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6992 - Supply of Wireless Outdoor LED Lighting Control System, 3.Statement of Work/ SpecificationsRFP #6992 Exhibit 3 Technical Specifications Supply of Wireless Outdoor LED Lighting Control System PURPOSE The City of Denton (COD) owns and maintains approximately 8,000 cobra-head and post top types of high pressure sodium (HPS) street light luminaires, located throughout the City’s eighty-nine square miles. The City intends to replace the existing HPS streetlight luminaires with a complete street light solution comprised of dimmable light emitting diodes (LED) street light luminaires and a wireless network wireless network control system. The wireless network control system shall be for the exclusive use of the City. The purpose of this technical specification is to provide information that will allow prospective suppliers to prepare submissions to supply completely assembled and tested Wireless Outdoor LED Lighting Control System (WOLLCS) to monitor, control and manage LED luminaires throughout the City of Denton. These control system is to be priced FOB destination to the City Warehouse Site, 901 Texas Street, in Denton, Texas. Freight shall be included in the price for each unit. Denton Municipal Electric (DME) has reviewed, through an LED pilot program, and determined Phillips, Holophane Lighting, and Howard to be the only acceptable manufactures for LED luminaires for current and future lighting projects; therefore, only proposals for Wireless Outdoor LED Lighting Control System that are compatible with the aforementioned luminaires shall be accepted. The intent of this Request for Proposal (RFP) is to select a single supplier that delivers the best value for the comprehensive project scope and to execute a Contract with the successful Respondent. As further detailed in this RFP, only Proposals that are responsive to all elements of the Project scope will be considered for evaluation. The Successful Respondent that has executed the Contract with the City (“Contractor”) will be responsible for the completion of the comprehensive Project scope. SERVICE CONDITIONS Site Location: The service location for this work will be within the Denton, Texas area. Service Elevation: Approximately 640 feet above sea level. Temperature: -20o F to 120o F. Other Considerations: Moderately humid climate with 10 to 30 inches of rain per year; wind up to 90 mph; thunderstorms with severe lightning occurring in all months of the year with the greatest frequency during the warmer months. SCOPE OF WIRELESS CONTROLSYSTEM SERVICES: The integrated wireless control and monitoring system shall provide the City the ability to monitor, maintain and control all City-owned street lights as described in these Technical Specifications. The result of the wireless control and monitoring design and deployment must provide a fully functioning system which all street lights can be individually controlled and monitored. The Respondent shall provide equipment and services to make the network control system function according to these Technical Specifications. SUBMISSIONS Submissions shall be provided using Exhibit 1. Additional information clarifying the supplier’s product may be attached to submission. Pricing shall include all costs to deliver goods as specified in this specification. Any special fees or commissions, and all freight for delivery to the City of Denton must be included in the quoted price. Submission shall include responses to questions using Exhibit 2 (Q&A.) Respondent is expected to answer all questions honestly and to the full extent. Incomplete submissions may be considered as no responsive this RFP. QUALITY CONTROL The manufacturer shall be responsible for the quality control of the manufacturing processes to assure all requirements of these specifications are met. The City reserves the right to observe, inspect and to require additional quality control investigations; either by its personnel or an independently employed quality control investigator, at any or all stages of fabrication at the manufacturer’s facilities. Inspections, with or without comment, shall not relieve the supplier of the requirement for conformance to these specifications, nor shall the inspections be construed as acceptance of work, not in accordance with the intent of these specifications. Failure to adequately maintain quality of fabrication until completion shall be grounds for cancellation of the Contract, order, or any part thereof. WRITTEN WARRANTY and GUARANTEES Written guarantees shall include any limitations as to the nature of failure or time limitations. The guarantee shall begin upon receipt of the accepted units, not on the date of manufacture. Guarantees shall indicate whether or not it is made on a full replacement basis or a prorated basis and if prorated then what are the terms. Manufacturer/supplier guarantees that the goods furnished under this specification are of high quality and agrees to replace any goods found to be defective during inspection, installation, or service for a minimum period of ten (10) years after unit is delivered to Denton. Failure(s) shall be the responsibility of the manufacturer. Respondent shall provide a methodology for return and replacement of any failed unit at no cost to DME or the City of Denton. Respondent guarantees that all products quoted and furnished under this agreement will be accepted at any normally used United States approved repair and warranty shop should one be available for the manufacturer’s product quoted. The City of Denton will not accept a manufacturer’s product that was rejected or substandard and then sold to a broker for either resale or