XTran Specification OTN Systems XTran MPLS-TP based series XTran: eXcellence in TRANsport OTN Systems XTran MPLS-TP Based Series Issue 5 Ref. No. Date of Issue BA-S423-E-5 January 2014 Copyright and trade secrets/liability The present document and its contents remain the property of OTN Systems nv and shall not, without prior written consent, be copied or transmitted or communicated to third parties, nor be used for any other purpose than such as underlies their delivery to the addressee. The present document and its contents may change in the course of time or may not be suitable in a specific situation. Consequently, they are recommended as suggested guideline only. OTN Systems nv hereby disclaims any liability for any damages that may result from the use of the present document unless it is used with respect to the operation and maintenance of equipment originally manufactured by OTN Systems nv and covered by its standard warranty. XTran: eXcellence in TRANsport OTN Systems XTran MPLS-TP based series XTran: eXcellence in TRANsport I Contents OTN Systems XTran MPLS-TP based series 1 2 3 4 5 6 7 8 9 10 11 12 13 14 Introduction MPLS-TP Deployment scenarios Key business benefits Platform architecture and modularity Interface building blocks Node building blocks Power options Demarcation device Managing your network with TXCare Security Protocol support Specifications Ordering Information 3 4 4 5 6 6 8 10 10 11 14 14 16 23 Page 2 of 24 XTran: eXcellence in TRANsport OTN Systems XTran MPLS-TP based series 1. Introduction The XTran network portfolio is designed for the power industry, railway authorities and other heavy industries that require an efficient packet based infrastructure. XTran network nodes are designed with specific mechanics and performance values to build a reliable multiservice network and comply to international standards as well as to the most demanding environmental standards like IEC 61850-3, IEEE 1613 and EN 50121-4. Primary XTran features • • • • • • • • • • • • • • • • Rugged industrial design with no moving parts Extended temperature range and EMC requirements Compact, DIN-RAIL or 19” mountable Modular Front access Supports meshed topologies Hot pluggable power supplies Substation compliance to IEC-61850-3 Highest reliability possible via dual common control Sub 50ms protection switching in all network topologies (MPLS-TP) Advanced monitoring capabilities based on MPLS-TP OAM enhancements Advanced network management suite for total control during deployment, operation and maintenance Built in features for fast deployment and easy replacement to reduce field interventions Easy to install and maintain via TXCare and built in auto-configuration options High level of security Based on open and industrial accepted MPLS-TP standard Page 3 of 24 2. MPLS-TP The latest evolution of MPLS is called the Multi- Protocol Label Switching - Transport Profile (MPLS-TP). This is the result of the joint effort by the Internet Engineering Task Force (IETF) and the International Telecommunication Union (ITU-T). These new evolutions are used to make MPLS suited as transport technology. This is done by including Operation, Administration and Maintenance (OAM) tools that are well known in traditional transport technologies, such as SONET/SDH. Moreover, to inherit reliability and operational simplicity from SONET/SDH networks, MPLS-TP supports Automatic Protection Switching (APS) to provide 1:1 or 1+1 protection. It supports the static configuration of LSPs (label-switched paths) or PWs (pseudowires), by enabling SNMP based tools for service and circuit provisioning. MPLS-TP is the solution for new generation transport or aggregation networks for utilities. This is because MPLS-TP adds crucial elements to MPLS which make the network a perfect match: • Transport-centric operational model based on a network management system and not based on an IP control plane: easy configuration resulting in low OPEX • Protection switching triggered by OAM and not dependent on dynamic signalling or control plane liveliness: this significantly increases availability and predictability • Comprehensive OAM fault and performance management: ability to ensure that strict timing requirements are met at service level • A connection-oriented network