Compare Products
Hide
VS
Models
Series
Highlight Features
In recent years, Ethernet interface standards have rapidly evolved from 10BASE-T and 100BASE-T to 1000BASE-T (IEEE 802.3ab), leading to widespread adoption across devices such as PCs and APs. However, as the Wi-Fi 6 technology has been introduced, APs can now deliver uplink rates of 10 Gbps, which poses a growing challenge for GE network devices. The RG-S6100 addresses this issue by offering 100M/1000M/2.5G/5G Base-T and 100M/1000M/2.5G/5G/10G Base-T Ethernet ports in auto-negotiation mode, providing better adaptability to Wi-Fi 6 APs.
Previously, PoE remote power supply scenarios only have access to PoE (IEEE 802.3af) and PoE+ (IEEE 802.3at) standards. However, if the power exceeds 30 W, users are unable to use PoE for power supply, opting instead for mains-powered cables or even high-voltage power deployment. This presents significant challenges related to deployment costs and timelines, maintenance, and security. By adhering to the IEEE802.3bt standard, the RG-S6100 offers high-power PoE power supply capabilities and achieves a maximum PoE output of 90 W through a single Ethernet port, providing a significantly improved user experience.
The RG-S6100 hardware supports both IPv4 and IPv6 dual stacks, as well as multi-layer line-rate switching in order to differentiate and process packets of each protocol effectively. With flexible IPv6 network communication solutions, the RG-S6100 can meet various IPv6 network demands such as planning or maintenance. The RG-S6100 supports a wide range of IPv4 routing protocols, covering IPv4 static routing, RIP, OSPFv2, IS-ISv4, and BGP4. Fitting for different network environments, one can select appropriate routing protocols for flexible network building. Additionally, the RG-S6100 also supports abundant IPv6 routing protocols such as IPv6 static routing, RIPng, OSPFv3, IS-ISv6, and BGP4+. These protocols can be flexibly selected to either upgrade an existing network to IPv6 or establish a new one.
The RG-S6100 supports Virtual Switching Unit (VSU). VSU enables multiple physical devices to be connected through aggregate links and virtualized into one logical device. By using the same IP address, Telnet process, and CLI for management, along with automatic version check and configuration, network administrators can manage just one logical device, thereby enhancing work efficiency.
Simplified management: The network administrator can manage multiple switches uniformly because there is no need to connect separately to each switch for configuring and managing them.
Simplified network topology: A VSU serves as a switch within a network and eliminates Layer 2 loops and MSTP configurations by connecting peripheral devices through aggregate links. Various control protocols can run on the VSU.
Fault rectification within milliseconds: A VSU connects to peripheral devices through aggregate links. If a fault occurs on one device or member link in the VSU, data and services can be switched to another member link within 30 ms.
High scalability: Devices can be added to or removed from a virtualized network, without affecting normal operation of other devices.
The RG-S6100 can effectively defend against virus spread and hacker attacks through multiple inherent mechanisms, such as DoS attack defense, IP scanning attack defense, validity check of ARP packets, and multiple hardware-based ACLs.
The hardware-based IPv6 ACL can easily control the access of IPv6 users at the network edge even if there are IPv6 users on an IPv4 network. The RG-S6100 allows IPv4 and IPv6 users to coexist and can control access permissions of IPv6 users, for example, restricting access to sensitive resources on the network.
The RG-S6100 provides a unique hardware CPU protection mechanism: CPU Protection Policy (CPP). CPP enables the RG-S6100 to classify data traffic sent to the CPU, process the traffic by queue priority, and apply the rate limit to traffic as required. CPP fully protects the CPU from being occupied by unauthorized traffic, malicious attacks, and resource consumption, which ensures the security of the CPU and the switch.
The RG-S6100 and its ports can be flexibly bound to a user’s IP address and MAC address, which strictly restricts the access of users connected to the ports or the switch.
