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H3C S10500X series switch is designed for the core layer of data centers and next-generation campus networks as well as the distribution layer of MANs. It provides the following features:
The S10500X series switch includes the S10506X, S10508X and S10510X models, with port density and performance to fit different deployment scales. It is your best choice to build a robust core network.
*H3Care CT Foundation Basic 9X5 NBD-Ship Service(1Y)
S10500X
H3C
New
1 Year
| Quantity: | |
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The system architecture incorporates the following advanced designs:
Clos multistage and multi-plane switching architecture: delivers great bandwidth scalability.
Orthogonal interconnection of switching fabric modules and service modules: Traffic between service modules is sent directly to the switching fabric modules through the orthogonal interconnectors, without cabling on the backplane, which significantly reduces signal loss and improves bandwidth efficiency. This design offers great bandwidth and capacity scalability, allowing the system capacity to be expanded to 100Tbps.
Compliant with 40GE and 100GE Ethernet standards: Enables the system to satisfy the growing demands of non-blocking campus networks.
Switching fabric module independency and redundancy: Independence between switching fabric modules and control engines maximizes the system availability and ensures bandwidth expansion.
Fan tray and power module redundancy: Guards the switch against unexpected fan tray and power module failures and significantly enhances system availability.
The switch innovatively uses distributed control engines, detection engines, and maintenance engines to deliver powerful control capability and millisecond-level HA.
Distributed control engines: Each service module is integrated with a strong control and processing system. It can efficiently process varieties of protocol packets and control packets, and provide refined control for protocol packets to safeguard against protocol packet attacks.
Distributed detection engines: Each service module can use BFD and OAM to detect faults in milliseconds and interact with control plane protocols for fast failover and convergence to ensure service continuity.
Distributed maintenance engines: The intelligent CPU system supports intelligent power management and online status monitoring of key components. It can power on and off modules in sequence, which reduces power impulse, electromagnetic radiation, and power consumption, and prolongs the device lifespan.
H3C Intelligent Resilient Framework 2 (IRF 2) virtualizes multiple S10500X switches into one logical switch called an IRF fabric. IRF improves system performance and delivers the following benefits:
High availability: The H3C proprietary routing hot backup technology ensures redundancy and backup of all information on the control and data planes and non-stop Layer 3 data forwarding in an IRF 2 fabric. It also eliminates single point of failure and ensures service continuity.
Redundancy and load balancing: The distributed link aggregation technology supports load sharing and mutual backup among multiple uplinks, which enhances the network redundancy and improves link resources usage.
Simplified topology and easy management: An IRF fabric appears as one node and is accessible at a single IP address on the network. This simplifies network device and topology managements, improves operating efficiency, and reduces maintenance cost.
The switch offers a wide range of solutions for data center virtualization and network convergence, including:
TRansparent Interconnection of Lots of Links (TRILL): Combine the simplicity and flexibility of Layer 2 switching with the stability, scalability, and rapid convergence capability of Layer 3 routing, to provide highest port density and flat network topology for addressing massive server accesses at data centers.
Virtual eXtensible LAN (VXLAN): A MAC-in-UDP technology that provides Layer 2 connectivity between distant network sites across an IP network. It also enables service isolation between different tenants.
Edge Virtual Bridging (EVB): Uses the Virtual Ethernet Port Aggregator (VEPA) mode to switch traffic of VMs to a physical switch connected to the server for processing. This not only ensures traffic forwarding between VMs, but also enables VM traffic policing and access control policy deployment.
Fibre Channel over Ethernet (FCoE): Integrates heterogeneous LANs and storage networks in data centers. In conjunction with Converged Enhanced Ethernet (CEE), FCoE combines the frontend network with the backend networking architecture, and integrates data, computing, and storage networks in data centers, to significantly reduce the costs for building and expanding data centers.
MP-BGP EVPN (Multiprotocol Border Gateway Protocol Ethernet Virtual Private Network) uses standard-based BGP protocol as the control plane for VXLAN overlay networks, providing BGP based VTEP auto peer discovery and end-host reachability information distribution. MP-BGP EVPN delivers many benefits, such as eliminating traffic flooding, reducing full mesh requirements between VTEPs via the introduction of BGP RR, achieving optimal flow-based end to end load sharing and more.
The S10500X series switch supports M-LAG, which enables links of multiple switches to aggregate into one to implement device-level link backup. M-LAG is applicable to servers dual-homed to a pair of access devices for node redundancy.
Streamlined topology: M-LAG simplifies the network topology and spanning tree configuration by virtualizing two physical devices into one logical device.
Independent upgrading: The DR member devices can be upgraded independently one by one to minimize the impact on traffic forwarding.
High availability: The DR system uses a keepalive link to detect multi-active collision to ensure that only one member device forwards traffic after a DR system splits.
The switch offers comprehensive IPv6 features, including:
IPv6 routing: IPv6 static routing, RIPng, OSPFv3, IS-ISv6, and BGP4+.
