Last updated: July 15, 2008

All about the various PC power supply cables and connectors

The various power supply cables

General info

If you'd like more technical data about ATX power connectors then you can find the current specifications and more at formfactors.org

Wires and connectors are not perfect conductors. They have resistance. When current passes through wires and connectors there is a voltage drop and that energy is lost as heat. As long as you don't overload them the voltage drop and extra heat don't matter. But the losses get worse as the current rises. That's why you see some power cables with more that one wire for the same voltage. Having multiple wires reduces the losses. If you seriously overload a line, the wire can get fairly warm. The resistance of connectors tends to increase as they are plugged and unplugged so after enough uses they can overheat and even melt when passing a large current. So a lot of changes in connectors over time has to do with adding more wires and connectors to make sure that none of these problems occur.

Some of the tables below provide the maximum wattage supported by a power cable and its associated power connector. Some specifications clearly spell out the maximum allowed wattage. Other specifications just provide the suggested connector and wire gauge and never specify a maximum wattage. And there's never really an absolute value to the maximum wattage anyway. If you draw a little more wattage then the maximum, the hardware doesn't immediately burst into flames. The voltage drop and power dissipation increase as you increase the current so there isn't a clear maximum wattage at which it stops working. Most of the specifications which spell out the maximum wattage provide a wide safety margin by defining a value which is far below the maximums supported by the connector and wire. If the table below provides an "Official cable/connector maximum wattage" then that specification has spelled out the maximum wattage. In most cases that wattage will be significantly below what can actually be handled by the suggested connector and wire. If the table provides an "Unofficial cable/connector maximum wattage" then that specification doesn't provide the maximum and the value in the table is a practical maximum wattage defined by the maximums for the connector and the suggested wire. An unofficial wattage doesn't have a wide safety margin built in because people differ on how much margin to provide. Some people happily use connector and wire maximums and other people like to have a wide safety margin.

Original PC main power cables

The original PC debuted in 1981 and used two cables to connect the PSU (power supply) to the motherboard. The two cables plug side by side into the motherboard connectors. Sometimes they are keyed so they only plug in one way and sometimes they aren't. Even if they're keyed you can insert them the wrong way if you put a little effort into it. You always have to remember to plug them in so the black wires are next to each other. It's either "black to black" or smoke and a shower of sparks.

Pinout Pin number Wire color Description 1 orange power good 2 red +5 volts or connector key 3 yellow +12 volts 4 blue -12 volts 5 black ground 6 black ground 1 black ground 2 black ground 3 white -5 volts 4 red +5 volts 5 red +5 volts 6 red +5 volts

Connector part numbers Motherboard connector Cable connector Terminals Maximum current per circuit Molex 15-48-0106 Molex 90331 Molex 08-50-0276 5 amps

Unofficial cable/connector maximum wattage delivery for main rails Voltage rail Number of lines Maximum current Maximum wattage +5 volts 3 or 4 15 or 20 amps 75 or 100 watts +12 volts 1 5 amps 60 watts

In old PCs, almost all of the chips ran directly off of the 5 volt rail. As a result the PSU delivers most of its wattage at 5 volts. There are three or four lines dedicated to the 5 volt rail. The other main rail is 12 volts. That was used primarily to run disk drives, motors, and fans. The two negative rails are "bias" supplies which only have to provide small amounts of current. Just for interest's sake, here's the specification for the PSU which came with the original IBM PC. It provides a maximum of 63.5 watts. Boy, those were the days.

Original IBM PC power supply Voltage Maximum current Maximum wattage +5 volts 7.0 amps 35 watts -5 volts 0.3 amps 1.5 watts +12 volts 2.0 amps 24 watts -12 volts 0.25 amps 3 watts

4 pin peripheral power cable

The four pin peripheral power cable dates back to the original PC. It was used for floppy drives and hard disks. It's still around and is now also used for all kinds of things including add-on fans, extra video card power, supplemental motherboard power, and case lighting. It's as old as the hills but is still very widely used. The connector is shaped so that it only fits in one way. You don't have to worry about inserting it the wrong way. People often use the term "4 pin Molex power cable" or "4 pin Molex" to refer to a four pin peripheral power cable. It's not a technically useful term because the 4 pin 12 volt cable is also a 4 pin Molex cable (Molex makes lots of connectors) but "4 pin Molex" is commonly used to refer to peripheral cables anyway.

Pinout Pin number Wire color Description 1 yellow +12 volts 2 black ground 3 black ground 4 red +5 volts

Connector part numbers Socket housing Socket Pin housing Pin Maximum current per circuit AMP 1-480424-0 AMP 60619-1 AMP 1-480426-0 AMP 60620-1 13 amps

I don't know of any official definition of the maximum current allowed in a peripheral cable. The connector can handle 13 amps according to the manufacturer. But you normally find 18 awg wire in the peripheral cables. If you have an 18 inch cable (about a half a meter) and are running 13 amps through 18 gauge wire then you get a voltage drop of about 0.25 volts counting both the power wire and the ground (it's got to go both ways) and the dissipation is about 3.3 watts. That's not good. I've just played it safe and listed the maximum current as 5 amps.