DHCP snooping enables the RG-S6100 to receive DHCP Response messages only from trusted ports, preventing spoofing from unauthorized DHCP servers. With DHCP snooping, the RG-S6100 dynamically monitors ARP packets, checks users’ IP addresses, and discards unauthorized packets that do not match binding entries. This effectively prevents ARP spoofing and source IP address spoofing.
The RG-S6100 also supports access control through source IP address-based Telnet, which can prevent unauthorized users and hackers from maliciously attacking and controlling the switch, and enhance the network management security of the switch.
Through the Secure Shell (SSH) and Simple Network Management Protocol version 3 (SNMPv3), the RG-S6100 can encrypt management information in Telnet and SNMP processes. This ensures information security of management devices and prevents hackers from attacking and controlling the devices.
The RG-S6100 rejects unauthorized network access and enables authorized network access by employing multi-element binding, port security, time-based ACL, and data stream-based rate limiting. It can strictly control user access to enterprise networks and campus networks and restrict the communication of unauthorized users.
The RG-S6100 supports the Network Foundation Protection Policy (NFPP) to enhance its security. By isolating attack sources, NFPP can protect the processor and channel bandwidth resources of the switch. This ensures normal packet forwarding and protocol status.
The RG-S6100 supports built-in redundant power modules and fan modules. The power and fan modules are hot swappable without affecting the normal operation of the switch. The switch also provides fault detection and alarms for power and fan modules. The fan speed can be automatically adjusted based on temperature changes to better adapt to various environments. The RG-S6100 adopts the front-to-rear airflow to enhance the cooling efficiency. By using overcurrent, overvoltage, and overheating protection technologies, the RG-S6100 achieves device-level and link-level reliability protection.
The RG-S6100 supports STP (IEEE 802.1D), RSTP (IEEE 802.1w), and MSTP (IEEE 802.1s) to achieve fast convergence, improve the fault tolerance capability, and ensure stable network operation and link load balancing. The RG-S6100 effectively utilizes network channels to improve the usage of aggregate links.
The Virtual Router Redundancy Protocol (VRRP) ensures network stability for the switch.
With the Rapid Link Detection Protocol (RLDP), the RG-S6100 can quickly detect link connectivity and unidirectional optical links. Through port loop detection, the switch can prevent network failures caused by the loops that occur in the scenario where an unauthorized port is connected to hubs.
When STP is disabled, the Rapid Ethernet Uplink Protection Protocol (REUP) can still provide basic link redundancy and millisecond-level fault rectification faster than STP.
The RG-S6100 supports Bidirectional Forwarding Detection (BFD) for upper-level protocols (such as routing protocols), rapidly detecting connectivity of the forwarding path between two routing devices. BFD greatly shortens the convergence time for upper-level protocols upon link status changes.
The RG-S6100 supports IPv4 and IPv6 multicast functions as well as multiple multicast protocols, including IGMP snooping, IGMP, Multicast Listener Discovery (MLD), Protocol Independent Multicast (PIM), PIM for IPv6, and Multicast Source Discovery Protocol (MSDP). It provides multicast service support for IPv4 networks, IPv6 networks, and IPv4 and IPv6 networks.
IGMP source port check and source IP address check supported by the RG-S6100 can effectively eliminate unauthorized multicast sources and enhance network security.
The RG-S6100 can classify and control various flows, such as MAC flows, IP flows, and application flows, to implement different policies such as fine-grained bandwidth control and forwarding priority. In this way, it provides differentiated services based on applications and characteristics of service quality required by the applications.
It provides QoS guarantee based on the DiffServ model, and can filter traffic based on 802.1p priorities and IP ToS values, and from Layer 2 to Layer 7. It supports SP, WRR, and other QoS policies.
The RG-S6100 adopts the next-generation hardware architecture, and advanced energy-efficient circuit design and components, to efficiently reduce energy consumption and noise. It is equipped with variable-speed axial fan modules to intelligently control the fan speed based on the ambient temperature. This reduces power consumption and noise while ensuring stable operation of the switch.
In the networking where PoE power supply is adopted, the RG-S6100 provides automatic and energy-saving modes.