scrap that would not be fully warranted by the original manufacturer. The respondent also guarantees that the City of Denton will be represented by the manufacturer, should an issue arise, and that all manufacturer’s warranties will be in effect for the life of the contract. TECHNICAL RESPONSIBILITIES AND REQUIREMENTS System Scalability: The System shall be capable of performing all functions and meeting all requirements described herein for a minimum of 10,000 Control Points. The System shall be capable of being upgraded to handle up to 10,000 additional Control Points. Detail Design: Detailed structural and electrical design is the responsibility of the supplier. Omissions: It is the intent of this specification to require the supplier to provide complete and fully functional Wireless Outdoor LED Lighting Control System that is equipped and featured appropriately to perform and operate as described herein. Further it is the intent of this specification to require that the control systems be constructed, as a minimum, in accordance with all US standards that apply to manufacture and testing of the Wireless Outdoor LED Lighting Control System. Omission of any minor details from this specification, minor mistakes or typographical errors in text, or mistakes in attempting to reference standards or data in the standards shall not relieve the supplier from the responsibility to furnish complete and fully functional Wireless Outdoor LED Lighting Control System that comply with accepted national standards and meet the intents communicated herein. Shop Assembly and Preparation for Shipment: The Wireless Outdoor LED Lighting Control System shall be shipped completely assembled ready for mounting and fully tested at the facility of the supplier. Delivery Schedule: The supplier shall submit a schedule with the proposal indicating the expected time (ARO) when approval drawings will be provided for each component of the Wireless Outdoor LED Lighting Control System ordered and the time (ARO) when they will be delivered, assuming one week return on approval drawings. Drawing Identification: All drawings shall be identified with a unique drawing number, the date, the manufacturer’s shop order number, the owner’s name, and purchase order number. Approval of Design: DME shall have an opportunity to approve the design, features and accessories of the Wireless Outdoor LED Lighting Control System for the first order. Subsequent orders of the same type of control system will not require approval drawings, unless specifically stated on the purchase order. Approval drawings shall contain sufficient information to confirm all data that was included in the proposal. The owner shall be furnished with an electronic set of approval drawings, equipment descriptive information, and any appropriate comments or notations at or before the time stated in the proposal. The owner will return drawings marked "approved" or "revised as noted". If changes are identified in the owner’s review, a revised drawing submittal may, at the owner’s option, be required to obtain final approval. Review of drawings by the owner will be with respect to general design and functionality, but shall not be construed to relieve the supplier from any responsibility or liability for proper design, fabrication, compliance with these specifications, compliance with all applicable standards, or for any errors that may have been contained in the shop drawings. The approval drawings shall provide information in sufficient detail to describe equipment operation and function, dimensions, space needs for installation, and recommended clearances for proper operation. The approval submittal shall include at least the following items: Outline drawings with all parts identified by item number referenced to a list of material. These drawings shall show detailed dimensions, locations of all components and devices, recommended clearances for proper operation and any special mounting requirements. Operational drawings including control schematics and connection diagrams. Nameplate data with associated information: The manufacturer’s name, model number, date of manufacture, serial number, voltage and amperage ratings for each component of the control system. Descriptive literature and drawings for all accessories and optional items. Final Drawings, Instruction Books, and test Reports: No later than the scheduled first shipment, the supplier shall furnish an electronic set of instruction books and final drawings for each component of the control system shipped. The set shall include at least the following: An electronic set of final drawing in AutoCAD “*.dwg” format along with a list of all drawing titles and file names. Operation instruction and descriptive literature Maintenance instructions. Parts list Materials and Workmanship: Only new materials shall be used in fabrication of the Wireless Outdoor LED Lighting Control System. Damaged or defective materials shall not be repaired and used. No peening, caulking, or filling shall be permitted in repairing cracks, pinholes, or other types of defects. Such defects in fabricated members shall be repaired by replacement. Wireless Network Design: The communication system is one of the core parts of any intelligent lighting control system. The Respondent shall be responsible for the design, hardware, and implementation of an optimized network scheme and topology, etc. The Respondent shall provide the following additional design data. Open Communications Protocol TALQ Compatible Proposed backhaul method Network speed (average number of seconds for a field device to respond to a command executed in the CMS under typical operating conditions) Ability to improve