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Products and SolutionsH3C CPE5100X Wi-Fi 7 Dual-Radio Access Point
Leveraging unprecedented ultra-high speed, enhanced security protection, and highly resilient connectivity capabilities, H3C Wi-Fi 7 Access Points deliver a transformative upgrade to user experience, emerging as the ideal network solution for high-density scenarios. Whether for on-premises, cloud, or hybrid deployment models, they can all seamlessly integrate into the existing network infrastructure. With their flexible deployment features, they comprehensively cover high-bandwidth and high-quality network experience scenarios, and accurately meet diverse needs.
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Wi-Fi 7 AP with Powerful Capabilities
H3C Wi-Fi 7 Series Access Points (APs) are specifically designed for demanding users, corely delivering secure, highly resilient, and high-performance Wi-Fi connectivity—accurately meeting the rigorous wireless experience requirements of enterprise-grade scenarios.
H3C Wi-Fi 7 series APs support three flexible AP modes (CloudAP, FitAP, AnchorAP), which can operate independently or work in collaboration with wireless controllers. They can be freely switched according to actual deployment needs, adapting to different network architectures. Meanwhile, they are paired with H3C’s Cloudnet cloud-based deployment platform and AD-Campus on-premises deployment platform—both platforms are equipped with capabilities for intelligent automated management, AI-driven insights, and unified infrastructure management and control. Leveraging these two flexible deployment options, users can easily enable full-lifecycle management of Wi-Fi 7 APs, maximizing the efficiency of intelligent O&M (Operations and Maintenance). This thus ultimately meets the diverse application scenario needs of various enterprises.
Wi-Fi 7 CPE5100X Key Features
Flexible and diverse networking modes
Used in scenarios such as industrial manufacturing, smart parks, and branches, the CPE5100s enable 5G-incapable devices to connect and use 5G networks for data transmission.The CPE5100X accesses the 5G network through the radio interface. It transmits camera video information and collection data to the application server, and receives and sends control directives from the application server to the attached devices.
Traditionally, APs connect to an AC over wires on a WLAN network, which is inconvenient and costly. This issue can be resolved by attaching APs to CPE5100s that connects to the uplink network over 5G. To further reduce network construction difficulty and cost, and improve overall reliability, you can configure the CPE5100s to operate in fit AP mode. In fit AP mode, each CPE5100X functions as one CPE plus one AP. The CPE5100X working in fit AP mode registers with the AC, and the AC manages all registered CPE5100s. As the authentication gateway of the Wi-Fi clients, the CPE5100X initiates authentication requests to the wireless authentication platform. The portal and MAC authentication modes are supported. This networking solution provides more benefits, such as Unified IP planning and assignment for Wi-Fi clients, Wi-Fi client transparent authentication across CPE5100s (fit AP), Wi-Fi client roaming across CPE5100X (fit AP).
5G/Wi-Fi dual uplink networking
The CPE5100X supports 5G and Wi-Fi dual uplink connections. In a network environment with both 5G and WLAN, the 5G and Wi-Fi links can back up each other to improve transmission reliability.In a scenario where both 5G and WLAN connections are available, you can configure the CPE5100X as a Wi-Fi client and connect an endpoint to the physical port on the CPE5100.You can configure Wi-Fi or 5G as the primary link, with the other link as the backup link. The system uses NQA and Track collaboration to facilitate link switchover. When the primary link fails, traffic automatically switches to the backup link. When the primary link restores, traffic is switched back.
5G and wired dual-link redundancy
CPE5100X supports dual uplink connections with both 5G and wired links. In network environments with both 5G and wired links deployed, the 5G and wired links can back up each other to enhance transmission reliability. You can configure the wired or 5G link as the primary link, and the other link as the backup link.Traffic switches between the primary and backup links dynamically through NQA and Track collaboration. When the primary link fails, traffic automatically switches to the backup link. When the primary link is restored, traffic switches back from the backup link.
Wi-Fi 7 standard
The IEEE 802.11be standard (Wi-Fi 7) is the latest Wi-Fi technical standard currently available, encompassing core enhanced features such as 4096 Quadrature Amplitude Modulation (4096-QAM), Multi-Link Operation (MLO), Enhanced Orthogonal Frequency Division Multiple Access (OFDMA), and preamble puncturing technology that supports a 320 MHz channel width.
