IE300 Series

Industrial Ethernet Layer 3 Switches

Allied Telesis ruggedized IE300 Industrial Ethernet switches provide enduring performance in harsh environments, such as those found in manufacturing, transportation and physical security. Offering high throughput, rich functionality and advanced security features, IE300 switches deliver the performance and reliability demanded by industrial deployments in the age of the Internet of Things (IoT).

IE300 Series

Overview

Allied Telesis IE300 Series are a highperforming and feature-rich choice for today’s networks. The IE300 are ideal for Industrial Ethernet applications, being qualified for manufacturing, roadway transportation (Traffic Control) and Smart Cities.

With a fanless design and a wide operating temperature range of -40°C to 75°C, they tolerate harsh and demanding environments, such as those found in industrial and outdoor deployment.

Network management

Allied Telesis Autonomous Management Framework™ (AMF) meets the increasing management requirements of today’s modern converged networks, by automating many everyday tasks such as configuration management.
AMF’s powerful features allow an entire network to be easily managed as a single virtual device.

Vista Manager™ EX is an intuitive visualization tool that complements the power of AMF. It allows users to monitor the network and quickly identify issues before they become major problems.

Securing the network edge

Ensuring data protection means controlling network access. Protocols such as IEEE 802.1X port-based authentication guarantee that only known users are connected to the network. Unknown users who physically connect can be segregated into a pre-determined part of the network. This offers network guests Internet access, while ensuring the integrity of private network data.

Gigabit and fast Ethernet support

The IE300 Series SFP ports support both gigabit and Fast Ethernet Small Form-Factor Pluggables (SFPs). This makes the IE300 Series ideal for environments where gigabit fiber switches will be phased in over time. This allows for connectivity to the legacy 100FX hardware until it is upgraded to gigabit Ethernet.

Support for both speeds of SFPs allows organizations to stay within budget as they migrate to faster technologies.

Network resiliency

The IE300 Series supports highly stable and reliable ICT network switching, with recovery times down to 50ms. The IE300 can be customized with the most appropriate mechanism and protocol to prevent network connection failure. Choices include Allied Telesis Ethernet Protection Switched Ring (EPSRing™), and the standards-based ITU-T G.8032.

Configurable power budget

On the PoE sourcing IE300 switches, you can configure both the overall power budget and the power feeding limit on a per-port basis, to establish a close relationship between the power sourcing feature and the real capabilities of the external Power Supply Unit (PSU).1

Future-proof

The IE300 Series ensures a future-proof network with a comprehensive feature set, and are Software Defined Networking (SDN) ready supporting OpenFlow v1.3.

Key Features

Allied Telesis Autonomous Management Framework (AMF)

  • AMF is a sophisticated suite of management tools that provide a simplified approach to network management. Common tasks are automated or made so simple that the every-day running of a network can be achieved without the need for highly-trained, and expensive, network engineers. Powerful features like centralized management, auto-backup, auto-upgrade, auto-provisioning and auto-recovery enable plug-and-play networking and zero-touch management.
  • AMF secure mode encrypts all AMF traffic, provides unit and user authorization, and monitors network access to greatly enhance network security.

Software Defined Networking (SDN)

  • OpenFlow is a key technology that enables the use of SDN to build smart applications that unlock value and reduce cost.

ICT Networks Resiliency

  • EPSRing™ and ITU-T G.8032 enable a protected ring capable of recovery within as little as 50ms. These features are perfect for high performance and high availability.
  • Spanning Tree Protocol compatible, RSTP; MSTP; static Link Aggregation Group (LAG), and dynamic Link Aggregation Control Protocol (LACP) support.

Quality of Service (QoS)

  • Comprehensive low-latency wire-speed QoS provides flow-based traffic management with full classification, prioritization, traffic shaping and min/max bandwidth profiles. Enjoy boosted network performance and guaranteed delivery of business-critical Ethernet services and applications. Time-critical services such as voice and video take precedence over non-essential services such as file downloads, maintaining responsiveness of your applications.

sFlow

  • sFlow is an industry standard technology for monitoring high speed switched networks. It provides complete visibility into network use, enabling performance optimization, usage accounting/billing, and defense against security threats. Sampled packets sent to a collector ensure it always has a real-time view of network traffic.

Active Fiber Monitoring

  • Active Fiber Monitoring prevents eavesdropping on fiber communications by monitoring received optical power. If an intrusion is detected, the link can be automatically shut down, or an operator alert can be sent.

VLAN Mirroring (RSPAN)

  • VLAN mirroring allows traffic from a port on a remote switch to be analyzed locally. Traffic being transmitted or received on the port is duplicated and sent across the network on a special VLAN.

