Availability: | |
---|---|
Quantity: | |
The ZY-SWO5826 is a cutting-edge, high-performance data center TOR switch introduced by us for cloud computing, data centers, and premium facilities. Featuring advanced hardware architecture, this switch delivers top-tier switching performance and a wide range of data center functionalities. With 24 10GE downlink ports and 2 100GE uplink ports, the ZY-SWO5826 boasts an 880Gbps backplane bandwidth and 660Mpps throughput. Developed with proprietary software, the ZY-SWO5826 integrates IPv6, MPLS VPN, network security, traffic analysis, and virtualization services. Alongside high-speed L2/L3/L4 switching capabilities, it incorporates various high-reliability technologies for data centers, such as uninterrupted upgrades, graceful restarts, and redundancy protection, ensuring continuous network communication.
The ZY-SWO5826 is a cutting-edge, high-performance data center TOR switch introduced by us for cloud computing, data centers, and premium facilities. Featuring advanced hardware architecture, this switch delivers top-tier switching performance and a wide range of data center functionalities. With 24 10GE downlink ports and 2 100GE uplink ports, the ZY-SWO5826 boasts an 880Gbps backplane bandwidth and 660Mpps throughput. Developed with proprietary software, the ZY-SWO5826 integrates IPv6, MPLS VPN, network security, traffic analysis, and virtualization services. Alongside high-speed L2/L3/L4 switching capabilities, it incorporates various high-reliability technologies for data centers, such as uninterrupted upgrades, graceful restarts, and redundancy protection, ensuring continuous network communication.
Application:
Carrier-level Layer 3 optical switches are essential components in telecommunications networks operated by service providers. These switches are deployed in central offices, data centers, and network aggregation points to handle high volumes of traffic and ensure reliable connectivity for voice, data, and video services. They play a critical role in enabling seamless communication between network nodes and delivering high-quality services to end-users.
Carrier-level Layer 3 optical switches offer advanced routing capabilities at the network layer, allowing for efficient packet forwarding based on IP addresses. These switches support features such as Virtual Private Network (VPN) services, Quality of Service (QoS) mechanisms, and traffic management tools to prioritize and optimize data traffic. Additionally, they provide robust security features, including access control and encryption, to safeguard sensitive information and protect against cyber threats. With high port density, scalability, and redundancy options, carrier-grade Layer 3 optical switches ensure reliable and high-performance network operations for service providers.
Application:
Carrier-level Layer 3 optical switches are essential components in telecommunications networks operated by service providers. These switches are deployed in central offices, data centers, and network aggregation points to handle high volumes of traffic and ensure reliable connectivity for voice, data, and video services. They play a critical role in enabling seamless communication between network nodes and delivering high-quality services to end-users.
Carrier-level Layer 3 optical switches offer advanced routing capabilities at the network layer, allowing for efficient packet forwarding based on IP addresses. These switches support features such as Virtual Private Network (VPN) services, Quality of Service (QoS) mechanisms, and traffic management tools to prioritize and optimize data traffic. Additionally, they provide robust security features, including access control and encryption, to safeguard sensitive information and protect against cyber threats. With high port density, scalability, and redundancy options, carrier-grade Layer 3 optical switches ensure reliable and high-performance network operations for service providers.