with bidirectional label-switched and co-routed paths: guaranteed symmetrical delay under all circumstances • Standard MPLS data paths and pseudowire constructs to allow dedicated programming and transparent connections between two points or multiple points • Interoperability with Ethernet/IP, guaranteeing data-path interoperability and architectural soundness with IP/MPLS 3. Deployment scenarios Depending on user requirements, the XTran portfolio can be used in at least two different scenarios. In both cases the XTran series ensures reliable and secure communication with low delay thanks to its connection oriented technology transmission paths with symmetrical delay. The XTran node can perform all functions needed in an MPLS-TP network. The node can serve as an edge node where traffic is received on a LAN port, mapped into a pseudowire and forwarded to the correct label switched path on a WAN port. The label switched paths over the network are bidirectional and co-routed. This means a symmetrical delay under all circumstances which is important for time synchronization protocols or services that support teleprotection. The different service types like E-LINE, E-LAN and Combinations allows the operator to create for each application a different logical network on top of the XTran physical infrastructure. The entire setup of the network is fixed provisioned via a network management system (TXCare platform). Page 4 of 24 Standalone operation In standalone operation the XTran portfolio can be used to create an independent aggregation network that collects all necessary applications. In this setup you do not require any other network equipment in the core of the network. All necessary layer 2 and layer 3 features to build such a network are provided. Aggregation for IP/MPLS In this mode the XTran series is used to solve the complexity issue when an IP/MPLS core network is deployed from core to access. In this case the XTran portfolio is used to aggregate the traffic before it enters the core. A unified MPLS solution with IP/MPLS in the core and MPLS-TP in the aggregation or transport is made possible due to the same pseudowire architecture and similar forwarding paradigm. 4. Key business benefits The XTran portfolio is designed in such a way that you can create clever networks which are tailored to your environment. As a result the investment in the XTran portfolio is a safe investment. Benefit Description Integrated functions Service segmentation, Authentication, Traffic shaping and Quality of Service, Access router functions, large capacity Ruggedized Compliancy with IEC-61850-3 and IEEE 1613, Fanless operation (no moving parts) Scalability From Mbps to 10G aggregation of traffic. Scalability through MPLS-TP. Network management TXCare platform for user friendly and fast deployment of the network. Supported by the automatic setup of the DCN and OAM features for continuous monitoring. Network flexibility Its modular design and mounting options allows XTran to be deployed in various locations. Various redundancy schemes Investment protection Long life cycle support 10G upgradable Page 5 of 24 Benefit Description Low TCO Fast deployment via auto configuration of DCN Monitoring capabilities Fast replacement feature (interchangeable flash memory) Hot swappable power supplies 5. Platform architecture and modularity An XTran network is based on modular network nodes, which are interconnected via a fiber optic infrastructure with speeds ranging from 1 Gbps to 10 Gbps (future) or copper-based cables covering several Mbps of capacity using SHDSL or E1/T1. All applications are connected to the network nodes and a dedicated part of the infrastructure is devoted to each application. This enables the virtualization of all applications silos on a single physical network which is cost effective and secure. Configuration and monitoring are carried out via a central point-and-click management system. This management platform is connected to the network nodes via a dedicated in-band communication channel. The operator is guided through an extensive set of wizards, which enables coherent settings at network level. The modular design allows the installation of today’s and tomorrow’s applications respecting the existing infrastructure. Modularity is