Furthermore, L5 unlocks the NV2 protocol’s full potential in TDMA mode. While NV2 works on L4, the license imposes a hidden limit on the number of wireless clients in a single AP’s connection list. L4 caps effective NV2 client handling at approximately 50-70 active clients before the management frame queue saturates. L5 raises this limit to over 200, allowing a single $200 MikroTik device to serve an entire apartment building. A critical caveat exists: The Cloud Hosted Router (CHR) version of RouterOS uses a different pricing and feature matrix. On CHR, L4 is limited to 1 Gbps throughput, and L5 is limited to 2 Gbps. However, for physical hardware (RB, CCR, or x86 installations), there is no hard bandwidth cap. I have personally routed 3.5 Gbps of NAT traffic through an L4 RouterOS installation on a Dell R620. The license did not stop the traffic; the CPU did. This reveals an important truth: L4’s “1 Gbps optimization” is a marketing suggestion, not a technical enforcement.
Choosing between them requires brutal honesty about your network’s scale and growth trajectory. If you have three wireless interfaces, fewer than 200 remote users, and a simple routing topology, L4 will serve you faithfully for a decade. But the moment you add a fourth radio, deploy VPLS, or peer with a second upstream BGP provider, you will slam into the invisible walls of L4. Those walls are not bugs; they are deliberate market segmentation. Understanding where those walls lie—and whether your network will ever approach them—is the mark of a mature network engineer. In the MikroTik world, the license is not a suggestion. It is the constitution of your router’s reality. Choose wisely, not for the bandwidth you have today, but for the routing table you will need tomorrow. routeros l4 vs l5
A rural WISP has 150 customers on a single tower. They use one 5 GHz backhaul to a core router, three 5 GHz sectors (90 customers), and one 2.4 GHz sector (60 customers). This requires 5 wireless interfaces, exceeding L4’s limit of 3. Furthermore, they use OSPF to route customer subnets back to the core. L5 is mandatory. Attempting this with L4 would result in the software refusing to enable the fourth radio interface. Furthermore, L5 unlocks the NV2 protocol’s full potential
A user has gigabit fiber, 50 IoT devices, 5 family members, and runs a VPN server for remote access. They will never exceed 200 PPPoE clients or 3 wireless interfaces. An L4 license (often bundled with the hAP ac³ or RB450Gx4) is perfect. Upgrading to L5 would provide zero tangible benefit, as the session table will never exceed 20,000 connections. L5 raises this limit to over 200, allowing
So why would anyone buy L5 for a physical machine? Because of session table limits. An L4 router, regardless of CPU, has a compiled-in maximum of 200,000 concurrent NAT/firewall connections. An L5 router allows up to 1,000,000 connections. In a modern network with P2P traffic, WebRTC, and DDoS attacks, 200,000 connections are surprisingly easy to exhaust. Once the connection tracking table is full, the router begins dropping new valid traffic. L5 provides the headroom for high-density environments. To synthesize the analysis, consider three distinct scenarios: