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0,26 € netto
Huawei AP362 is an access point from the eKitEngine series that supports the Wi-Fi 6 standard. It supports IEEE 802.11 b/g/n/ax protocols in the 2.4 GHz band and IEEE 802.11 a/n/ac/ax protocols in the 5 GHz band. The maximum theoretical throughput is 574 Mb/s in 2.4 GHz and 2402 Mb/s in 5 GHz. The device supports MU-MIMO (simultaneous transmission and reception of data from multiple users), BSS coloring (marking transmissions to reduce interference), and TWT (Target Wake Time - a feature that helps reduce energy consumption). The access point has a Smart antenna, which consists of multiple elements that can work independently. Depending on the needs, the antenna elements can modify the shape of the main beam and adapt to connected clients. The AP362 enclosure is designed for wall, ceiling, or T-rail mounting. The device has 1 gigabit Ethernet port (10/100/1000 Mb/s), which also serves as a Power over Ethernet (PoE) input in IEEE 802.3 af standard. Power can also be supplied using the DC socket (input voltage is 12 V).
The offered product can operate in several modes: Fat AP, Leader AP, Fit AP, or Cloud. In Fat AP mode, the device functions as an independent access point, allowing you to configure it like a regular wireless router. Leader AP mode enables you to configure the AP362 as a master device (leader) responsible for managing other compatible access points. Cloud mode allows you to connect the device to a controller located in the cloud, while Fit AP mode is used to connect it to another physical WLAN AC controller. Solutions from the eKitEngine series enable you to create an extensive and efficient wireless network, capable of covering very large areas. The devices support data roaming, band steering, and various authentication methods. They are ideally suited for a wide range of applications, from home use to large enterprises and restaurants.
Wi-Fi 6 AX3000 wireless network
AP362 is designed to transmit Wi-Fi 6 wireless networks and supports IEEE 802.11 b/g/n/ax protocols in the 2.4 GHz band and IEEE 802.11 a/n/ac/ax protocols in the 5 GHz band. The maximum theoretical throughput is 574 Mb/s in the 2.4 GHz band and 2402 Mb/s in the 5 GHz band. This speed is more than sufficient for most internet activities, including streaming 4K videos online, gaming, or downloading large files.
The access point also utilizes several additional features that positively impact network quality. MU-MIMO enables simultaneous transmission and reception of data from multiple clients, eliminating data queuing. Beamforming shapes the beam to improve connections with devices at the edge of the coverage area, while TWT (Target Wake Time) conserves energy by waking up connected devices only when a transmission is initiated.
Gigabit Ethernet port, Power over Ethernet / DC socket
The offered product is equipped with a single Gigabit Ethernet port (10/100/1000 Mbps), which simultaneously serves as a Power over Ethernet (PoE) input compliant with the IEEE 802.3af standard. Power can also be supplied using a standard DC socket, with an input voltage of 12 V. The maximum power consumption is 11.2 W.
Smart antennas
The access point features Smart antennas, comprised of multiple elements capable of operating independently. Depending on the requirements, these antenna elements can modify the shape of the main beam to provide the best possible coverage to connected clients. The device adapts to radio conditions, offering significantly better signal coverage compared to APs equipped with conventional omni-directional antennas. The gain in both frequency bands is 4 dBi.
Up to 256 clients
The Huawei AP362 can handle up to 256 client devices connected simultaneously. APs from the eKitEngine series are ideal for locations with or potentially hosting many users. The system supports load balancing and smart roaming, so if one access point becomes overloaded, users are switched to others.
The DFA (Dynamic Frequency Allocation) algorithm is used for automatically detecting wireless channel usage and recognizing overlapping transmissions. In the case of multiple access points, they operate to avoid interfering with each other. Additionally, technologies like EDCA (Enhanced Distributed Channel Access) and airtime scheduling enable the scheduling of channel utilization for specific client devices, ensuring equal access to the network for each of them.
A significant advantage of the eKitEngine-based system is the optimization of network utilization by client devices. Clients with low signal strength or slow connection speeds are automatically disconnected to improve overall transmission quality. Additionally, the AP362 features a 5G-prior function where client devices are primarily connected in the 5 GHz band to provide them with the best possible throughput. This reduces congestion and interference in the 2.4 GHz band significantly.
Advanced wireless system
The offered product is designed to work in a large wireless system composed of multiple access points. Such a network is capable of covering even very large areas, depending on the number of devices used. The system supports data roaming, where users are automatically switched between individual access points without losing their connection.
Huawei solutions offer a wide range of features related to bandwidth control, improving transmission quality, and security. For user authentication, you can utilize methods such as 802.1x, MAC addresses, or captive portals. An advanced management and monitoring system will help you reduce the time spent on network administration, for example, through automatic detection and recognition of various types of errors.
