlag. The flag causes the next output card update from the device master to check the status of the network redundancy device. If the device is not active i.e. no network connection to another board or the other board device master is not polling, PathInit is called.
Section 7 — Broadlinx Console Commands Table 73. S Command Arguments Detailed Description sendLoader (int type, int frame, int slot) Updates the loader. Example: sendLoader -1 Enter the command with no arguments to print a usage statement. setDaylightSavings (int on) Set daylight savings on or off. Typically daylight savings kicks in on a certain day and off again on another day.
Table 76. V Command versionShow Trinix NXT — Installation and Service Manual Arguments (void) Detailed Description No Help Text (ver.
Section 7 — Broadlinx Console Commands 336 Trinix NXT — Installation and Service Manual
Section 8 Broadlinx Version and Supported Trinix Boards The following tables show the version of firmware and Broadlinx for each type of board. The Table name will be the name of the board. For example, Under the board type Matrix Controller, Table 78 is the NR33000 board. This information is intended to help you understand what is required to update from your current version to the latest version of software. The legend below shows the meaning of the different colors that are used in each table.
Section 8 — Broadlinx Version and Supported Trinix Boards Matrix Controller Table 78. NR33000 Date Released 8/25/ 03 3/4/ 04 7/30/04 2/11/05 9/19/05 2/17/06 8/15/06 1/18/07 10/23/ 07 8/19/09 10/23/ 09 30Jul1 0 15Mar11 Sep11 Broadlinx Version 2.0.0 2.1. 1 2.2.0 2.2.1 2.2.2 2.3.0 2.4.0 2.4.1 2.4.2 3.0.1 3.0.2 3.1.0 3.2.0 3.3.
Matrix Table 80. DM33100 Date Released 8/25/ 03 3/4/ 04 7/30/ 04 2/11/ 05 9/19/ 05 2/17/ 06 8/15/ 06 1/18/07 10/23/ 07 8/19/ 09 10/23/ 09 30Jul1 0 15Mar1 1 Sep 11 Broadlinx Version 2.0.0 2.1.1 2.2.0 2.2.1 2.2.2 2.3.0 2.4.0 2.4.1 2.4.2 3.0.1 3.0.2 3.1.0 3.2.0 3.3.0 908 Loaders Firmware version 2 3 3 3 3 3 3 3 3 3 4 4 4 4 908 App Firmware version 5 6 7 7 7 8 8 8 8 8 8 9 9 9 FPGA Firmware version 5 5 5 6 6 6 7 7 7 9 9 9 9 9 Table 81.
Section 8 — Broadlinx Version and Supported Trinix Boards 908 App Firmware version 8 FPGA Firmware version 25 CPLD 7 Table 84. DM128[R]-3G Date Released 8/25/ 03 3/4/ 04 7/30/ 04 2/11/ 05 9/19/ 05 2/17/ 06 8/15/ 06 1/18/07 10/23/ 07 8/19/ 09 10/23/ 09 30Jul1 0 15Mar1 1 Sep 2011 Broadlinx Version 2.0.0 2.1.1 2.2.0 2.2.1 2.2.2 2.3.0 2.4.0 2.4.1 2.4.2 3.0.1 3.0.2 3.1.0 3.2.0 3.3.
Table 87. DM256x-3G Continued Date Released OCT 2011 Broadlinx Version 3.3.1 908 Loaders Firmware version 4 908 App Firmware version 9 FPGA Firmware version 25 CPLD 7 Reference Table 88. SR33500 Date Released 8/25/ 03 3/4/ 04 7/30/ 04 2/11/ 05 9/19/ 05 2/17/ 06 8/15/ 06 1/18/07 10/23/ 07 8/19/ 09 10/23/ 09 30Jul1 0 15Mar1 1 Sep201 1 Broadlinx Version 2.0.0 2.1.1 2.2.0 2.2.1 2.2.2 2.3.0 2.4.0 2.4.1 2.4.2 3.0.1 3.0.2 3.1.0 3.2.0 3.3.
Section 8 — Broadlinx Version and Supported Trinix Boards Table 89. TrxSR Date Released 30Jul10 15Mar11 Sep2011 OCT2011 Broadlinx Version 3.1.0 3.2.0 3.3.0 3.3.1 908 Loaders Firmware version 4 4 4 4 908 App Firmware version 7 8 9 9 FPGA Firmware ver- 6 sion 6 6 6 CPLD 4 4 4 4 Table 90. TrxOPM Date Released 15Mar11 Sep 2011 OCT2011 Broadlinx Version 3.2.0 3.3.0 3.3.
908 Loaders Firmware version 4 908 App Firmware version 6 Input Table 93. SI/HI-33110 Date Released 8/25/ 03 3/4/ 04 7/30/ 04 2/11/ 05 9/19/ 05 2/17/ 06 8/15/ 06 1/18/07 10/23/ 07 8/19/ 09 10/23/ 09 30Jul1 0 15Mar1 1 Sep 2011 Broadlinx Version 2.0.0 2.1. 1 2.2.0 2.2.1 2.2.2 2.3.0 2.4.0 2.4.1 2.4.2 3.0.1 3.0.2 3.1.0 3.2.0 3.3.
Section 8 — Broadlinx Version and Supported Trinix Boards 908 Loaders Firmware version 4 908 App Firmware version 2 FPGA Firmware version 6 CPLD 2 Table 97. VI33100 Date Released 8/25/ 03 3/4/ 04 7/30/ 04 2/11/ 05 9/19/ 05 2/17/ 06 Broadlinx Version 2.0.0 2.1.1 2.2.0 2.2.1 2.2.2 2.3.