the answer XTran provides to the multiple deployment scenarios required by utility customers. The XTran portfolio meets the performance requirements you may expect as an operator. The modular design, chassis options and interface modules guarantees the investment in the XTran technology. This investment allows your network to grow in the legacy domain by adding new legacy modules or to grow in the future by adding more Ethernet features. The architecture of the XTran family is ready for all today’s and tomorrow’s demands. It grows together with your needs and at your pace. 6. Interface building blocks Following interfaces are provided: Name Description Specification NSM-1 Node Support Module • Alarm contacts for local notification (2 output contacts) or alarm forwarding (2 input contacts) to the NMS. • Dual PoE power input for connecting an external power over Ethernet source. CSM310-A Central Switching Module • • • • • • • • Dual core CPU. MPLS-TP compliant switching fabric. Synchronization via Sync-E. Hardware support for time distribution via 1588 (Boundary and transparent clocking). Y.1731 performance monitoring. Automatic Protection Switching based on BFD. ERPS ring protection for multipoint Ethernet services. Easy CSM replacement feature via removable MicroSD Quick replace the CSM board in the field without manual reconfiguration. Page 6 of 24 Name Description Specification 4-GC-LW Gigabit Ethernet Interface • 3 x 10/100/1000 Cu Gigabit Ethernet ports. • 1 x Combo 10/100/1000 Cu or 100/1000 Gigabit fiber port (SFP based). • Sync-E, 1588v2 • PoE according to 802.3at. • Operation as WAN or LAN per port. 1-10G-LW 10 Gigabit Ethernet Interface 4-DSL-LW SHDL Interfaces 10-GL3-L Gigabit Ethernet Layer 3 4-E1T1-L E1/T1 Interface - LAN 2-C37.94 C37.94 Interface 2-CHA-LW SDH/SONET interface 4-4WEM-L 2W and 4W voice card with E&M signaling 7-SERIAL Serial interface card • 1 x 10gigabit Ethernet port • Sync-E, 1588v2 • Operation as WAN or LAN • • • • • • 4 x SHDSL ports. Support for channel bonding. Concentrator for demarcation devices EFM based on 802.3ag. Compliant with ETSI TS 101 524. Protection according to ETSI EN300386 / ETSI ES 201 468. • LAN or WAN operation. • • • • 10xGigabit Ethernet ports Operate as LAN Multiple VRF VRRP, PIM-SM, OSPF v2 • • • • • 4 x E1 or T1 ports 64 kbps cross connect per card. Up to 16 independent circuit emulated streams. Circuit emulation according to CESoPSN or SAToP Hitless switching (zero packet loss switchover between active and backup connection). • LAN operation. • • • • 2 x C37.94 ST ports 2 x E1 or T1 RJ45 ports Timeslot manipulation Circuit Emulation Streams • • • • • Sonet/SDH selectable: OC3/12 or STM1/4 Up to 63 VC-12 Up to 256 streams CESoP/SAToP 1+1 interface protection MSSPRING • • • • 4 x independent interfaces per card -48V for E&M signaling Support SAToPSN and CESoPSN Compatible with G.704 framing • up to 7 serial ports • configurable per port: RS233/422/485 Async or X.21, V.35, RS232 Sync • CES mode with mapping into time slots • Portserver mode (RS to IP) Page 7 of 24 7. Node building blocks The XTran portfolio consists of 3 three different node types: XT1104A, XT2206A and XT2210A. Name Description XT1104A 1 PSU slot, 1 CSM slot, 4 interface positions XT2206A 2 PSU slots, 2 CSM slots, 6 interface positions XT2210A 2 PSU slots, 2 CSM slots, 10 interface positions XT1104A XT2206A XT2210A Page 8 of 24 All nodes are modular and can be mounted 19”or DIN Rail depending on the needs. Chassis 2210 and 2206 can be equipped with dual power supplies and dual Central Switching Modules for redundancy purposes. Chassis 1104 is ultra-compact and can host a single power supply and one Central Switching module. All chassis are equipped with a node support module which hosts common functions like I/O contacts and inputs for power over Ethernet. The XTran portfolio currently supports Gigabit Ethernet, E1/T1 and SHDSL interfaces to pick up applications or create the WAN interfaces for the network. Other legacy interfaces will be available soon like RS232, 422, 485, X.21, V.35, C37.94…) The capacity per slot depends on the type of CSM card. It is therefore imperative to ensure that the interface cards are installed in the slot with the right capacity assigned to it. There are three different