Link Layer Discovery Protocol – Media Endpoint Discovery (LLDP – MED)

  • LLDP-MED extends LLDP basic network endpoint discovery and management functions. LLDP-MED allows for media endpoint specific messages, providing detailed information on power equipments, network policy, location discovery (for Emergency Call Services) and inventory.

VLAN Translation

  • VLAN Translation allows traffic arriving on a VLAN to be mapped to a different VLAN on the outgoing paired interface.
  • In Metro networks, it is common for a network Service Provider (SP) to give each customer their own unique VLAN, yet at the customer location give all customers the same VLAN-ID for tagged packets to use on the wire. SPs can use VLAN Translation to change the tagged packet’s VLAN-ID at the customer location to the VLAN-ID for tagged packets to use within the SP’s network.
  • This feature is also useful in Enterprise environments where it can be used to merge two networks together, without manually reconfiguring the VLAN numbering scheme. This situation can occur if two companies have merged and the same VLAN-ID is used for two different purposes.

VLAN ACLs

  • Simplify access and traffic control across entire segments of the network. Access Control Lists (ACLs) can be applied to a Virtual LAN (VLAN) as well as a specific port.

Security (Tri-Authentication)

  • Authentication options on the IE200 Series also include alternatives to IEEE 802.1X port-based authentication, such as web authentication to enable guest access, and MAC authentication for endpoints that do not have an IEEE 802.1X supplicant. All three authentication methods—IEEE 802.1X, MAC-based and Web-based—can be enabled simultaneously on the same port for tri-authentication.

Upstream Forwarding Only (UFO)

  • UFO lets you manage which ports in a VLAN can communicate with each other, and which only have upstream access to services, for secure multi-user deployment.

Dynamic Host Configuration Protocol (DHCP) Snooping

  • DHCP servers allocate IP addresses to clients, and the switch keeps a record of addresses issued on each port. IP source guard checks against this DHCP snooping database to ensure only clients with specific IP and/or MAC address can access the network. DHCP Snooping can be combined with other features, like dynamic ARP inspection, to increase security in layer 2 switched environments. It also provides a traceable history which meets the growing legal requirements placed on service providers.

Time synchronization with sub-microsecond precision (IEEE 1588 PTP)

  • Measurement and automation systems involving multiple devices often require accurate timing for event synchronization and data correlation. The IEEE 1588 Precise Time Protocol is a fault tolerant method of enabling clock synchronization in a distributed Ethernet network, and supports precise timing for automation applications and measurement systems.
  • The IE300 supports IEEE 1588-2008 (PTPv2) as Transparent Clock end-to-end mode, and performs an active role on Ethernet networks reducing the effects of Jitter.

PoE, PoE+ and Hi-PoE

  • Each port supplies either 15.40W (PoE), or 30.00W (PoE+); four ports are configurable for Hi-PoE, which uses all four pairs in the cable to supply up to 60W. When supplying Hi-PoE, the IE300 supports both single signature and dual signature negotiation with power devices. This supports PTZ cameras with heater/blowers for outdoor applications, enhanced infrared lighting, lighting controller and LED lighting fixtures, remote Point of Sale (POS) kiosks, and other devices.
  • The IE300 allows configuration of the overall power budget, as well as the power limit per port.

Continuous PoE

  • Continuous PoE allows the switch to be restarted without affecting the supply of power to connected devices. Smart lighting, security cameras, and other PoE devices will continue to operate during a software upgrade on the switch.

Industrial Automation

  • Modbus/TCP is intended for supervision and control of automation equipment; that is a variant of the MODBUS protocol using the TCP/IP for communications on Ethernet networks.

Alarm Input/Output

  • Alarm Input/Output is useful for security integration solutions to respond to events instantly, and automatically notify the monitoring control center. The 2-pin terminal blocks may be connected to sensors and actuator relays. Alarm Input receives signals from external devices like motion sensor and magnets that will trigger actions if something changes. Alarm output controls external devices upon an event (i.e. sirens, strobes, PTZ camera).

Enhanced Thermal Shutdown

  • The enhanced Thermal Shutdown feature acts to restrict PoE power and services when the switch exceeds the safe operating temperature. The system restores operation when the temperature returns to acceptable levels.

Premium Software License

  • The basic feature set can easily be upgraded with premium software licenses.
IE300 network

EPSRing and ITU-T G.8032 provide high speed resilient ring connectivity. This diagram shows the IE Series in a double ring network topology.

The IE Series operates at a large -40°C to +75°C temperature range and allows deployment in outdoor and harsh industrial environments.

PoE models feed 30 Watts per port, and support remotely controlled Pan, Tilt and Zoom (PTZ) video cameras.

The IE300 can source up to 60 Watts on four ports. The Hi-PoE utilizes all four pairs in the cable to provide power and expands the range of devices that can be added to the network, such as PTZ cameras with a heater/blower, enhanced infrared lighting, POS terminals, and thin
client computer.