Wi-Fi 6E is a core technical "extension" of Wi-Fi 6 to the 6 GHz frequency band, while Wi-Fi 7 represents a technical evolution and upgrade of Wi-Fi 6/Wi-Fi 6E — it builds on Wi-Fi 6E by adding and enhancing core functions including support for 320 MHz wide channels, Multi-Link Operation (MLO), and 4096-QAM (4K-QAM) modulation technology. These improvements can significantly boost data transmission rates and connection stability, making it particularly suitable for application scenarios with stringent low-latency requirements, such as AR and VR.
Wi-Fi 7 6GHz Frequency Band Advantages
Wi-Fi 7 makes full use of the up to 1200 MHz of available spectrum resources in the 6 GHz frequency band to achieve higher network throughput and better application performance.Relying on up to three 320 MHz independent channels that can be allocated in this frequency band, Wi-Fi 7 can more effectively support scenarios requiring low latency and high bandwidth, such as 8K and other ultra-high-definition (UHD) video, augmented reality/virtual reality (AR/VR), and high-speed large-file transmission.
Only devices compatible with the Wi-Fi 6E or Wi-Fi 7 standards can access the 6 GHz frequency band; older devices (e.g., those supporting only Wi-Fi 5 and earlier standards) need to continue using the 5 GHz or 2.4 GHz frequency bands. This frequency band division will neither cause interference to transmissions in the 6 GHz frequency band nor lead to reduced speeds for older devices in their original frequency bands.
H3C Cloudnet Cloud-Based Deployment and Management
H3C Wi-Fi 7 series APs can work in cloud AP mode, and can also collaborate with wireless controllers (ACs). If combined with the H3C Cloudnet cloud platform, enterprises can achieve unified monitoring and management of wired and wireless networks, and obtain an integrated operation and maintenance experience.
The Cloudnet platform is equipped with an intuitive interactive Web interface and advanced, scalable management tools. It adopts a fully distributed architecture, enabling comprehensive management of network, terminal, user, and service activation functions.
H3C AD-Campus On-Premises Deployment and Management
H3C Wi-Fi 7 series APs can work in cloud AP mode, and can also collaborate with wireless controllers (ACs). If combined with the H3C AD-Campus platform, enterprises can achieve unified monitoring and management of wired and wireless networks, and obtain an integrated operation and maintenance experience.
The AD-Campus platform is equipped with an intuitive, user-friendly web interface, supports network control, and provides a unified view of the network topology while enabling policy-based network management.
Diverse Multi-Device Collaboration Modes for APs
H3C Wi-Fi 7 series APs support operation in FitAP mode and work in collaboration with wireless controllers, switches, routers and security products with embedded wireless controllers. This enables them to adapt to scenarios of different scales, simplify O&M (Operations and Maintenance) to reduce costs, enhance network performance and security, support flexible business expansion, and ultimately achieve on-demand deployment while protecting customers' early-stage investments.
IoT Extended Functions
H3C Wi-Fi 7 series APs integrate practical extended functions to support smart applications across multiple scenarios. Each AP is built with a high-performance Bluetooth module (supporting BLE 5.0 or higher); when integrated with third-party professional positioning service systems, it can enable positioning services, meeting the needs for visual asset management in various scenarios.
In addition, to address the diverse connectivity requirements of the Internet of Things (IoT) ecosystem, the AP is equipped with PoE_out (Power over Ethernet Output) ports: the PoE_out ports can simultaneously provide data transmission and power supply for power-dependent IoT devices. This eliminates the need for additional power line deployment and significantly reduces the installation and O&M (Operations and Maintenance) costs of IoT devices.
AI-Powered Dynamic Power Save
H3C Wi-Fi 7 series APs employ a green design that supports Dynamic and Static SM Power Saving (SMPS) and Enhanced Automatic Power Save Delivery (E-APSD). They can dynamically adjust the MIMO working mode and efficiently put terminals to sleep. H3C Wi-Fi 7 series APs support green AP mode, which enables single radio standby while allowing for more precise power control; additionally, they feature a function that automatically wakes up APs at preset times and adapts to usage scenarios based on connection requirements—for instance, during low-demand periods such as non-working hours and weekends, this function automatically turns off radio modules, effectively reducing device power consumption and cutting operational costs.
Wireless Security policy
The APs support WPA2-Personal, WPA2-Enterprise, WPA3-Personal, WPA3-Enterprise authentication and encryption modes to ensure security of the wireless network.
APs support WIPS, and can monitor, identify, defend, counter, and perform refined management on the rogue devices, to provide security guarantees for air interface environment and wireless data transmission.
The CAPWAP link protection and DTLS encryption provide security assurance, improving data transmission security between the AP and the AC.