slot modes: • 1G mode: The CSM activates a single Gigabit Ethernet port in the slot. This slot type is typically used for the low speed interfaces (4-DSL-LW, 4-E1T1-L) • 4x1G mode: The CSM activates 4 gigabit Ethernet interfaces in the slot. This slot type is used for the gigabit Ethernet interface module (4-GC-LW) • 10G mode: The CSM activates a 10G interface in the slot. This slot is used for a 10G interface module (future) CSM310A possible slot configurations: Slot XT2210A XT2206A XT1104A 1 2 3 4 5 6 7 8 9 10 1G 1G 1G 1G 1G 1G 1G 1G 1G 1G 4X1G 4X1G 4X1G 4X1G 10G 10G 10G 10G 4X1G 1G 1G 1G 1G 1G 1G 4X1G 4X1G 4X1G 4X1G 10G 10G 1G 1G 1G 1G 4X1G 4X1G 4X1G 4X1G Page 9 of 24 8. Power options The XTran nodes can be powered via one or two internal, hot pluggable power supplies. The power supplies have a wide input range. In case two power supplies are installed, they work in a load sharing mode. A single power supply has the capacity to power the entire chassis. Name Description ACP-A • Input range: 90-264VAC • Output Power: 175W DCP-A • Input range: 18-60VDC • Output Power: 175W DCP-B • Input range: 88-300VDC • Output Power: 175W In case Power over Ethernet is needed an external PoE power supply must be attached via the NSM module. The two connectors allow operation in load sharing mode. 9. Demarcation device The XTran portfolio also contains a DSL demarcation device. This device is intended to be connected to the DSL interface board as spur, a dual homed spur or chained to other demarcation devices. In case of chaining or dual homing the links can be protected to increase reliability. Description Specification DSL ports 2 Ethernet ports 4x 10/100 Fast Ethernet port Power options 2x18-72 VDC DSL features • • • • EFM-C (802.3ah) ITU-T G.991.2 Annex G – 3.8 Mbps (TCPAM-16) 5.7 Mbps (TCPAM-32) Compliant with ETSI TS 101 524 Protection according to ETSI EN300386 / ETSI ES 201 468 Ethernet features • • • • • 802.1Q – VLAN tagging Port security (ACL) 802.1x via RADIUS authentication ITU G.8032 ERP MSTP Page 10 of 24 Description Specification OAM features • Y.1731 performance management • 802.3ah • Dying Gasp Management • CLI SNMP • Alarm contacts for triggering local alarms or forwarding local alarms 10. Managing your network with TXCare A network is a complex interworking of different nodes that require a lot of attention. It is imperative that this is planned carefully and thoughtfully. Network configurations should be done without adversely affecting your running applications. Network failures need to be detected, diagnosed and repaired. Service Level Agreements should be monitored and ensured. For security reasons it is important that users are logged and an audit trail is created. The OTN-Systems knowledge centre has taken all these aspects very seriously and under the XTran product family provides you with the TXCare management system ‚Takes‘-Care management has taken the features of the RFC 5951 and turned them into a workable Network Management System. • C = Configuration management • A = Assurance management • R = Resilience management • E = End-to-End management This is a fully integrated element management and network management. The TXCare can be fully adjusted to your IT infrastructure, it has a modular design and gives the opportunity to either run on one server or spread the load over multiple servers. It runs in a Windows based environments with servers and clients. Configuration Under configuration OTN Systems understands an easy and rapid deployment of a new network, an automatic discovery of an existing network and the possibility to add nodes to a network without hassle. The operator is able to map his network unto a map and even the physical paths of the fiber can be shown on the same map. Security is of the utmost importance. We give the choice to accomplish this in two ways. The first way is to make a configuration offline. Through a visual representation of the node the operator can add interface modules and set the port configurations (see fig.3). The physical connections, whether fiber or copper, can be made to the front ports of the interface modules. The second way is through a dedicated management channel (DCN). Management IP addresses are automatically given out to the deployed network upon startup. The in