Management can be automated with the Allied Telesis Autonomous Management Framework (AMF).

Product Specifications

PRODUCT 10/100/1000T (RJ-45) COPPER PORTS 100/1000X SFP PORTS TOTAL PORTS POE+ ENABLED PORTS SWITCHING FABRIC FORWARDING RATE
IE300-12GP 8 4 12 8 24Gbps 17.8Mpps
IE300-12GT 8 4 12 - 24Gbps 17.8Mpps

Performance

  • RAM memory: 512MB DDR SDRAM
  • ROM memory: 64MB flash
  • MAC address: 16K entries
  • Packet Buffer: 1.5 MBytes (12.2 Mbits)
  • Priority Queues: 8
  • Simultaneous VLANs: 4K
  • VLANs ID range: 1 – 4094
  • Jumbo frames: 9KB jumbo packets
  • Multicast groups: 1,023 (Layer 2), or 512 (Layer 2) and 512 (Layer 3)(2)

Other Interfaces

Type
Serial console (UART)
Port no.
1
Connector
RJ-45 female
Type
USB2.0 (Host Controller Class)
Port no.
1
Connector
Type A receptacle
Type
Alarm input (320µA @3.3Vdc)
Port no.
1
Connector
2-pin Terminal Block
Type
Alarm output (0.5A @30Vdc)
Port no.
1
Connector
2-pin Terminal Block
Type
Power Input
Port no.
2
Connector
2-pin Terminal Block

Reliability

  • Modular AlliedWare Plus operating system
  • Redundant power input
  • Full environmental monitoring of temperature and internal voltages. SNMP traps alert network managers in case of any failure
  • Enhanced thermal shutdown

Flexibility and Compatibility

  • Gigabit SFP ports supports any combination of Allied Telesis 10Mbps, 100Mbps and 1Gbps SFP modules, as listed in this document under Ordering Information

Industrial Automation

  • IEEE 1588v2 1-step End-to-End Transparent Clock
  • Modbus/TCP

Diagnostic Tools

  • Active Fiber Monitoring detects tampering on optical links
  • Automatic link flap detection and port shutdown
  • Built-In Self Test (BIST)
  • Cable fault locator (TDR)
  • Connectivity Fault Management (CFM)
    - Continuity Check Protocol (CCP) for use with G.8032 ERPS
  • Event logging via Syslog over IPv4
  • Find-me device locator
  • Ping polling for IPv4 and IPv6
  • Port and VLAN mirroring (RSPAN)
  • TraceRoute for IPv4 and IPv6
  • Uni-Directional Link Detection (UDLD)

IPv4 Features

  • Black hole routing
  • Directed broadcast forwarding
  • DHCP server and relay
  • DNS relay
  • Equal Cost Multi Path (ECMP) routing
  • Route redistribution (OSPF, RIP, and BGP)
  • Static unicast and multicast routes for IPv4
  • UDP broadcast helper (IP helper)

IPv6 Features

  • DHCPv6 server and relay
  • Device management over IPv6 networks with SNMPv6, Telnetv6 and SSHv6
  • IPv4 and IPv6 dual stack
  • IPv6 hardware ACLs
  • NTPv6 client and server
  • Static unicast routing for IPv6

Management

  • Front panel LEDs provide at-a-glance PSU status, PoE status, and fault information
  • Allied Telesis Autonomous Management Framework (AMF) node
  • Console management port on the front panel for ease of access
  • Eco-friendly mode allows ports and LEDs to be disabled to save power
  • Industry-standard CLI with context-sensitive help
  • Powerful CLI scripting engine
  • Built-in text editor
  • Event-based triggers allow user-defined scripts to be executed upon selected system events
  • SNMPv1/v2c/v3 support
  • Comprehensive SNMP MIB support for standards-based device management
  • USB interface allows software release files, configurations and other files to be stored for backup and distribution to other devices
  • Recessed Reset button

Quality of Service

  • 8 priority queues with a hierarchy of high priority queues for real-time traffic, and mixed scheduling, for each switch port
  • Extensive remarking capabilities
  • IP precedence and DiffServ marking based on Layer 2, 3 and 4 headers
  • Limit bandwidth per port or per traffic class down to 64kbps
  • Policy-based QoS based on VLAN, port, MAC and general packet classifiers
  • Policy-based storm protection
  • Strict priority, weighted round robin or mixed scheduling
  • Taildrop for queue congestion control
  • Wirespeed traffic classification with low latency essential for VoIP and real-time streaming media applications

(2) When PIM is enabled; see the Command Reference guide for recommended settings

