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RG-S6510-4C 100GE Data Center Access Switch

M-LAG/VSU/de-stacking for higher availability, PFC/ECN-based lossless RDMA network with high performance

Model

RG-S6510-4C

four service slots, 25GE/100GE line cards

RG-S6510-32CQ

32×100G ports

RG-S6510-48VS8CQ

Number of IPv4/IPv6 host routing entries: 128K/64K

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Dòng RG-S6510

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Tính năng nổi bật

96 x 25GE ports and 8 x 100GE ports, 32 x 100GE ports, housed in a 2 RU enclosure for flexible networking
Cross-device link aggregation (De-stacking/M-LAG/VSU), device-level redundancy, flexible networking, and high reliability
VXLAN tunneling technology, achieving unlimited data transmission and flexible resource allocation and scheduling
Lossless Ethernet, ensuring zero packet loss during RDMA E2E communication
Telemetry/gRPC/sFlow/SPAN-based network monitoring and automated O&M, making management simple and efficient

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Features
Specifications
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Order Information

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Features

Data Center 100GE Access Switch RG-S6510-4C

100GE high-density modular access switch with 10G/25G/100GE downlink ports
96 x 25GE ports and 8 x 100GE ports, 32 x 100GE ports, housed in a 2 RU enclosure for adaptation to different scenarios

Cross-device Link Aggregation, Implementing Device-level Redundancy, Flexible Networking, and High Reliability

De-stacking

M-LAG

VSU

De-stacking technology logically aggregates multiple switches through LACP to allow servers on the same network segment or on different network segments to communicate. This eliminates the need to synchronize data between switches, without affecting service transmission.

VXLAN Tunneling Technology, Achieving Unlimited Data Transmission and Flexible Resource Allocation and Scheduling

VXLAN technology creates virtual tunnels on an IP network by building a virtual Layer 2 network, implementing cross-region and cross-DC data migration, and flexible resource allocation and scheduling. The switch supports EVPN VXLAN to enhance the number of tenants, meeting requirements of identification and isolation between different networks on a large scale.

PFC- and ECN-based Lossless Ethernet with High Throughput and Low Latency in RDMA Scenarios

With RDMA technology, data does not need to be handled by the CPU during device communication. This reduces the CPU burden
and effectively solves the network latency problem.
PFC+ECN, intelligent data exchange, and packet loss prevention, ensuring lossless data transmission

Telemetry-based Network Monitoring and Automated O&M,
Making Management Simple and Efficient

The switch enabled with telemetry provides clear data status and hierarchy.
The switch uses the push mode to proactively collect and push information and to provide sub-second-level network monitoring in real time, making network management more efficient and accurate.

Specifications

Hardware Specifications

Item	RG-S6510-4C
Dimensions (W × D × H)	442 mm x 520 mm x 86 mm (17.40 in. x 20.47 in. x 3.39 in.)
Rack height	2 RU
Unit weight	14 kg (30.86 lbs., a chassis with two power modules and three fan modules)
Switching capacity	6.4 Tbps
Packet forwarding rate	2030 Mpps
Management port	1 x RJ45 console port 1 x RJ45 MGMT port
USB port	1 x USB 2.0 port (Type A connector)
Module Slot	4 x expansion module slots 2 x power module slots 3 x fan module slots
Power consumption	Maximum power consumption: 600 W Typical power consumption: 455 W Static power consumption: 202 W
Power input	RG-PA800I-F (AC input): Rated input voltage: 100 V AC to 127 V AC, 200 V AC to 240 V AC, 50 Hz/60 Hz Maximum input voltage: 90 V AC to 140 V AC, 180 V AC to 264 V AC, 47 Hz to 63 Hz Rated input current: 10 A to 5 A (100 V AC to 240 V AC) Power port type: C14 RG-PA800I-F (HVDC input): Rated input voltage: 240 V DC Maximum input voltage: 180 V DC to 310 V DC Rated input current: 5 A Power port type: C14 RG-PD800I-F (DC input): Rated input voltage: –48 V DC Maximum input voltage: –36 V DC to –72 V DC Rated input current: 23 A Power port: three-pin power connector
Temperature	Operating temperature: 0°C to 40°C (32°F to 104°F) Storage temperature: –40°C to +70°C (–40°F to +158°F) Note: At altitudes ranging from 2000 m (6561.68 ft.) to 5000 m (16,404.20 ft.), the maximum temperature decreases by 1°C (1.8°F) for every 200 m (656.17 ft.) increase in elevation.
Humidity	Operating humidity: 10% RH to 90% RH (non-condensing) Storage humidity: 5% RH to 95% RH (non-condensing)
Altitude	Operating altitude: ≤ 5,000 m (16,404.20 ft.) Storage altitude: ≤ 5000 m (16,404.20 ft.)
Cooling	Air cooling, front-to-rear airflow (port-side intake)

