Redwood Cabling Design Guide Executive summary This document reviews the system architecture and provides the cabling design guidelines and suitable operating environments for the implementation of a Redwood® energy-efficient LED lighting network. It complements the Redwood System Installation Guide and Redwood Commissioning and Administration Guide. Each option has pros and cons, which are discussed to help There are three primary cabling design options illustrated • compatibility with Redwood end-point devices in this guide: The optimal solution is dependent on the relative importance of 1) Dedicated cabling terminated on patch panels in the closet these factors as well as the labor rate for the specific installation and plugs near the sensors 2) Dedicated cabling terminated on patch panels in the closet and jacks near the sensors 3) Shared cabling terminated on patch panels in the closet and jacks near the sensors the user select between them. The four primary tradeoffs that should be taken into account are: • initial installed cost • flexibility for future modifications • cabling bulk in pathways at hand. The first two options are supported on CommScope cabling (recommended) as well as cabling components from other vendors that are fully compliant with ANSI/TIA-568-C, ISO/IEC 11801 and EN 50173-1 standards. The third option (cable sharing) is only supported on CommScope Category-6 (or better) cabling, as it has been thoroughly tested to support this more demanding configuration. 2 For more information, visit seagrp.com As noted, the three primary options include patch panels in the closet. Although patch panels are recommended, they are not required when deploying dedicated cabling (options 1 and 2 above). They are necessary when deploying shared cabling (option 3) to enable combining two Engine ports into one cable. The Appendix describes, in more detail, the rationale for recommending patch panels. Cables may be bundled in groups up to 48 cables for any portion of their length. The maximum ambient temperature for CommScope cabling is generally 50°C (122°F), although higher rated cables are available. The maximum ambient temperature for all cabling shall follow the manufacturer’s guidelines The cabling configurations described in this guide are eligible for registration in the CommScope Enterprise 20-Year Extended Product Warranty and Applications Assurance Program for the Redwood application, provided that only CommScope cabling components are used from end to end, and all other terms and conditions of the program are met. and be at least 10°C (18°F) below the maximum recommended operating temperature of the cabling to accommodate the effects of cable heating while providing power. Local fire and safety codes shall be followed. Local codes take precedence in case of conflict with this guide. It should be noted that the shared Cat-6 option is a recently introduced option that is not compatible with all Redwood end-point devices at this time: • Devices supporting cable sharing: Sensor-3, Universal Gateway, Dimmer Switch, Scene Controller Switch, some fixtures with embedded sensors (consult your Redwood representative) • Devices NOT supporting cable sharing: LED gateway and some fixtures with embedded sensors The cabling configurations described in this guide are eligible for registration in the CommScope Enterprise 20-Year Extended Product Warranty and Applications Assurance Program for the Redwood application, provided that only CommScope cabling components are used from end to end, and all other terms and conditions of the program are met. Consult your SEA Group representative with specifi c questions. For more information, visit seagrp.com 3 Redwood solution architecture Overview The Redwood system is an innovative energy-efficient lighting system that provides advanced control capabilities and building performance data to improve how commercial buildings are lit, heated, occupied and managed. Other control systems on the market are generally incrementally added to the existing electrical lighting wiring. Whether dimming, detecting motion, implementing daytime lighting, or managing to a scheduler, all of these systems traditionally sit “on top” of the power system and have fixed dependencies on the circuitry. As a result, they are complex to set up, labor-intensive, expensive to install, and difficult to modify once deployed. Redwood’s innovative approach combines power, sensing, control, and communications with a low-voltage, DC-powered, “self-aware” network architecture that automates lighting and enables building intelligence. This new approach to commercial lighting installs simply as one cohesive network of fixture and sensor hardware and is administered through a web-based dashboard from PCs and mobile devices. The Redwood design is comprised of the following elements: • A highly efficient (>83%) centralized power Engine (Redwood 4834 Engine) capable of powering multiple the Redwood sensors to control the LED luminaires, thereby light-emitting diode (LED) luminaires, with flexibility to providing light only when and where it is needed. support different currents and voltages for compatibility with various luminaires and applications. • One of the following three sensor options: 1) A Redwood sensor located adjacent to each luminaire. • Optional Redwood Dimmer Switches, which can provide manual override control of light levels for one group of lights. • Optional Redwood Scene Controller Switches, which can This compact device incorporates a gateway for provide manual override control for multiple groups of lights communicating with the Engine as well as a sensor pod simultaneously for setting scenes in large areas such as for monitoring occupancy, light level and temperature. conference rooms. 