Secure infrastructure
Trusted systems built on H3C Secure Boot provide a strong security foundation for H3C products.All device software compilations utilize RSA asymmetric encryption to ensure the integrity and authenticity of firmware and boot programs. The basic boot code in tamper-resistant partitions establishes a Root of Trust, and forms a Chain of Trust by verifying subsequent stages to enable secure system boot and validate software trustworthiness, thus effectively defending against man-in-the-middle attacks targeting software and firmware.
Doctor AP
Doctor AP mode, combining H3C AC and H3C intelligent O&M platform, collects wireless network information for scenarios where terminal access is abnormal, and analyzes and locates wireless faults quickly and accurately.
Radio Resource Management
Radio Resource Management (RRM), the AP monitors air interface channel utilization, channel interference, and signal conflict in real time, and works with H3C intelligent O&M platform to adjust RF parameters such as working channel, bandwidth, and power in a timely manner to maintain the optimal RF resource status.
Radio Resource Optimization Policy
Radio Resource Optimization Policy (RROP) refers to the collection of multiple wireless air interface optimization methods, which is committed to reducing or controlling the consumption of air interface media resources by management packets, broadcast packets, and invalid packets. Set aside more resources to provide users with better wireless application services.
Station Access Control Policy
The Station Access Control Policy (SACP) restricts, controls, and guides the access of wireless terminals to better AP or wireless services. In addition, terminal traffic is controlled and scheduled according to network applications to improve the overall performance of the wireless network and improve the experience and effect of wireless access applications.
Roaming protection
Wireless AP fully supports the Fast BSS Transition function defined in the 802.11r standard, which can accelerate the roaming process of wireless users, reduce the probability of connection interruption, and improve the roaming service quality. Through 802.11k protocol mechanism, AP and wireless client interact with each other to perceive the network topology in multiple dimensions. The AC recognizes and calculates the roaming time and roaming access location of the wireless client in full view, and negotiates the switch with the client through 802.11v and 802.11r mechanisms.
Application guarantee
APs support smart application control technology and can implement visualized control on Layer 4 to Layer 7 applications. Coupled with H3C WLAN ACs, the APs can identify a large number of common applications in various office scenarios. Based on the identification results, policy control can be implemented on user services, including priority adjustment, scheduling, blocking, and rate limiting to ensure efficient bandwidth resource and improve quality of key services.
Global Wi-Fi 7 regulations
On a global scale, while there is a broad consensus among countries on the need for greater Wi-Fi capacity, progress in opening up the 6GHz frequency band varies. H3C Wi-Fi 7 series APs can adjust flexibly based on the status of frequency band opening and regulatory requirements in different countries. Once relevant Wi-Fi 7 regulations are officially approved and certified, the devices will automatically update regulatory configurations to ensure compliance and smooth activation of Wi-Fi 7 functionality.
Hardware specifications
Weight | 2.05kg | |||||
Dimensions (W × D × H) | 260 mm × 260 mm × 84 mm (without mounting brackets) | |||||
Interface | 1 x 100/1000M/2.5G Ethernet, RJ-45, PoE input 1 x 1000M/10G optical port, SFP+, PoE input 1 x 10/100/1000M Ethernet, RJ-45, PoE output | |||||
Console port | 1 x Management console port (RJ-45) | |||||
SIM card slot | 2 x SIM card slots (only one active at a time) with automatic backup | |||||
PoE input | 1 x 100/1000M/2.5G Ethernet, 802.3bt/at 1 x 1000M/10G optical port, 802.3bt/at | |||||
PoE output | 1 x 10/100/1000M Ethernet, 802.3af | |||||