Software Specifications

Item	RG-S6510-4C
Layer 2 Protocols	IEEE802.3ad (Link Aggregation Control Protocol), IEEE802.1p, IEEE802.1Q, IEEE802.1D (STP), IEEE802.1w (RSTP), IEEE802.1s (MSTP), IGMP Snooping, MLD Snooping, Jumbo Frame (9 KB), IEEE802.1ad (QinQ and selective QinQ), GVRP
Layer 3 Protocols (IPv4)	BGP4, OSPFv2, RIPv1, RIPv2, MBGP, LPM Routing, Policy-based Routing (PBR), Route-policy, Equal-Cost Multi-Path Routing (ECMP), WCMP, VRRP, IGMP v1/v2/v3, PIM-SSM/SM/DM, MSDP, Any-RP
IPv6 Basic Protocols	Neighbor Discovery, ICMPv6, Path MTU Discovery, DNSv6, DHCPv6, ICMPv6, ICMPv6 redirection, ACLv6, TCP/UDP for IPv6, SNMP v6, Ping/Traceroute v6, IPv6 RADIUS, Telnet/SSH v6, FTP/TFTP v6, NTP v6, IPv6 MIB support for SNMP, VRRP for IPv6, IPv6 QoS
IPv6 Features	Static routing, ECMP, PBR, OSPFv3, RIPng, BGP4+, MLDv1/v2, PIM-SMv6, manual tunnel, automatic tunnel, IPv4 over IPv6 tunnel, and ISATAP tunnel
Data Center Features	VXLAN routing and VXLAN bridging EVPN VXLAN IPv6 VXLAN over IPv4 PFC, ECN, and other data center features RDMA M-LAG OpenFlow 1.3
Visualization	gRPC sFLOW sampling INT
QoS	Mapping of IEEE 802.1p, DSCP, and ToS priorities ACL-based traffic classification Priority marking/remarking Multiple queue scheduling mechanisms, including SP, WRR, DRR, SP+WRR, and SP+DRR Congestion avoidance mechanisms such as WRED and tail discarding
Virtualization	Virtual Switching Unit
Buffer Management	Buffer status monitoring and management, and identification of burst traffic
HA Design	GR for RIP/OSPF/BGP, BFD, REUP dual-link fast switching and RLDP unidirectional link detection, 1+1 power redundancy, and fan redundancy, and hot swapping for all line cards and power supply modules
Security Features	Network Foundation Protection Policy (NFPP), CPP, DDoS attack defense, illegitimate data packet detection, data encryption, source IP spoofing prevention, IP scanning prevention, RADIUS/TACACS, IPv4/v6 packet filtering by basic ACL, extended ACL or VLAN-based ACL, plaintext-based and MD5 ciphertext-based authentication for OSPF, RIPv2, and BGPv4 packets, telnet login and password mechanisms for restricted IP addresses, uRPF, broadcast packet suppression, DHCP Snooping, gateway ARP spoofing prevention, and ARP check
Management Mode	SNMP v1/v2c/v3, Netconf, telnet, console, MGMT, RMON, SSHv1/v2, FTP/TFTP, NTP clock, Syslog, SPAN/RSPAN, Telemetry, ZTP, Python, fan and power supply alarm, and temperature alarm
Other Protocols	DHCP Client, DHCP Relay, DHCP Server, DNS Client, UDP relay, ARP Proxy, and Syslog

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Installation

Installation Guide

Software and Configuration

Order Information

Chassis, Fan, and Power Modules

Product Model	Description
RG-S6510-4C	Four expansion module slots, supporting hot swapping. Two power supply module slots and three fan module slots The power supply model is RG-PA800I-F, and the fan model is M6500-FAN-F.
RG-PA800I-F	Power module, supporting 1+1 redundancy, hot swapping, front-to-rear ventilation design, AC and HVDC
RG-PD800I-F	Power module, supporting 1+1 redundancy, hot swapping, front-to-rear airflow design, and LVDC
M6500-FAN-F	Fan module, supporting 2+1 redundancy, hot swapping, and front-to-rear ventilation design

Expansion Modules

Product Model

Description

M6500-08CQ

8 x QSFP28 ports

The QSFP28 port supports a speed of 40 Gbps/100 Gbps.

