Juniper Networks QFX5200-32C
Versatile, High-Density 100GbE Data Center Switches with 32 QSFP+ transceiver or QSFP28 ports
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Overview:
The QFX5200 fixed-configuration access switch is ideally suited for leaf deployments in nextgeneration IP fabric networks. It features line-rate, high-density QSFP+/QSFP28 ports that support 10GbE, 25GbE, 40GbE, 50GbE, and 100GbE connections. Offering an advanced L2, L3, and MPLS feature set, network operators can use the QFX5200 to build large, high-density IP fabrics that support upgrades to 25GbE servers, network virtualization, and intelligent traffic forwarding based on proven, Internet-scale technology. The QFX5200 also supports a disaggregated version of Junos software in which control plane and data plane processes and functions run in parallel to maximize utilization of the highperformance quad-core CPU.
The QFX5200 switches are compact, 1U platforms that provide wire-speed packet performance, very low latency, and a rich set of Junos OS features. In addition to a high throughput Packet Forwarding Engine (PFE), the performance of the QFX5200 control plane is further enhanced with a powerful 1.8 GHz quad-core Intel CPU with 16 GB of memory and 64 GB SSD storage.
The QFX5200-48Y is a 10GbE/25GbE data center access switch that offers 48 small formfactor pluggable plus (SFP+) transceiver ports or SFP28 ports and six QSFP28 ports. The six QSFP28 ports can be configured as 6x40GbE or 6x100GbE, with an aggregate throughput of 3.6 Tbps or 4.2 Bpps per switch.
Product Description
Network operators are increasingly deploying scale-out, spine-and-leaf IP fabric architectures, built with fixed-configuration switches to support growing east-west traffic in the data center. The Juniper Networks QFX5200 line of next-generation, fixedconfiguration leaf/access switches offers flexible, cost-effective, high-density 10GbE, 25GbE, 40GbE, 50GbE, and 100GbE interfaces for server and intra-fabric connectivity, providing deployment versatility, investment protection, and future-proofing for today’s data centers.
In addition to leaf deployments in IP fabric architectures, the QFX5200 switch is also a great fit for multitier, multichassis link aggregation (MC-LAG) network implementations commonly used in enterprise networks.
Like other QFX Series switches, the QFX5200 supports advanced Layer 2, Layer 3, and MPLS features. For large public cloud providers-among the first to adopt 25GbE servers to meet explosive workload growth-the QFX5200 enables very large, dense, and fast IP fabrics based on proven, Internet scale technology. For enterprise customers seeking investment protection as they transition their server farms from 10GbE to 25GbE, the QFX5200 line provides native 10GbE and 25GbE downlink ports as well as 40GbE and 100GbE uplink connections.
The QFX5200 runs the same reliable, high-performance Juniper Networks Junos operating system used by network operators around the world. The QFX5200 supports a modular version of Junos OS that allows the switch’s control plane and data plane processes and functions to run in parallel, maximizing utilization of the high-performance quad-core CPU.
QFX5200 Configuration
The QFX5200 is a compact, 1 U platform featuring 32 quad small form-factor pluggable plus (QSFP+) transceivers or QSFP28 ports, with two redundant 850 W AC/DC power supplies and five fan trays. A QSFP28 module can be used for a 1x100GbE connection or 2x50GbE or 4x25GbE connections using breakout cables. A QSFP+ module can be used for a 1x40GbE connection or 4x10GbE connections using breakout cables. The QFX5200 features a high throughput 6.4 Tbps Packet Forwarding Engine (PFE). Control plane performance is further enhanced with a powerful 1.8 GHz quad core Intel CPU with 16 GB of memory and 64 GB SSD storage.
Product Highlights
The QFX5200 includes the following capabilities. Please refer to the Specifications section for currently shipping features.
- Native 25GbE configuration: Offering 48 ports of 25GbE and delivering 3.6 Tbps of line-rate switching, the QFX5200-48Y is optimized for top-of-rack deployments.
- High-density configuration: Offering 32 ports of 100GbE or 40GbE and delivering 6.4 Tbps line-rate switching performance, the QFX5200 is optimized for high-density fabric deployments.
- Flexible connectivity options: The QFX5200 offers a choice of 10GbE, 25GbE, 40GbE, 50GbE, and 100GbE interface speeds for server and intra-fabric connectivity, providing deployment versatility and investment protection.
