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RG-S6120-48XMG4VS2QXS-UP-H Next-generation Multi-GE Switches

Diverse access rates: 10 Gbps/5 Gbps/2.5 Gbps/1 Gbps/100 Mbps
Multiple power modes: PoE/PoE+/PoE++
4 x 25GE SFP28 ports and 2 x 40GE QSFP28 ports for uplink, enabling flexible networking and high-performance campus networks

Models

Series

Highlight Features

  • 48 x 10GE/5GE/2.5GE/GE/100M Base-T Ethernet ports for access, 4 x 25GE SFP28 ports and 2 x 40GE QSFP28 ports for uplink, meeting high-bandwidth campus network demands
  • Hardware-level multi-protection, ensuring service continuity
  • VSU, realizing flexible networking and high performance
  • Network security policies and real-time monitoring, enhancing network robustness
  • Intelligent speed regulation and auto sleeping, reducing energy consumption and noise
  • Diverse network management modes, enabling simple maintenance
Multi-GE Access
Recent years have witnessed the rapid evolution of the Ethernet interface standards from 10BASE-T and 100BASE-T to 1000BASE-T (IEEE 802.3ab) that is widely applied to devices covering PCs and APs. However, as the Wi-Fi 6 technology has been introduced, APs can delivers an uplink rate of 10 Gbps, posing an increasing challenge to GE network devices. The RG-S6100 provides 100M/1000M/2.5G/5G Base-T and 100M/1000M/2.5G/5G/10G Base-T Ethernet ports in auto-negotiation mode which can better adapt to Wi-Fi 6 APs.

High-Power PoE Power Supply
In the previous scenarios of PoE remote power supply, only PoE (IEEE 802.3af) and PoE+ (IEEE 802.3at) standards are available. If the power exceeds 30 W, PoE cannot be used for power supply. Instead, power cables must be deployed for mains power supply, and even EHV power deployment is required. This imposes tremendous challenges on deployment costs and period, maintenance, and security during the deployment. In compliance with the IEEE802.3bt standard, the RG-S6100 adopts high-power PoE power supply and achieves a maximum PoE output of 90 W through a single Ethernet port to significantly improve user experience.

IPv4/IPv6 Dual-Stack Multi-Layer Switching
The hardware of the RG-S6100 supports IPv4/IPv6 dual stacks and multilayer line-rate switching to differentiate and process IPv4 and IPv6 packets. The RG-S6100 also provides flexible IPv6 network communication solutions for users to perform network planning or maintain network status quo based on various IPv6 network demands. The RG-S6100 supports a wide range of IPv4 routing protocols, covering IPv4 static routing, RIP, OSPFv2, IS-ISv4, and BGP4. You can select appropriate routing protocols to flexibly build networks based on various network environments. Meanwhile, the RG-S6100 also supports abundant IPv6 routing protocols, including IPv6 static routing, RIPng, OSPFv3, IS-ISv6, and BGP4+. A routing protocol can be selected flexibly to upgrade the live network to an IPv6 network or establish a new IPv6 network.

Virtual Switching Unit
The RG-S6100 supports Virtual Switch Unit (VSU). VSU enables multiple physical devices to be connected through aggregate links and virtualized into one logical device. The devices use the same IP address, Telnet process, and CLI for management, and support automatic version check and automatic configuration. In this context, a network administrator only manages one logical device, improving working efficiency and experience.
Simplified management: The network administrator can manage multiple switches uniformly without connecting to each switch for separate configuration and management.
Simplified network topology: A VSU serves as a switch on a network and connects to peripheral devices through aggregate links. Therefore, no Layer 2 loop occurs and MSTP configuration is not required. Various control protocols can run on the VSU.
Fault recovery 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.

Sound Security Protection Policies
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 switch 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). The CPP enables the switch to classify data traffic sent to the CPU, process the traffic by queue priority, and apply the rate limit to traffic as required. The 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 and prevent spoofing from unauthorized DHCP servers. With DHCP snooping, the switch 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 switch also supports the device access control through source IP-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 switch 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 switch 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. The RG-S6100 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, the policy can protect the processor and channel bandwidth resources of the switch. This ensures normal packet forwarding and protocol status.

High Reliability
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 Spanning Tree Protocols (IEEE 802.1D, IEEE 802.1w, and 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) effectively facilitates network stability for the switch.
With the Rapid Link Detection Protocol (RLDP), the RG-S6100 can quickly detect the link connectivity and unidirectional optical fiber links. Through port loop detection, the switch can prevent network failures caused by the loops that occurs 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 recovery 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 the upper-level protocols upon link status changes.