IPv4-to-IPv6 transition: IPv6 manual tunnel, 6to4 tunnel, ISATAP tunnel, GRE tunnel, and IPv4-compatible automatic tunnel configuration.
The switch supports hardware-level encryption technology MACsec (802.1AE), which is an industry-standard security technology that provides secure communication for all traffic on Ethernet links. Compared with traditional application-based software encryption technology, MACsec provides point-to-point security on Ethernet links between directly connected nodes and is capable of identifying and preventing most security threats.
Features | S10506X | S10508X | S10510X |
Switching Capacity | 60Tbps | 80Tbps | 100Tbps |
Forwarding Capacity | 18000Mpps | 24000Mpps | 30000Mpps |
MPU slots | 2 | 2 | 2 |
MPU Name | LSUM1MPUS06XEC0 | LSUM1SUPXD0 | LSUM1MPUS10XE0 |
MPU Processor | 1.8GHz 4 cores | 1.2GHz 4 cores | 1.8GHz 4 cores |
MPU Flash /SDRAM | Flash 2GB SDRAM 8GB | Flash 2GB SDRAM 8GB | Flash 2GB SDRAM 8GB |
MPU Console Ports | 1x RJ-45 1x USB console | 1x RJ-45 1x USB console | 1x RJ-45 1x USB console |
MPU MGMT Ports | 2x 10/100/1000M RJ-45 2x 1000M SFP | 2x 10/100/1000M RJ-45 2x 1000M SFP | 2x 10/100/1000M RJ-45 2x 1000M SFP |
MPU USB Port | 1 | 1 | 1 |
LPU Slots | 6 | 8 | 10 |
Switching Fabric Module Slots | 5(2 integrated in MPU) | 5 | 5(2 integrated in MPU) |
Hardware Architecture | Orthogonal CLOS | ||
Redundancy | Redundant MPUs, switching fabric modules, power modules, and fan trays | ||
Operating Environment | Temperature: 0℃ to 45℃ (32°F to 113°F) Humidity: 5% to 95% (non-condensing) | ||
Input Voltage | AC:100V~240V DC:-48V~-60V | ||
Maximum Power Consumption | 4580W | 6270W | 7670W |
MTBF(Year) | 24.83 | 27.05 | 24.58 |
MTTR(Hour) | 0.5 | 0.5 | 0.5 |
Dimension (H x W x D)/mm | 397×440×660 9RU | 620×440×660 14RU | 664×440×660 15RU |
Fully Loaded Weight | < 85 kg < 187.4 lb | < 120 kg < 264.6 lb | < 130 kg < 286.6 lb |
The system architecture incorporates the following advanced designs:
Clos multistage and multi-plane switching architecture: delivers great bandwidth scalability.
Orthogonal interconnection of switching fabric modules and service modules: Traffic between service modules is sent directly to the switching fabric modules through the orthogonal interconnectors, without cabling on the backplane, which significantly reduces signal loss and improves bandwidth efficiency. This design offers great bandwidth and capacity scalability, allowing the system capacity to be expanded to 100Tbps.
Compliant with 40GE and 100GE Ethernet standards: Enables the system to satisfy the growing demands of non-blocking campus networks.
Switching fabric module independency and redundancy: Independence between switching fabric modules and control engines maximizes the system availability and ensures bandwidth expansion.
Fan tray and power module redundancy: Guards the switch against unexpected fan tray and power module failures and significantly enhances system availability.
The switch innovatively uses distributed control engines, detection engines, and maintenance engines to deliver powerful control capability and millisecond-level HA.
Distributed control engines: Each service module is integrated with a strong control and processing system. It can efficiently process varieties of protocol packets and control packets, and provide refined control for protocol packets to safeguard against protocol packet attacks.
Distributed detection engines: Each service module can use BFD and OAM to detect faults in milliseconds and interact with control plane protocols for fast failover and convergence to ensure service continuity.
Distributed maintenance engines: The intelligent CPU system supports intelligent power management and online status monitoring of key components. It can power on and off modules in sequence, which reduces power impulse, electromagnetic radiation, and power consumption, and prolongs the device lifespan.
H3C Intelligent Resilient Framework 2 (IRF 2) virtualizes multiple S10500X switches into one logical switch called an IRF fabric. IRF improves system performance and delivers the following benefits:
High availability: The H3C proprietary routing hot backup technology ensures redundancy and backup of all information on the control and data planes and non-stop Layer 3 data forwarding in an IRF 2 fabric. It also eliminates single point of failure and ensures service continuity.
Redundancy and load balancing: The distributed link aggregation technology supports load sharing and mutual backup among multiple uplinks, which enhances the network redundancy and improves link resources usage.
Simplified topology and easy management: An IRF fabric appears as one node and is accessible at a single IP address on the network. This simplifies network device and topology managements, improves operating efficiency, and reduces maintenance cost.