- Rich automation capabilities: The QFX5200 supports Zero Touch Provisioning (ZTP) and Juniper plug-ins for OpenStack Neutron and CloudStack NetworkGuru. Proactive application/flow path analysis is available via the Juniper Networks Cloud Analytics Engine to operationalize network monitoring and optimization.
- Advanced Junos OS features: The QFX5200 switch supports features such as BGP add-path, MPLS, L3 VPN, and Fibre Channel over Ethernet (FCoE).
- Disaggregated Junos software architecture: The QFX5200 supports a disaggregated version of Junos software with a modular architecture that allows the switch’s control and data plane processes and functions to run in parallel, maximizing utilization of the high-performance quad-core CPU.
QFX5200 Deployment Options
The following table depicts some of the many QFX5200 deployment options, including top-of-rack access as well as spineand-leaf configurations in a centralized or distributed gateway architecture.
Port Combinations | Switch | Deployment |
---|---|---|
48x10GbE + 6x40GbE | QFX5200-48Y | 10GbE access |
48x25GbE + 6x100GbE | QFX5200-48Y | 25GbE access |
32x100GbE | QFX5200-32C | Spine |
128x25GbE | QFX5200-32C | Leaf |
64x25GbE + 16x100GbE | QFX5200-32C | 25GbE access |
96x10GbE + 8x100GbE | QFX5200-32C | 10GbE access |
Figure 1 shows QFX5200-48Y 25GbE top-of-rack deployment with a Juniper Networks QFX10000 spine acting as a centralized gateway. In this topology, the QFX10000 switch can also be configured as a collapsed spine and edge device, acting as a centralized gateway for Virtual Extensible LAN (VXLAN), MPLS, and other tunneling protocols.
Figure 1: QFX5200-48Y and QFX10000 leaf-spine deployment
The QFX5200-32C can be deployed as a top-of-rack switch in a centralized gateway architecture. Figure 2 shows the QFX5200-32C as an access switch with a Juniper Networks QFX10000 spine configured as a centralized gateway. In this topology, the QFX10000 switch can also be configured as a collapsed spine and edge device, acting as a centralized gateway for VXLAN, MPLS, and other tunneling protocols. The 100GbE ports on QFX5200-32C can also be channelized to support 4x25GbE, 2x50GbE, or 4x10GbE downlinks.
Figure 2: QFX5200-32C and QFX10000 leaf-spine deployment with centralized gateway
The QFX5200-32C can also be positioned as a spine in a distributed gateway architecture. Figure 3 shows the QFX5110 as access switches configured as a distributed gateway along with the QFX5200 spine switch. The QFX5110 switches act as a distributed gateway for VXLAN and other tunneling protocols.
Figure 3: QFX5110 and QFX5200-32C leaf-spine deployment with distributed gateway
Architecture and Key Components:
The QFX5200 can be used in L3 fabrics and L2 networks with with MC-LAG. Customers can choose the architecture that best suits their deployment needs and easily adapt and evolve as requirements change over time. The QFX5200 switch serves as the universal building block for these two switching architectures, enabling data center operators to build cloud networks their way.
- Layer 3 Fabric: For customers looking to build scale-out data centers, a Layer 3 spine-and-leaf Clos fabric is ideal due to its predictable, nonblocking performance and scale characteristics. For example, a two-tier fabric built with QFX5200 switches as leafs and Juniper Networks QFX10000 switches as the spine can scale to support up to 18,432 40GbE ports, or 36,864 25GbE or 10GbE server ports in a single fabric. One of the most complicated tasks in building an IP fabric is assigning all of the implementation details, including IP addresses, BGP autonomous system (AS) numbers, routing policies, loopback address assignments, and many others. Automating the creation of an IP fabric at a large scale is equally difficult. To address these challenges, Juniper has created the OpenClos project to provide free and opensource tools that automate the creation of IP fabrics in the data center. A set of Python scripts developed as an opensource project that live on GitHub, OpenClos takes a set of inputs that describe the shape and size of a data center and outputs switch configuration files, as well as a cabling plan.
- MC-LAG: The QFX5200 supports the MC-LAG protocol between two switches to eliminate Spanning Tree Protocol (STP) in traditional L2 networks when deployed in the aggregation layer. The active/active operation of MC-LAG ensures complete bandwidth utilization between the network’s access and aggregation layers, while the dual control plane technology ensures the highest availability for applications.