Local power supply | POE injector (sold separately) | |||||
Antenna type | External antenna | |||||
Antenna gain | The Antenna Gains are dependent on External antenna | |||||
Frequencybands | 2.400 to 2.4835GHz ISM 5.150 to 5.250GHz U-NII-1 5.250 to 5.350GHz U-NII-2A 5.470 to 5.725GHz U-NII-2C 5.725 to 5.850GHz U-NII-3/ISM 5.850 to 5.895 GHz U-NII-4 5.925 to 6.425GHz U-NII-5 6.425 to 6.525GHz U-NII-6 6.525 to 6.875GHz U-NII-7 6.875 to 7.125GHz U-NII-8 5G NR NSA: n1/n2/n3/n5/n7/n8/n12/n13/n14/n18/n20/n25/n26/n28/n29/n30/n38/n40/n41/n48/n66/n70/n71/n75/n76/n77/n78/n79 5G NR SA: n1/n2/n3/n5/n7/n8/n12/n13/n14/n18/n20/n25/n26/n28/n29/n30/n38/n40/n41/n48/n66/n70/n71/n75/n76/n77/n78/n79 LTE-FDD: B1/B2/B3/B4/B5/B7/B8/B12/B13/B14/B17/B18/B19/B20/B25/B26/B28/B29/B30/B32/B66/B71 LTE-TDD: B34/B38/B39/B40/B41/B42/B43/B46(LAA)/B48 Note: The available bands and channels are dependent on the configured regulatory domain (country) | |||||
802.11b: Direct-sequence spread spectrum (DSSS) 802.11a/g/n/ac: Orthogonal frequency-division multiplexing (OFDM) 802.11ax/be: Orthogonal frequency-division multiple access (OFDMA) | ||||||
Modulation mode | 11b: BPSK, QPSK, CCK 11a/g/n: BPSK, QPSK, 16QAM, 64QAM 11ac: BPSK, QPSK, 16QAM, 64QAM, 256QAM 11ax: BPSK, QPSK, 16QAM, 64QAM, 256QAM, 1024QAM 11be: BPSK, QPSK, 16QAM, 64QAM, 256QAM, 1024QAM, 4096QAM 5G NR UL: π/2-BPSK, QPSK, 16QAM, 64QAM, 256QAM 5G NR DL: QPSK, 16QAM, 64QAM, 256QAM LTE UL: QPSK, 16QAM, 64QAM, 256QAM LTE DL: QPSK, 16QAM, 64QAM, 256QAM | |||||
Data rates (Mbps) | 802.11b: 1, 2, 5.5, 11 802.11a/g: 6, 9, 12, 18, 24, 36, 48, 54 802.11n: 6.5 to 600 (NSS = 1 to 4, HT20 to HT40) 802.11ac: 6.5 to 6,933 (MCS0 to MCS9, NSS = 1 to 8, VHT20 to VHT160) 802.11ax: 7.3 to 9,608 (MCS0 to MCS11, NSS = 1 to 8, HE20 to HE160) 802.11be: 7.3 to 23,059 (MCS0 to MCS13, NSS = 1 to 8, EHT20 to EHT320) | |||||
Maximum transmit power | 5G NR: 26 dBm (class 2) and 23 dBm (class 3) 6G: 27 dBm 5G: 27 dBm 2.4G: 30 dBm Note: Transmit power is multi-chain combined power, no antenna gain is included. The actual transmit power depends on local laws and regulations Note: To comply with spectrum regulatory requirements across different regions, the 6GHz RF (Radio Frequency) function of the device will be in a disabled state in countries/regions where the use of the 6GHz band is prohibited. Once the policy for 6GHz band usage in such countries/regions is implemented, this function can be officially activated in conjunction with future software update processes, ensuring the device operation complies with local regulations | |||||
Adjustable power granularity | Configurable in increments of 1dBm | |||||
Reset button | Restoration to factory default, AP mode control(CloudAP/FitAP) | |||||
Kensington | Kensington security slot | |||||
Wall mounting/Pole mounting, the AP does not come with the mounting bracket by default and must be purchased separately | ||||||
Indicators (LED) | Yellow/green/blue status LEDs for different working states indicate boot loader status, association status, operating status, and fault states of the system | |||||
Temperature | Operating temperature: -40°C to +65°C Storage temperature: -40°C to +85°C | |||||
Humidity | Operating humidity: 0% to 100% (non-condensing) Storage humidity: 0% to 100% (non-condensing) | |||||
Protection class | IP68 | |||||
Surge protection | Common Mode:6KV | |||||
Overall power consumption | Power Source | 6GHz/5GHz Radio | 2.4GHz/5GHz Radio | Link speed | PSE | Max PoE power consumption |
802.3bt | 2*2 | 2*2 | 2.5Gbps | Y | 39.8W | |
802.3at | 2*2 | 2*2 | 2.5Gbps | N | 24.8W | |
802.3af | - | - | - | - | - | |
POE injector | 2*2 | 2*2 | 2.5Gbps | Y | 39.8W | |
Note: Actual power consumption may vary depending on access point usage. | ||||||
Safety standards | GB 4943.1 EN 62368-1:2014+A11:2017 EN 60825-1:2014+A11:2021 EN 60950-22:2017 | |||||
EMC standards | EN 301 489-1 EN 301 489-3 EN 301 489-17 EN 60601-1-2 EN 55032:2015+A11:2020 EN 55035:2017 EN 55035:2017+A11:2020 | |||||
CISPR 32 CISPR 35 AS/NZS CISPR32 ICES-003 Issue 7 GB/T 9254.1 GB/T 9254.2 GB 17625.1 GB 17625.2 | ||||||