The RG-S6100 supports routine network diagnosis and maintenance based on SNMP, RMON, Syslog, and USB-based backup log and configuration. A network administrator can use various management and maintenance modes such as command line interface (CLI), web network management, and Telnet to facilitate device management.
A PoE button is available on the panel of the switch. You can press this button to check the communication status and PoE status of all ports on the switch.
Hardware Specifications |
RG-S6110-24MG4VS-UP |
RG-S6110-48MG4VS2QXS-UP |
RG-S6120-24XMG4XS4VS-UP-H |
RG-S6120-48XMG4VS2QXS-UP-H |
Interface Specifications |
||||
Fixed port |
24 x 100M/1000M/2.5GE/5GE electrical ports with auto-negotiation 4 x 10GE/25GE SFP28 ports Ports 1 to 24 support PoE/PoE+ and HPoE power supply (maximum output power of a HPoE-capable port: 90 W) |
48 x 100M/1000M/2.5GE/5GE electrical ports with auto-negotiation 4 x 10GE/25GE SFP28 + 2 x 40GE QSFP+ ports Ports 1 to 48 support PoE/PoE+ power supply (ports 1 to 24 support HPoE power supply, maximum output power of a HPoE-capable port: 90 W) |
24 x 100M/1000M/2.5GE/5GE/10GE electrical ports with auto-negotiation 4 x 10GE SFP+ ports 4 x 25GE SFP28 ports Ports 1 to 24 support PoE/PoE+ and HPoE power supply (maximum output power of a HPoE-capable port: 90 W) |
48 x 100M/1000M/2.5GE/5GE/10GE electrical ports with auto-negotiation 4 x 10GE/25GE SFP28 + 2 x 40GE QSFP+ ports Ports 1 to 48 support PoE/PoE+ power supply (ports 1 to 24 support HPoE power supply, maximum output power of a HPoE-capable port: 90 W) |
Fan module |
2 x fixed fan modules Fan speed regulating and fault alarms |
3 x fan module slots Fan speed regulating and fault alarms |
3 x fan module slots Fan speed regulating and fault alarms |
3 x fan module slots Fan speed regulating and fault alarms |
Power module |
1 x built-in power module |
2 x power module slots |
2 x power module slots |
2 x power module slots |
Fixed management port |
1 x MGMT port, 1 x console port, and 1 x USB2.0 port |
|||
System Specifications |
||||
Packet forwarding rate |
327 Mpps |
625 Mpps |
565 Mpps |
982 Mpps |
System switching capacity |
440 Gbps |
840 Gbps |
760 Gbps |
1320 Gbps |
Number of MAC addresses |
Number of global MAC addresses: 32,768 Number of static MAC addresses: 1,000 |
Number of global MAC addresses: 32,768 Number of static MAC addresses: 1,000 |
Number of global MAC addresses: 32,768 Number of static MAC addresses: 1,000 |
Number of global MAC addresses: 32,768 Number of static MAC addresses: 1,000 |
ARP table size |
16,000 |
16,000 |
16,000 |
16,000 |
ND table size |
4,000 |
4,000 |
4,000 |
4,000 |
Number of IPv4 unicast routes |
16,000 |
16,000 |
16,000 |
16,000 |
Number of IPv4 multicast routes |
4,000 |
4,000 |
4,000 |
4,000 |
Number of IPv6 unicast routes |
16,000 |
16,000 |
16,000 |
16,000 |
Number of IPv6 multicast routes |
2,000 |
2,000 |
2,000 |
2,000 |
Number of IGMP groups |
4,000 |
|||
Number of MLD groups |
1,000 |
|||
Number of ACEs |
Ingress: 2,500 Egress: 1,000 |
|||
Number of VSU members |
2 |
2 |
2 |
2 |
Dimensions and Weight |
||||
Dimensions (W x D x H) |
442 mm x 220 mm x 43.6 mm (17.40 in. x 8.66 in. x 1.72 in.) |
442 mm x 420 mm x 43.6 mm (17.40 in. x 16.54 in. x 1.72 in.) |
442 mm x 420 mm x 43.6 mm (17.40 in. x 16.54 in. x 1.72 in.) |
442 mm x 420 mm x 43.6 mm (17.40 in. x 16.54 in. x 1.72 in.) |
Weight (chassis and fan modules) |
3.65 kg (8.05 lbs) |
6.11 kg (13.47 lbs) |
6.11 kg (13.47 lbs) |
6.11 kg (13.47 lbs) |
CPU and Storage |
||||
CPU |
1.2 GHz single-core processor |
1.2 GHz single-core processor |
1.2 GHz single-core processor |
1.2 GHz single-core processor |
Storage |
1 GB DDR4 1 GB flash memory |
2 GB DDR4 1 GB flash memory |
1 GB DDR4 1 GB flash memory |
2 GB DDR4 1 GB flash memory |
Data packet buffer |
4 MB |
4 MB |
4 MB |
4 MB |
Power and Consumption |
||||
Maximum power consumption |
Without PoE: < 120 W Full PoE load: < 370 W |
Without PoE: < 240 W Full PoE load: < 1,600 W |
Without PoE: < 120 W Full PoE load: < 1,650 W |
Without PoE: < 240 W Full PoE load: < 1,600 W |
Maximum output power |
Built-in power: 460 W (370 W for PoE output power supply and 90 W for the chassis) |
RG-PA600I-P-F: 600 W (400 W/450 W for PoE output power supply and 150 W/200 W for the chassis) RG-PA1000I-P-F: 1,000 W (800 W/850 W for PoE output power supply and 150 W/200 W for the chassis) |
RG-PA600I-P-F: 600 W (400 W/450 W for PoE output power supply and 150 W/200 W for the chassis) RG-PA1000I-P-F: 1,000 W (800 W/850 W for PoE output power supply and 150 W/200 W for the chassis) |
RG-PA600I-P-F: 600 W (400 W/450 W for PoE output power supply and 150 W/200 W for the chassis) RG-PA1000I-P-F: 1,000 W (800 W/850 W for PoE output power supply and 150 W/200 W for the chassis) |
Rated input voltage |
AC input: 100 V AC to 240 V AC Frequency: 50/60 Hz Rated current per circuit: 6 A |
RG-PA600I-P-F: ● AC input: 100 V AC to 240 V AC ● Frequency: 50/60 Hz ● Rated current per circuit: 8 A RG-PA1000I-P-F: ● AC input: 100 V AC to 240 V AC ● Frequency: 50/60 Hz ● Rated current per circuit: 8 A
|
||
Maximum input voltage |
90 V AC to 264 V AC |
|||
Environment and Reliability |
||||
MTBF |
22.18 years |
27.02 years |
22.18 years |
27.02 years |
Primary airflow |
Front/Left-to-rear airflow |
Front/Left-to-rear airflow |
Front/Left-to-rear airflow |
Front/Left-to-rear airflow |
Operating temperature |
0°C to 45°C (32°F to 113°F) |
|||
Storage temperature |
–40°C to +70°C (–40°F to +158°F) |
|||
Operating humidity |
10% to 90% RH (non-condensing) |
|||
Storage humidity |
5% to 90% RH (non-condensing) |
|||
Operating altitude |
–500 m to +3000 m (–1640.42 ft. to +9842.52 ft.) |
–500 m to +3000 m (–1640.42 ft. to +9842.52 ft.) |
–500 m to +3000 m (–1640.42 ft. to +9842.52 ft.) |
–500 m to +3000 m (–1640.42 ft. to +9842.52 ft.) |
Operating noise |
Typical value: < 40 dBA@27°C (80.6°F) Maximum value < 78 dBA |
Typical value: < 60 dBA@27°C (80.6°F) Maximum value < 78 dBA |
Typical value: < 60 dBA@27°C (80.6°F) Maximum value < 78 dBA |
Typical value: < 60 dBA@27°C (80.6°F) Maximum value < 78 dBA |
Interface surge protection |
6 kV |
RG-S6100 Series |
|
Feature |
Description |
Ethernet switching |
Jumbo frame (maximum length: 9,216 bytes) |
IEEE 802.1Q (supporting 4K VLANs) |
|
Maximum number of VLANs that can be created: 4,094 |
|
Voice VLAN |
|
Super-VLAN and private VLAN |
|
MAC address-based, port-based, protocol-based, and IP subnet-based VLAN assignment |
|
GVRP |
|