Resiliency Features

  • Control Plane Prioritization (CPP) ensures the CPU always has sufficient bandwidth to process network control traffic
  • Dynamic link failover (host attach)
  • Ethernet Protection Switched Ring (EPSRing™) with SuperLoop Protection (EPSR-SLP)
  • Ethernet Ring Protection Switching (G.8032 ERPS)
  • Loop protection: loop detection and thrash limiting
  • PVST+ compatibility mode
  • Router Redundancy Protocol (RRP) snooping
  • Spanning Tree Protocol (STP) with root guard

Security Features

  • Access Control Lists (ACLs) based on layer 3 and 4 headers
  • Access Control Lists (ACLs) for management traffic
  • Authentication, Authorization and Accounting (AAA)
  • BPDU protection
  • Bootloader can be password protected for device security
  • DHCP snooping, IP source guard and Dynamic ARP Inspection (DAI)
  • DoS attack blocking and virus throttling
  • Dynamic VLAN assignment
  • MAC address filtering and MAC address lock-down
  • Network Access and Control (NAC) features manage endpoint security
  • Port-based learn limits (intrusion detection
  • Private VLANs provide security and port isolation for multiple customers using the same VLAN
  • RADIUS local server (100 users) and accounting
  • Secure Copy (SCP)
  • Strong password security and encryption
  • TACACS+ authentication and accounting
  • Tri-authentication: MAC-based, Web-based and IEEE 802.1X

Software Defined Networking (SDN)

  • OpenFlow v1.3 support

Environmental Specifications

  • Operating temperature range:
-40°C to 75°C (-40°F to 167°F)
  • Storage temperature range:
-40°C to 85°C (-40°F to 185°F)
  • Operating relative humidity range:
5% to 95% non-condensing
  • Storage relative humidity range:
5% to 95% non-condensing
  • Operating altitude:
3,000 meters maximum (9,843 ft)

    Mechanical

    • EN 50022, EN 60715 Standardized mounting on rails

    Environmental Compliance

    • RoHS
    • China RoHS
    • WEEE

    Electrical/Mechanical Approvals

    Compliance Mark

    • CE, FCC

    Safety

    • EN/IEC/UL 60950-1
    • EN/IEC/UL 60950-22
    • CAN/CSA-22.2 no. 60950-1
    • CAN/CSA-22.2 no. 60950-22

    EMC

    • CISPR 32
    • EN55024
    • EN55032 Class A
    • EN61000-3-2
    • EN61000-3-3
    • EN61000-4-2 (ESD)
    • EN61000-4-3 (RS)
    • EN61000-4-4 (EFT)
    • EN61000-4-5 (Surge)
    • EN61000-4-6 (CS)
    • EN61000-4-8
    • EN61000-4-11
    • FCC Part 15B, Class A

    Shock

    • EN60068-2-27
    • EN60068-2-31

    Vibration

    • EN60068-2-6

    Traffic Control

    • NEMA TS2

    Physical Specifications

    PRODUCT WIDTH x DEPTH x HEIGHT WEIGHT ENCLOSURE MOUNTING PROTECTION WEIGHT
    IE300-12GP 146 x 127 x 152 mm
    (5.75 x 5.00 x 6.00 in)
    2.0 kg (4.5 lb) aluminum shell DIN rail, wall mount IP30
    IE300-12GT 146 x 127 x 152 mm
    (5.75 x 5.00 x 6.00 in)
    2.0 kg (4.4 lb) aluminum shell DIN rail, wall mount IP30

    Power Characteristics

          NO POE LOAD* FULL POE LOAD***   MAX POE SOURCING PORTS
    PRODUCT INPUT VOLTAGE COOLING MAX POWER CONSUMPTION MAX HEAT DISSIPATION NOISE MAX POWER CONSUMPTION MAX HEAT DISSIPATION NOISE MAX POE POWER POE (15W) POE+ (30W) HI-POE (60W)
    IE300-12GP 48V DC *, 53.5V DC ** fanless 30W 102 BTU/hr - 320W 147 BTU/hr - 240W 8 8 4
    IE300-12GT 12~55V DC fanless 30W 102 BTU/hr - - - - - - -

    * sourcing IEEE 802.3at Type 1 (PoE)

    ** sourcing IEEE 802.3at Type 2 (PoE+, Hi-PoE)

    *** The Max Power consumption at full PoE load includes PD’s consumption and margin. The cooling requirements of the switch are smaller than the power draw, because most of the load is dissipated at the PoE powered device (PD) and along the cabling.

    Use these wattage and BTU ratings for facility capacity planning.