Table 100. HI33300-3G Continued Date Released Oct 2011 Broadlinx Version 3.3.1 908 Loaders Firmware version 4 908 App Firmware version 7 FPGA Firmware version 4 CPLD 2 Output Table 101. SO33110 Date Released 8/25/ 03 3/4/ 04 7/30/ 04 2/11/ 05 9/19/ 05 2/17/ 06 8/15/ 06 1/18/ 07 10/23/ 07 8/19/ 09 10/23/ 09 30Jul1 0 15Mar1 1 Sep 2011 Broadlinx Version 2.0.0 2.1.1 2.2.0 2.2.1 2.2.2 2.3.0 2.4.0 2.4.1 2.4.2 3.0.1 3.0.2 3.1.0 3.2.0 3.3.
Section 8 — Broadlinx Version and Supported Trinix Boards Table 103. HO33110 908 App Firmware version 5 6 7 7 7 8 8 8 8 8 9 9 9 9 FPGA Firmware version 11 12 13 13 13 14 14 16 16 19 19 19 19 19 1/18/ 07 10/23/ 07 8/19/ 09 10/23/ 09 30Jul1 0 15Mar1 1 Sep 2011 Table 104. HO33110 Continued Date Released Oct 2011 Broadlinx Version 3.3.1 908 Loaders Firmware version 4 908 App Firmware version 9 FPGA Firmware version 19 Table 105.
Table 107. HO33300-3G Date Released 8/25/ 03 3/4/ 04 7/30/ 04 2/11/ 05 9/19/ 05 2/17/ 06 8/15/ 06 1/18/ 07 10/23/ 07 8/19/ 09 10/23/ 09 30Jul1 0 15Mar1 1 Sep 2011 Broadlinx Version 2.0.0 2.1.1 2.2.0 2.2.1 2.2.2 2.3.0 2.4.0 2.4.1 2.4.2 3.0.1 3.0.2 3.1.0 3.2.0 3.3.
Section 8 — Broadlinx Version and Supported Trinix Boards FPGA Firmware version 3 3 CPLD 1 1 Table 111. FO33300 Date Released Sep 2011 Oct 2011 Broadlinx Version 3.3.0 3.3.
Section 9 Protected Paths Protected Paths Overview The Protected Path function is designed to monitor router outputs that are feeding critical downstream equipment. In the event of signal loss, the Protected Path function will automatically select the output that is carrying the same signal and trigger the system alarm. The first indication of signal loss is that the LED on the front door should switch to red.
Section 9 — Protected Paths Caveats When using the Protected Paths option, you should be aware of the following conditions. The time that it takes to make the switch from a primary path to a secondary path will depend on the size and configuration of the Routing switcher, as well as the control system. For example, two 128 Routing switchers are different than two 512 switchers. The 512 has a different power supply and has more cards.
Protected Paths Overview When adding an HO33120 or HO33300 output board to the Trinix router used in a Protected Path, the following should be observed: • Add the board during a non-critical time as it may take up to four seconds to recognize the board. A two-minute delay can cause signal disruption on the active board’s outputs. • Telnet into the control system and turn off the refresh feature; wait 30 seconds before turning on the refresh feature once the output board is powered up.
Section 9 — Protected Paths Verifying the Parameters on the Broadlinx Boards There is a known issue when a non-initialized Broadlinx board is made Active in a Trinix router that is using Protected Paths. The Broadlinx board will turn on all router outputs when it is installed. This action is not a defect as it is what the board should do when it is installed in a router that does not use Protected Paths.
Verifying the Parameters on the Broadlinx Boards Figure 240. Command Buttons on Bottom of Protected Paths Menu Wait a minute for the information to be saved and then return to the terminal session. Return to the Terminal Session 1. Enter the ll “/ata0”command on both the primary and secondary console connections. The Listing Directory Information will then be shown. 2. Verify that the dates and sizes of the paths.dat file are similar (Figure 241 on page 353). Figure 241.
Section 9 — Protected Paths 4. Enter deviceMasterShow at the command prompt for both the primary and secondary console connections. The Device Master information will then be shown. 5. Verify that the following values are the same on both boards: • Frames Added • Slaves Added Figure 243. The Device Master Information List If the values are the same, the Broadlinx board is ready to be initialized and activated.
Broadlinx Software with Protected Paths Installation Broadlinx Software with Protected Paths Installation These installation steps are for existing boards that do not have the latest software. This installation process requires multiple steps, such as: • Copying the application files to the Compact Flash cards. • Removing and then reinserting the Broadlinx boards back into the Trinix frame. Note • It is recommended that you remove and update one board at a time.
Section 9 — Protected Paths Figure 244. The Enter Button on the Signals: Protected Paths Web Page 4. Wait for a minute for the file to be copied. You can verify that the file has been started using a Telnet session to the Secondary processor address and then entering the following at the command prompt: ll "/ata0" 5. Activate the secondary processor. (Enter the redundancyBoardActivate command from a console session or press the button near the compact flash on the side with two buttons.
Broadlinx Software with Protected Paths Installation Note The above steps describe how to update both processors independently. Of course you can simply remove both processors and update them at the same time and re-enter the protected path configuration. You can also keep the paths web page up while the boards run and save the path data with the Enter button once the HTTP server has started on the board the page is connected to.
Section 9 — Protected Paths Figure 247. The Activate button on the Firmware Management Page The Update Progress window will then appear. 4. Close the update progress window when the update is completed. Restart any necessary systems from the firmware management page. Accessing the Protected Path Page The Protected path page can be accessed by two means: from the Navigation panel and from the Path tab on the top of the Signals page (Figure 252 on page 360).
Broadlinx Software with Protected Paths Installation From the Paths Tab Follow these steps to access the Protected Paths page: 1. Scroll down to the bottom of the Frame page. 2. Click the Signals button as shown in the figure below. The Signals: Monitor page will then appear. Figure 250. The Signal Button on the Paths Page 3. Click the Paths tab (Figure 251). Figure 251. The Paths Item in the Navigation Panel 4. The Signals: Protected Paths page will then appear.