Basic QinQ and selective QinQ |
|
STP (IEEE 802.1.d), RSTP (IEEE 802.1w), and MSTP (IEEE 802.1s) |
|
ERPS (G.8032) |
|
LACP (IEEE 802.3ad) |
|
LLDP/LLDP-MED |
|
IP service |
Static and dynamic ARP |
DHCP server, DHCP client, DHCP relay, and DHCP snooping |
|
DNS |
|
DHCPv6 server, DHCPv6 client, DHCPv6 relay, and DHCPv6 snooping |
|
Neighbor Discovery (ND) and ND snooping |
|
IP routing |
Static routing |
RIP and RIPng |
|
OSPFv2 and OSPFv3 |
|
GR |
|
IS-ISv4 and IS-ISv6 |
|
BGP4 and BGP4+ |
|
Equal and Weighted Cost Multi-Path (ECMP) |
|
Packet-based and flow-based load balancing |
|
Stateless Auto Configuration |
|
IPv4/IPv6 VRF |
|
IPv4/IPv6 PBR |
|
Multicast |
IGMPv1/v2/v3 and IGMP proxy |
IGMPv1/v2/v3 snooping |
|
IGMP filtering and IGMP fast leave |
|
PIM-DM, PIM-SM, and PIM-SSM |
|
PIM-SSM for IPv4 and IPv6 |
|
MSDP to achieve inter-domain multicast |
|
MLDv1/v2 |
|
MLD snooping |
|
MSDP |
|
PIM-SMv6 |
|
Multicast source IP address check Multicast source port check |
|
Multicast querier |
|
ACL and QoS |
Standard IP ACLs (hardware ACLs based on IP addresses) |
Extended IP ACLs (hardware ACLs based on IP addresses or TCP/UDP port numbers) |
|
Extended MAC ACLs (hardware ACLs based on source MAC addresses, destination MAC addresses, and optional Ethernet type) |
|
Expert-level ACLs (hardware ACLs based on flexible combinations of the VLAN ID, Ethernet type, MAC address, IP address, TCP/UDP port number, protocol type, and time range) |
|
Time-based ACLs |
|
ACL80 and IPv6 ACL |
|
Applying ACLs globally (hardware ACLs based on flexible combinations of the VLAN ID, Ethernet type, MAC address, IP address, TCP/UDP port number, protocol type, and time range) |
|
ACL redirection |
|
Port traffic identification |
|
Port traffic rate limiting |
|
802.1p/DSCP/ToS traffic classification |
|
Traffic classification based on 802.1p priorities, DSCP priorities, and IP precedences |
|
Traffic classification based on ToS values |
|
Congestion management: SP, WRR, DRR, WFQ, SP+WRR, SP+DRR, and SP+WFQ |
|
Congestion avoidance: tail drop, RED, and WRED |
|
Eight queues on each port |
|
Rate limiting in each queue |
|
Security |
Multi-AAA |
RADIUS and TACAS+ |
|
Filtering of invalid MAC addresses Broadcast storm suppression Hierarchical management of administrators and password protection BPDU guard |
|
RADIUS authentication and authorization |
|
Port- and MAC address-based 802.1x authentication |
|
IEEE802.1X authentication, MAC address bypass (MAB) authentication, and interface-based and MAC address-based 802.1X authentication |
|
Web authentication |
|
Hypertext Transfer Protocol Secure (HTTPS) |
|
SSHv1 and SSHv2 |
|
Global IP-MAC binding |
|
ICMPv6 |
|
Port security |
|
IP source guard |
|
SAVI |
|
ARP spoofing prevention |
|
CPP and NFPP |
|
Various attack defense functions including NFPP, ARP anti-spoofing, DHCP/DHCPv6 attack defense, ICMP attack defense, ND attack defense, IP scanning attack defense, and customizing attack defense packet types |
|
Loose and strict RPF uRPF ignoring default routes |
|
Reliability |
REUP |
ERPS (G.8032) |
|
Rapid Link Detection Protocol (RLDP), Layer 2 link connectivity detection, unidirectional link detection, and VLAN-based loop control |
|