IEC/EN 61000-4-2 IEC/EN 61000-4-3 IEC/EN 61000-4-4 IEC/EN 61000-4-5 IEC/EN 61000-4-6 IEC/EN 61000-4-8 IEC/EN 61000-4-11 IEC/EN 61000-3-2 IEC/EN 61000-3-3 | ||||||
Radio standards | ETSI EN 300 328 ETSI EN 301 893 ETSI EN 303 687 | |||||
RoHS standards | EN 301 893 V2.2.1 EN IEC 63000:2018 | |||||
Health standards | EN 50385:2017 EN IEC 62311:2020 | |||||
Cybersecurity | EN 18031-1:2024 EN 18031-2:2024 | |||||
Ecodesign | (EC) No 1275/2008, (EU) No 801/2013, EN 50564:2011 | |||||
MTBF (25°C) | 734102 hours | |||||
Software specifications
Item | Specification | |
Product capabilities | Basic information | Outdoor, dual-radio AP, 802.11a/b/g/n/ac/ac Wave 2/ax/be |
AP Operating Mode | Fit AP Mode, managed by Wireless LAN Controller Cloud AP Mode, managed by H3C intelligent O&M platform Note: AP Operating Modes can be switched via CLI, Wireless LAN Controller, H3C intelligent O&M platform, Reset button | |
Supported Wireless LAN Controllers | H3C WX2800X, WX3800X, WX5800X Series Wireless LAN Controllers | |
Frequency and MIMO | Dual-radio mode (Default) 5GHz, 2×2:2, 2.882Gbps 2.4GHz, 2×2:2, 0.688Gbps Dual-radio mode 6GHz, 2×2:2, 5.765Gbps 5GHz, 2×2:2, 2.882Gbps Dual-radio mode 5GHz, 2×2:2, 2.882Gbps 5GHz, 2×2:2, 2.882Gbps Dual-radio mode 6GHz, 2×2:2, 5.765Gbps 2.4GHz, 2×2:2, 0.688Gbps | |
Compliance and bandwidth | 6GHz, 802.11ax/be 20MHz/40MHz/80MHz/160MHz/320MHz 5GHz, 802.11a/n/ac/ax/be 20MHz/40MHz/80MHz/160MHz 2.4GHz, 802.11b/g/n/ax/be 20MHz/40MHz | |
Maximum transmission speed | 8.647 Gbps (2x2 320 MHz on 6GHz, and 2x2 160 MHz on 5GHz) 6.453 Gbps (2x2 320 MHz on 6GHz, and 2x2 40 MHz on 2.4GHz) 5.764 Gbps (2x2 160 MHz on 5GHz, and 2x2 160 MHz on 5GHz) 3.57 Gbps (2x2 160 MHz on 5GHz, and 2x2 40 MHz on 2.4GHz) | |
Maximum number of clients | 1024 (512 on 6GHz/5GHz, and 512 on 5GHz/2.4 GHz) Note: the actual number of users varies according to the environment | |
Maximum number of BSSIDs for each radio | 16 | |
5G capabilities | 3GPP Protocol | 3GPP Rel-16 |
5G NR Standard | 5G NSA 5G SA | |
LTE Standard | LTE-FDD LTE-TDD | |
5G NR MIMO | UL 2x2 DL 4×4 | |
LTE MIMO | UL 2x2 DL 4×4 | |
802.11be | 320MHz channel width | The 6GHz frequency band is one of the core key technologies of Wi-Fi 7. With its ultra-large available bandwidth of 1200 MHz, it can support a configuration of up to 3x 320 MHz channels, accurately supporting low-latency and high-bandwidth-consuming application scenarios such as high-definition video and AR/VR. Furthermore, this frequency band is restricted to access by devices that support Wi-Fi 6E or Wi-Fi 7, effectively avoiding interference and speed loss caused by traditional Wi-Fi devices at the source |
4096-QAM | As one of the key technologies of Wi-Fi 7, 4096-QAM is an quadrature amplitude modulation (QAM) technology capable of carrying 12 bits of data per symbol. Under identical coding conditions, it delivers a 20% increase in data rate compared to the 1024-QAM used in Wi-Fi 6, laying a solid technical foundation for various high-bandwidth applications | |
MLO | Multilink operation (MLO) is a core technology in Wi-Fi 7 (802.11be) that enables devices to establish simultaneous connections across multiple frequency bands and channels (2.4 GHz, 5 GHz, 6 GHz) to achieve dramatically improved throughput, latency, and reliability | |
Preamble puncturing | Preamble puncturing is a key technology for Wi-Fi 7 to break through the limitations of spectrum resources. By dynamically eliminating interfered subchannels, it enables the efficient utilization of non-contiguous spectrum resources, significantly enhancing the network's anti-interference capability and spectrum utilization efficiency | |
Multi-RU (Multi-Resource Unit) is a core physical-layer technology introduced in Wi-Fi 7. It enables the maximization of spectrum resource utilization through the dynamic aggregation of multiple Resource Units (RUs), addressing bandwidth bottlenecks and interference issues in high-density networks | ||
MU-MIMO | Uplink / Downlink Multi-user multiple-input multiple-output (MU-MIMO) | |
Uplink / Downlink Orthogonal frequency division multiple access (OFDMA) | ||