Section 9 — Protected Paths Broadlinx Protective Paths Web Page The Protective Paths web page is part of the Signals: Monitor page. All Protected paths can be changed together by checking either the Primary or Secondary check box and selecting the Enter button. Figure 252.
Broadlinx Protective Paths Web Page Alarm type drop-down list Selecting the type of alarm from the drop-down list will only display the alarms for the selected type. The selections are as follows: • No Alarms: Selecting the “No Alarms” option means any protected path failure/changeover events will not trigger the system alarm. (A Failure/changeover will still be indicated on the web page).
Section 9 — Protected Paths The Fail Back option refers to the ability to return to the primary output of a valid path, if the output on the secondary path becomes invalid. Note A manual Fail Back will not return to the primary path. The primary path must be activated manually. The fail back options are: • Auto: Selecting the “Auto” option will allow an automatic fail back to the Primary path from an active secondary path.
Broadlinx Protective Paths Web Page Secondary Column The Secondary column is used to enter the corresponding secondary output number for each protected pair. Note If the Trinix router is set to be used with an Encore control system (rear panel switch set to “INT XPT CNTL” = closed), these columns will automatically be shown as 1-based. If the Trinix router is set to be used with a Jupiter control system (“INT XPT CNTL” = open), these columns will automatically be shown as zero-based.
Section 9 — Protected Paths Table 112. Status Column Flag Colors Flag Color Definition A black status flag means that the output is not available because a supported board is not present in that slot. Black Toggle Column The Toggle column can be used to change from primary to secondary or secondary to primary. In this case the Toggle box is checked and the Enter button has been selected. Lock/Unlock Column The Lock/Unlock column can be used to prevent the paths from being modified or from switching.
Broadlinx Protective Paths Web Page Refresh The Refresh button will update and display the information on the active page. Pressing the Reload button (Located below the Grass Valley logo on the Web page Figure 257.) will cause both pages to refresh. Figure 257.
Section 9 — Protected Paths System Alarm Overview The Trinix system alarm is designed to monitor various router functions, including operation of cooling fans, frame power supplies, on-board power supplies, and primary vs. secondary Broadlinx board operation. Any alarm for these critical items will be treated as a Primary alarm. The alarm system has two modes: • No alarms, which will illuminate the green LED on the front door of the router and on the Status LED on the back of the router.
Encore Configuration Encore Configuration When the router is controlled by Encore, protected path operation requires configuration as follows: 1. Open the Global Level Configuration page if it is not already open. 2. Create two levels (one for each of the primary and secondary paths): Figure 258. The Global Level Configuration Screen 3.
Section 9 — Protected Paths Figure 259. The Physical Matrix Configuration Screen 4. Enable the Share option in the Segment configuration (this allows the segment to be shared across multiple logical matrices). 5.
Encore Configuration Figure 260. The Logical Matrix Configuration Screen 6. Assign one logical matrix to the primary level, assign primary logical matrix “Element 1” to be the Segment created in Step 3 above. 7. Assign the other logical matrix to the secondary level, assign secondary logical matrix “Element 1” to be the Segment created in Step 3. 8.
Section 9 — Protected Paths Figure 261. The Source Configuration Screen 9. Using the Destination Configure screen, select the desired destination and enter the logical matrix names and connector numbers for the primary and secondary levels on the selected destination: Figure 262.
Jupiter Configuration Note With Encore systems, there is no “follow” level locking function; in other words, it remains possible to inadvertently perform a breakaway switch. Jupiter Configuration As described earlier, the control system (for example, Encore or Jupiter) must be operated so that the secondary path is always ready to provide a copy of the protected signal.
Section 9 — Protected Paths Note The “#IN / #OUT” shown in the Switcher Description table is the overall system size. For this example the entry would be 512 x 512 for both logical levels. Switcher Input Tables With two logical levels defined on the Switcher Description table, the Switcher Input and Switcher Output tables will automatically show a column for each level.
Operation Notes Operation Notes Jupiter Systems CAUTION For Jupiter-controlled routers, replacing an HO-33120 output board that is part of a protected path scheme will cause a momentary loss of video on the active output. In other words, video will be lost on the board not being replaced. This interruption will continue for several seconds. Maintenance personnel should therefore plan on such replacement only when the protected output is not being used on air.
Section 9 — Protected Paths 374 Trinix NXT — Installation and Service Manual
Section 10 Encore Control The Trinix router was designed so it can be controlled by a variety of control systems. Trinix can be controlled using a direct Ethernet (“CPL”) integration with the Grass Valley Encore or SMS 7000 control system. The system is operated in the Internal Crosspoint Bus Control mode, during which the Broadlinx board sends commands to the Crosspoint bus.
Section 10 — Encore Control Figure 265. Encore Connections to Trinix PC Ethernet switch EN1 EN1 Primary Encore controller Secondary Encore controller EN2 EN2 Ethernet switch Ethernet switch NIC A connector NIC B connector Trinix Encore control panels Encore and Broadlinx The Broadlinx board is equipped with a plug-in, rechargeable lithiumion battery that is used to back up the Routing switcher status for Encore-controlled systems. This battery is rated for approximately 500 power cycles.
Sync Reference For information about Sync Reference, see Sync Reference Connections on page 157. Encore Configuration of Protected Paths Encore may be configured to use the Protected Paths option. See Encore Configuration on page 367 in the Protected Paths section. If the Trinix router is set to be used with an Encore control system, the INT XPT CNTL switch must be set to closed.
Section 10 — Encore Control 2. Rebooting Encore with no matrix present: • The Trinix routing switcher, with single NR card already installed, is powered up after Encore. Encore will detect the addition of the matrix controller but there was no correspondence prior to deletion of the same matrix controller. • This condition tells Encore that the RCE MAP may not be correct and the MAP should be read back from the matrix and used to refresh the RCE status.