Carrier-Class Network Operating System
The QFX5200 runs the same Junos OS used by all other Juniper Networks QFX Series and EX Series Ethernet Switches, as well as the Juniper routers that power the world’s largest and most complex networks.
By using a common operating system, Juniper delivers a consistent implementation and operation of control plane features across all products. Junos OS employs a highly available modular architecture that prevents isolated failures from bringing down an entire system. Key Junos OS features that enhance the functionality and capabilities of the QFX5200 include:
- Software modularity, with process modules running independently in their own protected memory space and with the ability to do process restarts
- Commit and rollback functionality, which ensures error-free network configurations
- A powerful set of scripts for on-box problem detection, reporting, and resolution
Figure 2: Disaggregated Junos software infrastructure
Junos Telemetry Interface
The QFX5200 supports Junos Telemetry Interface (JTI)*, a modern telemetry streaming tool designed for performance monitoring in complex, dynamic data centers. Streaming data to a performance management system enables network administrators to measure trends in link and node utilization, and troubleshoot such issues as network congestion in real time. JTI provides these capabilities
- Application visibility and performance management by provisioning sensors to collect and stream data and analyze application and workload flow path through the network.
- Capacity planning and optimization by proactively detecting hotspots and monitoring latency and microbursts.
- Troubleshooting and root cause analysis via high-frequency monitoring and correlating overlay and underlay networks
Features and Benefits:
- Automation and Programmability: The QFX5200 supports numerous network automation features, including operations and event scripts, ZTP, and Juniper plug-ins for OpenStack Neutron and CloudStack NetworkGuru.
- Flexible Forwarding Table: The QFX5200’s Flexible Forwarding Table (FFT) allows the hardware table to be carved into configurable partitions of Layer 2 media access control (MAC), Layer 3 host, and longest prefix match (LPM) tables. In a pure L2 environment, the QFX5200 supports 136,000 MAC addresses. In L3 mode, the table supports 104,000 host entries, while in LPM mode, it supports 128,000 prefixes. A filter-based forwarding mode supports 64,000 exact match filtering rules. Junos OS provides configurable options through a CLI, enabling each QFX5200 to be optimized for different deployment scenarios.
- Flow path analysis: QFX5200 supports the Cloud Analytics Engine’s automated application flow path analysis by responding to application probe packets with probe ingress and egress timestamps and rich network statistics such as ingress interface, hash computed egress interface, queue stats, interface error, bandwidth utilization at ingress, equal-cost multipath (ECMP) group load distribution, and more. The QFX5200 also reports underlay network path information and overlay tunnel bandwidth utilization on the switch in response to overlay probe packets for overlay and underlay correlation.
- MPLS: The QFX5200 supports a broad set of MPLS features, including L3 VPN, RSVP traffic engineering, and LDP to support standards-based multitenancy and network virtualization with per-flow SLAs at scale. The QFX5200 can also be deployed as a low-latency MPLS labelswitching router (LSR) or MPLS provider edge (PE) router in smaller scale environments. The QFX5200 and the Juniper Networks QFX5100 switch are the industry’s most compact, low-latency, high-density, low power family of switches to offer an MPLS feature set.
- FCoE: As a Fibre Channel over Ethernet (FCoE) transit switch, the QFX5200 provides an IEEE data center bridging (DCB) converged network between FCoE-enabled servers and an FCoE-to-FC gateway or FCoE-enabled Fibre Channel storage area network (SAN). The QFX5200 offers a full-featured DCB implementation that provides strong monitoring capabilities on the top-of-rack switch for SAN and LAN administration teams to maintain clear separation of management. In addition, FCoE Initialization Protocol (FIP) snooping provides perimeter protection, ensuring that the presence of an Ethernet layer does not impact existing SAN security policies. FCoE LAG support transports FCoE traffic and regular Ethernet traffic across the same link aggregation bundle over ports on a converged network adapter (CNA) while guaranteeing that the same physical link is used for an FCoE point-to-point virtual connection.
The FCoE transit switch functionality, including prioritybased flow control (PFC) and Data Center Bridging Capability Exchange (DCBX), are included as part of the default software.