2) A third-party fixture with an embedded Redwood sensor. 3) An LED Gateway and separate sensor pod located adjacent to each luminaire. The LED Gateway has one primary RJ45 jack for interfacing with structured Category • Optional Redwood Universal Gateway used to control one or two relays, which may be used to control AC-powered devices such as legacy fluorescent pendants, conference room projectors, etc. cabling. The LED Gateway has two additional jacks, • A scalable management and monitoring software system which may be connected to separate Engine ports for (Redwood Manager) that captures and stores data from luminaires that require more than 34 watts of power. the sensor arrays. Utilizing three connections in parallel, high-power luminaires up to 102 watts can be supported. 4 • Intelligent algorithms that utilize the data gathered from For more information, visit seagrp.com Redwood does not manufacture the LED luminaires. Instead, Running the embedded Redwood Manager software, the Redwood partners with leading LED fixture manufacturers to Redwood Engine powers and communicates with Redwood provide Redwood-compatible LED luminaires for commercial Sensors, LED Gateways, Dimmer Switches, Scene Controllers, spaces and data centers. Redwood-compatible fixtures are and Universal Gateways. It is the “brains” behind the available for general interior illumination (downlights, pendants, Redwood platform and performs the sophisticated controls that direct/indirect, lay-ins, troffers), accent lighting (wall washes, significantly reduce energy consumption. Multiple Engines may sconces, linear cove lighting), task lighting, and under-cabinet be linked together to power and control hundreds or thousands lighting. of fixtures. Figure 1 shows the Redwood architecture. Redwood Manager (Software) Redwood Sensor LED Downlight Apps Redwood Open Application Framework Redwood Director ems Redwood Engines AC oodsyst redw Redwood LED Gateway LED Fixture AC Redwood Scene Control Wall Switch AC AC Category Cabling Redwood Sensor Pod Fluorescent Pendant Redwood Universal Gateway Low Voltage AC Line Voltage Relay Redwood Sensor Pod Figure 1: This shows a typical Redwood® solution architecture. For more information, visit seagrp.com 5 Communication media This guide focuses on the structured Category cabling The Redwood Engine centralizes power conversion and control assemblies can be found in the relevant Redwood specification processing for LED lighting. All the LED drivers are located in sheets and Redwood instruction sheets. the Redwood Engine. The Redwood Engine takes line-voltage AC power, converts it to low-voltage DC, and distributes it via four-pair structured Category cabling to one of the Redwood end devices. Each of the Redwood end devices has an RJ45 jack, which accepts four-pair RJ45 plugs. Each Redwood Engine is connected to the LAN via a standard 10/100/1000BASE-T port. The default policy for each Engine is “construction mode,” where each fixture turns on independently when motion is detected and stays on until no motion is detected for 30 minutes. Once the LAN In addition to the four-pair structured Category cabling between is operational, the Engines are configured as part of the the Engine and the Redwood end devices, pre-connectorized commissioning process, including assignment of lights into low-voltage cabling assemblies are used to connect the groups, assignment of policies, etc. For installations with up Redwood end devices to adjacent devices as follows: to eight Engines, one of the Engines can be configured as the • LED fixtures come assembled with a whip cord, which either has an RJ45 plug (to interface with the RJ45 jack in Sensor-3 labelled “luminaire”) or a 10-pin miniature connector (to interface with an LED Gateway). • External sensor pods are shipped with a short RJ25 cord to connect to the LED Gateway or Universal Gateway. • A Universal Gateway wiring harness (10-pin miniature connector to raw ended wires) provides the connection between the Universal Gateway and the AC relay control connection point. This wiring harness is ordered separately. 6 connectivity. Additional guidance on the low-voltage cabling For more information, visit seagrp.com master controller. For installations with more than eight Engines, a Redwood Director must be deployed. A Redwood Director is also required if integration with external applications/ systems is required. Consult the Redwood Networking Guide for detailed instructions on network configuration. CommScope recommends structured Category-6 (or better) connectivity for all network connections. Physical layer design This section describes the three primary structured Category The optimal solution is dependent on the relative importance cabling design options that can be deployed between the of these factors as well as the labor rate for the specific Redwood Engine and the Redwood end devices. Each option installation at hand. has pros and cons, which are discussed to help the user select between them. The three primary tradeoffs that should be taken into account are: All cabling components deployed shall be compliant with ANSI/TIA-568-C, ISO/IEC 