Section 11 Analog Input Processing TRX-VI-33100 Module The TRX-VI-33100 video input module consists of a 16-input “universal” base board (VI-33100) and a 16-input digital-only mezzanine board (HI-33201). The VI-33100 universal base board auto-senses and accepts 16 composite analog SD, digital SD, or digital HD signals in any combination and passes them in digital SD or digital HD form (as appropriate) to the Trinix matrix board.
Section 11 — Analog Input Processing Customizing Analog Video Processing Settings When analog video signals are fed to the VI-33100 base board, each of the 16 inputs can be adjusted independently. The adjustments are made using a terminal connection to the board. Terminal Setup 1. Connect a straight-through RS-232 serial cable from the VI-33100 card front-edge 9-pin connector to the serial port of a PC with HyperTerminal software (or equivalent).
TRX-VI-33100 Module Figure 266. Main Menu ======= MAIN Menu Options ======= 1.) Setup Composite Video. 2.) Setup Video Processing. 3.) Setup Vertical Blanking. 4.) Setup Timing. 5.) Setup Picture Enhancer. 6.) Display Channel status. 7.) Save or Recall a Configuration File. Select a menu option: 5. At this point you may want to change the display settings to get as many rows and columns, and as small a font, as practical. For example, with HyperTerminal go to View > Font > and select a 6point font.
Section 11 — Analog Input Processing General notes about the setup application editor Here are a few conventions about the setup application editor that may be helpful to know: • Tables are edited using keyboard shortcut keys (not the mouse or cursor keys). The applicable shortcuts are listed on the bottom of the display. • The first step is usually selection of one of the 16 inputs (channels). • Channel numbers are hex-based. E.g.
TRX-VI-33100 Module Main Menu Options This section assumes that the Terminal Setup procedure has been performed. 1.) Setup Composite Video Composite video selections are summarized below in Table 116. These adjustments are made in the composite video path (before decoding to component digital format) and apply to all lines (active picture and VBI) The actual menus are shown on Figure 267 on page 383. Table 116. Composite Video Selections.
Section 11 — Analog Input Processing | | | | | | +------------- Input Video Gain (%) | | | | | | | | +----- Enable ACC (On/Off) | | | | | | | | | | +---+---+---+---+---+---+-------+--------------------------------------------+-0, 0, 0, 0, 2, 1, 100.0, 1 525 1, 0, 0, 0, 2, 1, 100.0, 1 N/A 2, 0, 0, 0, 2, 1, 100.0, 1 N/A 3, 0, 0, 0, 2, 1, 100.0, 1 N/A 4, 0, 0, 0, 2, 1, 100.0, 1 N/A 5, 0, 0, 0, 2, 1, 100.0, 1 N/A 6, 0, 0, 0, 2, 1, 100.0, 1 N/A 7, 0, 0, 0, 2, 1, 100.0, 1 N/A 8, 0, 0, 0, 2, 1, 100.
TRX-VI-33100 Module Table 117. Video Processing Selections Processing Function Type Insert EDH Range/Choices Resolution Default 0 1 = Allows EDH to be inserted Contrast / Y Gain 100% 50–200% (0.5% steps) Saturation / Chroma Gain 100% 50–200% (0.5% steps) Brightness / Y Offset 0 Mv ±400 mV (3 mV steps) Hue / Chroma Phase 0 degrees ±180 degrees (1.4 degree steps) Figure 269. Video processing menu for NTSC, showing setup for all 16 inputs. PAL display is similar.
Section 11 — Analog Input Processing 50.0% to 200.0% (0.5% steps) -180.0 to +180.0Deg (1.
TRX-VI-33100 Module Processing Function Type Blank Setup Range/Choices Resolution Default 0 0 = Pass this line pair as is 1 = Blank this line pair 2 = (NTSC only) Add Setup to this line pair 3 = (NTSC) Add Setup and blank this line pair NTSC-Reserve additional lines for data: 0 = No additional lines reserved 1 = Reserve lines 21 and 284 2 = Reserve lines 22 and 285 3 = Reserve lines 23 and 286 4 = Reserve lines 24 and 287 Reserve Line for Data Mode 0 PALx-Reserve additional lines for data: 0 = No ad
Section 11 — Analog Input Processing Disable (Off) Enable (On) 0 1 Notch Decode: Notch Decode Pass Through 1 2 NTSC-Reserve Data: None 0 21/284 1 22/285 2 23/286 3 24/287 4 VBI: None Blank Line Only Add Setup Only Setup & Blank 0 1 2 3 -------------------------------------------------------------------------------+------------- Channel Line Rate --------+ | +----------- Notch Decode Mode | | | +--------- Chroma Kill (On/Off) | | | | +------- Reserve Line for Data Mode | | | | | | | | | | |<-------- V
TRX-VI-33100 Module Press: 'M' to move/copy channel configuration. Press: 'Z' to set ALL channels to factory defaults. Press 'ESC' to return to Main Menu. When an input (channel) is selected, the display will show the values for that particular channel: Figure 274. Timing setup menu for one channel (NTSC shown).
Section 11 — Analog Input Processing 5, 6, 7, 8, 9, a, b, c, d, e, f, 0 0 0 0 0 0 0 0 0 0 0 N/A N/A N/A N/A N/A N/A N/A N/A N/A N/A N/A Press: '0 ~ 9' or 'A ~ F' to select channel to edit. Press: 'M' to move/copy channel configuration. Press: 'Z' to set ALL channels to factory defaults. Press 'ESC' to return to Main Menu. When an input (channel) is selected, the display will show the values for that particular channel (NTSC shown): Figure 276. Picture enhancer menu for one channel.
