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Podrobnosti produktu HPE Aruba Networking CX 5420 6-slot Switch:
HPE Aruba Networking CX 5420 Switch Series
HPE Aruba Networking CX 5420 chassis switches are modern, flexible, intelligent, and modular making them optimal for access, small core, and aggregation deployments. Designed for operational efficiency, CX 5420 chassis switches feature built-in MACsec* hardware capability, analytics, and automation - providing an enterprise-class access layer solution that's easy-to-deploy, simple, secure, and resilient.
Part of the HPE Aruba Networking CX switching portfolio, CX 5420 chassis switches were built from the ground up with cutting-edge hardware, software, and analytics and automation tools, and are ideal for small and medium campus and branch networks.
CX 5420 chassis switches combine a modern, fully programmable OS with the HPE Aruba Networking Network Analytics Engine for superior monitoring and troubleshooting capabilities across the network.
A powerful HPE Aruba Networking Gen7 ASIC architecture delivers performance and feature support with flexible programmability for tomorrow's applications. The HPE Aruba Networking Virtual Switching Extension (VSX) with live upgrades provides high availability, fast, non-disruptive upgrades, and simplified management. This advanced modular 4U chassis switch offers performance up to 960 Gbps with low latency, six half-width line card slots with line rate up to 64 bytes, and up to 90 W Smart Rate 10 GbE PoE. The Layer 3 chassis provide BGP/OSFP/RIP/PIM support with single data-plane VRF and management VRF.
HPE Aruba Networking Dynamic Segmentation extends HPE Aruba Networking's wireless role-based policy capability to HPE Aruba Networking wired switches. This means the same security, user experience, and simplified IT management is uniform throughout the network. Regardless of how users and IoT devices connect, consistent policies are enforced across wired and wireless networks, keeping traffic secure and separate.
Key features
Powerful, modular, intelligent Layer 3 chassis switch with BGP, VSX, OSPF and robust QoS
High performance switching with up to 960 Gbps in non blocking bandwidth and up to 714 Mpps for forwarding
High availability VSX live upgrades, redundant power supplies, and N+1 redundant fans
High capacity HPE Smart Rate 10GbE multi-gigabit for up to 90W Class-8 PoE
High speed 6-line card slots with up to 160 Gb/s forwarding per slot, line rate at 64 bytes
Intelligent monitoring, visibility, and remediation with HPE Aruba Networking Network Analytics Engine (NAE)
Single pane of glass management with HPE Aruba Networking Central across wired, wireless, and WAN
Support for automated configuration and verification with HPE Aruba Networking NetEdit. Secure and simple access for users and IoT devices via HPE Aruba Networking Dynamic Segmentation
Standard Features
Product Differentiators
The HPE Aruba Networking CX 5420 Switch Series is based on the HPE Aruba Networking CX Operating System (AOS-CX), a modern, database-driven operating system that automates and simplifies many critical and complex network tasks.
A built-in time series database to utilize software scripts for historical troubleshooting and analysis of past trends. This helps predict and avoid future problems caused by scale, security, and performance bottlenecks.
AOS-CX is built on a modular Linux architecture with a stateful database, providing it the following capabilities:
Easy access to all network state information allows unique visibility and analytics
REST APIs and Python scripting for fine-grained programmability of network tasks
A microservices architecture that enables full integration with other workflow systems and services
Continual state synchronization for superior fault tolerance and high availability
Continuous telemetry data with WebSocket subscriptions for event-driven automation
Software processes that communicate with the database rather than each other, ensuring near real-time state and resiliency and allowing individual software modules to be independently upgraded for higher availability
Every CX switch includes AOS-CX at no cost and an active, perpetual set of native features, providing everything needed to deploy, connect, and troubleshoot an enterprise network, including:
Network Analytics Engine (NAE)
Dynamic Segmentation
High availability and resiliency
Quality of Service (QoS)
Layer 2 switching
Layer 3 services and routing
IP Multicast
Network security
Support for NetEdit software
HPE Aruba Networking Central - unified single pane of glass management
HPE Aruba Networking Central is an AI-powered solution that simplifies IT operations, improves agility, and reduces costs by unifying management of all network infrastructure. Built for enterprise-grade resiliency and security, while simple enough for smaller businesses with limited IT staff, Central is your single point of visibility and control that spans the entire network-from branch to data center, wired and wireless LAN to WAN.
Available as a cloud-based or an on-premises solution, HPE Aruba Networking Central simplifies Day 0 through Day 2 operations. It offers streamlined workflows for virtual switch stack creation, automated monitoring using AI-powered insights and NAE, and a unified view of all devices and users, both wired and wireless. Comprehensive switch management capabilities include configuration, on boarding, monitoring, troubleshooting, and reporting.
An HPE Aruba Networking Central Advanced license expands these capabilities with premium security and AIOps, including the HPE Aruba Networking Central NetConductor Fabric Wizard and Policy Manager to enable dynamic segmentation.
With the HPE Aruba Networking Central Advanced license there is no need to purchase a CX Advanced license. This streamlines operational efficiency, reducing the need to keep track of multiple licenses, active terms, and renewal dates. For more information on HPE Aruba Networking Central licensing, see the HPE Aruba Networking Central SaaS Subscription Ordering Guide.
The HPE Aruba Networking Network Analytics Engine (NAE) automatically monitors and analyzes events that can impact network health, enhancing visibility and troubleshooting. Advanced telemetry and automation provide easy identification and troubleshooting of network, system, application, and security related issues., using Python agents, CLI-based agents, and REST APIs.