11801 and EN 50173-1 standards as well as applicable local fire and safety codes. In • initial installed cost case of conflict, local codes take precedence. • flexibility for future modifications The maximum length of the structured Category cabling (cable • cabling bulk in pathways plus all cords) shall not exceed 100 meters. For more information, visit seagrp.com 7 Option #1: Dedicated cabling with patch panels and plugs Option #1: Dedicated Cat-5e Cabling with Patch Panels and Plugs Any Redwood end-device ≤ 95m • Sensor 3 (shown) • LED Gateway • Integrated fixture • Dimmer switch • Scene Controller ≤ 5m • Universal Gateway Figure 2: This illustrates dedicated cabling with patch panels in the closet and plugs at the end device. In this option, Category-5e (or better) cords, panels, and cable are It is advised to provision a small amount of slack near the used, along with field terminated plugs at the end device. Each sensor to enable minor repositioning of sensors if needed (if channel consists of one cord in the closet, one port on a patch allowed by local codes). Note that Redwood-enabled fixtures panel, one dedicated horizontal cable, and one field-terminated come equipped with a short embedded cord and are, thus, plug directly onto the solid conductor horizontal cable. not part of the structured Category cabling. To support this option, Redwood has introduced a field terminated plug. The Redwood plug can be fitted on Cat-5e and Cat-6 cables (see plug specifications for cable compatibility). Pros of cabling option #1 Cons of cabling option #1 • Lowest initial cost option • Reduced flexibility (more difficult to move/reposition • Less apparatus in ceiling area (no jacks or mounting box in ceiling area) • Readily field testable using hand-held testers (use channel adapter for ceiling area) • Compatible with all Redwood end-point devices 8 For more information, visit seagrp.com devices and more difficult to redeploy for other applications) • Location of end of cable in user area is less controlled until sensor is mounted (may require interim management of cable slack loops) • Not fully compliant with structured cabling norms Option #2: Dedicated cabling with patch panels and jacks Option #2: Dedicated Cat-5e (or better) with Patch Panels and Jacks Any Redwood end-device ≤ 90m • Sensor 3 (shown) • LED Gateway • Integrated fixture • Dimmer switch ≤ 5m • Scene Controller ≤ 5m • Universal Gateway Figure 3: This illustrates dedicated cabling with patch panels in the closet and jacks near the end device. In this option, Category-5e (or better) components are Category cabling. In some jurisdictions, it may be acceptable deployed. The cabling connectivity for two channels is shown to tie-wrap the jacks to a permanently installed building (one in blue, one in green). Each channel consists of one element. In other jurisdictions, though, the outlets may need to cord in the closet, one port on a patch panel, one dedicated be mounted in a suitable mounting box such as a CommScope horizontal cable, one jack in the ceiling, and one cord in the M101, M102 or M202 surface-mount box (not shown in ceiling. Note that Redwood-enabled fixtures come equipped above figure). with a short embedded cord and are, thus, not part of the Pros of cabling option #2 Cons of cabling option #2 • Most flexible option (easy to move/reposition devices) • Highest initial cost option • Fully compliant with structured cabling standards • More apparatus in the ceiling area • Easy redeployment for non-lighting applications • May require mounting box for jacks • Easy demarcation for permanently installed cabling (clear test-points and handoff, which is most relevant if multiple parties are doing portions of the installation) • Compatible with all Redwood end-point devices For more information, visit seagrp.com 9 Option #3: Shared CommScope Cat-6 (or better) cabling with patch panels and jacks Option #3: Shared Cat-6 (or better) with Patch Panels and Jacks (this option is only supported on Commscope cabling) Select Redwood end-devices • Sensor 3 (shown) ≤ 90m • Select Integrated fixtures • Dimmer switch • Scene Controller ≤ 5m ≤ 5m • Universal Gateway Excludes LED gateway Figure 4: This illustrates shared CommScope Cat-6 (or better) cabling with patch panels in the closet and jacks near the end device. In this option, CommScope Category-6 (or better) components are deployed. The cabling connectivity for two channels is shown (one in blue, one in green, with the shared cable in orange). A Redwood SP12A splitter is plugged into one port on the patch panel (thereby providing two jack references). Similarly, an identical Redwood SP12A splitter is plugged into the jack in the ceiling (thereby providing two jack references). The splitter is internally configured to carry the Redwood power and communication signals on two pairs as opposed to four pairs. This cabling option is, thus, identical to option #2 except that each patch panel port, horizontal cable, and jack in the ceiling is “shared” between two ports. The number of Engine ports and sensors is identical to the other two configurations (i.e. only the permanent link portion is “shared”). It should be noted In some jurisdictions, it may be acceptable to tie-wrap the jacks to a permanently installed building element. If mounting boxes are used, the jacks should be mounted with the tab up in the boxes to provide easy access to the release tab on the splitter. Pros of cabling option #3 Cons