TRX-VI-33100 Module Remove Setup (On/Off) Chroma Kill (On/Off) Video Decode Mode AGC Enable (On/Off) Input Video Gain (%) ACC Enable (On/Off) Input Chroma Gain (%) : : : : : : : 0 0 2 1 100.0 1 100.0 0 0 2 1 100.0 1 100.0 0 0 2 1 100.0 1 100.0 0 0 2 1 100.0 1 100.0 Video Processor: Insert EDH (On/Off) : Contrast/Y Gain (%) : Saturation/Chroma Gain (%): Brightness/Y Offset (mV) : Hue/Chroma Phase (Deg) : 0 100.0 100.0 +000.0 +000.0 0 100.0 100.0 +000.0 +000.0 0 100.0 100.0 +000.0 +000.0 0 100.
Section 11 — Analog Input Processing b. Select “Save a configuration file to the PC.” Response: Prepare your terminal emulator to receive (upload) data now... c. For HyperTerminal, select “Transfer > Receive File.” d. Create or browse to a directory on the PC where the file will be stored. Suggestion: “c:\Program Files\Thomson\Trinix\VI-33100.” e. Select Xmodem for the protocol. Then select “Receive.” f. Enter a filename where the data will be saved on the PC. Suggestion: “config1.
Section 12 Troubleshooting Note It may take up to 30 seconds for the 3G modules alarms to clear when starting up the boards. The boards are operational; however the voltage sensing alarms can take up to 30 seconds to clear. This length of time to clear the alarms is due to the fact that the 3G modules are using new voltage averaging algorithms in the 908 Micro controllers to compare and verify all voltages.
Section 12 — Troubleshooting Off Supply is not powered (or is not operating) Asymmetrical Frames Power Supply LED Display Meaning On The AC input is OK. Blinking The Input is out of limit. On The DC input is OK. Blinking The supply is overloaded. On This is an Over-temperature warning. Blinking Service is required. On There is a fault.
Fans Display FAN ALARM Meaning Red Check fan Off Fan OK Input boards - SI-33110 SD, and HI-33110 HD Part side Ref ALARM -5VAOK IN_USE DS601 DS31 Display Meaning Red Master alarm for this board.
Section 12 — Troubleshooting Input boards - HI-3G Ref IN_USE DS610 XC_DONE DS521 ALARM 7V 3V3 2V5 -1V3 +3V3D +3V3 5V 396 DS601 DS3004 DS3003 DS3002 DS3001 DS968 DS1 DS963 Display Meaning Reserved for future use Green The FPGA is configured. Off Configure FPGA. Red Master alarm for this board. A DC supply has failed to turn on Off Board OK Green The Gain cell power is OK. Off Check the Gain cell power. Green The Equalizer and Misc. power is OK.
Output board - HO-3G Part side Ref XC_DONE P5V INUSE ALARM DS568 DS901 DS3 DS901 Display Meaning Green The Xilinx FPGAs are properly configured Off FPGAs failed to configure Green +5 V supply voltage present Off Check +5 V supply Yellow 1 or more outputs now in use on this board* Off No CrossPoints in use on this board Red Master alarm for this board Off Board OK Trinix NXT — Installation and Service Manual 397
Section 12 — Troubleshooting Matrix board - DM-128R-3G and DM-128-3G Part side Ref ALARM XC DONE DS401 DS402 Display Meaning Red Primary alarm for this board.
Matrix board - DM-256R-3G and DM-256-3G Part side Ref ALARM XC DONE IN USE A DS3 DS4 DS5 Display Red Primary alarm for this board.
Section 12 — Troubleshooting IN USE ACTIVE PS FAIL DS2175 DS2203 DS940 XPT-B (Only on DM256R) IN USE DS2123 Yellow Off XPT A is not being used Yellow XPT A is the active cross point (X PT) Off XPT A is not the active cross point (X PT) Red XPT A’s power has failed Off XPT A’s power is OK Yellow XPT B is being used Off ACTIVE PS FAIL 400 DS2022 DS937 XPT A is being used XPT B is not being used Yellow XPT B is the active cross point (X PT) Off XPT B is not the active cross p
Matrix board - DM-33100 Part side Ref PALARM 3V3 INUSE -3V3 DONE DS952 DS951 DS901 DS31 DS950 Display Meaning Red Primary alarm for this board.
Section 12 — Troubleshooting 512 Matrix board - DM-33501/33502 Part side Ref IN USE A P2V5A OK IN USE B XC DONE ALARM P2V5B OK P5V PS1 OK PS2 OK 402 DS201_1 DS204_1 DS201_2 DS402 DS401 DS204_2 DS901 - - Display Meaning Yellow A CrossPoint is active in XPT_A IC Off No CrossPoints are active in XPT_A IC Green P2V5A converter is OK (for XPT_A side) Off P2V5A converter has failed Yellow A CrossPoint is active in XPT_B IC Off No CrossPoints are active in XPT_B IC Green FPGAs a
Output boards - SO-33110 SD and HO-33110 HD Part side Ref INUSE DONE +10V +5VA 3.3V ALARM DS3 DS501 DS41 DS31 DS51 DS601 Display Meaning Yellow 1 or more CrossPoints now in use on this board* Off No CrossPoints in use on this board Green The Xilinx FPGAs are properly configured Off FPGAs failed to configure Green +10 V supply OK Off Check +10 V supply Green +5VA supply OK Off Check +5VA supply Green 3.3 V supply OK Off Check 3.
Section 12 — Troubleshooting Output board - HO-33120 HD Part side Ref XC_DONE P5V DS568 DS901 INUSE P_ALRM_N DS3 DS901 Display Meaning Green The Xilinx FPGAs are properly configured Off FPGAs failed to configure Green +5 V supply voltage present Off Check +5 V supply Yellow 1 or more outputs now in use on this board* Off No CrossPoints in use on this board Red Master alarm for this board Off Board OK SR-33000 Sync Reference / Output Monitor (OPM) board Part side Ref Display Mea
REF_ALRM A Yellow Reference A alarm PALRM Red Primary alarm SALRM Red Primary alarm - single fan failure Trinix NXT — Installation and Service Manual 405
Section 12 — Troubleshooting NR-33000 NIC/Sync/OPM board Part side 1 - Software Switch Override Active LED 2 - Solid 3 - Blinking Number Ref Display Meaning 1 SW OVR DS1 Yellow Software override switches 2 ACTIVE DS2 Solid yellow This card has control of Com Bus and/or CrossPoint Bus. CrossPoint bus active. Internal XPT control. 3 ACTIVE DS2 Dim or blinking yellow This card has control of Com Bus. Com bus activity. External XPT control (for example, the Jupiter VM-3000).