Item | ZY-SWO5826 | |
Interfaces | 24*10GE/GE (SFP+)+ 2*100GE/40GE (QSFP28) | |
Console | 1 RJ45, 1 MGMT | |
Backplane | 880Gbps | |
Forwarding rate | 660Mpps | |
Chassis | Dimensions(WxDxH)(mm) | 440x300x44 |
Weight(KG)(empty) | 6.1 | |
Package | Dimensions(WxDxH)(mm) | 576*448*94 |
Weight(KG) | 6.2 | |
Environment | Operating temperature/humidity | -10°C -50°C, 10%-90% non-condensing |
Storage temperature/humidity | -20°C-70°C; 5%-95% non-condensing | |
Power supply(hot-swop) | AC:100V-240V, 50Hz±10% DC: -36V~-72V | 2 |
Power status monitoring | Support | |
Total output BTU (1000BTU/H=293W) | 238.91 | |
Fan number | 4 (built-in) | |
Noise@25℃(dBA) | 57 | |
MTBF(H) | >200,000 | |
Forwarding mode | Store-forward | |
FLASH(MB) | 4096 | |
DRAM(MB) | 2048 | |
MAC | 13K | |
Jumbo frame | 16105 | |
Routing table | IPv4 | 16K |
ARP table | IPv4 | 16K |
Total SVI | 1K |
Item | ZY-SWO5826 | |
Interfaces | 24*10GE/GE (SFP+)+ 2*100GE/40GE (QSFP28) | |
Console | 1 RJ45, 1 MGMT | |
Backplane | 880Gbps | |
Forwarding rate | 660Mpps | |
Chassis | Dimensions(WxDxH)(mm) | 440x300x44 |
Weight(KG)(empty) | 6.1 | |
Package | Dimensions(WxDxH)(mm) | 576*448*94 |
Weight(KG) | 6.2 | |
Environment | Operating temperature/humidity | -10°C -50°C, 10%-90% non-condensing |
Storage temperature/humidity | -20°C-70°C; 5%-95% non-condensing | |
Power supply(hot-swop) | AC:100V-240V, 50Hz±10% DC: -36V~-72V | 2 |
Power status monitoring | Support | |
Total output BTU (1000BTU/H=293W) | 238.91 | |
Fan number | 4 (built-in) | |
Noise@25℃(dBA) | 57 | |
MTBF(H) | >200,000 | |
Forwarding mode | Store-forward | |
FLASH(MB) | 4096 | |
DRAM(MB) | 2048 | |
MAC | 13K | |
Jumbo frame | 16105 | |
Routing table | IPv4 | 16K |
ARP table | IPv4 | 16K |
Total SVI | 1K |
Product Name | Product Description | Power Configuration | Accessories |
ZY-SWO5826 | 24*10GE/GE (SFP+)+ 2*100GE/40GE (QSFP28) | AC:100V-240V, 50Hz±10% DC: -36V~-72V |
Product Name | Product Description | Power Configuration | Accessories |
ZY-SWO5826 | 24*10GE/GE (SFP+)+ 2*100GE/40GE (QSFP28) | AC:100V-240V, 50Hz±10% DC: -36V~-72V |
1. What is the importance of selecting the right EDFA based on optical power level?
Choosing the appropriate EDFA based on the optical power level is crucial to ensure optimal performance and prevent signal degradation. Different EDFAs have different power handling capabilities, and selecting the right one ensures efficient amplification without causing signal distortion or damage.
2. How can I determine the optical power level for selecting an EDFA?
The optical power level depends on factors such as the input signal strength, transmission distance, and network requirements. It is recommended to consult with a professional or refer to industry guidelines to determine the appropriate optical power level for your specific application.
3. What are the key specifications to consider for selecting an EDFA based on optical power level?
When choosing an EDFA, it is important to consider the maximum input power, output power, and gain specifications. These specifications should align with the optical power level requirements of your system to ensure reliable and efficient signal amplification.
4. Can the EDFA be adjusted to support different optical power levels?
Some EDFAs offer adjustable gain or have different models available for different power levels. It is advisable to check the specifications and capabilities of the EDFA to ensure it can meet the required optical power level for your application.
5. Are there any additional considerations for high-power applications?
In high-power applications, it is essential to consider factors such as heat dissipation, power stability, and safety measures. EDFAs designed for high-power applications often incorporate advanced cooling mechanisms and protective features to ensure reliable and safe operation.
Please note that the answers provided here are general guidelines. It is recommended to consult with a professional or the manufacturer for specific recommendations based on your optical power level requirements and network configuration.
1. What is the importance of selecting the right EDFA based on optical power level?
Choosing the appropriate EDFA based on the optical power level is crucial to ensure optimal performance and prevent signal degradation. Different EDFAs have different power handling capabilities, and selecting the right one ensures efficient amplification without causing signal distortion or damage.
2. How can I determine the optical power level for selecting an EDFA?
The optical power level depends on factors such as the input signal strength, transmission distance, and network requirements. It is recommended to consult with a professional or refer to industry guidelines to determine the appropriate optical power level for your specific application.
3. What are the key specifications to consider for selecting an EDFA based on optical power level?
When choosing an EDFA, it is important to consider the maximum input power, output power, and gain specifications. These specifications should align with the optical power level requirements of your system to ensure reliable and efficient signal amplification.
4. Can the EDFA be adjusted to support different optical power levels?
Some EDFAs offer adjustable gain or have different models available for different power levels. It is advisable to check the specifications and capabilities of the EDFA to ensure it can meet the required optical power level for your application.
5. Are there any additional considerations for high-power applications?
In high-power applications, it is essential to consider factors such as heat dissipation, power stability, and safety measures. EDFAs designed for high-power applications often incorporate advanced cooling mechanisms and protective features to ensure reliable and safe operation.
Please note that the answers provided here are general guidelines. It is recommended to consult with a professional or the manufacturer for specific recommendations based on your optical power level requirements and network configuration.