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H3C CR19000 Core Routers Series
The CR19000 core router series (hereinafter referred to as the CR19000) is a set of new-generation core routers developed for service provider-level applications. It can be deployed as service providers' backbone nodes and MAN core nodes, or data centers backbone interconnection nodes. The CLOS architecture, cutting-edge optical connection technology, and Comware V7 operating system enables the CR19000 to deliver extraordinary availability and compatibility, making it an ideal choice for service providers.Features:
Ultra-large capacity and unlimited expansion
The CR19000 router adopts the most advanced fourth-generation non-blocking CLOS switching architecture, which enables data to be transmitted at a super high speed with low latency. Support for variable-length cell switching significantly improves operation efficiency of the overall cluster.
On a single CR19000 with 1800G capacity on each slot, each port can provide a capacity as high as 400Gbps. The router supports a maximum of 360 100G ports and this number will be continuously increased.
The CR19000 supports multiple cluster modes, such as back-to-back, 2+6, and 3+12, and supports cascade of up to 12 chassis. Smooth expansion from a single chassis to a cluster protects users' investment
Open architecture and SDN-oriented design
With full support for SDN, the CR19000 provides various protocol interfaces for collaboration with external systems and can communicate comprehensively with SDN controllers. This enables users to precisely control network resources on demand and greatly improves network operation efficiency.High availability and enhanced security
The CR19000 provides comprehensive high availability performance by using the following methods:Advanced distributed architecture—With separated routing, service, and switching engines, the failure of a single hardware component does not affect the operation of the whole system. The separation of control plane and service plane prevents service processing and system control from affecting each other and ensures service continuity during active/standby switchover. Support for N+M redundancy of switching fabric modules guarantees line-speed traffic forwarding during switching fabric module replacement.
Comware 7-based operating system—The control plane of the OS adopts multi cores and the Symmetrical Multi-Processing (SMP) technology to provide separate processing and running space for each software module, enabling dynamic loading and independent upgrade. Support for running specific processes on the dedicated CPU set, together with preemptive scheduling and priority settings, guarantees resources for critical services when the CPU usage is high. Distributed computing and refined management further improves system stability.
Abundant availability features—The CR19000 supports abundant availability features, including hot patching, link detection protocols NSR, GR, BFD, and NQA, fast convergence protocols IP FRR and LDP FRR, and Embedded Automation Architecture (EAA). With all these features, the CR19000 is able to provide ultra-large service capacity and ultra-fast service convergence as required by service providers in large-scale deployment.
Green design
The industry-leading environment-friendly and sustainable design greatly increases the energy efficiency and ensures smooth upgrade.The router uses cut-through ventilation aisles, which brings much higher cooling efficiency than the traditional U-shaped, Z-shaped, or C-shaped air isles. This design enables the air to flow through the router with almost no loss in air volume and speed and can fully satisfy the cooling requirements of core network devices with continuously increasing capacity.
With the smart micro-module heat dissipation system, the router perfectly balances ventilation and power consumption. The cluster system can intelligently adjust the fan speed based on the hotspot information to meet the overall ventilation requirements.
Technical Specification:
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Item |
CR19000-8 |
CR19000-8 back-to-back cluster |
CR19000-16 |
CR19000-20 |
CR19000-20 3+12 cluster |
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MPU slots |
2 |
N/A |
2 |
2 |
N/A |
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Switching fabric slots |
6 |
N/A |
6 |
8 |
N/A |
|
line-card slots |
8 |
16 |
16 |
20 |
240 |
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Switching capacity |
43.2 Tbps |
86.4 Tbps |
86.4 Tbps |
172.8 Tbps |
1555.2 Tbps |
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System aggregated throughput |
14.4 Tbps |
28.8 Tbps |
28.8 Tbps |
36 Tbps |
432 Tbps |
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Power module |
8 power modules per chassis support for redundancy and smart power management |
16 power modules support for redundancy and smart power management |
24 power modules per chassis support for redundancy and smart power management |
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Fan trays |
6 fan trays per chassis support for redundancy and smart heat dissipation |