M6500-24VS2CQ

24 25GE SFP28 ports and two QSFP28 ports

SFP28 supports a speed of 10G/25G rates.

The QSFP28 port supports a speed of 40 Gbps/100 Gbps. One QSFP port can be split into four 10GE or 25GE ports.

25GE Optical Transceivers

Model	Description
VG-SFP-SR-SM850	25G SR optical transceiver, SFP28 form factor, LC, 850 nm, 100 m (328.08 ft.) over multimode fiber (MMF)
VG-SFP-LR-SM1310	25G LR optical transceiver, SFP28 form factor LC, 1310 nm, 10 km (32,808.40 ft.) over single-mode fiber (SMF)
VG-SFP-AOC5M	25G active optical cable (AOC), SFP28 form factor, 5 m (16.40 ft.)

40G Optical Transceivers

Model	Description
40G-QSFP-SR-MM850	40G SR optical transceiver, QSFP+ form factor, MPO, 150 m (492.13 ft.) over MMF
40G-QSFP-LR4-SM1310	40G LR4 optical transceiver, QSFP+, Duplex LC, 10 km (32,808.40 ft.) over SMF
40G-QSFP-LSR-MM850	40G SR optical transceiver, QSFP+ form factor, MPO, 400 m (1,312.34 ft.) over MMF
40G-QSFP-iLR4-SM1310	40G iLR4 optical transceiver, QSFP+, Duplex LC, 2 km (6,561.68 ft.) over SMF
40G-QSFP-LX4-SM1310	40G LX4 optical transceiver, QSFP+, Duplex LC, 150 m (492.13 ft.) over OM3/OM4 MMF, 2 km (6,561.68 ft.) over SMF
40G-AOC-30M	40G QSFP+ AOC, 30 m (98.43 ft.)
40G-AOC-5M	40G QSFP+ AOC, 5 m (16.40 ft.)

100G Optical Transceivers

Model	Description
100G-QSFP-SR-MM850	100G SR optical transceiver, QSFP28 form factor, MPO, 850 nm, 100 m (328.08 ft.) over MMF
100G-QSFP-LR4-SM1310	100G LR4 optical transceiver, QSFP28 form factor, Duplex LC, 1310 nm, 10 km (32,808.40 ft.) over SMF
100G-QSFP-iLR4-SM1310	100G iLR4 optical transceiver, QSFP28 form factor, Duplex LC, 1310 nm, 2 km (6,561.68 ft.) over SMF
100G-QSFP-ER4-SM1310	100GE ER4 optical transceiver, QSFP28 form factor, Duplex LC, 1310 nm, 40 km (131,233.60 ft.) over SMF
100G-AOC-5M	100G AOC), QSFP28 form factor, 5 m (16.40 ft.)
100G-AOC-10M	100G AOC), QSFP28 form factor, 10 m (32.81 ft.)

GE Optical Transceivers

Model	Description
GE-SFP-LH40-SM1310-BIDI	1G LH optical transceiver, SFP form factor, BIDI LC, 40 km (131,233.60 ft.) over SMF
GE-SFP-LX20-SM1310-BIDI	1G LX optical transceiver, SFP form factor, BIDI LC, 20 km (65,616.80 ft.) over SMF
GE-SFP-LX20-SM1550-BIDI	1G LX optical transceiver, SFP form factor, BIDI LC, 20 km (65,616.80 ft.) over SMF
MINI-GBIC-LH40-SM1310	1G LH optical transceiver, SFP form factor, Duplex LC, 40 km (131,233.60 ft.) over SMF
MINI-GBIC-LX-SM1310	1G LX optical transceiver, SFP form factor, Duplex LC, 10 km (32,808.40 ft.) over SMF
MINI-GBIC-SX-MM850	1G SR optical transceiver, SFP form factor, Duplex LC, 550 m (1,804.46 ft.) over MMF
MINI-GBIC-ZX80-SM1550	1G ZX optical transceiver, SFP form factor, Duplex LC, 80 km (262,467.19 ft.) over SMF

GE Copper Transceivers

Model	Description
Mini-GBIC-GT(F)	1G copper transceiver, SFP form factor, RJ45, 100 m (328.08 ft.) over Cat 5e/6/6a