Figure 3: Juniper Networks Cloud Analytics Engine
QFX5200-32C-S Hardware with SONiC Support
The QFX5200-32C-S Switch supports Juniper’s SONiC implementation, delivering best-of-breed hardware and routing for cloud providers while taking advantage of the flexibility, resiliency, and cost savings of SONiC’s open and disaggregated architecture. The SONiC-enabled QFX5200-32C-S, which plugs seamlessly into a unified SONiC network infrastructure, leverages the existing QFX5200-32C hardware and includes support for ONIE and IDEEPROM TLV formats. ONIE and SONiC images are installed on the hardware at the factory. The Juniper-provided SONiC image includes the platform and FRU device drivers only; it does not include Juniper software features such as Layer 2, Layer 3, MPLS, EVPN, and VXLAN, among others. The platform and FRU device drivers are uploaded to the SONiC Github open source repository. Customers can use their private SONiC patches by building and upgrading the ONIE and SONiC images on the switch.
Specifications:
Model: | QFX5200-32C |
---|---|
System Capacity | |
System throughput | Up to 6.4 Tbps (bi-directional) |
Forwarding capacity | Up to 2.4 Bpps |
QSFP+/QSFP28 ports | 32 QSFP+ or QSFP28 |
SFP+/SFP28 | 128 10GbE SFP+ through QSFP+ to SFP+ breakout cable 128 25GbE SFP28 through QSFP28 to SFP28 breakout cable |
Maximum 10GbE port density | 128 |
Maximum 25GbE port density | 128 |
Maximum 40GbE port density | 32 |
Maximum 50GbE port density | 64 |
Maximum 100GbE port density | 32 |
System Specifications | |
Dimensions (H x W x D) |
17.36 x 1.72 x 20.48 in (44.09 x 4.37 x 52.02 cm) |
Rack units | 1 U |
Weight | 23.8 lb (10.8 Kg) |
Operating system | Junos OS |
CPU | Intel Quad Core Ivy Bridge 1.8 GHz CPU, 16 GB SDRAM, 64 GB SSD |
Management and PTP interfaces |
|
Power |
|
Cooling |
|
Total packet buffer | 16 MB |
Warranty | Juniper standard one-year warranty |
Performance Scale (Unidimensional) | |
MAC addresses per system | 136,000 |
VLAN IDs | 4,096 |
Number of link aggregation groups (LAGs) | 128 |
Number of ports per LAG | 64 |
Number of FCoE VLANs/FC virtual fabrics | 4,095 |
Firewall filters |
|
IPv4 unicast routes | 128,000 prefixes; 104,000 host routes |
IPv4 multicast routes | 52,000 |
IPv6 multicast routes | 28,000 |
IPv6 unicast routes | 98,000 prefixes; 52,000 host routes |
Address Resolution Protocol (ARP) entries | 32,000 |
Generic routing encapsulation (GRE) tunnels | 1,024 |
MPLS labels | 16,000 |
MPLS IPv4 L3 VPNs (Premium Services License) | 2,048 |
Jumbo frame | 9,216 bytes |
Spanning Tree Protocol (STP) |
|
Traffic mirroring |
|
Environmental Ranges | |
Operating temperature | 32° to 104° F (0° to 40° C) |
Storage temperature | -40° to 158° F (-40° to 70° C) |
Operating altitude | Up to 10,000 (610 m) |
Relative humidity operating | 5% to 90% (noncondensing) |
Relative humidity non-operating | 5% to 95% (noncondensing) |
Seismic | Designed to meet GR-63, Zone 4 earthquake requirements |
Maximum Thermal Output | |
Maximum power draw | 480 W (AC, DC), 1,638 BTU/hr |
Typical power draw | 380 W (AC, DC), 1,296 BTU/hr |
Additional Feature Specifications:
Layer 2 Features
- STP-IEEE 802.1D (802.1D-2004)
- Rapid Spanning Tree Protocol (RSTP) (IEEE 802.1w); MSTP (IEEE 802.1s)
- Bridge protocol data unit (BPDU) protect
- Loop protect
- Root protect
- RSTP and VSTP running concurrently
- VLAN-IEEE 802.1Q VLAN trunking
- Routed VLAN Interface (RVI)
- Port-based VLAN
- MAC address filtering
- • QinQ
- VLAN Translation
- Static MAC address assignment for interface
- Per VLAN MAC learning (limit)
- MAC learning disable