band communication channel is auto Page 11 of 24 established between the different nodes. From a single location the TXCare will connect to all the individual nodes, interface modules and connection links. Thereupon a logical display of your network will be made available and the operator can start configuring the network further. After the nodes, interface modules and links are created TXCare is ready to be further configured. Tunnels (Label Switched Paths) and Services (Pseudowires) are created through wizards. These wizards guide you through the different logical steps for a well-functioning network. This includes parameters like bandwidth, quality of service, protection, delay, paths… The operator is able to overrule the suggested parameters and fine tune the network to reach a better performance. Layouts are used to further personalize the views on the network. These could be multiple logical as well as physical views. A picture file could be used as background and the nodes and fiber links are be mapped on it. Multiple views can be created and be used in the monitoring tab. Monitoring Advanced monitoring capabilities based on the OAM performance and fault management information. This gives a complete overview of the network in the layout that was setup in the configuration tab. TXCare works with three layers of views. The first layer (in orange) are the physical connections, the fiber or copper links between the nodes or coming from applications. The second layer (in blue) are the tunnels or LSPs which run over the physical cables. The third layer (in yellow) are the services (Pseudowires) which on their turn run inside the tunnels. At any given time the operator will see what is going on with the network and what application that are or will be affected. Alarms are displayed, the working and protect path, the logical ring with the standby link etc… are just a few of the many features available in this application. The events tile will give a complete overview of the undertaken action on the network. It provides an event log (system events) and an audit trail (user actions) to allow a reconstruction of actions that took place in the network and by whom. Page 12 of 24 Alarm is a self-explanatory display of the alarms in the network. Four levels of alarms are defined depending on the degree of failure. The performance of your network can be seen through the counters tile. It will contain information on the way the data packets are send over the network. Charts are very useful in establishing the SLA’s. Administration All administrative tasks are in this part of TXCare. User management allows to create multiple user with different rights. Depending on the responsibilities and task description of the user, degrees of access will be given to the network. At all-time a trail will be kept of the actions the person has taken on the network. TXCare contains a network database with all kinds of information: node names, node configurations including installed network and interface cards. The database is based on Microsoft SQL technology. It is possible to use the database to restore the network in case the setting in one or more nodes are lost due to hardware failure. An overview of the services are possible and the individual services can be started or stopped. This gives you full control of your IT infrastructure. Tools TXCare servers and hardware can configured fully redundant. Database synchronization and redundancy via warm standby. Southbound interface is based on SNMPv3 including third party elements for monitoring. Northbound interfaces could be used for integration in umbrella management systems for alarm forwarding or monitoring; ex. OPC, SNMP… The firmware of the network en interface modules can be performed from any point in the network. These are upgrades simultaneously based on best effort network load. TXCare provides a full report of all the network elements and their firmware status. Northbound integration The north bound interfaces are organized as add-on software modules on the TXCare platform which receive their information through the TXCare server and forward the information if needed to the umbrella management layer. The reason why we have chosen to always pass through the TXCare server is because in this