The Time Series Database (TSDB) stores configuration and operational state data, to quickly resolve network issues. The data may also be used to analyze trends, identify anomalies, and predict future capacity requirements.
HPE Aruba Networking Central uses NAE and agents to deliver switch monitoring, analytics, and enhanced troubleshooting for wired assurance. HPE Aruba Networking NetEdit and third-party tools such as ServiceNow and Slack provide intelligence to integrate NAE alerts into IT service management processes, speeding problem resolution
HPE Aruba Networking NetEdit - automated switch configuration and management
The HPE Aruba Networking CX portfolio can orchestrate multiple switch configuration changes for smooth end-to-end service rollouts. HPE Aruba Networking NetEdit introduces automation for rapid network-wide changes and ensures policy conformance for post-network updates. Intelligent capabilities include search, edit, validation (including conformance checking), deployment, and audit features.
Centralized configuration with validation for consistency and compliance
Simultaneous viewing and editing of multiple configurations to save time
Customized validation tests for corporate compliance and network change analysis
Automated large-scale configuration deployment without programming
Visibility into network health and topology via HPE Aruba Networking NAE integration
Notes: A separate software license is required to use NetEdit.
HPE Aruba Networking CX Mobile App - true deployment convenience
This easy-to-use mobile app simplifies connecting and managing HPE Aruba Networking CX 5420 chassis switches for any size project. Switch information can also be imported into HPE Aruba Networking NetEdit for simplified configuration management and to continuously validate conformance of configurations anywhere in the network.
With over 30 years of continuous investment, HPE Aruba Networking's ASICs form the basis for innovative and agile software feature advancements, improved performance, and deep visibility. These programmable ASICs are purpose built for a tighter integration of switch hardware and software within campus and data center architectures to optimize performance and capacity. Flexible ASIC resources enable HPE Aruba Networking's NAE solution to inspect all data, for superior analytics capabilities. The HPE Aruba Networking CX 5420 chassis switch is based on HPE Aruba Networking Gen7 ASIC architecture.
HPE Aruba Networking Dynamic Segmentation - campus and branch fabric
Providing seamless mobility, consistent policy enforcement, and automated configurations, HPE Aruba Networking Dynamic Segmentation is ideal for wired and wireless clients for networks of all sizes. It unifies role-based access and policy enforcement across LAN, WLAN, and SD-WAN networks with centralized policy definition and dedicated enforcement points. This ensures that users and devices can only communicate with destinations consistent with their role, keeping traffic secure and separate. Dynamic Segmentation establishes least privilege access to IT resources by segmenting traffic based on identity, a fundamental concept of both zero trust and SASE frameworks, which base trust on roles and policies, not on where and how a user or device connects.
The solution begins with colorless ports and role-based microsegmentation technologies. Colorless ports allow wired clients to connect to any switch port, using RADIUS-based control to automate configuration. This eliminates the need for manual onboarding of clients, including IoT devices, onto the network.
Role-based microsegmentation reduces subnet and VLAN sprawl, simplifies policy definition and employs client user roles for scalable policy enforcement. Independent of network constructs such as VLANs and VRFs, clients can be grouped into user roles based on their identity, which extends the colorless ports to the centralized overlay fabric. This enables client onboarding using automatic tunnel creation based on the associated user roles policy. The user roles policy provides a choice between microsegmentation (using centralized and unified policy enforcement for wireless and wired traffic with Layer 7 stateful firewall on gateways) or a distributed approach (using Layer 4 role-role ACL on switches).
Dynamic Segmentation enables scale and flexibility in network design by stretching VLANs and subnets across the network using VXLAN overlay fabric with Group Based Policy tagging to transport source role. The CX 5420 chassis switch attaches to the VXLAN Fabric as an Extended-Edge VTEP with static VXLAN to stub VTEP.
This switch series supports VXLAN-GBP-based policies to enable role-based microsegmentation. and when used in a HPE Aruba Networking Central NetConductor extended-edge campus solution, forms static VXLAN-GBP tunnels to fabric edge devices.
Mobility and IoT performance
The HPE Aruba Networking CX 5420 chassis switch uses the latest HPE Aruba Networking Gen7 ASICs. This ensures very low latency, increased packet buffering, and adaptive power consumption. Wire speed switching and routing ensure the demands of bandwidth-intensive applications are met today and in the future. Each switch includes the following:
Up to 960 Gbps non-blocking bandwidth and up to 714 Mpps for forwarding available.
Selectable queue configurations that increase performance by defining the number of queues and buffer associated memory.