- Link Aggregation and Link Aggregation Control Protocol (LACP) (IEEE 802.3ad)
- IEEE 802.1AB Link Layer Discovery Protocol (LLDP)ation and Link Aggregation Control Protocol (LACP) (IEEE 802.3ad)
Link Aggregation
- Multi-chassis link aggregation (MC-LAG)
- Redundant Trunk Group (RTG)
- LAG load sharing algorithm-bridged or routed (unicast or multicast) traffic:
- IP: SIP, Dynamic Internet Protocol (DIP), TCP/UDP source port, TCP/UDP destination port
- Layer 2 and non-IP: MAC SA, MAC DA, Ethertype, VLAN ID, source port
- FCoE packet: Source ID (SID), destination ID (DID), originator exchange ID (OXID), source port
Layer 3 Features
- Static routing
- RIP v1/v2
- OSPF v1/v2
- OSPF v3
- Filter-based forwarding
- Virtual Router Redundancy Protocol (VRRP)
- IPv6
- Virtual routers
- Unicast RPF (uRPF)
- Loop-free alternate (LFA)
- BGP (Advanced Services or Premium Services license)
- IS-IS (Advanced Services or Premium Services license)
- Dynamic Host Configuration Protocol (DHCP) v4/v6 relay
- VR-aware DHCP
- IPv4/IPv6 over GRE tunnels (interface-based with decap/ encap and firewall-based with decap only)
Multicast Features
- Internet Group Management Protocol (IGMP) v1/v2
- Multicast Listener Discovery (MLD) v1/v2
- IGMP proxy, querier
- IGMP snooping
- MLD snooping
- Protocol Independent Multicast PIM-SM, PIM-SSM, PIM-DM
- Multicast Source Discovery Protocol (MSDP)
Security and Filters
- Secure interface login and password
- RADIUS
- TACACS+
- Ingress and egress filters: Allow and deny, port filters, VLAN filters, and routed filters, including management port filters
- Filter actions: Logging, system logging, reject, mirror to an interface, counters, assign forwarding class, permit, drop, police, mark
- SSH v1, v2
- Static ARP support
- Storm control, port error disable, and autorecovery
- Control plane denial-of-service (DoS) protection
- DHCP snooping
Quality of Service (QoS)
- L2 and L3 QoS: Classification, rewrite, queuing
- Rate limiting:
- Ingress policing: 1 rate 2 color, 2 rate 3 color
- Egress policing: Policer, policer mark down action
- Egress shaping: Per queue on each port
- 10 hardware queues per port (8 unicast and 2 multicast)
- Strict priority queuing (LLQ), shaped-deficit weighted round-robin (SDWRR), weighted random early detection (WRED)
- 802.1p remarking
- Layer 2 classification criteria: Interface, MAC address, Ethertype, 802.1p, VLAN
- Congestion avoidance capabilities: WRED
- Trust IEEE 802.1p (ingress)
- Remarking of bridged packets
MPLS (Premium Services License)
- Static label-switched paths (LSPs)
- RSVP-based signaling of LSPs
- LDP-based signaling of LSPs
- LDP tunneling (LDP over RSVP)
- MPLS class of service (CoS)
- MPLS access control list (ACL)/policers
- MPLS LSR support
- IPv4 L3 VPN (RFC 2547, 4364)
- MPLS fast reroute (FRR)
Data Center Bridging (DCB)
- Priority-based flow control (PFC)-IEEE 802.1Qbb
- Data Center Bridging Exchange Protocol (DCBX), DCBx FCoE, and iSCSI type, length, and value (TLVs)
Fibre Channel over Ethernet (FCoE)
- FCoE transit switch (FIP snooping ACL installation)
- FCoE session path learning
- FCoE session health monitoring
- Graceful restart for FIP snooping
- FC-BB-6 VN2VN snooping
High Availability
- Bidirectional Forwarding Detection (BFD)
- Uplink failure detection (UFD)
Visibility and Analytics
- Switched Port Analyzer (SPAN)
- Remote SPAN (RSPAN)
- Encapsulated Remote SPAN (ERSPAN)
- Cloud Analytics Engine flow path analysis
- sFlow v5
Server Virtualization Management and SDN-Related Protocols
- Junos Space Virtual Control
- IEEE 802.1Qbg (VEPA hairpin forwarding)