DIP side 11 - LAN link OK 10 - LAN activity 9 - Secondary alarm 8 - Primary alarm 7 - Reference B alarm 6 - Reference A alarm 5 - 10 V (A and B) Supplies OK 4 - 5 V A supply OK 3 - 3V3 supply OK 2 - Xilinx FPGA load complete 1 - Output monitor is active Number Ref 1 USE 2 3 4 5 Meaning Yellow Output monitor is active XOK Green Xilinx load done 3V3 Green 3V3 supply OK Off Check 3V3 supply Green 5 VA supply OK Off Check 5 VA supply Green 10 V (A and B) supplies OK Off 10 V (A and/or
Section 12 — Troubleshooting 9 SALR Red single fan failure 10 LAN Flashing green LAN activity 11 LINK Green LAN link OK Dual 7-segment LEDs 12 - Dual 7-segment LEDs See NR-33000 dual 7-segment LED CPU codes on page 409. Number 12 408 Ref Dual 7-segment LEDs Display Meaning Numeric pattern CPU codes.
NR-33000 dual 7-segment LED CPU codes The CPU codes LEDs indicate the “boot phases” and are followed by a circular pattern. These “boot phases” are indicated by a sequence of letters/ numbers. The following text describes their meaning. S.0 S.1 B.C 1.C B r 3 2 6 4 2 8 5 6 1 2 S.2 S.3 S.4 S.5 S.6 S.7 End of bus 0 first access to segment display if the start type is BOOT_COLD End of bus 1 If there is a memory check sum error in the EEPROM.
Section 12 — Troubleshooting Signal flow Signal flow for a 256 x 256 router, which requires four matrix cards, is shown below. Figure 279.
Figure 280.
Section 12 — Troubleshooting Signal flow for a 256 x 256 router, which requires four matrix cards, is shown below in Figure 281. Figure 281.
Figure 282.
Section 12 — Troubleshooting Incompatible Switches Grass Valley recommends that you do not use un-managed switches with Broadlinx. The following, is a list of switches that do not work with Broadlinx. This list is not all encompassing and will be added to as new conflicting switches are found. Table 121.
Section 13 Trinix Fiber Option Trinix Fiber Boards Overview Each Trinix Fiber board provide 32 channels for both Input and Output board sets and may be used to send or receive SD, HD and 1080p/3G video signals through fiber optic cables. These boards use optical Input and Output SFP modules for fiber optic connectivity. These Small Form-factor Pluggable (SFP) devices are plugged into the Trinix rear panel, and fit into sockets that have been designed to house the SFPs.
Section 13 — Trinix Fiber Option Fiber Optic Cleaning Requirement Use an industry standard fiber optic cleaning kit, including oil-free compressed air, to clean the fiber connectors and the fiber end faces before making any fiber optic cable mating connections (including sub-module installation) and after every time the cables are disconnected. This cleaning requirement helps ensure optimum performance of the fiber optic interface.
Trinix Fiber Boards Overview WARNING Fiber-optic connectors need to be cleaned every time they are mated and un-mated; it is essential that fiber-optic users develop the necessary discipline to always clean the connectors before they are mated. Follow these steps when cleaning fiber-optic connectors: • When cleaning the connector sections, include the tips and sides of ferrules, the interior walls of alignment sleeves, and the interior and exterior of connector shells.
Section 13 — Trinix Fiber Option Refer to Contacting Grass Valley on page 4 at the front of this document for information on contacting Grass Valley Customer Service.
Specifications Specifications The functionality of the fiber Input and Output boards are similar to the HI/HO-33300 coax input and output boards. For the SFP specifications, see the current version of the 8943RDA/-D/DFR (SD/HD/3G-SDI Fiber Ready Reclocking DA), Installation manual on Grass Valleys web site (see Contacting Grass Valley on page 4 for more information). http://www.grassvalley.com/assets/media/3540/ Fiber_Optic_SFP_Devices.
Section 13 — Trinix Fiber Option FO-33300 Fiber Optic Output Board Outputs
Specifications LED Displays The Input and Output boards have the standard Trinix LEDs: • Red - Alarm. • Yellow - In use or Active • Green - Power supply presence and programmed FPGAs. The rear panel has dual color red and green LEDs, which will display the light above the SFP socket. The LEDs provide a visual indicator for valid SFP module and signal presence. Note If no LEDs are lighting up the SFP has not been installed.
Section 13 — Trinix Fiber Option Number Color Indication 606 Green FPGA is loaded 637 Yellow Active board 518 Red Alarm Condition 910-940 Green Power indicators Output Rear panel LEDs Color Indication None Off No SFPs have been installed. Red Solid Indicates an SFP alarm. This can be due to several errors, such as insufficient output power or excess output power, over or under temperature, and over or under power supply voltages.
Specifications Output Board LEDs Figure 284.
Section 13 — Trinix Fiber Option Trinix Fiber Boards Installation If you purchased the Trinix Fiber option with a Trinix Routing switcher, the boards will be installed at the factory. You will only need to install the boards on-site if they are to be used in an existing routing switcher, or used as a replacement board. Installing the three fiber boards requires that you remove the standard BNC rear panel and coax Input or Output boards, if they are present.