setup the security and central login can be organized from a single point of configuration, just like any other client login. The north bound interface is always intended for monitoring only. In case there is a requirement for configuration through this interface we provide a client sensitive start up where the operator can open a normal TXCare client with a direct browse to the specific network element. The reason for only allowing to monitor the network via this information is to guarantee consistency and avoid configuration failures which might jeopardize the reliability of the network. OTN Systems is flexible developing north bound interfaces. Over the years we have done all kinds of integrations which vary between simple I/O contacts to forward alarm over serial connections to SNMP forwarding. Page 13 of 24 11. Security The XTran portfolio focuses on security features relevant for the utility industry. Based on the implemented standards the XTran ensures the connectivity and defends the network from unwanted access. It also provides the necessary logging and audit trails to guarantee compliancy with local legislation. The security measures can be easily explained using RFC 5920 (MPLS/GMPLS Security Framework). • Attacks on the control plane: The XTran portfolio uses the MPLS-TP standard and does not rely on a dynamic control plane for setting up or maintaining the network performance. Instead of a control plane the XTran network is managed through a network management layer. All management traffic is exchanged via an in band communication channel deployed over the XTran network. So it is not possible to fake signalling or reservation protocols which might lead to cross connecting VPN’s to tap traffic All traffic that is exchanged over the DCN is encrypted via IPsec. This ensures that no hacking is possible to take control over the network • Attacks on the data plane Unwanted access on user ports can be prevented via ACL’s (Access Control Lists) and or 802.1x via RADIUS authentication. The MPLS-TP network standard guarantees end-to-end delivery via CRC check on each transmission path between XTran nodes. Encapsulation of user data in pseudowires (Ethernet over MPLS over Ethernet) allows for CRC check on user data by the end-devices Denial of Service is avoided through traffic shaping and traffic engineering via the network management system. 100% provisioning of the network with sub 50ms reconfiguration in case of network failure on preprovisioned backup paths. • Attacks on the Management Plane SNMPv3 management to the network elements Encryption of DCN channel (IPsec) Radius authentication within TXCare platform User management Logging, reporting, audit trail 12. Protocol support MPLS-TP compliancy (IETF/ITU) • • • • • • • • • • RFC5654: Requirements of a MPLS Transport Profile RFC5462: Multiprotocol Label Switching (MPLS) RFC5586: MPLS Generic Associated Channel RFC5860: requirements for MPLS-TP RFC5718: an in-band communication channel RFC5950: network management for MPLS-TP RFC5951: network management requirements for MPLS-based transport networks RFC6372: MPLS-TP Survivability Framework RFC6426: On demand connectivity verification RFC6428: Proactive connectivity verification Page 14 of 24 ITU • G.8032 ERP IETF • • • • • • RFC 2338 RFC 2328 RFC 2362 RFC 1112 RFC 2236 RFC 3376 VRRP OSPFv2 PIM-SM IGMP V1 IGMP V2 IGMP V3 IEEE • • • • • • • • • • • • • • • • 802.1s MSTP 802.1w RSTP 802.1D STP 802.1Q VLAN 802.310 BASE-T 802.3z 1000 BASE-SX 802.3z 1000 BASE-LX 802.3z 1000 BASE-EX 802.3z 1000 BASE-ZX 802.3u 100 BASE-T 802.3u 100 BASE-FX 802.3ab 1000 BASE-T 802.3-2008 10G-SR, LR, ER 802.3x Full duplex on 10BASE-T, 100 BASE-TX and 1000 BASE-T 802.3ad Link aggregation 802.3at Power Over Ethernet Page 15 of 24 13. Specifications Characteristics Name Description Specification Utility design Ruggedized design Extended temperature range: -20° to +65°C (-4° to 149°F) XTD: -40° to +70°C (-40° to 158°F) Compact design (19”or DIN Rail mountable) Cu and fiber optic connectivity Alarm contacts for local alarm triggering or forwarding of local alarms Legacy and Ethernet connectivity Availability and scalability Hot pluggable power supplies 50ms automatic protection switching (MPLS-TP) Hot pluggable interface boards Dual CSM for highest