Huawei AC6605 Wireless Access Controller wifi access controller
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Shanghai Chu Cheng Information Technology Co., Ltd.
Huawei AC6605 Wireless Access Controller huawei Wireless Controller
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Huawei AC6605 Wireless Access Controller
The Huawei AC6605-26-PWR access controller integrates 1000M Ethernet switch functionality for both wired and wireless access control. The AC6605-26-PWR offers users broad flexibility in configuring Access Points (APs). Used together with Huawei Premium Series Huawei APs, Enhanced Series Huawei APs and Standard Series Huawei APs, the AC6605-26-PWR delivers an enterprise grade networking solution for campus, industrial, and small- and medium-scale enterprise networks and extends hotspot coverage
Item | Specifications |
---|---|
Processor | Dominant frequency: 1 GHz |
Switching capacity | 128 Gbit/s |
Packet forwarding capacity | 10 Gbit/s |
DDR memory | 4 GB |
Flash memory | 256 MB |
Item | Description | |
---|---|---|
Dimensions (width x depth x height) | 442 mm x 420 mm x 44.4 mm | |
Maximum power consumption | 85 W | |
Weight | Net weight: 5.48 kg Fully configured with 150 W power supplies: 7.16 kg Fully configured with 500 W power supplies: 7.48 kg | |
Operating temperature | -5ºC to +50ºC | |
Relative humidity | 5% RH to 95% RH, noncondensing | |
Operating altitude | 150 W DC power supply: 0 m to 2000 m Others: 0 m to 3000 m | |
AC input voltage | Rated voltage | 100 V AC to 240 V AC, 50/60 Hz |
Voltage range | 90 V AC to 264 V AC, 47 Hz to 63 Hz | |
DC input voltage | Rated voltage | -48 V DC to -60 V DC |
Voltage range | -36 V DC to -72 V DC |
Parameter | Specifications |
---|---|
Number of managed APs | 512 |
Number of access users | Entire device: 10K Single AP: a maximum of 256 (depending on the AP model) |
Number of MAC address entries | 16K |
Number of VLANs | 4K |
Number of routing entries | 10K |
Number of ARP entries | 8K |
Number of multicast forwarding entries | 4K |
Number of DHCP IP address pools | 128 IP address pools, each of which contains a maximum of 16K IP addresses |
Number of local users | 1000 |
Number of ACLs | 8K |
Number of ESSIDs | 4K |
User group management | 128 user groups Each user group can reference a maximum of eight ACLs. Each user group can associate with a maximum of 128 ACL rules. |
Feature | Specifications |
---|---|
Networking between APs and ACs | APs and ACs can be connected through a Layer 2 or Layer 3 network. APs can be directly connected to an AC. APs are deployed on a private network, while ACs are deployed on the public network to implement NAT traversal. ACs can be used for Layer 2 bridge forwarding or Layer 3 routing. |
Forwarding mode | Direct forwarding (distributed forwarding or local forwarding) Tunnel forwarding (centralized forwarding) Centralized authentication and distributed forwarding Before users are authenticated, tunnel forwarding is used. After users are authenticated, local forwarding is used. |
Wireless networking mode | WDS bridging: Point-to-point (P2P) wireless bridging Point-to-multipoint (P2MP) wireless bridging Automatic topology detection and loop prevention (STP) Wireless mesh network Access authentication for mesh devices Mesh routing algorithm Go-online without configuration |
AC discovery | An AP can obtain the AC6605-26-PWR's IP address in any of the following ways: Static configuration DHCP Option 43 DNS The AC6605-26-PWR uses DHCP to allocate IP addresses to APs. DHCP relay is supported. On a Layer 2 network, APs can discover the AC6605-26-PWR by sending broadcast or multicast CAPWAP packets. |
CAPWAP tunnel | Centralized CAPWAP CAPWAP control tunnel and data tunnel (optional). CAPWAP tunnel forwarding and direct forwarding in an extended service set (ESS). Datagram Transport Layer Security (DTLS) encryption, which is enabled by default for the CAPWAP control tunnel Heartbeat detection and tunnel reconnection. |
Active and standby ACs | Enables and disables the switchback function. Supports load balancing. Supports 1+1 hot backup. |
Feature | Description | |
---|---|---|
Ethernet features | Ethernet | Operating modes of full duplex, half duplex, and auto-negotiation Rates of an Ethernet interface: 10 Mbit/s, 100 Mbit/s, 1000 Mbit/s, and auto-negotiation Flow control on interfaces Jumbo frames Link aggregation Load balancing among links of a trunk Interface isolation and forwarding restriction Broadcast storm suppression |
VLAN | Access modes of access, trunk, hybrid, and Default VLAN | |
MAC | Automatic learning and aging of MAC addresses Static, dynamic, and blackhole MAC address entries Packet filtering based on source MAC addresses Interface-based MAC learning limiting | |
ARP | Static and dynamic ARP entries ARP in a VLAN Aging of ARP entries | |
LLDP | LLDP | |
Ethernet loop protection | MSTP | STP RSTP MSTP BPDU protection, root protection, and loop protection Partitioned STP |
IPv4/IPv6 forwarding | IPv4 features | ARP and RARP ARP proxy Auto-detection |