Data Link Detection Protocol (DLDP) |
|
IPv4 VRRP v2/v3 and IPv6 VRRP |
|
BFD |
|
GR for RIP, OSPF, and BGP |
|
Power modules in 1+1 redundancy mode |
|
Hot swapping of power modules and fan modules (not supported by the RG-S6110-24MG4VS-UP) |
|
Device virtualization |
VSU |
NMS and maintenance |
SPAN, RSPAN, and ERSPAN |
sFlow |
|
NTP and SNTP |
|
FTP and TFTP |
|
SNMP v1/v2/c3 |
|
RMON (1, 2, 3, 9) |
|
Various types of RMON groups, including event groups, alarm groups, history groups, and statistics groups, as well as private alarm extension groups RMON used to implement Ethernet statistics, historical statistics, and alarm functions |
|
NETCONF |
|
Flow-based mirroring, and N:1 and 1:N port mirroring |
|
CWMP |
|
gRPC |
|
OpenFlow Special 1.3 Flow table analysis defined by all protocols Transmission of specified packets to the controller Configuring the controller's IP address and port Notifying port status changes to the controller |
|
CLI (Telnet/console), SSH, Syslog, SNMP over IPv6, Telnet v6, FTP/TFTP v6, DNS v6, and NTP for IPv6 |
|
Ruijie Could-based management |
Note: The item marked with the asterisk (*) will be available in the future.
Follow the steps to order an RG-S6100 multi-GE switch:
Models marked with asterisks (*) in Ordering Information will be available in the future.
The switch, expansion module, power module, and other components can be ordered as needed. Before ordering an expansion module or power module, contact the online customer service personnel for the latest support information about the module.
Model |
Description |
RG-S6110-24MG4VS-UP |
24 x 100M/1000M/2.5GE/5GE electrical ports with auto-negotiation 4 x 10GE/25GE SFP28 ports |
RG-S6110-48MG4VS2QXS-UP |
48 x 100M/1000M/2.5GE/5GE electrical ports with auto-negotiation 4 x 10GE/25GE SFP28 + 2 x 40GE QSFP+ ports |
RG-S6120-24XMG4XS4VS-UP-H
|
24 x 100M/1000M/2.5GE/5GE/10GE electrical ports with auto-negotiation 4 x 10GE SFP+ ports 4 x 25GE SFP28 ports |
RG-S6120-48XMG4VS2QXS-UP-H |
48 x 100M/1000M/2.5GE/5GE/10GE electrical ports with auto-negotiation 4 x 10GE/25GE SFP28 + 2 x 40GE QSFP+ ports |
RG-PA600I-P-F |
600 W AC power module |
RG-PA1000I-P-F |
1000 W AC power module |
RG-PA150I-F |
150 W AC power module |
Model |
Description |
Mini-GBIC-GT |
1000BASE-GT mini GBIC module |
MINI-GBIC-SX-MM850 |
1000BASE-SX, SFP transceiver, SM (850 nm, 500 m, LC). |
MINI-GBIC-LX-SM1310 |
1000BASE-LX, SFP transceiver, SM (1310 nm, 10 km, LC) |
MINI-GBIC-LH40-SM1310 |
1000BASE-LH, SFP transceiver, SM (1310 nm, 40 km, LC) |
MINI-GBIC-ZX80-SM1550 |
1000BASE-ZX80, SFP transceiver, SM (1550 nm, 80 km, LC) |
GE-SFP-LX20-SM1310-BIDI |
SFP BIDI Transceiver-TX1310/RX1550, 20 km, LC |
GE-SFP-LX20-SM1550-BIDI |
SFP BIDI Transceiver-TX1550/RX1310, 20 km, LC |
GE-SFP-LH40-SM1310-BIDI |
SFP BIDI Transceiver-TX1310/RX1550, 40 km, LC |
GE-SFP-LH40-SM1550-BIDI |
SFP BIDI Transceiver-TX1550/RX1310, 40 km, LC |
Model |
Description |
XG-SFP-SR-MM850 |
10GE LC connector module, applicable to the SFP+ port 62.5 μm/125 μm: 33 m 50 μm/125 μm: 66 m Modal bandwidth of 2000 MHz·km for a link length of up to 300 meters |
XG-SFP-LR-SM1310 |
10GE LC connector module with a link length of up to 40 km, 1310-nm wavelength, applicable to the SFP+ port |
