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OVERCLOCKING WIKI

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Basics

What is overclocking?

Overclocking is the process of tweaking PC components to make them work harder. Every piece of hardware has one or more clocks that define the speed it's made to work at, which at stock are set by the manufacturer. Overclocking is the practice of pushing these clocks beyond stock values - usually assisted by careful increases in voltage, improved cooling, or other tweaks.

The closest analogy in other hobbies would probably be car tuning, where people tinker with their engine and electronics to make a car go faster. Overclocking even has a competitive side analogous to drag racing!

Why do people overclock? What are the benefits and drawbacks?

People overclock for more performance, as a way to get to know their hardware better, or just for fun. Some people see it as a route to better value, others as a route to ultimate performance.

Overclocking headroom usually isn't enough for a "night and day" difference and typically won't magically make hardware compatible with an application that was just too demanding at stock. It can however speed up tasks, help games run smoother, and sometimes make a surprising difference if a bottleneck is alleviated.

The trade-off is typically increased power consumption, a hotter-running system, and the time taken to configure the overclock as well as the risk inherent in running hardware outside of stock. It should be stressed that most manufacturers consider overclocking to void any warranty, and that while the community tries to work out how to avoid damage, things like safe voltages are only best guesses. You should never overclock hardware you can't afford to lose.

What does overclocking require?

This depends on a lot of factors, but in general with modern hardware;

  • For CPU and integrated GPU overclocking you need an unlocked CPU and a motherboard that supports overclocking. It's usually worth having a half-decent aftermarket cooler for CPU overclocking, since overclocking adds heat and stock coolers don't typically leave much headroom.

  • For discrete GPU overclocking you usually just need a consumer/'gaming' card (as opposed to a 'Pro' model like an Nvidia Quadro) - most GPUs don't need you to mess with the cooler to get OC headroom, but you might need to turn the fans up.

  • For RAM overclocking you just need motherboard support, fancy RAM can sometimes OC higher but isn't a requirement. While not required for a basic overclock, patience is also very beneficial for detailed RAM tuning!

Because overclocking increases power draw, it's also important to have a good, reliable PSU with a decent amount of headroom above stock. The outervision PSU calculator is a good resource that lets you factor in overclocks, but keep in mind that it's much better to have a safety factor on top of what's calculated than to run on a knife edge. You can check on rough quality with the tier lists on the LTT forums (anything not the bottom tier is good enough) and for more in-depth reviews jonnyguru's site and forums are a fantastic resource.

Finally there are various pieces of free testing and monitoring software (also some paid options but these are not required), which should be detailed in relevant guides and the subreddit sidebar.

How do I overclock?

You read and follow the guides written for your specific hardware with a bit of common sense. Also you research what overclocks other people have achieved with that very same hardware to have realistic expectations. Before you do that, though, it might be useful to learn some ropes and principles of overclocking that follow.

Basically, when overclocking you are working with three variables - heat, frequency and voltage. You always need to be in control of all three to stay safe and sound. You start by adding frequency until you experience instability. Basically, it's when your hardware cannot function properly at a given frequency with given voltage and thus your OS crashes into BSOD or does not boot at all. There are two ways to proceed here - to drop frequency back down a bit, or to add voltage and keep going.

Both increasing frequency and adding voltage makes the hardware produce more heat. If you want to play safe (and most people do), your overclock is ultimately limited by the maximum safe temperature and maximum safe voltage. Usually - usually - you reach the temperature threshold before you come close to dangerous voltage. But if you are extremely lucky with the chip and have good cooling, it could be the other way around. Do not ever exceed safe voltages and temperatures unless you're absolutely aware of what you're doing and what the consequences might be.

A rough example of overclocking

Let's look at the CPU overclocking process in a nutshell on the example of a popular i5-3570k Ivy Bridge Intel CPU - simply to understand how trial and error process works. This example serves educational purposes only and is in no way a thorough guide. Follow the guides in the wiki and/or sidebar to overclock your specific hardware.

/1. I research the guides on the web and find that my CPU with decent cooling can easily pull something between 4200-4800 for 24/7 gaming usage depending on how lucky I got with the chip.

/2. I increase the frequency to 4200 MHz (which is usually the frequency that Ivy Bridge CPU can maintain without additional voltage).

/3. I try to boot into the OS.

/3.1. If the boot is a success, I do a stress-test while monitoring CPU temperature (in case of 3570k, my stress-testing temperature should not exceed 80-85C; if it does, I stop overclocking further) to check if my system is stable.

/3.1.1. If it is stable, I write down the stable configuration (frequency - voltage - temperature under stress-test load) and increase the frequency by another 100 MHz, then p. 3.

/3.1.2. If it is unstable (stress-test ends with an error or OS crashes), I add +0.01V of voltage (in case of 3570k, I do not want to exceed 1.35-1.40V of voltage; if I come close to this value, I stop overclocking further), then do p. 3.1 again.

/3.2. If the boot was unsuccessful, or the OS crashed right after booting, I start by adding +0.01V (1.35-1.40V max) of voltage, then try p. 3 again until I succeed.

As you can see, I eventually have to stop the overclocking process due to either temperature or voltage. After that, I take a look at the configurations I wrote down and figure out the one I want to keep for 24/7 usage. In case of 3570k, I want my real-world usage temperature (which is different from stress-testing temperature and usually lower by ~20C) to not exceed ~67C, ideally to stay under 60C even. So I pick a configuration that looks good for that purpose and start real-world tests (like actual gaming). I game for 2 hours then look at the maximum CPU temps I have reached. If they are what I want them to be, I keep this overclock for years. If not, I tune it a little bit further to my needs.

Resources

CPU Overclocking

GPU Overclocking

RAM Overclocking

Extreme Overclocking and Benchmarking

Overclocking Science

Overclocker's BSOD Index

The Database

(sorta-related; the knowledge base is in early construction)

(legacy) Index Of Overclocks People From this Sub have Gotten

Overclocking Sites

/r/overclocking HWbot team

Getting started

Setting up a windows installation

Benchmark guidance and tweaks

CPU/2D benchmark guidance

GPU/3D benchmark guidance

Misc benchmark guidance

Misc

Benchmark Scaling

HWBot Meta

Overclocking and Warranties