Powerful Multi-Service Capability
The RG-S6100 supports the 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). The switches provide multicast service support for IPv4 networks, IPv6 networks, and IPv4 and IPv6 coexistent networks.
The IGMP source port and source IP address check function supported by the RG-S6100 can effectively eliminate unauthorized multicast sources and enhance the network security.

Sound QoS Policies
The RG-S6100 is capable of classifying and controlling various flows including MAC flows, IP flows, and application flows, to implement fine-grained bandwidth control, forwarding priority, and other flow policies. Furthermore, the switch can provide services based on applications and QoS levels required by different applications.
The Differentiated Services (DiffServ) model supports IEEE 802.1p priorities, IP ToS values, traffic filtering based on Layer 2 to Layer 7 information, Strict Priority (SP), Weighted Round Robin (WRR), and other QoS policies.

Energy-Saving Design
The RG-S6100 adopts the next-generation hardware architecture, and advanced energy-efficient circuit design and components, to reduce energy consumption and noise. RG-S6100 series switches are equipped with variable-speed axial fan modules to intelligently control the fan speed based on the ambient temperature, which reduces the 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.

Easy Network Maintenance
The RG-S6100 supports SNMP, RMON, Syslog, and USB-based log and configuration backup for routine network diagnosis and maintenance. Administrators can utilize diversified management and maintenance methods, including the CLI, web-based NMS, and Telnet to facilitate device management.
A PoE button is available on the panel of the switch. You can press this button to check both communication status and PoE status of all ports on the switch.

Documents

Specifications

Hardware Specifications

Multi-GE Switch

Hardware Specifications

RG-S6110-24MG4VS-UP

RG-S6110-48MG4VS2QXS-UP

 RG-S6120-24XMG4XS4VS-UP-H

RG-S6120-48XMG4VS2QXS-UP-H

Ports

 

 

 

 

Fixed Service Port

24 x 100M/1000M/2.5GE/5GE electrical ports with auto-negotiation
4 x 10GE/25GE SFP28 ports

48 x 100M/1000M/2.5GE/5GE electrical ports with auto-negotiation
4 x 10GE/25GE SFP28 ports + 2 x 40GE QSFP28 ports

24 x 100M/1000M/2.5GE/5GE/10GE electrical ports with auto-negotiation

4 x 1G/10GE SFP+ ports

4 x 10G/25G QSFP28 ports

 

48 x 100M/1000M/2.5GE/5GE/10GE electrical ports with auto-negotiation
4 x 10GE/25GE SFP28 ports + 2 x 40GE QSFP28 ports

Module Slot

Built-in power module

2 x fixed fan modules

2 x power module slots

3 x fan module slots

2 x power module slots

3 x fan module slots

2 x power module slots

3 x fan module slots

Fixed Management Port

1 x MGMT port

1 x console port

1 x USB port

1 x MGMT port

1 x console port

1 x USB port

1 x MGMT port

1 x console port

1 x USB port

1 x MGMT port

1 x console port

1 x USB port

System

 

 

 

 

Switching Capacity

2.56 Tbps/25.6 Tbps

2.56 Tbps/25.6 Tbps

2.56 Tbps/25.6 Tbps

2.56 Tbps/25.6 Tbps

Packet Forwarding Rate

(Actual)

327 Mpps

625 Mpps

565 Mpps

982Mpps

Power Supply and Consumption

 

 

 

 

Typical Power Consumption

Without PoE: < 110 W (Total power consumption of all modules)

Full PoE load: < 370 W (Total power consumption of all modules)

Without PoE: < 200 W (Total power consumption of all modules)

Full PoE load: < 1600 W (Total power consumption of all modules)

Without PoE: < 150 W (Total power consumption of all modules)

Full PoE load: < 1650 W (Total power consumption of all modules)

Without PoE: < 200 W (Total power consumption of all modules)

Full PoE load: < 1600 W (Total power consumption of all modules)

Power Module Model

Built-in power module

RG-PA600I-P-F

RG-PA1000P-F

RG-PA600I-P-F

RG-PA1000P-F

RG-PA600I-P-F

RG-PA1000P-F

Rated Input Voltage

Built-in power module

AC input

Rated voltage range: 100 V AC to 240 V AC

Maximum voltage range: 90 V AC to 264 V AC

Frequency: 50/60 Hz

Rated current per circuit: 6 A

Available model: RG-PA600I-P-F

AC Input

Rated voltage range: 100 V AC to 240 V AC

Maximum voltage range: 90 V AC to 264 V AC

Frequency: 50/60 Hz

Rated current per circuit: 8 A

 