Support for pre-standard PoE detection to power legacy PoE devices
Support for Energy Efficient Ethernet IEEE 802.3az to reduce power consumption during low network traffic periods
Auto-MDIX for automatic adjustments to straight- through or crossover cables on
10/100/1000, Smart Rate, and 10GBASE-T ports
Unsupported Transceiver Mode (UTM) to insert and enable all unsupported 100M through 25G transceivers and cables. (No warranty or support for the transceiver/cable is provided when this feature is used)
IPv6 capabilities include:
- IPv6 host to manage switches in an IPv6 network
- Dual stack (IPv4 and IPv6) transitions from IPv4 to IPv6, supporting connectivity for both protocols
- MLD snooping to forward IPv6 multicast traffic to the appropriate interface
- IPv6 ACL/QoS supports ACL and QoS for IPv6 network traffic
- IPv6 routing supports Static, MP-BGP, RIPng, and OSPFv3 protocols
- Security for RA guard, DHCPv6 protection, dynamic IPv6 lockdown, ND snooping, IPv6 Destination Guard, IPv6 DHCP Guard, and IPv6 Router Advertisement Guard
Jumbo frames for high-performance backups and disaster-recovery systems with a maximum frame size of 9198 bytes
Packet storm protection against broadcast and multicast storms with user-defined thresholds
Smart link for simple, fast-converging link redundancy and load balancing with dual uplinks to avoid Spanning Tree complexities
High availability and resiliency
To maximize uptime we offer high availability and multicast features for Layer 3 deployments, including:
Hot swappable power supplies
- N+1 and N+N redundancy for high reliability in case of power line or supply failure
- Up to 4 power supplies to increase total available PoE power
Virtual Router Redundancy Protocol (VRRP) allows groups of two routers to dynamically create highly available routed environments in IPv4 and IPv6 networks
Uni-directional Link Detection (UDLD) to monitor link connectivity and shut down ports at both ends if uni-directional traffic is detected, preventing loops in STP-based networks
IEEE 802.3ad LACP supports up to 144 LAGs, each with up to 16 links per LAG, providing support for static or dynamic groups and a user-selectable hashing algorithm
IEEE 802.1s Multiple Spanning Tree for high link availability in VLAN environments (where multiple spanning trees are required) and legacy support for IEEE 802.1d and IEEE 802.1w
IEEE 802.3ad Link Aggregation Control protocol (LACP) and port trunking supports static and dynamic trunks, with each trunk supporting up to sixteen links (ports) per static trunk
Hot-patching support for standalone.
Quality of Service (QoS) features
The HPE Aruba Networking CX 5420 Series includes the following to support congestion actions and traffic prioritization:
Strict priority (SP) queuing and Deficit Weighted Round Robin (DWRR)
Traffic prioritization (IEEE 802.1p) for real-time classification
Class of Service (CoS) to set IEEE 802.1p priority tags based on IP address, IP Type of Service (ToS), Layer 3 protocol, TCP/UDP port number, source port, and DiffServ
Rate limiting sets per-port ingress enforced maximums and per-port, per-queue minimums
Per-queue limiting of transmission rates for egressing frames using Egress Queue Shaping (EQS)
Large buffers for graceful congestion management
Engine, the 5420 Switch Series offers the following:
Built-in programmable and easy to use REST API interface
Simple Day 0 provisioning
Scalable ASIC-based wire speed network monitoring and accounting with no impact on network performance, allowing network operators to gather a variety of network statistics and information for capacity planning and real-time network monitoring
Management interface control enables or disables each of the following depending on security preferences, console port, or reset button
Industry-standard CLI with a hierarchical structure for reduced training time and expense and increased productivity in multivendor environments
Management security restricts access to critical configuration commands, provides multiple privilege levels with password protection, and local and remote syslog capabilities allow logging of all access
sFlow (RFC 3176) ASIC-based wire speed provides network monitoring and accounting with no impact on network performance. so network operators can gather a variety of statistics and information for capacity planning and real-time network monitoring
Supports SNMP (v2c/v3) and a wide range of read, write, and trap capabilities for industry-standard Management Information Base (MIB), private extensions, and common use cases, such as system, port, PoE, and VLAN management
Remote monitoring (RMON) with standard SNMP to monitor essential network functions. Supports events, alarms, history, and statistics groups as well as a private alarm extension group. RMON, and sFlow provide advanced monitoring and reporting capabilities for statistics, history, alarms, and events
Support for TFTP and SFTP provides different mechanisms for configuration updates. Trivial FTP (TFTP) allows bidirectional transfers over a TCP/ IP network. Secure File Transfer Protocol (SFTP) runs over an SSH tunnel for additional security
Debug and sampler utility supports ping and traceroute for IPv4 and IPv6
Network Time Protocol (NTP) synchronizes timekeeping among distributed time servers and clients so timekeeping remains consistent among all network clock-dependent devices so devices can provide diverse applications based on the consistent time
IEEE 802.1AB Link Layer Discovery Protocol (LLDP) advertises and receives management information from adjacent devices on a network, facilitating easy mapping by network management applications
Dual flash images provide independent primary and secondary operating system files for backup while upgrading
Multiple configuration files can be stored to a flash image
Ingress and egress port monitoring enable more efficient network problem solving
Unidirectional link detection (UDLD) monitors links between two switches and blocks the ports on both ends of the link if the link goes down at any point