availability designs 100% traffic engineering of services MPLS-TP service types Ethernet capabilities E-LINE Point to point service (VPWS) E-LAN Multipoint (VPLS) Ring Logical Ethernet Ring Protection schemes 1:1, 1+1, ERP logical rings L2 Ethernet aggregation MSTP (multiple spanning tree) Multicast handling through IGMP Virtual forwarding instances VLAN handling Broadcast and multicast storm control IP Routing Unicast routing protocols (OSPF) Multicast routing protocols (PIM-SM) Redundancy schemes VRRP Individual routing schemes VRF Inter VLAN routing Page 16 of 24 Name Description Specification QoS 3 level hierarchical scheduler 4k Flexible queues 2 rate, 3 color ingress policing 802.1p priority evaluation (VLAN priority) Differential services based on IP header Handling of priority queues Strict Priority Based, Weighted Deficit Round Robin scheduling Network security Node IEEE 802.1x authentication (RADIUS) Access control lists based on MAC and IP addresses (black/white list) IPsec encryption of the DCN traffic Connection oriented network Disable unused ports Connection oriented network (logical separation of services) Manageability TX-Care Radius authentication for client server operation Monitoring and configuration Auto provisioned and auto setup DCN for management SNMP v1/v2/v3 Management port on each CSM module 2 input contacts allowing forwarding of local alarms to the TXCare platform 2 output contacts for local triggering of alarms Removable memory allowing easy replacement of CSM in the field OAM Hardware supported OAM Automatic protection switching via BFD Performance monitoring based on Y.1731 EFM support based on 802.1ah 1k Local MEP, 4k Remote MEP Indicators CSM Display Network ID, loadware version, fault codes LED’s Status LEDs for power inputs and general status of interface boards Specific LEDs per interface card: link, synchronization, speed… LAN or WAN operation Page 17 of 24 Name Description Specification Performance indicators High performance switching fabric Non-blocking 64 Gbps MTU up to 9k 8k Routing entries 32k MAC addresses 4k IP Multicast entries 2k Labels 512 bidirectional pseudowires 1k virtual forwarding instances 128 VRF instances Dimensions XT-2210-A: H=132,5mm/W=434mm/ D=210mm XT-2210-A: H=5.21 in/W=17.08 in/ D=8.26 in XT-2206-A: H=132,5mm/W=354mm/ D=210mm XT-2206-A: H=5.21 in/W=13,93 in/ D=8.26 in XT-1104-A: H=132,5mm/W=214mm/ D=210mm XT-1104-A: H=5.21 in/W=8.42 in/ D=8.26 in Power consumption CSM-310-A (25W), 4-GC-LW (8W), 4-DSL-LW (10W), 4-E1T1-L (7,3W), NSM-A (2W) Environmental Phenomena Test Description Test Levels Class Immunity (according to IEC61850-3) ESD RF field AM modulated EN 61000-4-2 IEC 61000-4-3 Enclosure contact + 6 kV B Enclosure air + 8 kV B Enclosure 10 V/m 80% AM (1 kHz), 80 – 1000 MHz A 20 V/m 80% AM (1 kHz), 800 – 1000 MHz 10 V/m 80% AM (1 kHz), 1400 – 2100 MHz 5 V/m 80% AM (1 kHz), 2100 – 2500 MHz 1V/m 80% AM (1 kHz), 2500 – 2700 MHz Fast transient EN 61000-4-4 Signal ports + 4 kV B Power ports + 4 kV B Page 18 of 24 Phenomena Surge RF conducted Power frequency magnetic field Voltage dips Voltage interruptions Damped oscillatory wave Mains freq. voltage Test Description Test Levels Class EN 61000-4-5 Signal ports + 4 kV line to earth,+ 2 kV line to line C AC Power ports + 4 kV line to earth, + 2 kV line to line C DC Power ports + 2 kV line to earth, + 1 kV line to line C Signal ports 10 V 80% AM (1 kHz), 0,15 – 80 MHz A Power ports 10 V 80% AM (1 kHz), 0,15 – 80 MHz A EN 61000-4-8 Enclosure (XT2210A, XT2206A, XT1104A) 100 A/m continuous A EN 61000-4-8 Enclosure (XTD4-D) 300 A/m continuous A EN 61000-4-9 Enclosure 1000 A/m pulse C EN 61000-4-11 AC Power ports 30% 1 cycle B 60% 50 periods C 100% 5 periods C 100% 50 periods C Signal ports 2,5 kV common mode, 1 kV differential mode B Power ports 2,5 kV common mode, 1 kV differential mode B Signal ports 30 V continuous A 300 V pulse C 30 V continuous A 300 V pulse C A EN 61000-4-6 EN 61000-4-11 EN 61000-4-12 EN 61000-4-16 AC Power ports DC Power ports AC voltage ripple EN 61000-4-17 DC Power ports 10% of voltage level Voltage dips and interruption EN 61000-4-29 DC power ports 30% and 60% reduction for 100 C ms 100% reduction for 50 ms C Immunity (According to IEEE 1613) ESD C37.90.3 Enclosure 2, 4, 8 kV class 1 RF Field