The switch offers a wide range of solutions for data center virtualization and network convergence, including:
TRansparent Interconnection of Lots of Links (TRILL): Combine the simplicity and flexibility of Layer 2 switching with the stability, scalability, and rapid convergence capability of Layer 3 routing, to provide highest port density and flat network topology for addressing massive server accesses at data centers.
Virtual eXtensible LAN (VXLAN): A MAC-in-UDP technology that provides Layer 2 connectivity between distant network sites across an IP network. It also enables service isolation between different tenants.
Edge Virtual Bridging (EVB): Uses the Virtual Ethernet Port Aggregator (VEPA) mode to switch traffic of VMs to a physical switch connected to the server for processing. This not only ensures traffic forwarding between VMs, but also enables VM traffic policing and access control policy deployment.
Fibre Channel over Ethernet (FCoE): Integrates heterogeneous LANs and storage networks in data centers. In conjunction with Converged Enhanced Ethernet (CEE), FCoE combines the frontend network with the backend networking architecture, and integrates data, computing, and storage networks in data centers, to significantly reduce the costs for building and expanding data centers.
MP-BGP EVPN (Multiprotocol Border Gateway Protocol Ethernet Virtual Private Network) uses standard-based BGP protocol as the control plane for VXLAN overlay networks, providing BGP based VTEP auto peer discovery and end-host reachability information distribution. MP-BGP EVPN delivers many benefits, such as eliminating traffic flooding, reducing full mesh requirements between VTEPs via the introduction of BGP RR, achieving optimal flow-based end to end load sharing and more.
The S10500X series switch supports M-LAG, which enables links of multiple switches to aggregate into one to implement device-level link backup. M-LAG is applicable to servers dual-homed to a pair of access devices for node redundancy.
Streamlined topology: M-LAG simplifies the network topology and spanning tree configuration by virtualizing two physical devices into one logical device.
Independent upgrading: The DR member devices can be upgraded independently one by one to minimize the impact on traffic forwarding.
High availability: The DR system uses a keepalive link to detect multi-active collision to ensure that only one member device forwards traffic after a DR system splits.
The switch offers comprehensive IPv6 features, including:
IPv6 routing: IPv6 static routing, RIPng, OSPFv3, IS-ISv6, and BGP4+.
IPv4-to-IPv6 transition: IPv6 manual tunnel, 6to4 tunnel, ISATAP tunnel, GRE tunnel, and IPv4-compatible automatic tunnel configuration.
The switch supports hardware-level encryption technology MACsec (802.1AE), which is an industry-standard security technology that provides secure communication for all traffic on Ethernet links. Compared with traditional application-based software encryption technology, MACsec provides point-to-point security on Ethernet links between directly connected nodes and is capable of identifying and preventing most security threats.
Features | S10506X | S10508X | S10510X |
Switching Capacity | 60Tbps | 80Tbps | 100Tbps |
Forwarding Capacity | 18000Mpps | 24000Mpps | 30000Mpps |
MPU slots | 2 | 2 | 2 |
MPU Name | LSUM1MPUS06XEC0 | LSUM1SUPXD0 | LSUM1MPUS10XE0 |
MPU Processor | 1.8GHz 4 cores | 1.2GHz 4 cores | 1.8GHz 4 cores |
MPU Flash /SDRAM | Flash 2GB SDRAM 8GB | Flash 2GB SDRAM 8GB | Flash 2GB SDRAM 8GB |
MPU Console Ports | 1x RJ-45 1x USB console | 1x RJ-45 1x USB console | 1x RJ-45 1x USB console |
MPU MGMT Ports | 2x 10/100/1000M RJ-45 2x 1000M SFP | 2x 10/100/1000M RJ-45 2x 1000M SFP | 2x 10/100/1000M RJ-45 2x 1000M SFP |
MPU USB Port | 1 | 1 | 1 |
LPU Slots | 6 | 8 | 10 |
Switching Fabric Module Slots | 5(2 integrated in MPU) | 5 | 5(2 integrated in MPU) |
Hardware Architecture | Orthogonal CLOS | ||
Redundancy | Redundant MPUs, switching fabric modules, power modules, and fan trays | ||
Operating Environment | Temperature: 0℃ to 45℃ (32°F to 113°F) Humidity: 5% to 95% (non-condensing) | ||
Input Voltage | AC:100V~240V DC:-48V~-60V | ||
Maximum Power Consumption | 4580W | 6270W | 7670W |
MTBF(Year) | 24.83 | 27.05 | 24.58 |
MTTR(Hour) | 0.5 | 0.5 | 0.5 |
Dimension (H x W x D)/mm | 397×440×660 9RU | 620×440×660 14RU | 664×440×660 15RU |
Fully Loaded Weight | < 85 kg < 187.4 lb | < 120 kg < 264.6 lb | < 130 kg < 286.6 lb |