performance (reduction in command latency or increase in reporting frequency) through incorporation of additional network equipment if needed. Communication System Components: In the event the proposed wireless monitoring and control system requires system components that are not listed above, include all additional wireless monitoring and control system elements needed, and all costs (one-time) and fees (recurring) for each element. System Functionality and Miscellaneous Features Additional Data: Luminaires function normally (turn on at dusk, turn off at dawn) when communications are off line Accessible from standard web browser Ability to instantly poll a fixture or group of fixtures for current operational data Ability to log ongoing data for each fixture On-board GPS Included on each controller Light Sensor to measure LED light output included on each controller Photocell included on each Controller Ability to turn fixtures on/off in response to ambient light levels Ability to store data (including schedules and monitoring data) on each controller during offline operation Lumen depreciation compensation Experience integrating other network systems DESIGN FEATURES Photocell The receptacle shall comply with ANSI C136.10 criteria. Photocell should have a special filter for LED Light to prevent false turn offs, and shall be designed to Fail-Off to prevent “day burners”. Photocell should be designed and constructed to pass ASTM-D-1056 for durability. Electronic components of photocell should be sealed by a process equivalent to MIL-I-46058C to ensure protection from environment and excess heat. Sealed components should pass a MIL-PRF-31032 compliant process to ensure non-contamination in sealing. Surge protection should be in the form of an MOV, with minimum protection against surges according to IEEE C62.42 C or to withstand 20kA & 20kV; whichever is greater. Photo sensor should be tested in a manner consistent with MIL-STD-202D. Photocell housing should be constructed using material rated for Ultra Long Life UV protection. Photocell shall operate in voltage ranges from 120V-480V, and shall operate normally for input fluctuations of ± 10%. Photocell switching should occur at zero current in the current waveform to protect the life of relay contacts, or relay contacts must be rated for 7500 cycles at full rated load. Photocell shall carry 10 years of warranty Wireless Controller Functions Collect/Monitor energy consumption, W, kWh, voltage, current, and power factor. During Offline Operation, Field Devices shall be capable of monitoring and STORING the following offline TIME-STAMPED Control Point parameters: Luminaire status (ON, OFF, Dimmed State, Warnings, and Errors), Input voltage (RMS), current (mA), power (W), and power factor in all operating states and Cumulative energy consumption (kWh). During Online Operation, Field Devices shall be capable of REPORTING all online Control Point parameters for ALL Control Points at a maximum Reporting Frequency of once every 24 hours. During Online Operation, Field Devices shall be capable of REPORTING all Control Point parameters for A SINGLE Control Point at a maximum Reporting Frequency of once every 3 minutes. Field Devices shall automatically REPORT all data STORED during Offline Operation once Online Operation is restored. Field Devices shall be capable of controlling a single Luminaire or groups of Luminaires. Field Devices shall be capable of Manual Control, whereby the ON/OFF and DIMMED state of a single Luminaire or group of Luminaires is modified in response to commands from the Central Management System. Field Devices shall be capable of Scheduled Control, whereby the ON/OFF and DIMMED state of a single Luminaire or a group of Luminaires is modified according to a predefined schedule. Field Devices shall be capable of Scheduled Control that is defined for a minimum of 5 times/events per day). Field Devices shall be capable of Scheduled Control that is either time-based, whereby Controllers modify Luminaire operation when a specific time in the schedule occurs, or event-based, whereby Controllers modify Luminaire operation when the next event in the schedule occurs During Offline Operation Field Devices shall be capable of maintaining Luminaire control by continuing to operate according to the most recently programmed Scheduled Control or a default Scheduled Control if one has not yet been programmed, or using input from an integral photocell. GPS enabled Compatible with secure Central Management System Delivers real-time power monitoring data including RMS voltage and current Field Device programming must allow user to set time-based schedules (e.g. turn on/off based on sunrise/sunset according to astronomical clock, dim lights at certain times of day, etc.) and event based schedules (e.g. turn on/off based on photocell triggers, etc.) Controllers shall be integrated (mechanically and electrically connected) at Control Points: External to Luminaires, using a NEMA C136.41 standard twist-lock receptacle for both electrical and dimming control signal connectivity. Controllers shall be capable of actuating the status (ON state, OFF state) of Luminaires. Controllers shall be capable of actuating a Luminaire DIMMED state using a 0-10V control signal. Events can be scheduled in advance using the 365 day scheduling capabilities The controller shall comply with (NWTL-111) and ANSI C136.1 Collects data from the Controller, then sends data wirelessly to Central Management System (CMS) Wirelessly interfaces with other network equipment The Controller shall be 100% compatible with the existing luminaries without any need of retrofitting A Controller with low power consumption