IP SLA for Voice monitors quality of voice traffic using the UDP Jitter and UDP Jitter for VoIP tests
Layer 2 switching
The following layer 2 services are supported:
VLAN support and tagging for IEEE 802.1Q (4094 VLAN IDs)
Jumbo packet for improved large data transfer performance; supports frame size of up to 9198 bytes
IEEE 802.1v protocol VLANs isolate select non-IPv4 protocols automatically into their own VLANs
Rapid Per-VLAN Spanning Tree (RPVST+) allows each VLAN to build a separate spanning tree to improve link bandwidth usage and is compatible with PVST+
MVRP allows automatic learning and dynamic assignment of VLANs
Bridge Protocol Data Unit (BPDU) tunnelling Transmits STP BPDUs transparently, allowing correct tree calculations across service providers, WANs, or MANs
Port mirroring duplicates port traffic (ingress and egress) to a monitoring port; supports 4 mirroring groups
STP supports standard IEEE 802.1D STP, IEEE 802.1w Rapid Spanning Tree Protocol (RSTP) for faster convergence, and IEEE 802.1s Multiple Spanning Tree Protocol (MSTP)
Internet Group Management Protocol (IGMP) controls and manages the flooding of multicast packets in a Layer 2 network
QinQ improves VLAN utilization by adding another 802.1Q tag to tagged packets
Layer 3 services
The following layer 3 services are supported:
Loopback interface address defines an address in Open Shortest Path First (OSPF), improving diagnostic capability
Address Resolution Protocol (ARP) determines the MAC address of another IP host in the same subnet and supports static ARP.; Gratuitous ARP allows detection of duplicate IP addresses. Proxy ARP allows normal ARP operation between subnets or when subnets are separated by a Layer 2 network
Dynamic Host Configuration Protocol (DHCP) simplifies the management of large IP networks and supports clients. DHCP Relay enables DHCP operation across subnets
DHCP server centralizes and reduces the cost of IPv4 address management
Domain Name System (DNS) provides a distributed database that translates domain names and IP addresses, simplifying network design and supporting client and server
Internal loopback testing for maintenance and increased availability. Loopback detection protects against incorrect cabling or network configurations and can be enabled on a per-port or per-VLAN basis for added flexibility
Route maps provide more control during route redistribution and allow filtering and altering of route metrics
Layer 3 routing
The following layer 3 routing services are supported:
Border Gateway Protocol (BGP) provides IPv4 and IPv6 routing, which is scalable, robust, and flexible
Border Gateway Protocol 4 (BGP-4) delivers an implementation of the Exterior Gateway Protocol (EGP) utilizing path vectors. It uses TCP for enhanced reliability for the route discovery process, reduces bandwidth consumption by advertising only incremental updates, supports extensive policies for increased flexibility and scales to very large networks with graceful restart capability
Multi-protocol BGP (MP-BGP) enables sharing of IPv6 routes using BGP and connections to BGP peers using IPv6
Routing Information Protocol version 2 (RIPv2) provides an easy-to-configure routing protocol for small networks while RIPng provides support for small IPv6 networks
Open Shortest Path First (OSPF) delivers faster convergence. It uses link-state routing Interior Gateway Protocol (IGP), which supports NSSA, and MD5 authentication for increased security and graceful restart for faster failure recovery
OSPF provides OSPFv2 for IPv4 routing and OSPFv3 for IPv6 routing
Static IP routing provides manually configured routing; includes ECMP capability
Static IPv4 and IPv6 routing provides simple manually configured IPv4 and IPv6 routes
IP performance optimization provides a set of tools to improve IPv4 network performance. It includes directed broadcasts, customization of TCP parameters, support of ICMP error packets, and extensive display capabilities
Dual IP stack maintains separate stacks for IPv4 and IPv6 to ease the transition from an IPv4-only network to an IPv6-only network design
mDNS (Multicast Domain Name System) Gateway enables discovery of mDNS groups across L3 boundaries
Equal-Cost Multipath (ECMP) enables multiple equal-cost links in a routing environment to increase link redundancy and scale bandwidth
Security
The HPE Aruba Networking CX 5420 Switch Series comes with an integrated trusted platform module (TPM) for platform integrity. This ensures the boot process starts from a trusted combination of HPE Aruba Networking AOS-CX switches. Other security features include:
AOS-CX uses FIPS 140-2 validated cryptography for protection of sensitive information
Access control list (ACL) support for both IPv4 and IPv6; allows for filtering traffic to prevent unauthorized users from accessing the network or for controlling network traffic to save resources. Rules can either deny or permit traffic forwarding and can be based on a Layer 2 header or a Layer 3 protocol header
ACLs also provide filtering based on the IP field, source/ destination IP address/subnet, and
source/destination TCP/UDP port number on a per-VLAN, per-port, or global basis
Remote Authentication Dial-In User Service (RADIUS)
Terminal Access Controller Access-Control System (TACACS+) is an authentication tool using TCP with encryption of the full authentication request, providing additional security
Management access security for both on- and off- box authentication for administrative access.
RADIUS or TACACS+ can be used to provide encrypted user authentication. Additionally, TACACS+ can also provide admin authorization service
Control Plane Policing sets rate limit on control protocols to protect CPU overload from DOS attacks
Multiple user authentication methods with an IEEE 802.1X supplicant on the client in conjunction with a RADIUS server to authenticate in accordance with industry standards
Web based authentication using Captive Portal on HPE Aruba Networking ClearPass is supported for use cases such as Guest Access and for devices that don't support 802.1x or MAC Auth.
