By James Yu and Sarju Shah - Posted on Friday, August 4, 2006
The FX and Extreme Edition chips fill a need for extreme overclockers who are looking to create the fastest chip possible using any means necessary. But regular enthusiasts know that paying $1,000 for an unlocked chip violates the spirit of overclocking--the entire purpose of the act is to get an inexpensive processor running as fast as a ridiculously expensive one.
For this edition of Press Start, we'll get you familiar with the basics of overclocking and explain what kind of equipment you'll need to get started. This feature isn't a comprehensive guide, as there are entire Web sites devoted to the subject, but hopefully you'll learn enough to determine whether or not you'd like to give overclocking a try.
The CPU model greatly affects what kind of overclock you can expect. Numerous Web sites and forums cover which processors are the most suitable for overclocking. For a good budget overclocking attempt, you want to stick to CPUs that cost less than $250. Sometimes, great bargains appear in the $150 range, but they don't come along too often. Among modern processors, the best bets for overclocking lie in the budget segments of Intel's new Core2 Duo and AMD's Athlon 64 X2 processors. Exact model numbers will vary as time goes on, but you usually want to go with the slower processor models since they're cheaper and provide more overclocking headroom.
Not all CPUs of the same model will overclock to the same levels. Some CPUs can run a little faster, while others can't. The more expensive processors have all been qualified to run at higher speeds, but the cheaper processors may have only graded out at lower speeds. When you buy a processor specifically for overclocking you're basically betting that the manufacturer's production quality is high enough that even the inexpensive chips can run at much faster speeds.
Pair up your CPU with memory suitable for the job. If you're going for a budget overclock, purchase only the speed you need. Low latency memory and high-speed memory cost a substantial amount and provide marginal gains in comparison to a large CPU overclock. If you're looking to squeeze out the most performance, regardless of budget, then premium memory is worth exploring. Buying faster memory "in preparation for the future" is pointless since you'll likely need a new a type of memory by the time you're ready to upgrade.
You will also need a motherboard that's willing to cooperate in the overclocking plan. Companies like Asus, DFI, MSI, Gigabyte, and Abit all manufacture motherboards specifically made for the tweaker. These motherboards feature extra options in the BIOS, more advanced cooling features, and better power-handling capabilities. Stay away from Intel brand boards and many name-brand pre-built systems if you plan on overclocking since they often don't have the BIOS settings that allow you to overclock the processor.
Extra cooling in the form of faster fans, better heat sinks, and water cooling (if you want to go exotic) all help to improve your chances of achieving a successful overclock. Some notable companies in the field of cooling include Thermaltake, Zalman, Alpha, and Thermalright among others, but lots of overclockers have had good success using the standard cooling units that come with the processor.
A good thermal paste, when correctly applied, is an absolute must-have especially if you're sticking with the stock heatsink and fan. There's no shortage of companies pedaling a cornucopia of metallic slimes: Arctic Silver, OCZ, Masscool, Antec, Kingwin, Cooler Master, and Artic Cooling. The key to unlocking the benefits of thermal compounds involves how you apply them. Make sure to place an even and very thin layer over the CPU. If you have too much paste on the CPU, the compound actually inhibits the transfer of heat to the heatsink.
Are you an experienced veteran with several processors under your belt? What CPU do you have and how high have you overclocked it?
The other component to the CPU's final speed is the front-side bus (FSB). The FSB refers to how fast the communication link between the CPU and chipset operates. Modern computers typically operate on a 133MHz, 200MHz, or 266MHz FSB. Although, you've probably seen numbers like 533MHz, 800MHz, 1000MHz, and 1066MHz thrown around, those figures are based off the original FSB. In Intel's case, the company uses a quad-pumped bus that allows the chipset to communicate four times per cycle (or Hz), which means that a quad-pumped 200MHz FSB effectively communicates like it's at 800MHz (4x200MHz). In AMD's case, the company actually stepped away from traditional FSB architecture, and adopted the HyperTransport bus, which has a default value of 200MHz. Using that figure, you then multiply the HyperTransport bus speed and the multiplier to arrive at the final CPU speed.
If you know how to multiply, then you can overclock. Most overclocking follows the following formula:
(Multiplier) x (FSB) = Final CPU speed
Depending on what kind of CPU you own, there are essentially two different methods to overclocking--multiplier overclocking and bus-speed overclocking.
Multiplier-unlocked CPUs allow you to change the multiplier at will. You can easily switch the 2.6GHz Athlon FX-60's default multiplier from 13 to 14, and have the CPU running at 2.8GHz in no time at all. The great benefit of a CPU with an unlocked multiplier means that you don't have to push the rest of your computer beyond its limits if you don't want to. You can put all the stress only on the CPU and leave the FSB untouched to keep the rest of the system operating within normal parameters.
Most overclocker-friendly motherboards will offer the option to change multiplier settings in the CPU section of the BIOS. However, most of us won't have the luxury of using the multiplier to overclock.
The trick to overclocking the FSB is to move up in small increments until you experience minor instabilities. Motherboards built for overclocking will allow you to edge up the speed in very small increments, and they'll also offer several voltage options to help maintain system stability.
Both types of overclocking can benefit from increased power levels. However, don't push the CPU voltage levels too high. More power inevitably leads to more heat, which directly translates to a reduced electronic life span. If you're trying to squeak out an extra 100MHz with a disproportionate amount of power, you're better off going with the slower speed and a lower voltage setting. You're not likely to notice the difference between 2.8GHz and 2.9GHz, but you will notice when your computer becomes a premature doorstop.
Forcing computer components to operate outside of normal specifications comes with risks. Be well aware that overclocking will void any warranty you have. If you play it safe and only increase the CPU voltage by a few percentage points, the overclock shouldn't affect the longevity of your equipment by very much. As long as you keep the temperatures low, everything should be fine.
An overclocked system using a normal fan and heat-sink cooling unit doesn't require much more care than a non-overclocked system. Get a can of compressed air and clean dust out of the case regularly. Go in for a deeper cleaning if the system starts to lock up while running games or other processor-intensive applications. Clear out the case air filters, and make sure to wipe down the CPU heatsink as well as the motherboard northbridge heatsink to get rid of dust that can trap heat.
Are you an experienced veteran with several processors under your belt? What CPU do you have and how high have you overclocked it?