What Is a VRM and How Does It Affect Your Processor’s Performance? | Computing

Your motherboard’s VRM, or Voltage Regulator Module, is a crucial but underappreciated piece of hardware. With a series of electronic components, the VRM ensures your CPU or GPU receives clean power at a consistent voltage.

A poor VRM can lead to degraded performance and limit a processor’s ability to function under load. It can even lead to unexpected shutdowns, especially when overclocking. In fact, before the exact software cause was known, insufficient VRM design was implicated in Apple’s recent throttling problems with i9 MacBook Pros.

Discover below what a VRM is and how it affects processor performance.

How Does a VRM Work?

A VRM’s first job is to convert the 12-volt power from your computer’s power supply down to a usable voltage. For processors, this is typically between 1.1v to 1.3v. The delicate electronics inside can be easily shorted by too many volts. Precision is also crucial when powering a processor, and the required voltage must be delivered as exactly as possible. That’s why VRMs are more complex than a simple piece of wire. But at their heart they are basically a buck converter, precisely stepping down voltage to appropriate levels.

The VRM uses three components to do its job: MOSFETs, inductors (also called chokes), and capacitors. There’s also an integrated circuit (IC) to control it all, sometimes called a PWM controller. A simplified schematic of a single-phase VRM can be found below.

A more detailed discussion of each component’s function can be found on WikiChip’s VRM page.

Multi-Phase VRMs

Modern computers require more than a single phase VRM. Modern power systems use a multi-phase VRM. Multiple phases spread the power load over a broader physical area, reducing heat production and stress on components as well as providing other electrical improvements related to efficiency and per-part costs.

Each phase of a modern multi-phase VRM supplies a fraction of the power required, taking turns to provide power to the CPU. Taken individually, each phase provides a brief moment of power, visualized as a square-shaped wave.

Each phase’s burst of power is staggered from the last, so that while only one phase is operating at a time, the total amount of power never changes. This, in turn, produces a smooth, reliable power source – the “clean” power required for a CPU to function optimally. You can see a simplified system in operation below.

VRM Phase Numbering and Truth in Advertising

VRMs are typically sold as something like “8+3” or “6+2.” The number before the plus indicates the number of phases dedicated to cleaning power for the CPU. The number after the plus indicates the VRM phases left to power other motherboard components like RAM.

When the first number is greater than 8, such as “12+1,” “18+1,” or even higher, the manufacturer often makes use of a device called a doubler. A doubler allows them to multiply the benefit of the existing phases without building additional phases into the board. While this isn’t quite as effective as wholly separated phases, it does allow for some electrical improvements at less cost. And since it allows manufacturers to raise a buyer-facing number at small expense to themselves, they often take advantage.

Some manufacturers, Gigabyte especially, have also begun to label phases wired in parallel as if they are two separate phases. In fact, this is really one phase duplicated. Its electrical signals are synced rather than staggered, removing many of the benefits of a true additional phase. But manufacturers are often willing to bend the dictionary definition of a word if it suits their purposes. Unethical, surely, and perhaps legally murky as well. But as always, cavet emptor.

How Does a VRM Improve Performance?

The goal with a VRM is the provision of clean and reliable power. Yet even a basic VRM can deliver sufficient performance to maintain a mid-range CPU at stock speeds. When overclocking or pushing component limits, the quality of the VRM becomes more important.

Overclockers should seek out a VRM made from reliable components. If its components are cheap, they may fail to supply sufficient voltage under load, causing surprise shutdowns. The most variable components are capacitors and chokes. Look for leak-resistant capacitors. These are often marketed under names like “Japanese Capacitors,” “Dark Capacitors,” or “Solid Capacitors.” High overclocks will require better chokes as well. You can find this named as super-ferrite chokes (SFCs) or “Premium Alloy Chokes.” Also look for heatsinks over some or all MOSFETs – finned, if possible.

Conclusion: Finding a Good VRM

Even with knowledge it can be difficult to shop for a capable VRM. Cost is little guide, and marketing material, as mentioned, can be intentionally misleading. Detailed information about component and part numbers is rarely revealed to consumers. This is where hyper-detailed component reviews from GamersNexus.net can be invaluable. Their recommendations can generally be trusted as fair and impartial, as well as highly educated.

Image credit: Texas Instruments Application Report: Multiphase Buck Design From Start to Finish (Part 1)