How to Choose Best Aggregation Switch?

When selecting an aggregation switch, several critical factors must be considered to ensure optimal performance. These factors may include but are not limited to speed, features, and price. However, in today's highly competitive distribution Layer layer switch market, switches differ in small features, which require careful consideration to select the most suitable switch that is used for the distribution layer in networking. To help you become familiar with these complexities, we present a comprehensive guide to choosing the best aggregation switch.

Aggregation Switch Meaning

What is an Aggregation Switch?

 

An aggregation switch, also known as a distribution layer switch, it performs as both layer 3 and layer 2 devices in the network architecture, enabling the connection of upper core layer switches with access switches and allowing traffic communication between each other. 

 

Importance of Choosing the Best Aggregation Switch

 

In today's rapidly evolving network communications industry, the ability to respond quickly to changing market conditions and customer needs is crucial to the success of any organization. As an integral part of the network infrastructure, selecting the best network aggregation switch is critical to ensuring smooth and efficient data flow across the network. A high-quality aggregation switch offers enterprises the capability to reduce network latency, optimize network performance, enhance user experience, and minimize the risk of network downtime or bottlenecks. 

 

How Does Distribution Layer Switch Work?

 

The aggregation switch, serving as a central hub for data traffic management, collects and forwards data from multiple access switches, which are commonly used to connect network endpoints like servers, computers, and other devices. The aggregation switch implements a series of robust security protocols to authenticate and authorize data traffic before forwarding it efficiently to the core switch, enabling complex data exchange processes. Being a data processing center, aggregation switches require high-capacity processing capabilities to effectively identify valuable traffic and achieve optimal network performance. This makes it ideal for enterprise networks, campus networks, and data center networks.

Distribution Layer Switch VS Access Layer Switch

Function Grade

The distribution Layer Switch differs in function grade. Access layer switches are primarily utilized at layer 2 of the network architecture to establish connections with end devices. Aggregation layer switches can be both used in distribution layer devices, typically operating at layer 3 and are responsible for receiving traffic from the access layer and forwarding it to the core layer in the upper layer.

Port Type

 

Access layer switches feature high port density to accommodate a diverse range of end devices, including PCs, VoIP phones, printers, routers, and IP cameras. In the case of aggregation layer switches, it is critical to prioritize high forwarding performance to efficiently handle all traffic from the access layer. This necessitates a high switching and forwarding capacity, exemplified by the QTS7300-48X2Q4C aggregation layer switch, which delivers an impressive switching capacity of 1920 Gbps and a forwarding rate of 1440 Mpps, enabling it to meet the demands of high-speed networks.

 

Traffic Management 

 

The aggregation switches play a crucial role in managing and controlling traffic from the access layer switch, necessitating a comprehensive range of capabilities, including traffic monitoring, filtering, isolation, and anti-attack measures. Additionally, the aggregation switch must possess load-sharing functionality for the core switch, a capability not typically present in access layer switches.

How to Choose the Best Aggregation Switch？

  

Before choosing the best switch for your network, It is very necessary to ask yourself the following questions, which can help with guidance.

Port  Configuration

 

Since the aggregation layer switch uplink port is connected to the core layer switch and the downlink port is connected to the access layer switch, the prerequisite for us to pick the best aggregation layer switch is to consider the type and number of ports. This will ensure efficient forwarding of the entire network traffic. For example, if your network requires 100G ports for uplink and 10G ports for downlink, then you need to pick a switch with both 10G downlink ports and 100G uplink ports. In terms of the number of ports, it depends on the devices you want to connect, the more ports means the more devices can be connected. A switch with a higher port density can reduce the need for additional switches, thereby simplifying the network architecture and reducing management costs. 

Redundancy

 

The level of redundancy in switches can vary. It is important to note that the redundancy being referred to here pertains to the power supply and fan design of the switch. Typically, switches have at least one power supply, while some have two power supplies, providing 1+1 redundancy and hot-swappable features that guarantee seamless operation and continued functionality even if one power source is disconnected. The fan contributes to efficient heat dissipation, despite producing some noise during operation. When selecting an appropriate switch, consideration should be given to the need for a fan.

Management of Distribution Layer Switch

  

The management of an aggregation switch involves configuration, monitoring, and troubleshooting. Network administrators employ a variety of management tools, such as SNMP, CLI, and web-based interfaces, to effectively manage the aggregation switch. Troubleshooting is a critical component of aggregation switch management and involves using various diagnostic tools, including packet capture, port mirroring, and cable testers, to identify and resolve issues. To isolate network problems, network administrators use different techniques, such as ping testing and traceroute. Successful troubleshooting requires strong analytical and logical thinking skills to identify the root cause of problems. By managing the aggregation switch properly, network administrators can minimize the impact of network issues and ensure the efficient operation of the network.

Multigig Switch

In most small to medium businesses, network infrastructures are based on Cat5e and Cat6 cabling. However, 1 Gbps starts to feel exhausted while the demand for higher speed grows from the edge, these cables fall short. Accommodating 10GBASE-T speeds demands Cat6a or superior Ethernet cables, and integrating higher optical fiber access necessitates costly fiber cables, a notable burden for SMBs. Enter the multi-gigabit switch, a savvy solution. By merging speeds from 2.5G to full gigabit, it cleverly leverages existing Cat5e and Cat6 cabling, sidestepping the need for expensive re-cabling during the transition to 2.5G speeds. QSFPTEK has unveiled the S7300-48TE4X2Q multi-gig switch, engineered to vault data rates past 1Gbps. Boasting 48 ports with multi-gig RJ45 interfaces primed for 100M, 1000M, and 2.5GBASE-T speeds, it also flaunts 4 10Gb SFP+ ports and 2 40Gb QSFP+ uplink ports. The 2.5G switch ports usher in vastly improved gigabit speeds, staying compatible with 100M and 1000Mbps connections, a perfect fit for scenarios like Wi-Fi access or next-gen multi-rate LAN wired networks. Furthermore, SFP+ and QSFP+ uplink ports establish 10G and 40G links, fortifying the network's core connectivity.