Four operating modes
Access points can operate in four modes:
- Fat AP - the access point operates independently, and configuring and managing it resembles the process for standard wireless routers. It's suitable for small networks where you use only one AP.
- Leader AP - It allows configuring the device as a "leader," thereby taking on the role of a controller in the network. You can connect other access points to the device in Leader AP mode to create an expanded system. This mode is best suited for small networks, such as offices or restaurants, and helps reduce costs associated with purchasing additional controllers.
- Cloud AP - in this mode, the access point can be managed from a cloud-based platform. This platform significantly simplifies monitoring and conducting initial configurations, eliminating the need for additional management devices.
- Fit AP - this is the basic mode of operation in which the access point connects to a controller.
Multiple uses
The Huawei AP362 will find its application in many places. With high throughput and performance, it is suitable for homes and small businesses as the sole access point. You can also successfully utilize it in large, advanced networks consisting of many devices. It supports numerous modern features and can be used as a primary access point in advanced, extensive networks.
Specifications
Huawei AP362 | |
Technical specifications | |
---|---|
Dimensions (H x W x D) | Φ180 mm x 35 mm |
Weight | 0,51 kg |
Interface type | 1 x 10M/100M/1GE (RJ45) (GE supports PoE input) |
Interface type | Indicates the power-on, startup, running, alarm, and fault states of the system. |
Power specifications | |
Power input | DC: 12 V ± 10% PoE power supply: in compliance with 802.3af |
Maximum power consumption | 11,2 W |
Environmental | |
Operating temperature | -10°C to +50°C |
Storage temperature | -40°C to +70°C |
Operating humidity | 5% to 95% (non-condensing) |
Radio specifications | |
Antenna type | Built-in smart antennas |
Antenna gain |
2,4 GHz: 4 dBi 5 GHz: 4 dBi |
Maximum number of SSIDs for each radio | ≤ 16 |
Maximum number of users | ≤ 256 |
Maximum transmit power |
2.4 GHz: 20 dBm |
Power increment | 1 dBm |
Maximum number of non-overlapping channels |
2.4 GHz (2.412 GHz - 2.472 GHz) 802.11 b/g
802.11 n
802.11 ax
5 GHz (5.18 GHz - 5.825 GHz) 802.11 a
802.11 n
802.11 ac
802.11 ax
(The table uses the number of non-overlapping channels supported by China as an example. The number of non-overlapping channels varies in |
Fat/Fit AP mode | |
WLAN features | Compliance with IEEE 802.11ax and compatibility with IEEE 802.11a/b/g/n/ac/ac Wave 2 Maximum ratio combining (MRC) Space time block code (STBC) Cyclic Delay Diversity (CDD)/Cyclic Shift Diversity (CSD) Beamforming Multi-user multiple-input multiple-output (MU-MIMO) Orthogonal frequency division multiple access (OFDMA) Compliance with 1024-quadrature amplitude modulation (QAM) and compatibility with 256-QAM, 64-QAM, 16-QAM, 8-QAM, quadrature phase shift keying (QPSK), and binary phase shift keying (BPSK) Target wake time (TWT) Low-density parity-check (LDPC) Frame aggregation, including A-MPDU (Tx/Rx) and A-MSDU (Tx/Rx) 802.11 dynamic frequency selection (DFS) Short guard interval (GI) in 20 MHz, 40 MHz, 80 MHz and 160 MHz modes Priority mapping and scheduling that are compliant with Wi-Fi multimedia (WMM) to implement priority-based data processing and forwarding Automatic and manual rate adjustment (the rate is adjusted automatically by default) WLAN channel management and channel rate adjustment Automatic channel scanning and interference avoidance Service set identifier (SSID) hiding Signal sustain technology (SST) Unscheduled automatic power save delivery (U-APSD) Control and Provisioning of Wireless Access Points (CAPWAP) in Fit AP mode Extended Service Set (ESS) in Fit AP mode Advanced cellular coexistence (ACC), minimizing the impact of interference from cellular networks Multi-user call admission control (CAC) 802.11k and 802.11v smart roaming 802.11r fast roaming (≤ 50 ms) |
Network features | Compliance with IEEE 802.3ab Auto-negotiation of the rate and duplex mode and automatic switchover between the Media Dependent Interface (MDI) and Media Dependent Interface Crossover (MDI-X) Compliance with IEEE 802.1q SSID-based VLAN assignment VLAN trunk on uplink Ethernet ports Management channel of the AP uplink port in tagged and untagged mode DHCP client, obtaining IP addresses through DHCP Tunnel data forwarding and direct data forwarding STA isolation in the same VLAN IPv4/IPv6 access control lists (ACLs) Link Layer Discovery Protocol (LLDP) Uninterrupted service forwarding upon CAPWAP channel disconnection in Fit AP mode Unified authentication on the AC in Fit AP mode AC dual-link backup in Fit AP mode Network Address Translation (NAT) in Fat AP mode IPv6 in Fit AP mode Telemetry in Fit AP mode, quickly collecting AP status and application experience parameters IPv6 Source Address Validation Improvements (SAVI) Multicast Domain Name Service (mDNS) gateway protocol |