802.11ax | TWT | Target Wake Time, allowing clients to sleep for a predetermined period of time and be awakened only when network communication is needed, effectively reducing the power consumption |
BSS coloring/SR | Spatial reuse, dividing different BSSs into different colors to avoid co-frequency interference and improve the user experience of wireless networks | |
MU-MIMO | Uplink / Downlink Multi-user multiple-input multiple-output (MU-MIMO) | |
OFDMA | Uplink / Downlink Orthogonal frequency division multiple access (OFDMA) | |
WLAN basics | A-MPDU | Aggregated MAC Protocol Data Unit, improves the data transmission efficiency of wireless networks by optimizing the composition of TX/RX directional data packets |
A-MSDU | Aggregated MAC Service Data Unit, improves the data transmission efficiency of wireless networks by optimizing the composition of TX/RX directional data packets | |
LDPC | Low-density Parity-Check, improves the communication efficiency of wireless networks through error correction coding technology | |
LACP | Link Aggregation Control Protocol, achieving bandwidth aggregation, redundancy backup, and load balancing, the APs require at least 2 ports | |
STBC | Space-Time Block Coding, improve the Channel capacity of wireless networks through multi-antenna coding technology | |
DFS | 802.11 Dynamic Frequency Selection, automatically identify DFS frequency bands, automatically adjust frequencies of the devices, and avoid interference with other devices | |
TxBF | Transmit Beamforming, improve the signal-to-noise ratio of wireless network signal transmission by adjusting the beam direction of antenna transmitting signals | |
CCF | Cellular coexistence feature, use built-in software filtering to minimize the impact of interference from 3G/4G cellular networks | |
MRC | Maximum-ratio combining, improve signal reception quality | |
CDD/CSD | Cyclic Delay Diversity/Cyclic Shift Diversity, improve signal reception quality | |
Tunnel management | CAPWAP tunnel | Unicast/broadcast/DNS/DHCP/static IP method for discovering AC |
NAT | NAT between AC and AP | |
DTLS | Tunnel between AC and AP support DTLS encryption | |
IPv4/IPv6 | Tunnel between AC and AP support IPv4 and IPv6 | |
Time synchronization | Synchronizing clock information from AC | |
Dual tunnel | Establishing CAPWAP tunnels with two ACs | |
PPPOE | PPPOE Client | |
IPsec | Cloud AP mode Support IPsec | |
WLAN extension | RF adjustment | Automatic channel/power/bandwidth adjustment |
SSID hiding | Restrict access and improve wireless network security by SSID hiding | |
User access count restriction based on SSID and RF | ||
Forwarding mode | Centralized forwarding/local forwarding/policy forwarding | |
Local forwarding | Local forwarding based on SSID and VLAN | |
VLAN binding | Binding VLAN based on interface/SSID/MAC | |
User isolation | VLAN-based user isolation SSID-based user isolation | |
Load balancing | Traffic-based load balancing User-based load balancing Frequency band-based load balancing, dual-5G devices only | |
Band steering | ||
Roaming | 802.11k and 802.11v smart roaming 802.11r fast transition roaming | |
Multicast enhancement | IPv4/IPv6 MLD Snooping/IGMP Snooping Convert multicast data into unicast data for transmission, reducing network congestion | |
Wireless location | Fit AP mode support RSSI location | |
IOT | IoT expansion by connecting third-party RFID or Zigbee gateways through PSE port | |
Mesh | Mesh link Mesh link security Multi-hop Mesh | |
Wireless probing | Monitor the wireless network environment by monitoring wireless network messages | |
Hotspot 2.0 | Fit AP mode support Hotspot 2.0 | |
Bonjour gateway | Forwarding mDNS packets across VLANs | |
User authentication | 802.1X authentication | Local and remote 802.1X authentication |
MAC authentication | Local and remote MAC authentication | |
Portal authentication | Local and remote Portal authentication Guest/Captive portal Portal mac-trigger | |
PSK | PSK and Private-PSK | |
PPSK | Fit AP mode support Private Pre-Shared Key, obtain passwords to access wireless networks through the H3C intelligent O&M platform | |
Social Media APPs Authentication | Cloud AP mode support Google/Facebook/Twitter through the H3C intelligent O&M platform | |