Unofficial cable/connector maximum wattage delivery Voltage rail Number of lines Maximum current Maximum wattage +5 volts 1 5 amps 25 watts +12 volts 1 5 amps 60 watts

Current power supplies usually have at least two separate peripheral power cables, each of which has two or more peripheral connectors. When you're plugging in multiple high powered devices it's a good idea to spread the load between all of your cables. Don't just plug all your devices into one cable unless they're relatively low load devices. Spreading the current between the cables reduces the voltage drops and power loss. If they're relatively low current devices like fans or it's just a disk drive or two then it doesn't really matter. But if you're putting lots of hard disks into a computer (some can draw almost 3 amps at 12 volts when doing some operations) or connecting a video card's auxiliary power, then spread the loads between the peripheral power cables. It's also helpful if you use a connector as close to the PSU as possible rather than sticking things at the end of the cable. Extra wire just means more voltage drop. And if you're using a peripheral connector to PCI Express adapter then be sure to plug each of the adapter's peripheral connectors into a separate PSU cable. They gave you two peripheral connectors for a reason. Plugging them both into the same PSU cable forces your video card to draw its 12 volt power through one 18 gauge wire. That increases your voltage drop and power dissipation in the cable. Some current high-end video cards can suck up more than 10 amps at 12 volts with most of it coming through the PCI Express connector so it pays to be careful. It will probably work if you don't spread the load but there's no excuse for not doing it properly. They gave you multiple cables. You might as well use them. Plus there's just something creepy about having warm wires even if they're not melting.

You will occasionally run into peripheral connectors which don't have all four wires. They are usually 12 volt only cables intended for fans. Never plug one of those into a disk drive. Drives expect both 5 and 12 volts to be provided. Some of the two-wire peripheral connectors are for speed-controlled fans. That means that the voltage changes depending on the desired fan speed. The connector will only provide 12 volts when the fan is going full speed and the voltage decreases to slow the fan down. Definitely don't plug that one into anything but a fan! Normally this kind of peripheral connector has "fan" printed on it to warn you. As long as a peripheral connector has four wires: one yellow, two black, and one red and it doesn't have some kind of printed warning attached then it's a standard peripheral cable and you can plug it into anything.

Floppy drive power cable

The four pin floppy drive cable showed up when PCs started including 3.5 inch floppy drives. This kind of cable is also sometimes used as an auxiliary power cable for AGP video cards which use more power than can be drawn from the motherboard slot. The connector is shaped so that it only fits in one way so you don't have to worry about inserting it the wrong way. Floppy cables are built with small connectors and 20 awg wire so they are limited to relatively low current uses.

Pinout Pin number Wire color Description 1 red +5 volts 2 black ground 3 black ground 4 yellow +12 volts

Connector part numbers Socket housing Socket Maximum current per circuit AMP 171822-4 AMP 170262-1 3 amps

Unofficial cable/connector maximum wattage delivery Voltage rail Number of lines Maximum current Maximum wattage +5 volts 1 3 amps 15 watts +12 volts 1 3 amps 36 watts

6 pin auxiliary power cable

The aux power cable was added to provide extra wattage to motherboards for 3.3 and 5 volts. This connector is rarely used anymore. It's most commonly found on older dual CPU AMD motherboards. You're more likely to sight Bigfoot than a motherboard which uses this connector. It plugs into the 6 pin version of the motherboard connector used by the original PC main power cables.

Pinout Pin number Wire color Description 1 black ground 2 black ground 3 black ground 4 orange +3.3 volts 5 orange +3.3 volts 6 red +5 volts

Connector part numbers Motherboard connector Cable connector Terminals Maximum current per circuit Molex 15-48-0106 Molex 90331-0010 Molex 08-50-0276 5 amps

Unofficial cable/connector maximum wattage delivery Voltage rail Number of lines Maximum current Maximum wattage +3.3 volts 2 10 amps 33 watts +5 volts 1 5 amps 25 watts

SATA power cable

SATA was introduced to upgrade the ATA interface (also called IDE) to a more advanced design. SATA includes both a data cable and a power cable. The power cable replaces the old 4 pin peripheral cable and adds support for 3.3 volts (if fully implemented). The connector is shaped so it can only be plugged in the correct way.