of cabling option #3 • Typically lowest total installed cost dependent on labor rate • Typically the highest cabling material cost • Reduced cable bulk (half as many horizontal cables) • Splitter may partially cover the default labeling area on some patch panels • Most flexible option (easy to move/reposition devices) • More apparatus in the ceiling area • Fully compliant with structured cabling standards • May require mounting box for jacks • Easy redeployment for non-lighting applications • The number of drops in the ceiling for possible redeployment is cut in half. • Easy demarcation for permanently installed cabling (clear test-points and handoff, which is most relevant if multiple parties are doing portions of the installation) 10 that this option is only supported on CommScope Category-6 (or better) cabling from end to end. Redwood and CommScope have performed extensive testing and systems engineering to ensure that cable sharing can be supported on CommScope SYSTIMAX® and Uniprise® cabling even under the worst-case supported operating conditions. Neither the use of cabling from other vendors nor the use of CommScope Category-5e cabling is supported with Option #3 for both performance and safety reasons. For more information, visit seagrp.com • Not compatible with Redwood LED Gateway • Not compatible with some fixtures with integrated sensors (consult your Redwood representative with specific questions) Physical layer installation and environmental considerations General requirements The Redwood Engine and the Redwood end-point devices shall be installed according to the Redwood System Installation Guide and Redwood Commissioning and Administration Guide (latest issues shall apply). Redwood compatible LED fixtures must be installed according to the vendor’s installation instructions. For non-integrated fixtures, the Redwood Sensors and Sensor Pods must be installed next to each fixture. In general, the Redwood Scene Controllers and Dimmer Switches should be located near the fixtures they control. Ensure that cables and cords with the appropriate fire rating are used and installed in accordance with all applicable local regulations and practices. For instance, ensure that all cords used in a plenum environment are plenum rated. Prerequisite: Determine locations for all fixtures, Redwood Sensors, Redwood Dimmers & Scene Controllers, and Redwood Gateways and Sensor Pods. Please refer to the Redwood Commissioning and Administration Guide. Engine Installation Requirements In commercial office buildings, the Redwood Engines are typically located in 19 inch racks in the wiring closet and in close proximity to the RJ45 patch panels and cable management. Mounting brackets and mounting screws are included with each engine. Multiple engines are stacked at the bottom of each rack with patch panels and cable management located above the engines. This way the cables can be terminated on the back of sequential narrow depth patch panels while the Redwood Engines extend further back. This arrangement also ensures the weight is concentrated towards the bottom of the rack. The Redwood Engines may also be mounted in cabinets or other arrangements as long as clearance requirements and environmental operating specifications are met (see below). In data centers, where rack space often comes at a premium, the Redwood Engines may be rack or cabinet mounted but are often vertically wall mounted using the Redwood Wall Mount Kit (PN# WALLMOUNT-TRAY-1G). The required orientation for wall mounted engines is with the front/jack face of the engines facing down. Each engine requires a minimum front/back clearance of 6” (153mm) and may dissipate up to 375 watts of power. Minimum front and back clearances are a key design requirement for air circulation to ensure adequate dissipation of heat from the engines. All Redwood engines must be located in environments where they will remain within their rated operating specifications. Cable bundling and cabling operating temperature When remote power is applied to twisted-pair cabling, the temperature of the cabling will rise slightly due to resistive heat generation in the conductors. The level of temperature rise will increase when cables are bundled. The electrical performance of the cable will also degrade slightly due to the temperature rise. Category-5e (or better) cables that have a temperature rating of at least 60°C installed in open cable pathways such as cable baskets or perforated cable trays may be bundled in groups as large as 48 cables. The cables may be bundled along their entire length or a portion thereof. The maximum ambient operating environment for cables rated at 60°C shall not exceed 50°C. This ensures that all Category-5e (or better) cables in the bundle will remain below 60°C even when all cables in the bundle carry the maximum remote power simultaneously. Redwood and CommScope Enterprise R&D have performed extensive testing and systems engineering to ensure that cable sharing (option #3 above) can also be supported on CommScope SYSTIMAX and Uniprise Category-6 (or better) cabling under these same conditions. Cable sharing is only supported on Category-6 (or better) cabling from CommScope, and is NOT supported on any other cabling. By using cabling with higher temperature ratings and reducing the maximum cabling length, a Redwood solution can be deployed on cabling with a maximum ambient operating environment in excess of 50°C. Please direct specific questions