Management and Operations
- Junos Space Network Director
- Role-based CLI management and access
- CLI via console, telnet, or SSH
- Extended ping and traceroute
- Junos OS configuration rescue and rollback
- Image rollback
- SNMP v1/v2/v3
- Junos XML management protocol
- High frequency statistics collection
- Beacon LED for port and system
- Automation and orchestration
- Zero Touch Provisioning (ZTP)
- OpenStack Neutron Plug-in
- Puppet
- Chef
- Python
- Junos OS event, commit, and OP scripts
Standards Compliance
IEEE Standards
- IEEE 802.1D
- IEEE 802.1w
- IEEE 802.1
- IEEE 802.1Q
- IEEE 802.1p
- IEEE 802.1ad
- IEEE 802.3ad
- IEEE 802.1AB
- IEEE 802.3x
- IEEE 802.1Qbb
- IEEE 802.1Qaz
T11 Standards
- INCITS T11 FC-BB-5
Supported RFCs
- RFC 768 UDP
- RFC 783 Trivial File Transfer Protocol (TFTP)
- RFC 791 IP
- RFC 792 ICMP
- RFC 793 TCP
- RFC 826 ARP
- RFC 854 Telnet client and server
- RFC 894 IP over Ethernet
- RFC 903 RARP
- RFC 906 TFTP Bootstrap
- RFC 951 1542 BootP
- RFC 1058 Routing Information Protocol
- RFC 1112 IGMP v1
- RFC 1122 Host requirements
- RFC 1142 OSI IS-IS Intra-domain Routing Protocol
- RFC 1256 IPv4 ICMP Router Discovery (IRDP)
- RFC 1492 TACACS+
- RFC 1519 Classless Interdomain Routing (CIDR)
- RFC 1587 OSPF not-so-stubby area (NSSA) Option
- RFC 1591 Domain Name System (DNS)
- RFC 1745 BGP4/IDRP for IP-OSPF Interaction
- RFC 1772 Application of the Border Gateway Protocol in the Internet
- RFC 1812 Requirements for IP Version 4 routers
- RFC 1997 BGP Communities Attribute
- RFC 2030 SNTP, Simple Network Time Protocol
- RFC 2068 HTTP server
- RFC 2131 BOOTP/DHCP relay agent and Dynamic Host
- RFC 2138 RADIUS Authentication
- RFC 2139 RADIUS Accounting
- RFC 2154 OSPF w/Digital Signatures (Password, MD-5)
- RFC 2236 IGMP v2
- RFC 2267 Network ingress filtering
- RFC 2328 OSPF v2 (edge mode)
- RFC 2338 VRRP
- RFC 2362 PIM-SM (edge mode)
- RFC 2370 OSPF Opaque link-state advertisement (LSA) Option
- RFC 2385 Protection of BGP Sessions via the TCP Message Digest 5 (MD5) Signature Option
- RFC 2439 BGP Route Flap Damping
- RFC 2453 RIP v2
- RFC 2474 Definition of the Differentiated Services Field in the IPv4 and IPv6 Headers
- RFC 2597 Assured Forwarding PHB (per-hop behavior) Group
- RFC 2598 An Expedited Forwarding PHB
- RFC 2697 A Single Rate Three Color Marker
- RFC 2698 A Two Rate Three Color Marker
- RFC 2796 BGP Route Reflection-An Alternative to Full Mesh IBGP
- RFC 2918 Route Refresh Capability for BGP-4
- RFC 3065 Autonomous System Confederations for BGP
- RFC 3376 IGMP v3 (source-specific multicast include mode only)
- RFC 3392 Capabilities Advertisement with BGP-4
- RFC 3446, Anycast RP
- RFC 3569 SSM
- RFC 3618 MSDP
- RFC 3623 Graceful OSPF Restart
- RFC 4271 Border Gateway Protocol 4 (BGP-4)
- RFC 4360 BGP Extended Communities Attribute
- RFC 4456 BGP Route Reflection: An Alternative to Full Mesh Internal BGP (IBGP)
- RFC 4486 Subcodes for BGP Cease Notification Message
- RFC 4724 Graceful Restart Mechanism for BGP
- RFC 4812 OSPF Restart Signaling
- RFC 4893 BGP Support for Four-octet AS Number Space
- RFC 5176 Dynamic Authorization Extensions to RADIUS
- RFC 5396 Textual Representation of Autonomous System (AS) Numbers
- RFC 5668 4-Octet AS Specific BGP Extended Community
- RFC 5880 Bidirectional Forwarding Detection (BFD)
- Configuration Protocol (DHCP) server
Supported MIBs
- RFC 1155 SMI
- RFC 1157 SNMPv1
- RFC 1212, RFC 1213, RFC 1215 MIB-II, Ethernet-Like MIB and TRAPs
- RFC 1850 OSPFv2 MIB
- RFC 1901 Introduction to Community-based SNMPv2
- RFC 2011 SNMPv2 for Internet protocol using SMIv2