will be preferred Compatible with 0-10V dimming ballasts Field Devices shall be capable of normal operation over an ambient temperature range of: -40 degrees C to 70 degrees C (cold environment). Field Devices installed external or remote to luminaires shall be rated: Minimum IP66 Controllers log cumulative energy consumption at each luminaire Offline monitoring and storing of luminaire status, on state time, energy consumption While online, capable of reporting luminaire parameters Capable of reporting all online parameters for all control points once every 24 hours. Capable of reporting all online parameters for one control point once every 3 minutes Automatic reporting of stored data collected during offline operation J. Central Management Control System (CMS) COD is open to both hosted and non-hosted (in-house) LED lighting management solution. The Respondent shall assist DME in any customization of the Central management System (CMS) interface or functionality (e.g. user setup, maintenance reports and notifications, default daily scheduling, etc.) as needed. K. Description of Central Management Software Describe the specific Central Management Software that other Components are required to be Compatible, Interoperable, or Interchangeable with. See examples below for structure and format. Vendor Hosted Solution: Central Management Software make: [Make] Central Management Software model: [Model] Central Management Hardware platform: Cloud User Access Interface User Hosted Solution: Central Management System make: [Make] Central Management System model: [Model] Central Management Hardware platform: Server Database make Database model RAM HD NIC L. CMS Minimum Functional Requirements: The LED wireless network control system offered by the Proposer must meet the minimum requirements listed below. Hardware Warranty 10 years Software (Application and Firmware) Warranty 10 Years System Scalability to 10,000 control points System Upgradability additional 10,000 control points Ability to control different users groups with different permissions Capable of storing pole number, GPS location, fixture model, input voltage, wattage, installation date for all control points. The Central Management System shall ensure secure communication between itself and all Field Devices by logically enabling security features inherent to the underlying communications protocols The Central Management System shall be capable of detecting and reporting communication failures between Field Devices and the Central Management System. The Central Management System shall be capable of remotely monitoring Field Device performance, in order to identify and report any exception to normal Field Device Operation. The Central Management System shall be capable of storing the following asset information for all Control Points: Pole number, Pole GPS location, Pole grouping, Luminaire make and model, Luminaire nominal input voltage and Luminaire installation date. Automated Reporting of Malfunctioning Controllers and Luminaires The Central Management System shall be capable of RETRIEVING and STORING the following online Control Point parameters such as ON/OFF, Dimmed state, Warnings, Error, Input RMS Voltage, Current (mA), power (W), PF in all operating states and Cumulative energy consumption 9kWh). The Central Management System shall be capable of programming the online Control Point parameter Reporting Frequency and timing for ALL Control Points. The Central Management System shall be capable of programming the online Control Point parameter Reporting Frequency and timing for A SINGLE Control Point. The Central Management System shall be capable of defining Luminaire groups. The Central Management System shall be capable of Manual Control, whereby the ON/OFF and DIMMED state of a single Luminaire or group of Luminaires is modified in response to commands created by the Central Management System. The Central Management System shall be capable of creating programs for Scheduled Control, whereby the ON/OFF and DIMMED state of a single Luminaire or a group of Luminaires is modified according to a predefined schedule. The Central Management System shall be capable of creating programs for Scheduled Control containing a minimum of 5 times/events per day. The Central Management System shall be capable of generating Notifications, whereby specified Remote Monitoring reports (pre-defined or customized) are sent to assigned users and/or user groups via text message (SMS) and/or email.. Custom Reports On demand Reports Fixture Malfunction Cycling Day-burner Unspecified Malfunction No Communication No power Low System Voltage High System Voltage Low Wattage Excessive Power Use Control via handheld “smart” devices in the field (i.e. iOS & Android) The Dashboard view shall summarize the status of all Controllers, and Wireless Network Equipment within the network The system shall provide runtime charts (bar or line), and allow comparison of variables against similar devices (voltage, watts, amps, etc.) M. CMS Software License and Ongoing Support The Respondent shall specify any costs (one-time) or fees (recurring) for software licenses for users. Ongoing software support may be acquired at the sole option of the City. This shall include, at a minimum, the detection and correction of any errors in the software and the implementation of all updates, upgrades, and installation of additional programs to the software to remedy such errors. It will be the Respondent’s responsibility to install software upgrades onto the target hardware. The Respondent shall specify all costs (one-time) and fees (recurring) for optional ongoing software support and the scope of services covered. N. Surge