Supports MAC-based client authentication
Concurrent IEEE 802.1X, Web, and MAC authentication schemes per switch port accept up to 32 sessions of IEEE 802.1X, Web, and MAC authentications
Secure management access delivers secure encryption of all access methods (CLI, GUI, or MIB) through SSHv2, SSL, and/or SNMPv3
Switch CPU protection provides automatic protection against malicious network traffic attempts to shut down the switch
ICMP throttling defeats ICMP denial-of-service attacks by enabling any switch port to automatically throttle ICMP traffic
Identity-driven ACL enables implementation of a highly granular and flexible access security policy and VLAN assignment specific to each authenticated network user
STP BPDU port protection blocks Bridge Protocol Data Units (BPDUs) on ports that do not require BPDUs, preventing forged BPDU attacks
Dynamic IP lockdown works with DHCP protection to block traffic from unauthorized hosts, preventing IP source address spoofing
Dynamic ARP protection blocks ARP broadcasts from unauthorized hosts, preventing eavesdropping or theft of network data
STP root guard protects the root bridge from malicious attacks or configuration mistakes
Port security allows access only to specified MAC addresses, which can be learned or specified by the administrator
MAC address lockout prevents specifically configured MAC addresses from connecting to the network
Source-port filtering allows only specified ports to communicate with each other
Secure shell encrypts all transmitted data for secure remote CLI access over IP networks
Secure Sockets Layer (SSL) encrypts all HTTP traffic, allowing secure access to the browser-based management GUI in the switch
Secure FTP allows secure file transfer to and from the switch; protects against unwanted file downloads or unauthorized copying of a switch configuration file
Critical Authentication Role ensures that important infrastructure devices such as IP phones are allowed network access even in the absence of a RADIUS server
MAC pinning allows non-chatty legacy devices to stay authenticated by pinning client MAC addresses to the port until the client logs off or gets disconnected
Security banner displays a customized security policy when users log in to the switch
RadSec enables RADIUS authentication and accounting data to be passed safely and reliably across insecure networks
Private VLAN (PVLAN) provides traffic isolation between users on the same VLAN. Typically, a switch port can only communicate with other ports in the same community and/or an uplink port, regardless of VLAN ID or destination MAC address. This extends network security by restricting peer-peer communication to prevent a variety of malicious attacks.
Auto VLAN Creation automates VLAN creation on access switches for authenticated clients.
DHCP smart relay allows the DHCP relay agent to use secondary IP addresses when the DHCP server does not reply to the DHCP-OFFER message
Supports device fingerprinting to identify a device based on collected attributes and analyze information using ClearPass Device Insight. This provides better visibility and informs network access control decisions
IEEE 802.1AE MACsec* provides switch-to-switch and switch-to-host security on a link between two ports using standard encryption and authentication, available on uplink and downlink ports
Multicast
IGMP Snooping allows multiple VLANs to receive the same IPv4 multicast traffic, lessening network bandwidth demand by reducing multiple streams to each VLAN
Multicast Listener Discovery (MLD) enables discovery of IPv6 multicast listeners; supports MLD v1 and v2
Protocol Independent Multicast (PIM) defines modes of IPv4 and IPv6 multicasting to allow one-to-many and many-to-many transmission of information. Support for PIM Sparse Mode (SM), Source-Specific Multicast (SSM), and Dense Mode (DM) for both IPv4 and IPv6
Internet Group Management Protocol (IGMP) utilizes Any-Source Multicast (ASM) to manage IPv4 multicast networks; supports IGMPv1, v2, and v3
Convergence
IP multicast routing includes PIM Sparse, Source-Specific Multicast, and Dense modes to route IP multicast traffic
IP multicast snooping (data-driven IGMP) prevents flooding of IP multicast traffic
Protocol Independent Multicast for IPv6 supports one-to-many and many-to-many media casting use cases such as IPTV over IPv6 networks
LLDP-MED (Media Endpoint Discovery) defines a standard extension of LLDP that stores values for parameters such as QoS and VLAN to automatically configure network devices such as IP phones