to Redwood technical support staff for review. It should be noted that the maximum operating temperature for Redwood Engines, directors, sensors, gateways and wall switches is generally 50°C. Cables installed in conduit or enclosed trunking cannot dissipate heat as effectively and require smaller bundles. Many variables must be taken into account in assessing maximum cable bundles under these conditions. Please direct specific questions to SEA Group technical staff for review. For more information, visit seagrp.com 11 Cabling Installation Practices This guideline is not intended to serve as an installation guide for the Redwood equipment or the installed cabling. Design and installation of low voltage cabling must follow proper cabling installation practices and must comply with applicable national and local regulations, as well as manufacturer’s instructions. cold temperature bending of cables. • Installation temperature for copper cables varies depending upon the jacket material. However, at the extreme temperatures care must be exercised to prevent excessive kinking or increases in pulling tension. If The following documents provide relevant information CommScope cable has been stored below 32°F (0°C) for design purposes: for more than 8 hours, the cable must be conditioned at • SYSTIMAX SCS Design and Installation Guidelines • Telecommunications cabling and associated standards such as ANSI/TIA/EIA (568-C, 569-B, 942), ISO/IEC 11801, and CENELEC (EN 50173, EN 50174). • National and local codes such as the National Electrical Code (NEC) in the US • Manufacturer’s cable and component design and installation guidelines Additionally, the following installation practices must be taken into account: • Telecommunications cables should be installed with room temperature, 59°F to 86°F (15°C to 30°C) for at least 4 hours before installation. • Maximum pulling tension of each cable should be kept below 110 N (25 lbf). The use of cable-pulling lubricant is not allowed. • If slack loops are deployed, their length should be minimized. Ensure that cable is not twisted while creating a slack loop in order to avoid untwisting the cable pairs. • Maintain the required bend radius and avoid cable kinks or jacket damage. • Avoid untwisting and separation of cable pairs. proper pathway support. Cables must not be placed Maintain twists to the point of termination and avoid directly on fluorescent light fixtures, and must not be pair wrapping. supported by, or attached to, ceiling tile support systems, electrical conduits, gas pipes, or water pipes. • All cables and components must be installed according to manufacturer’s guidelines, and should be visually inspected for proper installation. • Cable installation should not significantly deform the cable jacket due to excessive pulling tension, overall twisting, compression, or bends over 90 degrees. • Cable ties should be applied loosely to cable bundles and allow sliding of the cable tie across the cable bundle so as not to distort cable jacket. 12 • Avoid water, high humidity, chemical exposure, and For more information, visit seagrp.com • Manufacturer’s specifications for cable fill limits in conduit and pathways must be followed. Cabling must not exceed 23 cm (9 in.) depth, or 15 cm (6 in) for standards compliance. • Power separation of installed cabling must comply with applicable local or national safety regulations, as well as manufacturer’s guidelines for transmission performance. • Bonding and grounding practices must comply with applicable local or national safety regulations. Appendix: Additional physical layer design options Support for VisiPatch 360® in place of modular panels and jacks Pros of VisiPatch 360 in place of panels and jacks • Very low initial deployment cost CommScope’s VisiPatch 360 is a versatile, high-density, • Can be wall mounted (no rack space needed) high-performance alternative to modular panels. It is also often • Can be installed before racks are present used as a consolidation point for zone wiring architectures in place of jacks in the ceiling. This solution can be utilized with both dedicated Category-5e cabling as well as shared CommScope Category-6 cabling. Due to the versatility of the VisiPatch 360 solution, there are too many physical • Supports cable sharing without modular splitters Cons of VisiPatch 360 in place of panels and jacks layer options to list here. Some of these options may be very • May require proprietary VisiPatch 360 patch cords attractive in certain environments offering low initial installed • Zone deployments may require longer cords, if zone cost and high flexibility for future modifications. Please consult your CommScope cabling representative for additional box is used in ceiling information and approval of specific architectures. Support for direct connections from cable to Redwood Engines (i.e. elimination of patch panels) Pros of direct connections • Low initial cost (requires only field-terminated plugs) • Does not consume rack space (no panel is required) Most cabling installations deploy modular patch panels (or VisiPatch panels) in the wiring closet to simplify administration, simplify testing, and improve flexibility. CommScope strongly recommends the use of patch panels, but does not require them for Redwood installations. In situations where the likelihood of equipment being moved within the lifetime of the building is low, the small incremental cost of the patch panel and corresponding