Protection: Surge protection shall be in the form of a Metal Oxide Varistor (MOV) wired line to neutral MOV shall be rated for a minimum of 320 Joules (8x20 microseconds) Gateway shall be rated for a maximum of 6500 Amp surge O. Reference Standards: ANSI C136.10 - American National Standard for Roadway and Area Lighting Equipment Locking-Type Photo control Devices and Mating Receptacles - Physical and Electrical Interchangeability and Testing. NECA 1- Standard for Good Workmanship in Electrical Construction; 2010. NECA 130 - Standard for Installing and Maintaining Wiring Devices; National Electrical Contractors Association. NEMA 250 - Enclosures for Electrical Equipment (1000 Volts Maximum). NFPA 70 - National Electrical Code; National Fire Protection Association; Most Recent Edition Adopted by Authority Having Jurisdiction, Including AII Applicable Amendments and Supplements. UL 773 - Plug-in Locking Type Controllers for Use with Area Lighting; Current Edition, Including AII Revisions. UL 916 - Energy Management Equipment; Current Edition. UL 917 - Clock-Operated Switches; Current Edition. P. Training: The Respondent shall provide comprehensive training at the User's facility, covering (at a minimum) installation, calibration, testing and programming, configuration, administration, operation, and troubleshooting of the system. The contractor shall integrate a review of the User’s manual and commissioning materials into User training. The Respondent training shall be scheduled based on availability of User’s staff. The Respondent shall provide training manuals and all other documentation (i.e. Operations and Maintenance manuals) in Adobe™ Acrobat format. The Respondent shall provide all necessary instructional equipment to be used during the training sessions for training purposes. The Respondent training shall provide instruction using the installed System (not using a remote system or a simulated system), and geared towards new users. The User may elect to record these training sessions for User’s sole use for future training purposes. The resulting recordings shall be the sole property of the User and for the sole use of the User. The Respondent shall specify the degree of coordination needed with the User's IT staff in regard to interfacing with existing systems. Q. Quality Assurance 1. Proposed products must be able to operate in all LED Luminaire models proposed in the Supply of LED Luminaires for Street Lighting Technical Specifications. 2. DME may request photocell samples(s) identical to product proposal(s) submitted for inspection. DME may request testing reports (from above mentioned standards) of photocell sample(s) to verify performance is within manufacturer-reported tolerances. 3. Proposed products must be available, in full production, at the time of this bid. Bids for prototypes and conceptual products will not be accepted. 4. All photocells should be stamped with a Date-of-Manufacture on the bottom of the device. 5. Any Manufacturer offering products that comply with the above mentioned criteria may be considered. R. Required Submittal Documents (in addition to required forms located in main RFP) Manufacturer shall provide a written product warranty, with a minimum of 10 years, beginning upon delivery to the City of Denton Warehouse. ATTACHMENT A DEFINITIONS Lighting terminology is used herein consistent with IES RP-16-10, with clarifications and exceptions noted as necessary. Lighting control terminology is used herein consistent with IES TM-23-11, with clarifications and exceptions noted as necessary. Astronomical Clock – a device that determines the expected time of sunrise and sunset for a given calendar date (i.e., day, month, year) and geographical location. Backhaul (Communication Network) – a communication network linking the Central Management System to the Field Device Network. Central Management System – a computer environment that functions as the core of the System by providing all shared System services, and consolidating and storing (or managing the storage of) all System data. Compatibility – the ability of a device to operate on a network or in the same physical environment with another device without corrupting, interfering with, or hindering the operation of the other device. For example, a Controller in an outdoor environment is compatible with a nearby telecommunication device (e.g. supporting an overhead cable TV communication system) if neither device corrupts, interferes with, or hinders the operation of the other device. Component – any installed, replaceable and/or upgradable item with a unique product number that is necessary to meet the requirements of this specification. Control Point – the location where a Luminaire is installed on a pole or other apparatus. Controller – from IES TM-23-11: the device that originates a command to execute a lighting change. Most commonly associated with a lighting control station or control console, a controller may also be a sensor or other automatic device operating without human interaction. In lighting control applications, the lighting controller usually contains all the instructions for operating all connected lighting fixtures based on information from sensors and user switches and dimmers. Most digital controllers will implement one or more protocols that control the operations of fixtures, relays and other devise that are physically and electrically connected to a communications bus. For the purposes of this document, refers specifically to a device that that physically monitors and controls Luminaires installed at Control Points, reacts and responds to logical and physical inputs, makes control decisions using internal algorithmic