Workstation motherboards and gaming motherboards are very different from each other. People might often confuse these two, but there is a huge difference between the two of them.
Workstation vs Gaming Motherboard
Both workstation motherboards and gaming motherboards have their own set of features. The main difference between the boards lies in the high-end components like memory, CPU socket, the number of PCI-E slots and ports.
The gaming motherboards focus on high performance and high stability for their products while workstation motherboards focus more on compatibility with other devices in a work environment. They also tend to be more reliable than gaming motherboards as their designs are focused on enterprise computers. Gaming boards, however, focus on overclocking and use high-end silicon components to achieve stable operation at all times.
What’s a Workstation?
Workstations are computers intended to be used by professionals, especially those doing some kind of computationally intensive task. It might be an engineer running a 3D modeling program, a digital artist rendering animations, or a data scientist doing research. Whatever the case, these are people who need more power than you’ll find in your average PC, which means they need a workstation.
Although both provide a wide range of features, the main difference between these two lies in their target audience and design. The gaming motherboards are made for people who want better performance from their computer while workstation motherboards are designed with reliability in mind.
What’s a Gaming PC?
Like a workstation, a gaming PC has to be stronger than an ordinary computer. Modern games require increasingly higher technical specifications, which is why a powerful gaming PC requires parts that are far more powerful than what most non-gaming PC users will ever need. But running games is a very specific type of process, and gaming PCs are optimized around those needs specifically. Consequently, the differences between a workstation and a gaming PC usually vary from one component to the next.