Available model: RG-PA1000I-P-F

AC Input

Rated voltage range: 100 V AC to 240 V AC

Maximum voltage range: 90 V AC to 264 V AC
Frequency: 50/60 Hz

Rated current per circuit: 8 A

Available model: RG-PA600I-P-F

AC Input

Rated voltage range: 100 V AC to 240 V AC

Maximum voltage range: 90 V AC to 264 V AC

Frequency: 50/60 Hz

Rated current per circuit: 8 A

 

Available model: RG-PA1000I-P-F

AC Input

Rated voltage range: 100 V AC to 240 V AC

Maximum voltage range: 90 V AC to 264 V AC
Frequency: 50/60 Hz

Rated current per circuit: 8 A

Available model: RG-PA600I-P-F

AC Input

Rated voltage range: 100 V AC to 240 V AC

Maximum voltage range: 90 V AC to 264 V AC

Frequency: 50/60 Hz

Rated current per circuit: 8 A

 

Available model: RG-PA1000I-P-F

AC Input

Rated voltage range: 100 V AC to 240 V AC

Maximum voltage range: 90 V AC to 264 V AC
Frequency: 50/60 Hz

Rated current per circuit: 8 A

Maximum Input Voltage

 

 

 

 

PoE-capable Port

Ports 1 to 24 support PoE/PoE+ and HPoE power supply
Maximum output power of a HPoE-capable port: 90 W

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

Ports 1 to 24 support PoE/PoE+ and HPoE power supply
Maximum output power of a HPoE-capable port: 90 W

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 alarming

3 x hot swappable fan modules

Fan speed regulating and fault alarming

3 x hot swappable fan modules

Fan speed regulating and fault alarming

3 x hot swappable fan modules

Fan speed regulating and fault alarming

Environment and Reliability

 

 

 

 

Surge Protection

6 kV

6 kV

6 kV

6 kV

Temperature Monitoring

Temperature alarm

Temperature alarm

Temperature alarm

Temperature alarm

Operating Temperature

0°C to 45°C (32°F to 113°F)

0°C to 45°C (32°F to 113°F)

0°C to 45°C (32°F to 113°F)

0°C to 45°C (32°F to 113°F)

Storage Temperature

–40°C to +70°C (–40°F to +158°F)

–40°C to +70°C (–40°F to +158°F)

–40°C to +70°C (–40°F to +158°F)

–40°C to +70°C (–40°F to +158°F)

Operating Humidity

10% RH to 90% RH (non-condensing)

10% RH to 90% RH (non-condensing)

10% RH to 90% RH (non-condensing)

10% RH to 90% RH (non-condensing)

Storage Humidity

5% RH to 95% RH (non-condensing)

5% RH to 95% RH (non-condensing)

5% RH to 95% RH (non-condensing)

5% RH to 95% RH (non-condensing)

 

 

Software Specifications

Software Specifications

RG-S6110-24MG4VS-UP

RG-S6110-48MG4VS2QXS-UP

 RG-S6120-24XMG4XS4VS-UP-H

RG-S6120-48XMG4VS2QXS-UP-H

VLAN

4K IEEE 802.1Q VLAN

Port-based VLAN

Private VLAN

GVRP

Super VLAN

QinQ

Basic QinQ and selective QinQ

Link Aggregation

LACP (IEEE 802.3ad)

Port Mirroring

Traffic mirroring

Many-to-one mirroring and one-to-many mirroring

RSPAN

Link aggregation mirroring

Spanning Tree Protocols

STP, RSTP, and MSTP

DHCP

DHCP Server

DHCP Client

DHCP Snooping

DHCP Relay

IPv6 DHCP Snooping

IPv6 DHCP Client

IPv6 DHCP Relay

Basic IPv6 Protocols

IPv6 addressing, ICMPv6, and Path MTU Discovery

IP Routing

Static routing

RIP and RIPng

OSPFv2, OSPFv3, IS-ISv4, and IS-ISv6

BGP4 and BGP4+

ECMP

Multicast

IGMP v1/v2/v3 and IGMP proxy

IGMP v1/v2/v3

IGMP filtering and IGMP fast leave

PIM-DM, PIM-SM, and PIM-SSM

MLD Snooping and MLD

MSDP

ACL

The following flexible and diversified hardware ACLs are supported:

Standard IP ACLs (IP-based hardware ACLs)