     

    Latency (microseconds)

      PORT SPEED
    PRODUCT 10Mbps 100Mbps 1000Mbps
    IE300-12GP 54μs 7.9μs 3.4μs
    IE300-12GT 54μs 7.9μs 3.4μs
    AlliedWare Plus Operating System

    Version 5.4.9-2

    Authentication
    RFC 1321
    MD5 Message-Digest algorithm
    RFC 1828
    IP authentication using keyed MD5
    Automation

    Modbus/TCP
    IEEE 1588-2008 Precision Clock Synchronization Protocol v2

    Border Gateway Protocol (BGP)

    BGP dynamic capability
    BGP outbound route filtering

    RFC 1772
    Application of the Border Gateway Protocol (BGP) in the Internet
    RFC 1997
    BGP communities attribute
    RFC 2439
    BGP route flap damping
    RFC 2545
    Use of BGP-4 multiprotocol extensions for IPv6 inter-domain routing
    RFC 2918
    Route refresh capability for BGP-4
    RFC 3882
    Configuring BGP to block Denial-of-Service (DoS) attacks
    RFC 4271
    Border Gateway Protocol 4 (BGP-4)
    RFC 4360
    BGP extended communities
    RFC 4456
    BGP route reflection - an alternative to full mesh iBGP
    RFC 4724
    BGP graceful restart
    RFC 4760
    Multiprotocol Extensions for BGP-4
    RFC 5065
    Autonomous system confederations for BGP
    RFC 5492
    Capabilities Advertisement with BGP-4
    RFC 5925
    The TCP Authentication Option
    RFC 6793
    BGP Support for Four-Octet Autonomous System (AS) Number Space
    RFC 7606
    Revised Error Handling for BGP UPDATE messages
    Encryption (management traffic only)
    FIPS 180-1
    Secure Hash standard (SHA-1)
    FIPS 186
    Digital signature standard (RSA)
    FIPS 46-3
    Data Encryption Standard (DES and 3DES)
    Ethernet Standards

    IEEE 802.2 Logical Link Control (LLC)
    IEEE 802.3 Ethernet
    IEEE 802.3ab 1000BASE-T
    IEEE 802.3af Power over Ethernet (PoE)
    IEEE 802.3at Power over Ethernet up to 30W (PoE+)
    IEEE 802.3az Energy Efficient Ethernet (EEE)
    IEEE 802.3u 100BASE-X
    IEEE 802.3x Flow control - full-duplex operation
    IEEE 802.3z 1000BASE-X

    IPv4 Features
    RFC 768
    User Datagram Protocol (UDP)
    RFC 791
    Internet Protocol (IP)
    RFC 792
    Internet Control Message Protocol (ICMP)
    RFC 793
    Transmission Control Protocol (TCP)
    RFC 826
    Address Resolution Protocol (ARP)
    RFC 894
    Standard for the transmission of IP datagrams over Ethernet networks
    RFC 919
    Broadcasting Internet datagrams
    RFC 922
    Broadcasting Internet datagrams in the presence of subnets
    RFC 932
    Subnetwork addressing scheme
    RFC 950
    Internet standard subnetting procedure
    RFC 951
    Bootstrap Protocol (BootP)
    RFC 1027
    Proxy ARP
    RFC 1035
    DNS client
    RFC 1042
    Standard for the transmission of IP datagrams over IEEE 802 networks
    RFC 1071
    Computing the Internet checksum
    RFC 1122
    Internet host requirements
    RFC 1191
    Path MTU discovery
    RFC 1256
    ICMP router discovery messages
    RFC 1518
    An architecture for IP address allocation with CIDR
    RFC 1519
    Classless Inter-Domain Routing (CIDR)
    RFC 1542
    Clarifications and extensions for BootP
    RFC 1591
    Domain Name System (DNS)
    RFC 1812
    Requirements for IPv4 routers
    RFC 1918
    IP addressing
    RFC 2581
    TCP congestion control
    IPv6 Features
    RFC 1981
    Path MTU discovery for IPv6
    RFC 2460
    IPv6 specification
    RFC 2464
    Transmission of IPv6 packets over Ethernet networks
    RFC 3484
    Default address selection for IPv6
    RFC 3587
    IPv6 global unicast address format
    RFC 3596
    DNS extensions to support IPv6
    RFC 4007
    IPv6 scoped address architecture
    RFC 4193
    Unique local IPv6 unicast addresses
    RFC 4213
    Transition mechanisms for IPv6 hosts and routers
    RFC 4291
    IPv6 addressing architecture
    RFC 4443
    Internet Control Message Protocol (ICMPv6)
    RFC 4861
    Neighbor discovery for IPv6
    RFC 4862
    IPv6 Stateless Address Auto-Configuration (SLAAC)
    RFC 5014
    IPv6 socket API for source address selection
    RFC 5095
    Deprecation of type 0 routing headers in IPv6
    RFC 5175
    IPv6 Router Advertisement (RA) flags option
    RFC 6105
    IPv6 Router Advertisement (RA) guard
    Management