Cons of direct connections • More difficult administration and reconfiguration (challenging to connect a specific cable to a specific equipment port with dressed cables) • More difficult to identify specific horizontal cables patch cord may not be justified. Note that patch panels (or during troubleshooting (less friendly/accessible VisiPatch 360 panels) are required to deploy cable sharing. labeling) To reiterate, CommScope strongly recommends the use • Less clear demarcation for permanently installed of patch panels, but will support installations without cabling (no clear test-points and handoff, which is patch panels. most relevant if multiple parties are doing portions of the installation) • Can’t support cable sharing on CommScope Cat-6 cabling (increasing cable bulk) For more information, visit seagrp.com 13 Frequently Asked Questions Question: What are the testing requirements for the Question: Are splitters for cable sharing compatible with all Category cabling used to support Redwood CommScope patch panels that have 24 ports per “U”? Answer: Continuity testing to detect pair continuity, opens, Answer: Somewhat. CommScope recommends the use of shorts, reversals and transpositions is mandatory for all patch panels where all 24 ports in the patch panel are in a installations and must be performed on 100 percent of the single aligned row. FlexiMAX panels where individual jacks are copper cabling runs. Performance testing of the permanently staggered alternatively up/down will result in extension above installed cabling is recommended but not mandatory. the “U” space when splitters are inserted into the upper staggered Question: Do patch panels have to be rack mounted? the lower staggered locations. To avoid interference, blanking Answer: No, patch panels can be wall mounted using means panels should be used above and below the group of patch that enable access to the back for initial termination and panels or a 0.5U space should be allocated. Where termination future inspection. In addition, although CommScope strongly of individual jacks is desired, another alternative is to deploy recommends the deployment of patch panels for administration CommScope’s new M2400 panels, where all 24 individual and future flexibility, they are not required. M-series jacks can be terminated in a single aligned row in the Question: We are renovating our existing building and panel, thus avoiding potential interference. planning to abandon our obsolete Category-5e cabling. Can Question: Can I disconnect structured Category cabling on abandoned cabling be re-provisioned for use with Redwood a Redwood solution while power is on? systems? Answer: Yes. When the flow of electricity is interrupted via Answer: There is a high likelihood that all or a high portion of disconnect, the associated momentum results in “inductive cabling needs can be met by salvaging the obsolete cabling. kick,” which will cause a few sparks in rapid succession. A Please direct specifics to our technical support for additional common example of severe inductive kick and the associated guidance. sparks can be observed when unplugging a vacuum cleaner Question: Which pin-assignment arrangement does CommScope recommend for terminating conductors? while running. Standards-compliant Category-5e (or better) cabling and all Redwood end points are designed to withstand the negative effects of “inductive kick” when disconnected Answer: CommScope recommends the TIA-568B pin while carrying current. Cable sharing results in currents per assignment. Whichever pin assignment is used, it must be used contact in excess of those supported by standards, but all of consistently throughout the installation. CommScope’s Category-6 and Category-6A connectors were Question: Can foiled cabling (F/UTP) or cabling with a shield around each pair (S/FTP) be used? Answer: CommScope recommends the use of U/UTP cabling to minimize the stiffness of cables and cords, but F/UTP and S/FTP cables are also supported. Question: When deploying cable sharing, does every cable at the patch panel need to deploy cable sharing? 14 locations and below the “U” space when splitters are inserted into designed with adequate margin to withstand these higher current levels. Question: Can the configurations utilizing the Redwood fieldterminated plug be registered for the CommScope 20 Year Extended Product Warranty and Applications Assurance? Answer: The configurations using the Redwood field-terminated plug can be registered for the CommScope 20 Year Extended Product Warranty and Applications Assurance, provided that Answer: When deploying cable sharing, all cabling terminated only CommScope cabling components are used from end to on the patch panel must be CommScope Category-6 cabling. end, and all other terms and conditions of the program are Splitters are needed only on those ports of the patch panel met. Applications Assurance for these configurations is limited where cable sharing is desired. to the Redwood application. For more information, visit seagrp.com www.seagrp.com Visit our website or contact your local SEA Group representative for more information. All trademarks identified by ® or ™ are registered trademarks or trademarks, respectively, of CommScope, Inc. This document is for planning purposes only and is not intended to modify or supplement any specifications or warranties relating to CommScope products or services.
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