Extensible Authentication Protocol (EAP) | EAP-Transport Layer Security (TLS) EAP-Tunneled TLS (TTLS) Microsoft Challenge Handshake Authentication Protocol (MSCHAP) v2 Protected EAP (PEAP) v0 or EAP-MSCHAP v2 EAP-Flexible Authentication via Secure Tunneling (EAP-FAST) PEAP v1 or EAP-Generic Token Card (GTC) EAP-Subscriber Identity Module (SIM) | |
Wireless security | Encryption | TKIP, CCMP WEP40, WEP104 WPA2-Personal (802.11i) WPA2-Enterprise with 802.1X WPA3-Personal, WPA3-Enterprise WPA3-Enhanced Open (OWE) Advanced Encryption Standard (AES) |
Forwarding security | Packet filtering MAC address filtering Broadcast storm suppression | |
Wireless EAD | Coupled with EAD (End user Admission Domination) solution, implement security policies for terminals accessing the network to improve wireless network security | |
Management frame protection | Provide management frame protection for wireless clients to enhance wireless network security | |
WIPS | Wireless Intrusion Prevention System, protect the network from unauthorized access, such as Rogue AP, Rogue client, Rogue Wireless Bridge, Ad-hoc | |
IPSG | IP source guard (IPSG) prevents spoofing attacks by using an IPSG binding table to filter out illegitimate packets | |
Layer 2 and Layer 3 | IP address configuration | Static IP/DHCP assigned IP |
DHCP | Server/client/relay | |
NAT | NAT/NAT66/NAT LOG | |
LLDP | Link Layer Discovery Protocol, discovering and identifying other LLDP enabled devices and neighboring devices in the network | |
STP | Spanning Tree Protocol, preventing loops in the network | |
IPv4 | ICMP/ACL/DHCP/TFTP/FTP/DNS | |
IPv6 | ICMP/ACL/DHCP/TFTP/FTP/DNS | |
Service assurance | Remote AP | After the tunnel between AC and AP is disconnected, AP continues to provide services to clients |
Doctor AP* | Fit AP mode support Doctor AP, simulates wireless client access process, diagnoses network issues, and improves network experience | |
Spectrum Analysis | Displaying the non-Wi-Fi interference sources through the H3C intelligent O&M platform | |
Only 802.11ax accessing | Only wireless clients that support 802.11ax can access the network, improving the network experience | |
Intelligent bandwidth guarantee | Ensure that different wireless services can obtain the lowest guaranteed bandwidth during network congestion | |
Port Aggregation | Multiple uplink ports for port aggregation to increase uplink bandwidth (only applicable to multiple uplink port APs) | |
Broadcast suppression | Discard ARP request and response packets from wireless clients during the suppression cycle | |
Prohibit weak signal client access | AP prohibits wireless clients with signals below the threshold from accessing, to avoid low-signal clients occupying more channel resources | |
Terminal roaming navigation | Adjust the AP transmission power to create more roaming conditions and improve the roaming experience | |
Actively triggering client relinking | AP actively sends messages to allow wireless clients to reconnect or roam actively | |
Adjust channel reuse between APs | RF chip adjusts the environmental noise perceived by the device to improve AP transmission efficiency | |
Fast forwarding function for client data services | Intelligent optimization of RF chip business processing can improve performance | |
Shorten client sleep time | RF chips shorten client sleep time and improve transmission efficiency through beacons | |
Software version anomaly repairing | After the software version is damaged due to abnormal circumstances, AP can automatically download the available software version through AC or cloud platform | |
Service quality | WMM | Wi-Fi Multimedia, Improve the service quality of audio and video transmission in wireless networks through EDCA scheduling algorithm |
QoS | Priority Class, by marking TOS/DSCP fields to distinguish data streams with different priorities, high priority data streams can be quickly distributed, thereby improving service quality Priority Class, support mapping from wireless priority to wired priority QoS policy mapping, support QoS policy mapping based on SSID and VLAN Layer 2 to Layer 4 packet filtering and traffic classification CAR (Committed Access Rate), by limiting data transmission rate, avoid network congestion caused by traffic congestion | |