AM Modulated C37.90.2 Enclosure Freq sweep test 20V/m 80% Amplitude Modulated @ 1kHz class 1 Enclosure Keying test: 20V/m Pulse Modulated 100% 0,5sec on 0,5sec off class 1 Page 19 of 24 Phenomena Fast transient Test C37.90.1 Damped oscillatory C37.90.1 wave Description Test Levels Class Enclosure Spot frequency test: 20V/m, for < 900 MHz 80% AM, for 900 MHz PM 50% @ 200 Hz class 1 Power ports & output ports 4 kV CM, 4 kV TM class 1 Digital data ports 4 kV CM class 1 Power ports & output ports 2,5 kV CM, 2,5 kV TM class 1 Digital data ports 2,5 kV CM class 1 HV Impulse C37.90 Circuits rated > 50V 5 kV Dielectric strength C37.90 Signal port to other isolated port 1500 Vrms 50 Hz 1min Signal port to other isolated port 1500 Vrms 50 Hz 1min Signal port to ground 2000 Vac rms Signal ports 2 kV Power ports 2 kV Signal ports 2 kV line to earth, Fast transient Surge EN 61000-4-4 EN 61000-4-5 A A B 1 kV line to line AC Power ports 2 kV line to earth, B 1 kV line to line DC Power ports 2 kV line to earth, 1 kV line to line Emission Radiated emission Conducted emission EN 55022 Enclosure Class A and Class B EN 55016-2-3 Enclosure Class A and Class B FCC part 15 Enclosure Class A and Class B EN 55022 DC power ports Class A and Class B Temperature Operating temperature Operating (XT2210A, XT2206A, XT1104A) –20 to +65ºC (fan less) (-4° to 149°F) Operating (XTD4-D) –40 to +70ºC (fanless) (-40° to 158°F) Page 20 of 24 B Phenomena Operating temperature: cold Operating temperature: dry heat Non-operating temperature: cold Non-operating temperature: dry heat Humidity Test Description Test Levels Class 60068-2-1 Operating (XT2210A, XT2206A, XT1104A) -20ºC (-4°F) Ad 60068-2-1 Operating (XTD4-D) -40°C (-40°F) 60068-2-2 Operating (XT2210A, XT2206A, XT1104A) +65ºC (149°F) 60068-2-2 Operating (XTD4-D) +70°C (158°F) 60068-2-1 Non-operating (XT2210A, XT2206A, XT1104A) –30ºC (-22°F) 60068-2-1 Non-operating (XTD-4-D) -40°C (-40°F) 60068-2-2 Non-operating (XT2210A, XT2206A, XT1104A) +75ºC ( 167°F) 60068-2-2 Non-operating (XTD-4-D) +85°C (185°F) 60068-2-30 Operating 5 to 95% relative humidity Vibration and Shock Vibration 60870-2-2 and Operating 60721-3-3 or -4 3 mm displacement 2-9 Hz 10m/s^2 (~1 g) 9-200 Hz 15m/s^2(~1.5g) 200-500 Hz Vibration 60255-21-1 Operating 60068-2 3 and 5mm displacement 2-9 Hz 10m/s^2 (~1 g) 9-150 Hz Shock 60870-2-2 and 60721-3-3 or -4 Operating Shock 60255-21-1 Operating 11 ms half-sine duration peak accel. 100m/s^2 (10g) 60068-2 6 ms half-sine duration peak accel. 150m/s^2 100 shocks per 6 directions On the issue date, some standards may still be pending. Page 21 of 24 Bd Ab Bb Page 22 of 24 14. Ordering Information Hardware Interface Module Order Number XT-2210-A S30926-B2210-X1 XT-2206-A S30926-B2206-X1 XT-1104-A S30926-B1104-X1 ACP-A V30912-A5020-A1 DCP-A V30912-A5020-A2 DCP-B V30912-A5020-A3 NSM-A S30924-Q100-X101 CSM310-A S30924-Q500-X101 4-DSL-LW S30924-Q200-X101 4-E1T1-L S30924-Q201-X101 1-10G-LW S30924-Q202-X101 4-GC-LW S30924-Q203-X101 XTD-4C-D S30928-B1-X1 2-C37.94 S30924-Q204-X101 4-4WEM-L S30924-Q205-X101 7-SERIAL S30924-Q207-X101 Serial Drop cable (3m) - 2 per card 2-CHA-LW S90927-C6-A30 S30924-Q211-X101 Page 23 of 24 Optical modules SFP Type Distance SFP 850nm - SX Typical distance: 1,5 km / 0.9 miles SFP 1310nm - LX Typical distance:3 km / 1,8 miles SFP 1310nm - EX Typical distance: 32 km / 20 miles SFP 1550nm - ZX Typical distance: 70 km / 43.5 miles SFP 1550nm - DWDM C-band Typical distance: 80 km / 50 miles SFP 1550nm - DWDM C-band Typical distance: 120 km / 74.5 miles SFP 1310 nm - BIDI Typical distance: 20 km / 12.5 miles SFP 1550nm - BIDI Typical distance: 20 km / 12.5 miles SFP 1310nm - BIDI Typical distance: 40 km / 24.8 miles SFP 1550nm - BIDI Typical distance: 40 km / 24.8 miles STM1/4-I optic SFP module Typical distance: 0.5 km / 0.31 mile STM1/4-S1 optic SFP module Typical distance: 15 km / 9.3 miles Software/Loadware Name Order Number OS License (one per node) OS License Redundancy lic. (one per node) Redundancy License TXCare license(one per node) up to 100 nodes TXCare Node License XT-2210-A TXCare Node License XT-2206-A TXCare Node License XT-1104-A Page 24 of 24 OTN Systems NV Industrielaan 17b, B-2250 Olen, Belgium. Fax: +32 14 25 20 23 E-mail: info@otnsystems.com www.otnsystems.com - www.otn.be