Trinix Fiber Boards Installation DIP Switch Settings Figure 285. Closed Open SYNC SEL A SYNC SEL B S705 AUTO RCLK BYPASS 0 BYPASS 1 BYPASS 2 BYPASS 3 BYPASS 4 BYPASS 5 BYPASS 6 BYPASS 7 S701 BYPASS 8 BYPASS 9 BYPASS 10 BYPASS 11 BYPASS 12 BYPASS 13 BYPASS 14 BYPASS 15 S702 BYPASS 16 BYPASS 17 BYPASS 18 BYPASS 19 BYPASS 20 BYPASS 21 BYPASS 22 BYPASS 23 S703 BYPASS 24 BYPASS 25 BYPASS 26 BYPASS 27 BYPASS 28 BYPASS 29 BYPASS 30 BYPASS 31 S704 Switch settings are shown in Table 124. Table 124.
Section 13 — Trinix Fiber Option Follow these steps to install the Trinix fiber option: 1. Remove the coaxial Input or Output boards from the front of the routing switcher. Move to the rear of the router. 2. Remove the standard BNC rear panel from the rear of the Trinix frame. a. Remove the top and bottom screw for the rear panel (Figure 286). Hold the rear panel in place to prevent possible damage from it falling. Figure 286.
Trinix Fiber Boards Installation 5. Align the panel in the proper direction. The rear panel circuit board near the end of the panel marked with "32," must fit into the card guide inside the frame. If the panel does not fit properly into the hole, or is at an angle relative to the rear panel surface of the frame, the panel is probably not in the card guide. 6. Fasten the rear panel to the frame using the provided screws. Figure 287.
Section 13 — Trinix Fiber Option 10. Close the Trinix routing switcher’s door. Keep the routing switcher’s door closed during operation to maintain optimum cooling conditions.
Appendix 14 Front-Air Vent Front-Air Vent (FAV) Overview The Front-Air Vent (FAV) is an optional accessory that is installed on the bottom of a Trinix NXT frame. The FAV will draw cool air through the front of the frame to cool the Trinix router. The FAV provides another option for the “bottom to top” airflow feature of the Trinix, which is “natural, proven, and quiet.” An FAV is quiet and can be used in human work spaces.
Appendix 14 — Front-Air Vent Figure 288. The FAV Front and Side View Side or “Ear” Front View Screws Aligned With the Cut Outs Router FAV Overlapping Router Side View Once the FAV is installed, it will occupy 1RU. The additional 1RU that was used during installation could then be used for other equipment or however your needs demand. This section describes the installation process of the FAV. This option is designed to work with the Trinix 256x256, 512x512, 128x256, and 256x512 frames.
Installation Procedure Installation Procedure Follow the installation steps to ensure correct installation of the FAV. Tools Required • The proper sized Phillips screwdriver, • A light source (as needed). Installing the FAV Note The 1RU Front Air Vent requires a minimum space of 2RUs during installation. Follow these steps to install the FAV: 1. Position the FAV under the Trinix frame and align the Rack-Mounting holes on the FAV with the holes that are on the frame. 2.
Appendix 14 — Front-Air Vent From the Rear Panel 1. Remove two screws from the Router’s input\output panel that are aligned with the screws on the FAV. 2. Place the Mounting brackets over the holes and then replace the existing screws (see Figure 290 below). Figure 290. Rear View of the FAV Rack-Mounting holes Trinix router FAV Mounting brackets Note 432 The Mounting brackets can be adjusted as necessary.
Appendix 15 Trinix Frame Slot Maps This appendix provides images with the slot numbers identified. This information is helpful when updating or down-grading a board as you will need to know the specific slot that the board occupies.
Appendix 15 — Trinix Frame Slot Maps Trinix 512x512 Frame Slot Numbers Broadlinx NR-33000 Primary Slot # 00 Power Supply A Power Supply C Slot # 70 Slot # 72 Power Supply B Power Supply D Slot # 71 Slot # 73 Broadlinx NR-33000 Secondary Slot # 01 Rear Chassis Boards SR-33500 Slot # 04 Sync Ref RP-33500 Slot # 06 Rear Panel FAN A FAN B FAN C FAN D FAN E FAN F Slot # 64 Slot # 65 Slot # 66 Slot # 67 Slot # 68 Slot # 69 Inputs Inputs Inputs Inputs Outputs Outputs Outputs Output
Trinix 256x256 Frame Slot Numbers N R N R P R I M A R Y S E C N D R Y 00 01 FAN A FAN B FAN C Power Supply A Power Supply B Slot # 32 Slot # 33 Slot # 34 Slot # 35 Slot # 36 Matrix Brd In 1-128 Out 129-256 Slot# 18 Matrix Brd In 129-256 Out 1-128 Slot# 17 Matrix Brd In 1-128 Out 1-128 Slot# 16 Matrix Brd In 129-256 Out 129-256 Slot# 19 Inputs Inputs Inputs Inputs Outputs Outputs Outputs Outputs Outputs Outputs Outputs Outputs Inputs Inputs Inputs Inputs 225-256 193-224 161
Appendix 15 — Trinix Frame Slot Maps Trinix 128x128 Frame Slot Numbers Power Supply A Slot # 34 Primary Broadlinx Slot # 00 Power Supply B Slot # 35 Secondary Broadlinx Slot # 01 Output 97-128 Slot # 27 Fan A Slot # 32 Fan B Slot # 33 Output65-96 Slot # 26 Input 97-128 Slot # 11 M a t r i x Input 65-96 Slot # 10 Slot # 16 Output 33-64 Slot # 25 Output 1-32 Slot # 24 Input 33-64 Slot # 09 Input 1-32 Slot # 08 436 Trinix NXT — Installation and Service Manual
Trinix 256x512 Frame Slot Numbers 071827609_256x512-Slotmap Trinix NXT — Installation and Service Manual 437
Appendix 15 — Trinix Frame Slot Maps Trinix 128x256 Frame Slot Numbers 438 Trinix NXT — Installation and Service Manual
Trinix 512x1024 Frame Slot Numbers 071827612_512x1024_slot Trinix NXT — Installation and Service Manual 439
Appendix 15 — Trinix Frame Slot Maps 440 Trinix NXT — Installation and Service Manual
Appendix 16 Expanded System Sizes This appendix provides the expanded system sizes, Frame IDs, and the Video signals that may be processed. Color Coding The SD/HD/3G vs. SD/HD color coding represents the use of 2x2 (3G capable) splitter combiners or the 4x4 splitter combiners (which are not 3G capable). Table 125. Color Legend SD/HD/3G 3 Gb/s Capable SD/HD Non 3 Gb/s Capable Expanded Systems Table 126.