User bandwidth management | Allocate available bandwidth per STA Allocate total bandwidth for all STA shares based on SSID Dynamically adjust the available bandwidth of STA based on business | |
ATF | Air Time Fairness, by allocating an equal amount of RF usage time, reducing wireless channel congestion and improving the efficiency and fairness of wireless networks | |
CAC | Call Admission Control, improve the quality of service for wireless clients that have already received high priority by limiting the number of wireless clients that have received high priority Support number of users/Channel utilization based | |
Application Identification | SQA (Software Quality Assurance), identifies audio and video services based on SIP protocol, prioritizing service quality assurance UCC (Unified Communications and Collaboration), increase the processing priority of audio and video services and prioritize ensuring service quality | |
Power saving | Green AP mode | Dynamically adjust MIMO configuration based on wireless client access status to reduce device power consumption |
U-APSD | Unscheduled Automatic Power Save Delivery, reduce device power consumption by scheduling VoIP data streams separately from non-VoIP data streams | |
SM Power Save | Spatial Multiplexing Power Save, reduce device power consumption through low-power standby mode | |
Management and maintenance | GUI | Cloud AP mode support WEB management via HTTP/HTTPS |
Cloud AP mode support SNMP V1/V2c/V3 In Fit AP Mode, the Wireless LAN Controller can support SNMP V1/V2c/V3 | ||
MIB | RFC 1213 MlB-II Stands for Management Information Base RFC 3418 Management Information Base (MlB) for the Simple Network Management Protocol (SNMP) | |
Remote debugging | SSH V2.0/Telnet/FTP/TFTP | |
Local debugging | Support CLI | |
Information maintenance | Cloud AP mode support Syslog | |
Secure boot | Supporting firmware protection, ensuring the integrity of the subsequent running program codes through the trusted Boot-Loader, forming a trusted device boot chain | |
Netconf | Cloud AP mode Support Netconf provides programmable and scalable methods to manage network devices | |
IEEE standards | 802.11 | IEEE 802.11a/b/g/n/ac/ac Wave 2/ax/be IEEE 802.11d/e/h/i/w/u IEEE 802.11k/v/r |
802.3 | 802.3af/802.3at/802.3bt 802.3az | |
802.15 | 802.15.1 | |
Wi-Fi certified | Wi-Fi Alliance:Wi-Fi 7, Wi-Fi 6E, Wi-Fi 6, WMM, WPA, WPA2 and WPA3 – Enterprise, Personal (SAE), Enhanced Open (OWE) | |
- The features marked with * can be implemented through software upgrade.
- The options may be different depending on the specific requirement. Restrictions and limitations may apply. To confirm availability, refer to related user guide or visit H3C website https://www.h3c.com/en/home/htb/.
Product code | Description |
9801A60H | H3C CPE5100X NR External Antennas 5G Customer Premises Equipment (The AP does not come with the mounting bracket by default and must be purchased separately) |
9821A06Q | EWPA-TR-Outdoor-B WA6620X,Outdoor Mounting bracket,structure |
ADP060-55V-PoE-GL H3C 55V Power Supply 60W PoE Injector | |
9821A04F | EWPA-WP-M25*1.5 Water-proof cover, WA5300X Outdoor Series-M25*1.5,10PCS |
2701A02K | ANT-2547V 2.4GHz(4dBi)&5.150~5.850GHz(7dBi),Dual Band Omni Antenna,N-J,Outdoor |
ANT-2510P-M4 Directional Antenna,2400~2500MHz&4900~5950MHz,[email protected]&10dBi@5GHz,Vertical@40°&Horizon@40°,20W,N-J Type | |
2701A02H | ANT-5014P-M4 Directional Antenna,5150~5850MHz,14dBi@5G,Vertical@30°&Horizon@30°,50W,N Type |
2701A02S | ANT-256-08P-M4 Directional Antenna,2400~2500MHz&5150~7150MHz,[email protected]&8dBi@5GHz&8dBi@6GHz,Vertical@35°&Horizon@120°,20W,N Type |
2701A02V | ANT-256-477V Omni Antenna,2400~2500MHz&5150~7150MHz,[email protected]&7dBi@5GHz&7dBi@6GHz,Vertical,Omni,100W,N-J |
9827A03D | ANT-5G-NR-V 5G NR Rod Antenna Kit,5.08dbi(max)@600~960MHz/1710~2170MHz/2300~2700MHz/3300~3800MHz/4400~5000MHz/5150~7125MHz,CPE5100X |
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