- RFC 2012 SNMPv2 for transmission control protocol using SMIv2
- RFC 2013 SNMPv2 for user datagram protocol using SMIv2
- RFC 2233, The Interfaces Group MIB Using SMIv2
- RFC 2287 System Application Packages MIB
- RFC 2570 Introduction to Version 3 of the Internet-standard Network Management Framework
- RFC 2571 An Architecture for describing SNMP Management Frameworks (read-only access)
- RFC 2572 Message Processing and Dispatching for the SNMP (read-only access)
- RFC 2576 Coexistence between SNMP Version 1, Version 2, and Version 3
- RFC 2578 SNMP Structure of Management Information MIB
- RFC 2579 SNMP Textual Conventions for SMIv2
- RFC 2580 Conformance Statements for SMIv2
- RFC 2665 Ethernet-like interface MIB
- RFC 2787 VRRP MIB
- RFC 2790 Host Resources MIB
- RFC 2819 RMON MIB
- RFC 2863 Interface Group MIB
- RFC 2932 IPv4 Multicast MIB
- RFC 3410 Introduction and Applicability Statements for Internet Standard Management Framework
- RFC 3411 An architecture for describing SNMP Management Frameworks
- RFC 3412 Message Processing and Dispatching for the SNMP
- RFC 3413 Simple Network Management Protocol (SNMP)- (all MIBs are supported except the Proxy MIB)
- RFC 3414 User-based Security Model (USM) for version 3 of SNMPv3
- RFC 3415 View-based Access Control Model (VACM) for the SNMP
- RFC 3416 Version 2 of the Protocol Operations for the SNMP
- RFC 3417 Transport Mappings for the SNMP
- RFC 3418 Management Information Base (MIB) for the SNMP
- RFC 3584 Coexistence between Version 1, Version 2, and Version 3 of the Internet-standard Network Management Framework
- RFC 3826 The Advanced Encryption Standard (AES) Cipher Algorithm in the SNMP User-based Security Model
- RFC 4188 Definitions of Managed Objects for Bridges
- RFC 4318 Definitions of Managed Objects for Bridges with Rapid Spanning Tree Protocol
- RFC 4363b Q-Bridge VLAN MIB
Approvals
Safety
- CAN/CSA-C22.2 No. 60950-1 Information Technology Equipment-Safety
- UL 60950-1 Information Technology Equipment-Safety
- EN 60950-1 Information Technology Equipment-Safety
- IEC 60950-1 Information Technology Equipment-Safety (All country deviations): CB Scheme report
- EN 60825-1 Safety of Laser Products-Part 1: Equipment Classification
EMC
- FCC 47CFR, Part 15 Class A USA Radiated Emissions
- ICES-003 Class A
- EN 55022 Class A
- CISPR 22 Class A
- EN 55024
- CISPR 24
- EN 300 386
- VCCI Class A
- AS/NZA CISPR22 Class A
- KN22 Class A
- CNS 13438 Class A
- EN 61000-3-2
- EN 61000-3-3
- ETSI
- ETSI EN 300 019: Environmental Conditions & Environmental Tests for Telecommunications Equipment
- ETSI EN 300 019-2-1 (2000)-Storage
- ETSI EN 300 019-2-2 (1999)-Transportation
- ETSI EN 300 019-2-3 (2003)-Stationary Use at Weatherprotected Locations
- ETSI EN 300 019-2-4 (2003)-Stationary Use at NonWeather-protected Locations
- ETS 300753 (1997)-Acoustic noise emitted by telecommunications equipment
Environmental Compliance
- Restriction of Hazardous Substances (ROHS) 6/6
- China Restriction of Hazardous Substances (ROHS)
- Registration, Evaluation, Authorisation and Restriction of Chemicals (REACH)
- Waste Electronics and Electrical Equipment (WEEE)
- Recycled material
- 80 Plus Silver PSU Efficiency
Telco
- Common Language Equipment Identifier (CLEI) code
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Documentation:
Download the Juniper Networks QFX5200 Ethernet Switch Data Sheet (PDF).
Pricing Notes:
- All Prices are Inclusive of GST
- Pricing and product availability subject to change without notice.
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