2 fan trays support for redundancy and smart heat dissipation |
33 fan trays per chassis support for redundancy and smart heat dissipation |
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Dimensions (H × W × D) |
843 × 440 × 743 mm (33.19 × 17.32 × 29.25 in), 19 RU |
931 × 440 × 857 mm (36.65 × 17.32 × 33.74 in), 21 RU |
1820 × 440 × 850 mm (71.65 × 17.32 × 33.46 in), 41 RU |
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Operating temperature |
0°C to 45°C (32°F to 113°F) |
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Operating humidity |
5% to 95%, non-condensing |
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Operatingaltitude |
–60 m (–196.85 ft) to +5000 m (+16404.20 ft) |
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Ports |
1000BASE-X-SFP fiber ports 10GBASE-R/W-SFP+ fiber ports 40GBASE-R-QSFP+ fiber ports 100GBASE-R-CFP2 fiber ports 100GBASE-R-QSFP28 fiber ports POS-OC192c/STM64c-XFP fiber ports POS-OC48c/OC12c/OC3c-SFP fiber ports |
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EMC standards |
FCC Part 15 (CFR 47) CLASS A ICES-003 CLASS A VCCI-3 CLASS A VCCI-4 CLASS A CISPR 22 CLASS A EN 55022 CLASS A AS/NZS CISPR22 CLASS A CISPR 24 EN 55024 EN 61000-3-2 EN 61000-3-3 EN 61000-6-1 ETSI EN 300 386 EN 301 489-1 EN 301 489-17 |
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Safety standards |
UL 60950-1 CAN/CSA C22.2 No 60950-1 IEC 60950-1 EN 60950-1/A11 AS/NZS 60950 EN 60825-1 EN 60825-2 FDA 21 CFR Subchapter J GB 4943 |
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Interfaces |
GE, 10GE, 40GE, and 100GE interfaces OC-192c/STM-64c POS interfaces POS-OC48c/OC12c/OC3c-SFP interfaces |
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Data link layer |
PPP, HDLC Ethernet link aggregation, port mirroring DLDP |
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QinQ |
VLAN termination |
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Traffic statistics |
Traffic statistics on both the incoming and outgoing traffic |
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QoS |
Priority marking/remarking CAR (Ingress/Egress) CBQ Congestion management Queue scheduling QoS policy (applied on an interface, globally, and on the control plane) Dynamic modification of QoS policies QPPB |
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ACL |
Ingress/Egress ACL Basic ACLs, advanced ACLs Applying an ACL to an interface or globally |
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IPv4 protocol |
TCP, UDP, RawIP, Ping, Traceroute Telnet, FTP, TFTP ICMPv4 DNS DHCP NTP ARP, ARP Proxy |
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IPv6 protocol |
Dual IPv4 and IPv6 protocol stacks TCP6, UDP6, RawIP6, Pingv6, Traceroute6 Telnetv6, FTPv6, TFTPv6 DNS6 ICMPv6 VRRPv3 DHCPv6 ND PMTUD (IPv6) 6PE |
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IPv4 routing protocol |
RIPv1/v2 OSPFv2 IS-IS BGPv4 IPv4 static routing/routing policy/route recursion/policy-based routing |
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IPv6 routing protocol |
RIPng OSPFv3 IS-IS6 BGPv4+ IPv6 static routing/routing policy/route recursion/policy-based routing |
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Layer 3 multicast |
Static multicast routes IPv4 intra-AS multicast routes IPv4 inter-AS multicast routes IPv4 multicast group management IPv6 intra-AS multicast routes IPv6 multicast group management Multicast VPN |
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Interconnect |
VXLAN |
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MPLS |
Basic MPLS MPLS L3VPN VPWS/VPLS 6VPE MPLS TE P2MP |
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SDN |
BGP-LS BMP Flowspec Segment routing OpenFlow PCEP |
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Device security |
Protection against data packet-based attacks Protection against protocol packet-based attacks Attack detection Protection of protocol packets Diagnosis on packet transmitting and receiving |
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Network security |
Packet validity check uRPF Packet filtering ARP attack protection Protocol-based traffic limiting NetStream |
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User security |
Device management security AAA SSH |
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Device management |
CLI management by accessing the device through console port, Telnet, or sTelnet (SSH) |
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File management |
Uploading/downloading files through FTP/TFTP Formatting files Creating, copying, deleting, saving files and directories |
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Network maintenance |
Ping TraceRoute LSP Ping/Tracert Loop detection on a port |
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Network management and monitoring |
SNMPv3 IMC LLDP/LLDP-MED MIB PTP |
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High availability |
Hot swapping of cards Redundancy of switching fabric modules Active/standby switchover Hot patching GR NSR VRRP, VRRPE BFD for VRRP/BGP/IS-IS/RIP/OSPF/static routing IP FRR |
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