    AT Enterprise MIB including AMF MIB and traps
    Optical DDM MIB
    SNMPv1, v2c and v3
    IEEE 802.1AB Link Layer Discovery Protocol (LLDP)

    RFC 1155
    Structure and identification of management information for TCP/IP-based Internets
    RFC 1157
    Simple Network Management Protocol (SNMP)
    RFC 1212
    Concise MIB definitions
    RFC 1213
    MIB for network management of TCP/IP-based Internets: MIB-II
    RFC 1215
    Convention for defining traps for use with the SNMP
    RFC 1227
    SNMP MUX protocol and MIB
    RFC 1239
    Standard MIB
    RFC 1724
    RIPv2 MIB extension
    RFC 2578
    Structure of Management Information v2 (SMIv2)
    RFC 2579
    Textual conventions for SMIv2
    RFC 2580
    Conformance statements for SMIv2
    RFC 2674
    Definitions of managed objects for bridges with traffic classes, multicast filtering and VLAN extensions
    RFC 2741
    Agent extensibility (AgentX) protocol
    RFC 2787
    Definitions of managed objects for VRRP
    RFC 2819
    RMON MIB (groups 1,2,3 and 9)
    RFC 2863
    Interfaces group MIB
    RFC 3176
    sFlow: a method for monitoring traffic in switched and routed networks
    RFC 3411
    An architecture for describing SNMP management frameworks
    RFC 3412
    Message processing and dispatching for the SNMP
    RFC 3413
    SNMP applications
    RFC 3414
    User-based Security Model (USM) for SNMPv3
    RFC 3415
    View-based Access Control Model (VACM) for SNMP
    RFC 3416
    Version 2 of the protocol operations for the SNMP
    RFC 3417
    Transport mappings for the SNMP
    RFC 3418
    MIB for SNMP
    RFC 3621
    Power over Ethernet (PoE) MIB
    RFC 3635
    Definitions of managed objects for the Ethernet-like interface types
    RFC 3636
    IEEE 802.3 MAU MIB
    RFC 4022
    MIB for the Transmission Control Protocol (TCP)
    RFC 4113
    MIB for the User Datagram Protocol (UDP)
    RFC 4188
    Definitions of managed objects for bridges
    RFC 4292
    IP forwarding table MIB
    RFC 4293
    MIB for the Internet Protocol (IP)
    RFC 4318
    Definitions of managed objects for bridges with RSTP
    RFC 4560
    Definitions of managed objects for remote ping, traceroute and lookup operations
    RFC 5424
    The Syslog protocol
    RFC 6527
    Definitions of managed objects for VRRPv3
    RFC 5424
    The Syslog protocol
    Multicast Support

    Bootstrap Router (BSR) mechanism for PIM-SM
    IGMP query solicitation
    IGMP snooping (IGMPv1, v2 and v3)
    IGMP snooping fast-leave
    IGMP/MLD multicast forwarding (IGMP/MLD proxy)
    MLD snooping (MLDv1 and v2)
    PIM-SM and SSM for IPv6

    RFC 2236
    Internet Group Management Protocol v2 (IGMPv2)
    RFC 2710
    Multicast Listener Discovery (MLD) for IPv6
    RFC 2715
    Interoperability rules for multicast routing protocols
    RFC 3306
    Unicast-prefix-based IPv6 multicast addresses
    RFC 3376
    IGMPv3
    RFC 3590
    Source Address Selection for the Multicast Listener Discovery (MLD) Protocol
    RFC 3810
    Multicast Listener Discovery v2 (MLDv2) for IPv6
    RFC 3956
    Embedding the Rendezvous Point (RP) address in an IPv6 multicast address
    RFC 3973
    PIM Dense Mode (DM)
    RFC 4541
    IGMP and MLD snooping switches
    RFC 4604
    Using IGMPv3 and MLDv2 for source-specific multicast
    RFC 4607
    Source-specific multicast for IP
    RFC 7761
    Protocol Independent Multicast - Sparse Mode (PIM-SM): Protocol specification
    Open Shortest Path First (OSPF)

    OSPF link-local signaling
    OSPF MD5 authentication
    OSPF restart signaling
    Out-of-band LSDB resync