Advanced Function 

Aggregation layer switches typically accept all traffic from the access layer and forward it to the core, so to ensure a high performance and secure operation of the network, we should usually consider the following four advanced features when selecting the best aggregation layer switch.

Qos: Aggregation switches play a crucial role in network architecture by collecting and forwarding data from multiple access switches, serving as the hub for data from multiple access switches. They are ideal for implementing quality of service (QoS) to prioritize critical traffic, such as voice and video, through classification, labeling, and scheduling techniques. At the same time, QoS can limit the bandwidth allocated to non-critical traffic, optimizing network performance and resource allocation.

Link aggregation(LACP): Link aggregation is an important feature of aggregation switches, following specific protocols and standards such as IEEE 802.3ad, LACP, or PAgP. enables network administrators to combine multiple physical links into a single logical link, increasing available bandwidth, reducing congestion, and increasing network throughput. Link aggregation also provides redundancy, ensuring that in the event of a link failure, traffic can be automatically rerouted through the remaining links, minimizing the impact of the failure on the network.

Security protocols: The security policy for aggregation switches contains access control, traffic filtering, and attack prevention measures. Access control employs authentication and authorization protocols, such as RADIUS and TACACS+, to analyze and manage access behavior and ensure that only authorized users and devices can connect to the network. Traffic filtering is essential in preventing unsafe traffic from entering the network by monitoring and controlling the flow of traffic. Attack prevention strengthens the network's resilience against denial-of-service (DoS) and distributed denial-of-service (DDoS) attacks, with mechanisms such as rate limiting, packet inspection, and access control lists (ACLs) utilized to detect and thwart such attacks.

Aggregation Switch Cost

 

In the diverse switch market, switches are used in the core distribution layer architecture. Typically, core distribution and access layer switch function at Layer 3 with full L3 functionality, allowing for a more advanced approach to holding data management, and for aggregation switches, which have high forwarding characteristics not found at the access layer, while being a more cost-effective solution than core switches.

  

QT Network Distribution Layer Switch Guide

 

QT, a provider of high-performance and cost-effective products for customers, offers a range of aggregation layer switches that feature advanced functions and high forwarding rates, along with dual power supplies, and support full Layer 2 and 3 functionality, including routing, below are some of the popular models of network aggregation layer switches that have consistently received positive reviews from customers.

   

Model Name	Port	Transmission Capacity	Features
S7300-48X2Q4C	48x 10G SFP+ 2x 40G QSFP+ 4x 100G QSFP28	Switching Capacity: 1920 Gbps Forwarding Rate: 1440 Mpps	Support full L3 functions including maximum stacking of 8 devices, IPv6, VPN High security by supporting DHCP Server Relay/Snooping. Powerful and Rich QOS Easy management with Console, Telnet, SSH v1/2, HTTP/HTTPS, SNMP v1/v2/v3, RMON, TFTP, FTP, SFTP feature
S7300-24X2C	24x 10G SFP+ 2x 100G QSFP28	Switching Capacity: 800Gbps Forwarding Rate: 600Mpps	A maximum of 8 devices can be stacked Support IPv4/IPv6 ACL and MAC whitelisting Support Console, Telnet, SSH v1/2, HTTP/HTTPS · SNMP v1/v2/v3, RMON · TFTP, FTP, SFTP
S7300-48TE4X2Q	48x 100M/1000M/2.5GBASE-T RJ45  4x 1000M/10G SFP+  2x 40G QSFP+	Switching Capacity: 600Gbps Forwarding Rate: 360Mpps	Support advanced L3 routing protocols support including OSPF, BGP, RIP, etc Support STP/RSTP/MSTP/VRRP/LACP/ERPS/BFD Support Anti-attack from DDoS, TCP/UDP Flood

QT Aggregation Switch Features

 

MLAG: Multi-Chassis Link Aggregation (MLAG) is a networking technology that enables you to connect multiple switches in your network and make them function as a single logical switch, enhancing network redundancy and high availability by allowing one switch to take over the traffic forwarding tasks while master switch happens to fail.

  

VRRP: QT aggregation layer switches are equipped with advanced Virtual Router Redundancy Protocol (VRRP) capabilities that allow a group of routers to function as a unified virtual router. A primary router is designated to forward packets sent to the virtual IP address. Other routers in the group act as backup routers. In case of a primary router failure, one of the backup routers automatically takes over as the new host router to continue forwarding packets to the virtual IP address. The adoption of VRRP greatly enhances failover capability and ensures network reliability. 

 

IPv6: The latest version of the Internet Protocol is available, IPv6 features a larger address space with 128-bit addresses allowing for a virtually unlimited number of unique addresses. Providing better scalability, security, and mobility support, IPv6 also supports seamless mobility, allowing devices to maintain their connectivity even when moving between networks.

 

Simple management: Each aggregation layer switch supports CLI/Telnet/SSH/SSL/SNMP/WEB for easy management, allowing to choice of the most convenient management method for network needs to ensure effective management of the networks with flexibility and convenience.

  

Conclusion

 

When we want to pick the best distribution Layer switch, some key factors must be considered. Firstly, You should be clear about the environment in which the device will be used. Secondly, the function features should be considered, including, QoS, link aggregation, security protocols, etc., as well as the price. Overall, in practice, we had better take comprehensive consideration to meet the requirements of our network solutions. We are glad to receive your inquiry via  [email protected] at any time.