and logic functions, and communicates via a network protocol. Field Devices – the entire set of networked Components (hardware and embedded software, consisting of Controllers and possibly Gateways) installed in the field that, following purchase, installation, start-up and commissioning, function together to adaptively control and remotely monitor Luminaires. Graphical User Interface (GUI) – from IES TM-23-11: a screen-based, pictorial or Diagrammatic representation of a system. In many lighting control systems, the GUI becomes one point of contact between the system and a user. Host Site – The physical location of the Central Management System. For the purposes of this document, refers specifically to a facility owned and operated by the User, the Vendor, or an independent 3rd party. The Central Management System is said to be hosted by the owner and operator of the Host Site. Interoperability – the ability of a device to operate on a network in a consistent manner with a similar or related device, sharing a common defined set of information. Latency –The measure of time delay in a system. For the purposes of this document, refers specifically to the time delay between a creation and execution of a command (e.g. the time delay between an automated or manually created command to change the light output of a set of luminaires in the System and actual change in light output. Luminaire – from IES RP-16-10: a complete lighting unit consisting of a lamp(s) and ballast(s) (when applicable) together with the parts designed to distribute the light, to position and protect the lamps, and to connect the lamps to a power supply. For the purposes of this document, refers specifically to a roadway lighting Luminaire installed with electrical service at a Control Point. Network – from IES TM-23-11: a group of systems that function cooperatively and/or interdependently to provide a chain of command for lighting control. For the purposes of this document, refers specifically to either a Field Device Network or a Backhaul Network. The Field Device Network is typically a Local Area Network (LAN) that connects and enables communication between (exclusively) Field Devices. The Backhaul Network is typically a Wide Area Network (WAN) that connects and facilitates communication between (at a minimum) one or more Field Device networks with a Central Management System. Online Operation - the normal operating condition whereby Field Devices are communicating with the Central Management System. Offline Operation – any condition whereby Field Devices are not communicating with the Central Management System. Such conditions can occur during Start-Up or Commissioning, or as a result of an unplanned event that interrupts an existing network connection. Photoelectric Sensor – a device that measures the ambient light level and compares it with a preset threshold. The Photoelectric sensor itself may be installed at a Control Point, or located remotely, such as at an electrical service point with multiple light contactors. Protocol/Communication Mode/Method – from IES TM-23-11: a set of standard rules –the syntax, semantics, and synchronization – for communicating over a computer network or a lighting control system or both. The protocol defines the methods for data representation, signaling, authentication and error correction to ensure control or enable the connection, communication, and data transfer between computing or control endpoints. Protocols may be implemented by hardware, software, or a combination of the two. At the lowest level, a protocol defines the behavior or hardware connection. For the purposes of this document, protocols/communication modes/methods are only introduced and used when referenced to a standard that is explicitly identified in Section 1.1 REFERENCES. For example, the use of “0-10VDC” as the required protocol for communication between a Controller and Luminaire may include a reference to IEC 60929, which is explicitly identified in Section 1.1 REFERENCES as 60929 ed4.0 (2011-05) “AC and/or DC-supplied electronic control gear for tubular fluorescent lamps - Performance requirements”, Annex E (normative) “Control interface for controllable control gear.” Vendor – the seller of any Component of the System. User – the purchaser of Components and/or operator of the System. Scalability – the ability of a system to handle a growing amount of work, or its ability to be enlarged to accommodate that growth. For the purposes of this document, may refer to the ability of the System to handle the transport of a greater amount of data (e.g. retrieve more information from each Controller), to transport data at a higher data rate (e.g. reduce command latency or scheduled time between data updates), or to be enlarged to accommodate the described increase in work, or accommodate additional Control Points. The System – the entire set of set of networked Components (hardware and software, typically consisting of Field Devices, Backhaul, a Central Management System, and one or more Management Stations) that, following purchase, installation, start-up, and commissioning, function together to adaptively control and remotely monitor Luminaires. Warranty – All Components of Hardware shall be covered by a single-source written replacement warranty covering material and workmanship for a period of Minimum of TEN years. All software and firmware shall be covered by a written replacement warranty for a period of TEN year. This shall include support for software and firmware shall include bug fixes, patches, upgrades, and any other miscellaneous products and/or services that are necessary to ensure the full functionality of the software and firmware.