    RFC 1245
    OSPF protocol analysis
    RFC 1246
    Experience with the OSPF protocol
    RFC 1370
    Applicability statement for OSPF
    RFC 1765
    OSPF database overflow
    RFC 2328
    OSPFv2
    RFC 2370
    OSPF opaque LSA option
    RFC 2740
    OSPFv3 for IPv6
    RFC 3101
    OSPF Not-So-Stubby Area (NSSA) option
    RFC 3509
    Alternative implementations of OSPF area border routers
    RFC 3623
    Graceful OSPF restart
    RFC 3630
    Traffic engineering extensions to OSPF
    RFC 4552
    Authentication/confidentiality for OSPFv3
    RFC 5329
    Traffic engineering extensions to OSPFv3
    RFC 5340
    OSPFv3 for IPv6 (partial support)
    Quality of Service (QoS)
    IEEE 802.1p
    Priority tagging
    RFC 2211
    Specification of the controlled-load network element service
    RFC 2474
    DiffServ precedence for eight queues/port
    RFC 2475
    DiffServ architecture
    RFC 2597
    DiffServ Assured Forwarding (AF)
    RFC 2697
    A single-rate three-color marker
    RFC 2698
    A two-rate three-color marker
    RFC 3246
    DiffServ Expedited Forwarding (EF)
    Resiliency Features

    ITU-T G.8023 / Y.1344 Ethernet Ring Protection Switching (ERPS)

    IEEE 802.1ag
    CFM Continuity Check Protocol (CCP)
    IEEE 802.1AX
    Link aggregation (static and LACP)
    IEEE 802.1D
    MAC bridges
    IEEE 802.1s
    Multiple Spanning Tree Protocol (MSTP)
    IEEE 802.1w
    Rapid Spanning Tree Protocol (RSTP)
    IEEE 802.3ad
    Static and dynamic link aggregation
    RFC 5798
    Virtual Router Redundancy Protocol version 3 (VRRPv3) for IPv4 and IPv6
    Routing Information Protocol (RIP)
    RFC 1058
    Routing Information Protocol (RIP)
    RFC 2080
    RIPng for IPv6
    RFC 2081
    RIPng protocol applicability statement
    RFC 2082
    RIP-2 MD5 authentication
    RFC 2453
    RIPv2
    Security Features

    SSH remote login
    SSLv2 and SSLv3
    TACACS+ accounting and authentication (AAA)

    IEEE 802.1X
    authentication protocols (TLS, TTLS, PEAP and MD5)
    IEEE 802.1X
    multi-supplicant authentication
    IEEE 802.1X
    port-based network access control
    RFC 2818
    HTTP over TLS (“HTTPS”)
    RFC 2865
    RADIUS authentication
    RFC 2866
    RADIUS accounting
    RFC 2868
    RADIUS attributes for tunnel protocol support
    RFC 2986
    PKCS #10: certification request syntax specification v1.7
    RFC 3579
    RADIUS support for Extensible Authentication Protocol (EAP)
    RFC 3580
    IEEE 802.1x RADIUS usage guidelines
    RFC 3748
    PPP Extensible Authentication Protocol (EAP)
    RFC 4251
    Secure Shell (SSHv2) protocol architecture
    RFC 4252
    Secure Shell (SSHv2) authentication protocol
    RFC 4253
    Secure Shell (SSHv2) transport layer protocol
    RFC 4254
    Secure Shell (SSHv2) connection protocol
    RFC 5246
    TLS v1.2
    RFC 5280
    X.509 certificate and Certificate Revocation List (CRL) profile
    RFC 5425
    Transport Layer Security (TLS) transport mapping for Syslog
    RFC 5656
    Elliptic curve algorithm integration for SSH
    RFC 6125
    Domain-based application service identity within PKI using X.509 certificates with TLS
    RFC 6614
    Transport Layer Security (TLS) encryption
    for RADIUS
    RFC 6668
    SHA-2 data integrity verification for SSH
    Services
    RFC 854
    Telnet protocol specification
    RFC 855
    Telnet option specifications
    RFC 857
    Telnet echo option
    RFC 858
    Telnet suppress go ahead option
    RFC 1091
    Telnet terminal-type option
    RFC 1350
    Trivial File Transfer Protocol (TFTP)
    RFC 1985
    SMTP service extension
    RFC 2049
    MIME
    RFC 2131
    DHCPv4 (server, relay and client)
    RFC 2132
    DHCP options and BootP vendor extensions
    RFC 2616
    Hypertext Transfer Protocol - HTTP/1.1
    RFC 2821
    Simple Mail Transfer Protocol (SMTP)
    RFC 2822
    Internet message format
    RFC 3046
    DHCP relay agent information option (DHCP option 82)
    RFC 3315
    DHCPv6 (server, relay and client)
    RFC 3396
    Encoding Long Options in the Dynamic Host Configuration Protocol (DHCPv4)
    RFC 3633
    IPv6 prefix options for DHCPv6
    RFC 3646
    DNS configuration options for DHCPv6
    RFC 3993
    Subscriber-ID suboption for DHCP relay agent option
    RFC 4954
    SMTP Service Extension for Authentication
    RFC 5905
    Network Time Protocol (NTP) version 4
    VLAN Support

    Generic VLAN Registration Protocol (GVRP)