Appendix 16 — Expanded System Sizes Table 128. 256x256 Frame Expanded System Inputs 1024 Frame ID=5 Frame ID=7 Frame ID=13 Frame ID=15 Frame ID=4 Frame ID=6 Frame ID=12 Frame ID=14 Frame ID=1 Frame ID=3 Frame ID=9 Frame ID=11 Frame ID=0 Frame ID=2 Frame ID=8 Frame ID=10 128 - 256 384 - 512 640 - 768 896 -1024 896 768 640 512 384 256 128 Outputs Table 129.
Table 131.
Appendix 16 — Expanded System Sizes 444 Trinix NXT — Installation and Service Manual
Glossary Glossary a large number of devices, including a CE-300A Control Board (internal to Mars), a SC-400 Control Board (internal to Venus), a CE-3000 Matrix Con- 10/100BaseT - an ETHERNET configuration that uses twisted pair wiring (typically Cat 5 UTP unshielded twisted pair cable with RJ45 8-pin connectors) to transmit data up to 100 Mbps.
Glossary HI-33110- precursor to HI-33200 SD/HD Refresh - continuous repetition of switch- Input Module. Consists of a 16-input ing instructions and confirmation of base board (HI-33110) and a 16-input crosspoint status. Reports any inter- mezzanine board (HI-33011), provid- ruption of service – for example, if ing 32 inputs. The module supports crosspoint board is removed. When data rates of 3 Mbps to 1.485 Gbps.
Index Index Symbols ... 299 +10V Output board LED 397, 403, 404 +5VA Output board LED 403 Numerics 0/1-based connector numbers 66 0-based/1-based 218 10/100BaseT defined 445 10VOK SR-33000 board LED 404 16554 Head.4.ToP DV-33512 with Redundant NR Operation 167 3.
Index CDRH 24 CENELEC 24 CFR 24 Chassis 39 Chroma gain control 383 Chroma Kill 386 summary 383 CM-4000 106, 214 Com Bus 36, 111, 224 Comb filter 383 Composite sync 157 Configuration 121, 292 Connector numbering 218 Connectors 113 0-based/1-based 66 miscellaneous 149 Console A & B connectors 149 Contrast / Y Gain 385 Control connector 150 Control system Jupiter 33, 106, 214 Cooling 56 Cooling Asymmetric Frames Cooling System 58 CPL 33, 375 CPU codes NR-33000 409 Crosspoint Defined 445 Crosspoint bus connecti
Index Fans 56 FAQ database 4 FCC 23 Ferrite 107, 216 Firewall 109, 110, 221, 222 Firmware (Broadlinx display) 297 Firmware Management menu 297 FPGA Defined 445 FPGA Active/Pending 299 FRAME IFC connector 128 Frame number for input/output blocks 212 Frame switch 212 Freight damage 125 frequently asked questions 4 Fuse value requirements 127 Fuses 153, 154 G Gain control 383 Gateway IP 296 GPIO/TC Connector 149 Grass Valley web site 4 H HD 482 S1 24 HI-33011 446 HI-33110 446 equalization 115 LEDs 395 HI-332
Index LEDs power supply 133 Level Defined 446 setting Jupiter control 217 SMS/Encore control 219 license SNMP 37 LINK NR-33000 board LED 408 lithium-ion battery 132, 376 Loader board 87 Logical level name defined 446 Logical level number defined 446 M MAC 37 Manually Setting the Time 294 Matrix Cable, VDE modifications 107, 216 Matrix bus Defined 446 Microcontroller active/pending 299 Microsoft Internet Explorer 36 Monitor 200 Monitor switch 203 Monitor tab 316 Monitored (Broadlinx display) 316 Monochrome
Index Pre-wiring 66 Primary Contoller IP 296 Primary Ref In 1 connector 129 Processing (signal) 379 Protected Paths Configuration 349, 415 Encore 367 Jupiter 371 Overview 95 Planning 98 Proxy 288 PS IFC connector 128 PS1 OK 512 Matrix board LED 402 PS2 OK 512 Matrix board LED 402 Q Quad output systems 74 R Rack mounting 126 spacers for power supply access 126 Reboot Broadlinx board 287 Reclocker (Broadlinx display) 316, 317 Reclocking HD outputs 197 monitor outputs 206 Recommended TMV Location 424 Redunda
Index SR-33000 157 LEDs 404 PALARM 153 Switch S2 206, 210 switches & jumpers 175 SR-33500 switches 176 Status Defined 446 switcher hardware 312 Status (red/green light) 300 Subnet mask 287 Super crosspoint bus Defined 445 SW OVR NR-33000 board LED 406 Switch point 170 Switched (Broadlinx display) 316 Sync inputs 113, 114 Sync redundant switch 148 Sync reference 61 T Target Name 296 Tera Term 380 Terminator 107, 215 LD-33100 Loader board 87 The Asymmetric Frame 34 The HO-33G Output Board 115 Time Management
XLD SR-33000 board LED 404 XOK NR-33000 board LED 407 XPT BUS connector 214 Trinix NXT — Installation and Service Manual 453