Extended IP ACLs (hardware ACLs based on IP addresses or TCP/UDP port IDs)

MAC-based extended ACLs (hardware ACLs based on source MAC addresses, destination MAC addresses, and optional Ethernet type)

Time-based ACLs

Expert ACLs (hardware ACLs based on flexible combinations of the VLAN ID, Ethernet type, MAC address, IP address, TCP/UDP port ID, protocol type, and time)

ACL80

IPv6 ACL

QoS

Port traffic identification

Port traffic rate limiting

802.1p/DSCP/ToS traffic classification

Eight priority queues per port

SP, WRR, DRR, SP+WRR, SP+DRR, and RED/WRED queue scheduling

Security Features

Filtering of invalid MAC addresses

Broadcast storm suppression

Hierarchical management of administrators and password protection

RADIUS and TACAS+

SSH

BPDU Guard

CPP and NFPP

Management Features

SNMP, CLI (Telnet/Console), RMON (1,2,4,9), Syslog, NTP, SNMP over IPv6, IPv6 MIB support for SNMP, Telnet v6, FTP/TFTP v6, DNS v6, NTP for v6, Traceroute v6

sFlow, using the random sampling technology to conduct flow information sampling on the traffic of a switch

High Reliability

VSU (virtualizing multiple devices into one device)
GR for RIP, OSPF, BGP
BFD
REUP
RLDP
1+1 power redundancy
Hot swapping of power and fan modules

Order Information

Follow the steps to order a RG-S6100 multi-GE switch:

  • Select a model of RG-S6100 series switches. The device is fully equipped with fan modules that do not need to be purchased separately.
  • Select power modules based on switch models. At least one power module is required.
  • Select optical modules based on optical interfaces of the switch.

Models marked with asterisks (*) in the ordering information are available later.

Switch and Power 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

fixed AC power supply and  fans

RG-S6110-48MG4VS2QXS-UP

48 x 100M/1000M/2.5GE/5GE electrical ports with auto-negotiation, support PoE/PoE+/PoE++(25-48 ports only support PoE/PoE+)
4 x 10GE/25GE SFP28 + 2 x 40GE QSFP28 ports

2 modular power supply slots (at least one RG-PA600I-P-F/ RG-PA1000I-P-F power module needed,no power module in default),3 modular fan slots (3 fan modules are equipped by default)

 RG-S6120-24XMG4XS4VS-UP-H

24 x 100M/1000M/2.5GE/5GE/10GE electrical ports with auto-negotiation, support PoE/PoE+/PoE++

4 x 1G/10GE SFP+ ports ,4 x 10G/25G QSFP28 ports

2 modular power supply slots (at least one RG-PA600I-P-F or RG-PA1000I-P-F power module needed,no power module in default),3 modular fan slots (3 fan modules are equipped by default)

RG-S6120-48XMG4VS2QXS-UP-H

48 x 100M/1000M/2.5GE/5GE/10GE electrical ports with auto-negotiation, support PoE/PoE+/PoE++(25-48 ports only support PoE/PoE+)
4 x 10GE/25GE SFP28 + 2 x 40GE QSFP28 ports

2 modular power supply slots (at least one RG-PA600I-P-F/ RG-PA1000I-P-F power module needed,no power module in default),3 modular fan slots (3 fan modules are equipped by default)

RG-PA600I-P-F

600 W AC power module

RG-PA1000I-P-F

1000 W AC power module

 

GE Optical Module

Model

Description

Mini-GBIC-GT

1000BASE-GT mini GBIC module

 

10GE Optical Module

Model

Description

XG-SFP-SR-MM850

10GE SR, SFP+ transceiver, LC, 850-nm wavelength, applicable to SFP+ port
62.5 μm/125 μm : 33 m over MMF
50 μm/125 μm: 66 m over MMF
2000 MHz·km: 300 m over MMF

XG-SFP-LR-SM1310

10GE LR, SFP+ transceiver, LC, 1310-nm wavelength, 10 km over SMF, applicable to SFP+ ports

XG-SFP-ER-SM1550

10GE ER, SFP+ transceiver, LC, 1550-nm wavelength, 40 km over SMF, applicable to SFP+ ports

XG-SFP-AOC1M

10GE SFP+ active optical cable, 1 m, including one cable and two interface modules

XG-SFP-AOC3M

10GE SFP+ active optical cable, 3 m, including one cable and two interface modules

XG-SFP-AOC5M

10GE SFP+ active optical cable, 5 m, including one cable and two interface modules

 

25GE Optical Module

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

 

40GE Optical Module

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

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