10GE Optical Transceivers

Model	Description
XG-LR-SM1310	10G LR optical transceiver, SFP + form factor, Duplex LC, 10 km (32,808.40 ft.) over SMF
XG-SFP-ER-SM1550	10G ER optical transceiver, SFP + form factor, Duplex LC, 40 km (131,233.60 ft.) over SMF
XG-SFP-LR-SM1310	10G LR optical transceiver, SFP + form factor, Duplex LC, 10 km (32,808.40 ft.) over SMF
XG-SFP-SR-MM850	10G SR optical transceiver, SFP + form factor, Duplex LC, 300 m (984.25 ft.) over MMF
XG-SFP-ZR-SM1550	10G ZR optical transceiver, SFP + form factor, Duplex LC, 80 km (262,467.19 ft.) over SMF
XG-SR-MM850	10G SR optical transceiver, SFP + form factor, Duplex LC, 300 m (984.25 ft.) over MMF
XG-SFP-AOC1M	10G AOC, SFP+ form factor, 1 m (3.28 ft.)
XG-SFP-AOC3M	10G AOC, SFP+ form factor, 3 m (9.84 ft.)
XG-SFP-AOC5M	10G AOC, SFP+ form factor, 5 m (16.40 ft.)

Higher Education

5-Star Hotel Solution

RG-S6510-4C 100GE Data Center Access Switch

Data Center 100GE Access Switch RG-S6510-4C

100GE high-density modular access switch with 10G/25G/100GE downlink ports
96 x 25GE ports and 8 x 100GE ports, 32 x 100GE ports, housed in a 2 RU enclosure for adaptation to different scenarios

Cross-device Link Aggregation, Implementing Device-level Redundancy, Flexible Networking, and High Reliability

De-stacking

M-LAG

VSU

VXLAN Tunneling Technology, Achieving Unlimited Data Transmission and Flexible Resource Allocation and Scheduling

PFC- and ECN-based Lossless Ethernet with High Throughput and Low Latency in RDMA Scenarios

With RDMA technology, data does not need to be handled by the CPU during device communication. This reduces the CPU burden
and effectively solves the network latency problem.
PFC+ECN, intelligent data exchange, and packet loss prevention, ensuring lossless data transmission

Telemetry-based Network Monitoring and Automated O&M,
Making Management Simple and Efficient

The switch enabled with telemetry provides clear data status and hierarchy.
The switch uses the push mode to proactively collect and push information and to provide sub-second-level network monitoring in real time, making network management more efficient and accurate.

Higher Education

5-Star Hotel Solution

RG-S6510-4C 100GE Data Center Access Switch

Data Center 100GE Access Switch RG-S6510-4C

100GE high-density modular access switch with 10G/25G/100GE downlink ports96 x 25GE ports and 8 x 100GE ports, 32 x 100GE ports, housed in a 2 RU enclosure for adaptation to different scenarios

Cross-device Link Aggregation, Implementing Device-level Redundancy, Flexible Networking, and High Reliability

De-stacking

M-LAG

VSU

VXLAN Tunneling Technology, Achieving Unlimited Data Transmission and Flexible Resource Allocation and Scheduling

PFC- and ECN-based Lossless Ethernet with High Throughput and Low Latency in RDMA Scenarios

With RDMA technology, data does not need to be handled by the CPU during device communication. This reduces the CPU burden and effectively solves the network latency problem.PFC+ECN, intelligent data exchange, and packet loss prevention, ensuring lossless data transmission

Telemetry-based Network Monitoring and Automated O&M,Making Management Simple and Efficient

The switch enabled with telemetry provides clear data status and hierarchy.The switch uses the push mode to proactively collect and push information and to provide sub-second-level network monitoring in real time, making network management more efficient and accurate.

100GE high-density modular access switch with 10G/25G/100GE downlink ports
96 x 25GE ports and 8 x 100GE ports, 32 x 100GE ports, housed in a 2 RU enclosure for adaptation to different scenarios

With RDMA technology, data does not need to be handled by the CPU during device communication. This reduces the CPU burden
and effectively solves the network latency problem.
PFC+ECN, intelligent data exchange, and packet loss prevention, ensuring lossless data transmission

Telemetry-based Network Monitoring and Automated O&M,
Making Management Simple and Efficient

The switch enabled with telemetry provides clear data status and hierarchy.
The switch uses the push mode to proactively collect and push information and to provide sub-second-level network monitoring in real time, making network management more efficient and accurate.