    IEEE 802.1ad
    Provider bridges (VLAN stacking, Q-in-Q)
    IEEE 802.1Q
    Virtual LAN (VLAN) bridges
    IEEE 802.1v
    VLAN classification by protocol and port
    IEEE 802.3ac
    VLAN tagging
    Voice over IP (VoIP)

    Voice VLAN
    ANSI/TIA-1057 Link Layer Discovery Protocol-Media Endpoint Discovery (LLDP-MED)

    NAME DESCRIPTION INCLUDES
    AT-FL-IE3-G8032 IE300 series license for ITU-T G.8032 and Ethernet CFM ITU-T G.8032
    Ethernet CFM
    AT-FL-IE3-L2-01 IE300 series Layer-2 Premium license EPSR Master
    VLAN Translation
    VLAN double tagging (QinQ)
    UDLD
    AT-FL-IE3-L3-01 IE300 series Layer-3 Premium license OSPF (256 routes)
    OSPFv3 (256 routes)
    BGP4 (256 routes)
    BGP4+ for IPv6 (256 routes)
    PIM-SM, DM and SSM
    PIMv6-SM and SSM
    RIP
    RIPng
    VRRP and VRRPv3
    AT-FL-IE3-MODB IE300 Series Modbus/TCP license Modbus/TCP
    AT-FL-IE3-OF13-1YR OpenFlow license OpenFlow v1.3 for 1 year
    AT-FL-IE3-OF13-5YR OpenFlow license OpenFlow v1.3 for 5 years

    Switches

    The DIN rail and wall mount kits are included.

    AT-IE300-12GP-80

    8x 10/100/1000T, 4x 100/1000X SFP,
    Industrial Ethernet, Layer 3 Switch, Hi-PoE Support

    AT-IE300-12GT-80

    8x 10/100/1000T, 4x 100/1000X SFP,
    Industrial Ethernet, Layer 3 Switch

    Supported SFP Modules

    Refer to the installation guide for the recommended Max. Operating Temperature according to the selected SFP module.

    1000Mbps SFP Modules

    AT-SPBD10-13

    10 km, 1G BiDi SFP, LC, SMF (1310Tx/1490Rx)

    AT-SPBD10-14

    10 km, 1G BiDi SFP, LC, SMF (1490Tx/1310Rx)

    AT-SPBD20-13/I

    20 km, 1G BiDi SFP, SC, SMF, I-Temp (1310Tx/1490Rx)

    AT-SPBD20-14/I

    20 km, 1G BiDi SFP, SC, SMF, I-Temp (1490Tx/1310Rx)

    AT-SPBD20LC/I-13

    20 km, 1G BiDi SFP, LC, SMF, I-Temp (1310Tx/1490Rx)

    AT-SPBD20LC/I-14

    20 km, 1G BiDi SFP, LC, SMF, I-Temp (1490Tx/1310Rx)

    AT-SPEX

    2 km, 1000EX SFP, LC, MMF, 1310 nm

    AT-SPEX/E

    2 km, 1000EX SFP, LC, MMF, 1310 nm, Ext. Temp

    AT-SPLX10

    10 km, 1000LX SFP, LC, SMF, 1310 nm

    AT-SPLX10/I

    10 km, 1000LX SFP, LC, SMF, 1310 nm, I-Temp

    AT-SPLX10/E

    10 km, 1000LX SFP, LC, SMF, 1310 nm, Ext. Temp

    AT-SPLX40

    40 km, 1000LX SFP, LC, SMF, 1310 nm

    AT-SPLX40/E

    40 km, 1000LX SFP, LC, SMF, 1310 nm, Ext. Temp

    AT-SPSX

    550 m, 1000SX SFP, LC, MMF, 850 nm

    AT-SPSX/I

    550 m, 1000SX SFP, LC, MMF, 850 nm, I-Temp

    AT-SPSX/E

    550 m, 1000SX SFP, LC, MMF, 850 nm, Ext. Temp

    AT-SPTX

    100 m, 10/100/1000T SFP, RJ-45

    AT-SPTX/I

    100 m, 10/100/1000T SFP, RJ-45, I-Temp

    AT-SPZX80

    80 km, 1000ZX SFP, LC, SMF, 1550 nm

    100Mbps SFP Modules

    AT-SPFX/2

    2 km, 100FX SFP, LC, MMF, 1310 nm

    AT-SPFX/15

    15 km, 100FX SFP, LC, SMF, 1310 nm

    AT-SPFXBD-LC-13

    15 km, 100FX BiDi SFP, LC, SMF (1310 Tx/1550 Rx)

    AT-SPFXBD-LC-15

    15 km, 100FX BiDi SFP, LC, SMF (1550 Rx/1310 Tx)

    Accessories

    AT-VT-Kit3

    Management cable (USB to serial console)