Unicast routing features | Static route RIP-1 and RIP-2 OSPF BGP IS-IS Routing policies and policy-based routing URPF check DHCP client,server and relay DHCP snooping | |
Multicast routing features | IGMPv1, IGMPv2, and IGMPv3 PIM-SM Multicast routing policies RPF | |
Device reliability | BFD | BFD |
Layer 2 multicast features | Layer 2 multicast | IGMP snooping Prompt leave Multicast traffic control Inter-VLAN multicast replication |
Ethernet OAM | EFM OAM | Neighbor discovery Link monitoring Fault notification Remote loopback |
QoS features | Traffic classification | Traffic classification based on the combination of the L2 protocol header, IP 5-tuple, outbound interface, and 802.1p priority |
Action | Access control after traffic classification Traffic policing based on traffic classification Re-marking packets based on traffic classifiers Class-based packet queuing Associating traffic classifiers with traffic behaviors | |
Queue scheduling | PQ scheduling DRR scheduling PQ+DRR scheduling WRR scheduling PQ+WRR scheduling | |
Congestion avoidance | SRED WRED | |
Configuration and maintenance | Terminal service | Configurations using command lines Error message and help information in English Login through console and Telnet terminals Send function and data communications between terminal users |
File system | File systems Directory and file management File uploading and downloading using FTP and TFTP | |
Debugging and maintenance | Unified management over logs, alarms, and debugging information Electronic labels User operation logs Detailed debugging information for network fault diagnosis Network test tools such as traceroute and ping commands Interface mirroring and flow mirroring | |
Version upgrade | Device software loading and online software loading BootROM online upgrade In-service patching | |
Security and management | System security | Different user levels for commands, preventing unauthorized users from accessing AC SSHv2.0 RADIUS and HWTACACS authentication for login users ACL filtering DHCP packet filtering (with the Option 82 field) Defense against control packet attacks Defenses against attacks such as source address spoofing, Land, SYN flood (TCP SYN), Smurf, ping flood (ICMP echo), Teardrop, and Ping of Death attacks |
Network management | ICMP-based ping and traceroute SNMPv1, SNMPv2c, and SNMPv3 Standard MIB RMON |
Feature | Specifications |
---|---|
AP access control | Displays MAC addresses or SNs of APs in the whitelist. Adds a single AP or multiple APs (by specifying a range of MAC addresses or SNs) to the whitelist. Automatically discovering and manually confirming APs. Automatically discovering APs without manually confirming them. |
AP region management | Supports three AP region deployment modes: ·Distributed deployment: APs are deployed independently. An AP is equivalent to a region and does not interfere with other APs. APs work at the maximum power and do not perform radio calibration. ·Common deployment: APs are loosely deployed. The transmit power of each radio is less than 50% of the maximum transmit power. ·Centralized deployment: APs are densely deployed. The transmit power of each radio is less than 25% of the maximum transmit power. Specifies the default region to which automatically discovered APs are added. |
AP profile management | Specifies the default AP profile that is applied to automatically discovered APs. |
AP type management | Manages AP attributes including the number of interfaces, AP types, number of radios, radio types, maximum number of virtual access points (VAPs), maximum number of associated users, and radio gain (for APs deployed indoors). Provides default AP types. Supports user-defined AP types. |
Network topology management | Supports LLDP topology detection. |
The AC6605-26-PWR is connected to an aggregation switch in chain or branched mode.
The AC6605-26-PWR processes both control flows and data flows. Management flows must be transmitted over Control And Provisioning of Wireless Access Points (CAPWAP) tunnels. Data flows can be transmitted over CAPWAP tunnels or not, as required.
The CAPWAP protocol defines how APs communicate with ACs and provides a general encapsulation and transmission mechanism for communication between APs and ACs. CAPWAP defines data tunnels and control tunnels.
Data tunnels encapsulate 802.11 data packets to be sent to the AC.
Control tunnels transmit control flows for remote AP configuration and WLAN management.
Two forwarding modes are available according to whether data flows are transmitted on CAPWAP tunnels:
Direct forwarding: is also called local or distributed forwarding.
Tunnel forwarding: is also called centralized forwarding. It is usually used to control wireless user traffic in a centralized manner.
You can select the chain or branched mode according to networking requirements. On the AC, you can configure direct forwarding for some APs and tunnel forwarding for other APs. In tunnel forwarding mode, all wireless user traffic is aggregated to an AC, which may create a switching bottleneck. Therefore, tunnel forwarding is seldom used on enterprise networks.