PoE allocations supports multiple methods (allocation by usage or class, with LLDP and LLDP-MED) to allocate PoE power for more efficient power management and energy savings
Auto VLAN configuration for voice RADIUS VLAN uses a standard RADIUS attribute and LLDP-MED to automatically configure a VLAN for IP phones
Technical Specifications
HPE Aruba Networking 5420 6-slot Switch (S0U59A)
Description
1 x 5420 6-slot Chassis (S0U60A)
1 x 5420 Management Module (S0U55A)
1 x Fan Tray (S0U54A)
1 x 6-slot Accessory Kit (S0U57A)
1 x 2-post 6-slot Rack Kit (S0U56A)
1 open management slot
6 open line card module slots
Supports the management card in the open management slots:
SOU55A, S0U58A
Supports any of the following line cards in the open slots:
Supports 4 field replaceable and hot-swappable power supply slots
Supported power supplies: S0U53A
PoE availability is dependent on the number of management modules, line cards, fan trays and the number of power supplies used. Power supplies are not included; order separately
Fans
1 field-replaceable and hot-swappable system fan tray
64MB packet buffer memory shared dynamically among ports
Performance
Model switching capacity
960 Gbps (480 Gbps in + 480 Gbps out)
Model throughput capacity
714 Mpps
Average latency (LIFO-64-bytes packets)
2.5 micro sec
Switch Virtual Interface (SVI) (dual stack)
512
IPv4 host table (ARP)
25,600
IPv6 host table (ND)
25,600
Performance*
IPv4 unicast routes
16,384
IPv6 unicast routes
8,192
MAC table capacity
32,768
IGMP groups
2,048
MLD groups
2,048
IPv4/IPv6/MAC ACL
entries (ingress)
MAC - 10,233
IPv4 - 10,233
IPv6 - 2,558 (1/4 of scale)
IPv4/IPv6/MAC ACL
entries (egress)
MAC - 5,113
IPv4 - 5,113
IPv6 - 1,278 (1/4 of scale)
Notes:
*Pending final validation
Environment
Operating temperature
32°F to 113°F (0°C to 45°C), up to 5,000 feet
Derate 1°C every 1,000 feet from 5,000 feet to 10,000 feet
Can support excursion to 131°F (55°C) for short periods1 of time
Notes: 1No more than 96 consecutive hours and 360 hours total (15 days) in 1 year
Operating relative humidity
5% to 95% relative humidity at 113°F (45°C), non-condensing
Non-operating
-40°F to 158°F (-40°C to 70°C) up to 15,000 feet
Non-operating storage relative humidity
5% to 95% relative humidity at 149°F(65°C), non-condensing
Max operating altitude
Up to 10,000 feet (3 km)
Max non-operating altitude
Up to 15,000 feet (4.5 km)
Acoustics
Sound power (LWAd): 4.7 Bel,
Sound pressure (LpAm, Bystander): 44.6 dB
when tested with 2x S0U53A power supply at low voltage line,
loaded with 2 x S0U55A, 3 x S0U67A, 3 x S0U68A
with a loading of 50% traffic on all ports
Sound power (LWAd): 5.5 Bel,
Sound pressure (LpAm, Bystander): 52.1 dB
when tested with 4x S0U53A power supply at low voltage line,
loaded with 2 x S0U55A, 6 x S0U66A and
drawing a total of 2000W PoE, with a loading of 50% traffic on all ports
Primary airflow
Front to back
Electrical Characteristics
Frequency
50Hz/60Hz
AC voltage
S0U53A PSUs: 100-127/200-240VAC
Current
11.6A @ 100-127VAC
9A @ 200VAC
8A @ 208-240VAC
Power output
S0U53A: 1600W @ 200-240Vac, 1000W @ 100-127Vac
80plus.org certification
Platinum for S0U53A PSU
Safety
IEC 62368-1:2014 2nd Ed w/all known national deviations
IEC 62368-1:2018 3rd Ed w/all known national deviations
IEC 60825-1:2014 / EN 60825-1:2014+A11:2021 Class 1 Laser
EN 62368-1:2014 +A11:2017 2nd Ed.
EN IEC 62368-1:2020 +A11:2020 3rd Ed.
UL 62368-1 3rd Ed./ CAN/CSA C22.2 No. 62368-1:19
CNS 15598-1:2020
Emissions
EN 55032:2015+A11:2020 Class A, CISPR 32:2015+A1:2019 Class A, FCC Part 15B Class A, VCCI 32-1 Class A, ICES-003 Class A, AS/NZS CISPR 32 Class A, CNS 15936:2016
Lasers
IEC 60825-1:2014 / EN 60825-1:2014+A11:2021 Class 1 Laser
Immunity
Generic
Directive 2014/35/EU
EN
CISPR 35:2016/EN 55035:2017+A11:2020
ESD
IEC 61000-4-2
Radiated
IEC 61000-4-3
EFT/Burst
IEC 61000-4-4
Surge
IEC 61000-4-5
Conducted
IEC 61000-4-6
Power frequency magnetic field
IEC 61000-4-8
Voltage dips and
interruptions
IEC 61000-4-11
Harmonics
EN IEC 61000-3-2
Flicker
EN IEC 61000-3-3
Mounting and enclosure
Cable management kit and 2-post rack mounting kit included.
4-post rack mounting kit available separately
Standards and Protocols
ANSI/TIA-1057 LLDP Media Endpoint Discovery (LLDP-MED)
CPU DoS Protection
Bootstrap Router (BSR) Mechanism for PIM, PIM WG draft-ietf-savi-mix
IEEE 802.1AB-2005
IEEE 802.1ak-2007
IEEE 802.1AX-2008 Link Aggregation
IEEE 802.1D MAC Bridges
IEEE 802.1p Priority
IEEE 802.1Q VLANs
IEEE 802.1s Multiple Spanning Trees
IEEE 802.1t-2001
IEEE 802.1v VLAN classification by Protocol and Port
IEEE 802.1w Rapid Reconfiguration of Spanning Tree
IEEE 802.3ab 1000BASE-T