XG-SFP-ER-SM1550 |
10GE LC connector module with a link length of up to 40 km, 1550-nm wavelength, applicable to the SFP+ port |
XG-SFP-AOC1M |
10GE SFP+ port cable, 1 m, including one cable and two interface modules |
XG-SFP-AOC3M |
10GE SFP+ port cable, 3 m, including one cable and two interface modules |
XG-SFP-AOC5M |
10GE SFP+ port cable, 5 m, including one cable and two interface modules |
Model |
Description |
VG-SFP-SR-MM850 |
25GE SR, SFP28, 850-nm wavelength, 100 m over MMF |
VG-SFP-LR-SM1310 |
25GE LR, SFP28, 1310-nm wavelength, 10 km over SMF |
VG-SFP-AOC5M |
25GE SFP+ active optical cable, 5 m, including two modules |
Model |
Description |
40G-QSFP-SR-MM850 |
40GE SR, QSFP+ transceiver, applicable to QSFP+ ports OM3 and OM4 MMF, MPO, 8-core, 850-nm wavelength, 100 m over OM3 MMF or 150 m over OM4 MMF |
40G-QSFP-LR4 SM1310 |
40GE LR4, QSFP+ transceiver, LC, 1310-nm wavelength, 2-core, 10 km over SMF, applicable to QSFP+ ports |
40G-AOC-5M |
40GE QSFP+ active optical cable, 5 m, including one cable and two interface modules |
40G-AOC-10M |
40GE QSFP+ active optical cable, 10 m, including one cable and two interface modules |
Ruijie Networks websites use cookies to deliver and improve the website experience.
See our cookie policy for further details on how we use cookies and how to change your cookie settings.
Cookie Manager
When you visit any website, the website will store or retrieve the information on your browser. This process is mostly in the form of cookies. Such information may involve your personal information, preferences or equipment, and is mainly used to enable the website to provide services in accordance with your expectations. Such information usually does not directly identify your personal information, but it can provide you with a more personalized network experience. We fully respect your privacy, so you can choose not to allow certain types of cookies. You only need to click on the names of different cookie categories to learn more and change the default settings. However, blocking certain types of cookies may affect your website experience and the services we can provide you.
Through this type of cookie, we can count website visits and traffic sources in order to evaluate and improve the performance of our website. This type of cookie can also help us understand the popularity of the page and the activity of visitors on the site. All information collected by such cookies will be aggregated to ensure the anonymity of the information. If you do not allow such cookies, we will have no way of knowing when you visited our website, and we will not be able to monitor website performance.
This type of cookie is necessary for the normal operation of the website and cannot be turned off in our system. Usually, they are only set for the actions you do, which are equivalent to service requests, such as setting your privacy preferences, logging in, or filling out forms. You can set your browser to block or remind you of such cookies, but certain functions of the website will not be available. Such cookies do not store any personally identifiable information.
Bize Ulaşın
How can we help you?
Your opinions and feelings are crucial for our improvement.
Fill in the survey