QoS features | Priority mapping and scheduling that are compliant with WMM to implement priority-based data processing and forwarding WMM parameter management for each radio WMM power saving Priority mapping for upstream packets and flow-based mapping for downstream packets Queue mapping and scheduling User-based bandwidth limiting Adaptive bandwidth management (automatic bandwidth adjustment based on the user quantity and radio environment) to improve user experience Airtime scheduling Air interface HQoS scheduling Intelligent multimedia scheduling |
Security features | Open system authentication WEP authentication/encryption using a 64-bit, 128-bit, 152-bit or 192-bit encryption key WPA2-PSK authentication and encryption (WPA2-Personal) WPA2-802.1X authentication and encryption (WPA2-Enterprise) WPA3-SAE authentication and encryption (WPA3-Personal) WPA3-802.1X authentication and encryption (WPA3- Personal) WPA-WPA2 hybrid authentication WPA2-WPA3 hybrid authentication WPA2-PPSK authentication and encryption in Fit AP mode WAPI authentication and encryption Wireless intrusion detection system (WIDS) and wireless intrusion prevention system (WIPS), including rogue device detection and containment, attack detection and dynamic blacklist, and STA/AP blacklist and whitelist 802.1X authentication, MAC address authentication, and Portal authentication DHCP snooping Dynamic ARP Inspection (DAI) IP Source Guard (IPSG) 802.11w Protected Management Frames (PMF) DTLS encryption |
Maintenance features | Unified management and maintenance on the AC in Fit AP mode Automatic login and configuration loading, and plug-and-play (PnP) in Fit AP mode Batch upgrade in Fit AP mode Telnet STelnet using SSHv2 SFTP using SSHv2 Web-based local AP management through HTTP or HTTPS in Fat AP mode Real-time configuration monitoring and fast fault locating using the NMS SNMP v1/v2/v3 in Fat AP mode System status alarm Network Time Protocol (NTP) in Fat AP mode |
Location service |
Wi-Fi terminal location (The AP supports the locating service only in Fit or cloud AP mode) |
Cloud mode | |
WLAN features |
Compliance with IEEE 802.11ax and compatibility with IEEE 802.11a/b/g/n/ac/ac Wave 2 Automatic channel scanning and interference avoidance |
Network features | Compliance with IEEE 802.3ab Auto-negotiation of the rate and duplex mode and automatic switchover between the Media Dependent Interface (MDI) and Media Dependent Interface Crossover (MDI-X) Compliance with IEEE 802.1q SSID-based VLAN assignment DHCP client, obtaining IP addresses through DHCP STA isolation in the same VLAN Access control lists (ACLs) Unified authentication on the Cloud management platform Network Address Translation (NAT) |
QoS features | Priority mapping and scheduling that are compliant with WMM to implement priority-based data processing and forwarding WMM parameter management for each radio WMM power saving Priority mapping for upstream packets and flow-based mapping for downstream packets Queue mapping and scheduling User-based bandwidth limiting Airtime scheduling Air interface HQoS scheduling |
Security features | Open system authentication WEP authentication/encryption using a 64-bit, 128-bit, 152-bit or 192-bit encryption key WPA2-PSK authentication and encryption (WPA2-Personal) WPA2-802.1X authentication and encryption (WPA2-Enterprise) WPA3-SAE authentication and encryption (WPA3-Personal) WPA3-802.1X authentication and encryption (WPA3- Personal) WPA-WPA2 hybrid authentication WPA2-WPA3 hybrid authentication 802.1X authentication, MAC address authentication, and Portal authentication DHCP snooping Dynamic ARP Inspection (DAI) IP Source Guard (IPSG) |
Maintenance features | Unified management and maintenance on the Cloud management platform Automatic login and configuration loading, and plug-and-play (PnP) Batch upgrade Telnet STelnet using SSHv2 SFTP using SSHv2 Web-based local AP management through HTTP or HTTPS Real-time configuration monitoring and fast fault locating using the NMS System status alarm Network Time Protocol (NTP) |