IEEE 802.3ad Link Aggregation Control Protocol (LACP)
IEEE 802.3ae 10-Gigabit Ethernet
IEEE 802.3af Power over Ethernet
IEEE 802.3at Power over Ethernet
IEEE 802.3az Energy Efficient Ethernet (EEE)
IEEE 802.3bt Power over Ethernet
IEEE 802.3z 1000BASE-X
RFC 1122 Requirements for Internet Hosts - Communications Layers
RFC 1215 Convention for defining traps for use with the SNMP
RFC 1256 ICMP Router Discovery Messages
RFC 1350 TFTP Protocol (revision 2)
RFC 1393 Traceroute Using an IP Option
RFC 1403 BGP OSPF Interaction
RFC 1519 CIDR
RFC 1542 BOOTP Extensions
RFC 1583 OSPF Version 2
RFC 1591 Domain Name System Structure and Delegation
RFC 1657 Definitions of Managed Objects for BGP-4 using SMIv2
RFC 1772 Application of the Border Gateway Protocol in the Internet
RFC 1812 Requirements for IP Version 4 Router
RFC 1918 Address Allocation for Private Internet
RFC 1997 BGP Communities Attribute
RFC 1998 An Application of the BGP Community Attribute in Multi-home Routing
RFC 2131 DHCP
RFC 2132 DHCP Options and BOOTP Vendor Extensions
RFC 2236 IGMP
RFC 2328 OSPF Version 2
RFC 2375 IPv6 Multicast Address Assignments
RFC 2385 Protection of BGP Sessions via the TCP MD5 Signature Option
RFC 2401 Security Architecture for the Internet Protocol
RFC 2402 IP Authentication Header
RFC 2439 BGP Route Flap Damping
RFC 2460 Internet Protocol, Version 6 (IPv6) Specification
RFC 2464 Transmission of IPv6 over Ethernet Networks
RFC 2545 Use of BGP-4 Multiprotocol Extensions for IPv6 Inter-Domain Routing
RFC 2576 (Coexistence between SNMP V1, V2, V3)
RFC 2579 (SMIv2 Text Conventions)
RFC 2580 (SMIv2 Conformance)
RFC 2710 Multicast Listener Discovery (MLD) for IPv6
RFC 2711 IPv6 Router Alert Option
RFC 2787 Definitions of Managed Objects for the Virtual Router Redundancy Protocol
RFC 2918 Route Refresh Capability for BGP-4
RFC 2925 Definitions of Managed Objects for Remote Ping, Traceroute, and Lookup Operations (Ping only)
RFC 2934 Protocol Independent Multicast MIB for IPv4
RFC 3019 MLDv1 MIB
RFC 3046 DHCP Relay Agent Information Option
RFC 3056 Connection of IPv6 Domains via IPv4 Clouds
RFC 3065 Autonomous System Confederation for BGP
RFC 3068 An Anycast Prefix for 6to4 Relay Route
RFC 3137 OSPF Stub Router Advertisement sFlow
RFC 3376 IGMPv3
RFC 3417 (SNMP Transport Mappings)
RFC 3418 Management Information Base (MIB) for the Simple Network Management Protocol (SNMP)
RFC 3484 Default Address Selection for IPv6
RFC 3509 Alternative Implementations of OSPF Area Border Routers
RFC 3575 IANA Considerations for RADIUS
RFC 3623 Graceful OSPF Restart
RFC 3768 VRRP
RFC 3810 Multicast Listener Discovery Version 2 (MLDv2) for IPv6
RFC 3973 PIM Dense Mode
RFC 4022 MIB for TCP
RFC 4113 MIB for UDP
RFC 4213 Basic Transition Mechanisms for IPv6 Hosts and Routers
RFC 4251 The Secure Shell (SSH) Protocol
RFC 4252 SSHv6 Authentication
FC 4253 SSHv6 Transport Layer
RFC 4254 SSHv6 Connection
RFC 4271 A Border Gateway Protocol 4 (BGP-4)
RFC 4273 Definitions of Managed Objects for BGP-4
RFC 4291 IP Version 6 Addressing Architecture
RFC 4292 IP Forwarding Table MIB
RFC 4293 Management Information Base for the Internet Protocol (IP)
RFC 4360 BGP Extended Communities Attribute
RFC 4419 Key Exchange for SSH
RFC 4443 ICMPv6
RFC 4456 BGP Route Reflection: An Alternative to Full Mesh Internal BGP (IBGP)
RFC 4486 Subcodes for BGP Cease Notification Message
RFC 4541 IGMP & MLD Snooping Switch
RFC 4552 Authentication/Confidentiality for OSPFv3
RFC 4601 PIM Sparse Mode
RFC 4607 Source-Specific Multicast for IP
RFC 4675 RADIUS VLAN & Priority
RFC 4724 Graceful Restart Mechanism for BGP
RFC 4760 Multiprotocol Extensions for BGP-4
RFC 4861 IPv6 Neighbor Discovery
RFC 4862 IPv6 Stateless Address Auto-configuration
RFC 4940 IANA Considerations for OSPF
RFC 5065 Autonomous System Confederation for BGP
RFC 5095 Deprecation of Type 0 Routing Headers in IPv6
RFC 5187 OSPFv3 Graceful Restart
RFC 5340 OSPFv3 for IPv6
RFC 5424 Syslog Protocol
RFC 5492 Capabilities Advertisement with BGP-4
RFC 5519 Multicast Group Membership Discovery MIB (MLDv2 only)
RFC 5701 IPv6 Address Specific BGP Extended Community Attribute
RFC 5722 Handling of Overlapping IPv6 Fragments
RFC 5798 VRRP (exclude Accept Mode and sub-sec timer)
RFC 5905 Network Time Protocol Version 4: Protocol and Algorithms Specification
RFC 6620 FCFS SAVI
RFC 6987 OSPF Stub Router Advertisement
RFC 7047 The Open vSwitch Database Management Protocol
RFC 7313 Enhanced Route Refresh Capability for BGP-4
RFC 768 User Datagram Protocol
RFC 783 TFTP Protocol (revision 2)
RFC 791 IP
RFC 792 ICMP
RFC 793 TCP
RFC 813 Window and Acknowledgement Strategy in TCP
RFC 815 IP datagram reassembly algorithms
RFC 8201 Path MTU Discovery for IP version 6
RFC 3065 Autonomous System Confederation for BGP
RFC 3068 An Anycast prefix for 6to4 Relay Route
RFC 3137 OSPF Stub Router Advertisement sFlow
RFC 3376 IGMPv3
RFC 3417 (SNMP Transport Mappings)
RFC 3418 Management Information Base (MIB) for the Simple Network Management Protocol (SNMP)
RFC 3484 Default Address Selection for IPv6
RFC 3509 Alternative Implementations of OSPF Area Border Routers
RFC 3575 IANA Considerations for RADIUS
RFC 3623 Graceful OSPF Restart
RFC 3768 VRRP
RFC 3810 Multicast Listener Discovery Version 2 (MLDv2) for IPv6
RFC 3973 PIM Dense Mode
RFC 4022 MIB for TCP
RFC 4113 MIB for UDP
RFC 4213 Basic Transition Mechanisms for IPv6 Hosts and Routers
RFC 4251 The Secure Shell (SSH) Protocol
RFC 4252 SSHv6 Authentication
RFC 4253 SSHv6 Transport Layer
RFC 4254 SSHv6 Connection
RFC 4271 A Border Gateway Protocol 4 (BGP-4)
RFC 4273 Definitions of Managed Objects for BGP-4
RFC 4291 IP Version 6 Addressing Architecture
RFC 4292 IP Forwarding Table MIB
RFC 4293 Management Information Base for the Internet Protocol (IP)
RFC 4360 BGP Extended Communities Attribute
RFC 4419 Key Exchange for SSH
RFC 4443 ICMPv6
RFC 4456 BGP Route Reflection: An Alternative to Full Mesh Internal BGP (IBGP)
RFC 4486 Subcodes for BGP Cease Notification Message
RFC 4541 IGMP & MLD Snooping Switch
RFC 4552 Authentication/Confidentiality for OSPFv3
RFC 4601 PIM Sparse Mode
RFC 4607 Source-Specific Multicast for IP
RFC 4675 RADIUS VLAN & Priority
RFC 4724 Graceful Restart Mechanism for BGP
RFC 4760 Multiprotocol Extensions for BGP-4
RFC 4861 IPv6 Neighbor Discovery
RFC 4862 IPv6 Stateless Address Auto-configuration
RFC 4940 IANA Considerations for OSPF
RFC 5065 Autonomous System Confederation for BGP
RFC 5095 Deprecation of Type 0 Routing Headers in IPv6
RFC 5187 OSPFv3 Graceful Restart
RFC 5340 OSPFv3 for IPv6
RFC 5424 Syslog Protocol
RFC 5492 Capabilities Advertisement with BGP-4
RFC 5519 Multicast Group Membership Discovery MIB (MLDv2 only)
RFC 5701 IPv6 Address Specific BGP Extended Community Attribute
RFC 5722 Handling of Overlapping IPv6 Fragments
RFC 5798 VRRP (exclude Accept Mode and sub-sec timer)
RFC 5905 Network Time Protocol Version 4: Protocol and Algorithms Specification
RFC 6620 FCFS SAVI
RFC 6987 OSPF Stub Router Advertisement
RFC 7047 The Open vSwitch Database Management Protocol
RFC 7313 Enhanced Route Refresh Capability for BGP-4
RFC 768 User Datagram Protocol
RFC 783 TFTP Protocol (revision 2)
RFC 791 IP
RFC 792 ICMP
RFC 793 TCP
RFC 813 Window and Acknowledgement Strategy in TCP
RFC 815 IP Datagram Reassembly Algorithms
RFC 8201 Path MTU Discovery for IP version 6
RFC 826 ARP
RFC 879 TCP Maximum Segment Size and Related Topics
RFC 896 Congestion Control in IP/TCP Internetworks
RFC 917 Internet subnets
RFC 919 Broadcasting Internet Datagrams
RFC 922 Broadcasting Internet Datagrams in the Presence of Subnets (IP_BROAD)
RFC 925 Multi-LAN Address Resolution
RFC 951 BOOTP
RFC 1027 Proxy ARP
SNMPv1/v2c/v3
RFC 4861 IPv6 Neighbor Discovery
RFC 4862 IPv6 Stateless Address Auto-configuration
ITU-T Rec G.8032/Y.1344 Mar. 2010
RFC 1757 Remote Network Monitoring Management Information Base
2.5G/5GBASE-T (IEEE 802.3bz-2016),
2.5G/5G NBASE-T
10GBASE-T (IEEE 802.3an-2006)
25-Gigabit Ethernet (IEEE 802.3by-2016, 802.3cc-2017)
RFC 3101 OSPF Not-so-stubby-area Option
RFC 4750 OSPFv2 MIB Partial Support no SetMIB
SKLADEM:
Zboží je skladem v zobrazované výši a lze ho ihned objednat a dodat na Vámi určenou adresu, popřípadě vydzvednout po domluvě přímo v našem skladě. NENÍ SKLADEM, DOSTUPNOST NA DOTAZ:
Pokud není uvedeno jinak, předpokládaná doba naskladnění je min. 14dní, prosím zavolejte 315 810 620 pro upřesnění dodání. REPAIR:
Jedná se o zboží, které je vráceno distributorem po servisním zásahu, je opravené, odzkoušené a plně funkční. U tohoto druhu zboží, pokud není skladem, nelze zjistit datum dodání a lze jen sledovat přímo na internetu. Na zboží je dána plná 2 letá záruka. POŠKOZENÝ OBAL:
Jedná se o zboží, u kterého vinou transportu došlo k poškození obalu, popřípadě originální krabice. U tohoto druhu zboží, pokud není skladem, nelze zjistit datum dodání a lze jen sledovat přímo na internetu. Aktualizace cen:
Ceny na myIT.cz se aktualizují několikrát za den v závislosti na kurzu. Veškeré nechtěné překlepy, změny cen jsou vyhrazeny.
do 24H:
MERCUSYS switch MS108G (8xGbE, fanless)
MERCUSYS MS105G switch (5xGbE, fanless)
TP-Link LiteWave switch LS105G (5xGbE, fanless)
TP-Link switch TL-SF1005D (5x100Mb/ s, fanless)
NAPIŠTE NÁM RYCHLE