Pinout Pin number Wire number Wire color Description 1 5 orange +3.3 volts 2 5 orange +3.3 volts 3 5 orange +3.3 volts 4 4 black ground 5 4 black ground 6 4 black ground 7 3 red +5 volts 8 3 red +5 volts 9 3 red +5 volts 10 2 black ground 11 2 black ground 12 2 black ground 13 1 yellow +12 volts 14 1 yellow +12 volts 15 1 yellow +12 volts

Connector part numbers Cable connector Terminals Maximum current per circuit Molex 67582-0000 Molex 67581-0000 1.5 amps

Official cable/connector maximum wattage delivery Voltage rail Number of lines Maximum current Maximum wattage +3.3 volts 3 4.5 amps 14.85 watts +5 volts 3 4.5 amps 22.5 watts +12 volts 3 4.5 amps 54 watts

You have to be careful about SATA power cables. Some of them are missing the 3.3 volt wire. People with older power supplies often use adapters which convert from 4 pin peripheral cables to SATA power cables. But since 4 pin peripheral connectors only supply 5 and 12 volts, the SATA connector is missing 3.3 volts (there's no orange wire). There are also a few older power supplies which inexplicably have SATA power cables which are missing the 3.3 volt wire. Currently, SATA drives rarely use 3.3 volts. That may be because there are too many people using adapters so the drive makers don't want the headaches which come with using 3.3 volts. But in the future, 3.3 volt drives may become common so you need to be careful when using SATA power cables which don't implement 3.3 volts.

ATX 20 pin main power cable

In 1996 PC makers started switching to the ATX standard which defined a new 20 pin motherboard power connector. It includes a 3.3 volt rail which is used to power newer chips which require a lower voltage than 5 volts. It also has a standby 5 volt rail which is always on even when the power supply is turned off to provide standby power to the motherboard when the machine is sleeping. The new connector also allows the motherboard to turn the power supply on and off rather than depend on the user to flip a power switch. This connector is polarized so it can only be plugged in pointing in the correct direction.

Pinout Pins 1 through 10 Pins 11 through 20 Description Wire color Pin number Pin number Wire color Description +3.3 volts orange 1 11 orange +3.3 volts +3.3 volts orange 2 12 blue -12 volts ground black 3 13 black ground +5 volts red 4 14 green PS_ON# ground black 5 15 black ground +5 volts red 6 16 black ground ground black 7 17 black ground PWR_OK gray 8 18 white -5 volts (optional) VSB +5 volts purple 9 19 red +5 volts +12 volts yellow 10 20 red +5 volts

Some of the voltage lines on the connector may have smaller sense wires which allow the power supply to sense what voltage is actually seen by the motherboard. These are pretty common on the 3.3 volt line in pin 11 but are sometimes used for other voltages too. The -5 volt line on pin 18 was made optional in ATX12V 1.3 (introduced in 2003) because -5 had been rarely used for years. Newer motherboards virtually never require -5 volts but many older motherboards do. Most newer power supplies don't provide -5 volts in which case the white wire is missing.

Connector part numbers Motherboard connector Cable connector Terminals Maximum current per circuit Molex 39-28-1203 Molex 39-01-2200 Molex 39-00-0168,

Molex 44476-1111 6 amps

Unofficial cable/connector maximum wattage delivery for main rails Voltage rail Number of lines Maximum current Maximum wattage +3.3 volts 3 18 amps 59 watts +5 volts 4 24 amps 120 watts +12 volts 1 6 amps 72 watts

Dell used to ship many computers which used motherboards and power supplies which looked like plain old ATX but were not really ATX at all. If you plugged a real ATX power supply into the motherboard then things went kaboom (or frzzzzzap or ...). Sadly, some large computer vendors like to lock customers into buying upgrades from them rather from a third party. That's nasty enough but Dell built their non-standard computers and motherboards with what looked like standard ATX components. You only found out otherwise once sparks started flying. The Dell PCs which were carrying this ticking time-bomb were made between 1996 and 2000. If you're replacing a Dell power supply from this era then you should call Dell and make sure it's not a proprietary design. And if they say yes then be sure to voice your displeasure. This is an evil business practice which should stop.

You can plug a 20 pin ATX power cable into a motherboard with a 24 pin ATX connector. The image above shows the 20 pin power cable plugged into a 24 pin motherboard. A 20 pin power cable only fits into one end of a 24 pin motherboard connector so you can't insert it incorrectly. The 24 pin motherboard connector is actually just the 20 pin connector with 4 extra pins added on the end. The original 20 pins were unchanged. The extra 4 pins are not separate rails. They're just extra lines to provide more current to the same rails. On every 24 pin motherboard I've seen, the extra lines for ground, 3.3, 5, and 12 are just connected to the other lines on the same rail from the 20 pin connector. I've never heard of exceptions and it doesn't make sense for motherboard makers to create any. As a result, you can plug a 20 pin cable into a 24 pin motherboard and it will work just fine. At least, it will for a while. They added those extra 4 pins for a reason. When you plug a 20 pin cable into a 24 pin connector you're not providing the extra current carrying capacity which may be needed by the motherboard. If your motherboard's current requirements are low enough then it will work properly with only a 20 pin power cabled plugged in. But if the motherboard draws enough current, then you can overheat the 20 pins you're using on the 24 pin connector. I've seen enough pictures of burned ATX main connectors to assure you that this happens. In adding the extra four pins, 3.3 volts went from 3 to 4 lines. 5 volts when from 4 to 5 lines. 12 volts went from 1 to 2 lines so its capacity doubled. Connectors really do get hot if you overload them so the safest thing to do is use a real 24 pin power supply on a motherboard with a 24 pin connector. Note that your 24 pin machine may work fine with a 20 pin power supply until you add a PCI Express card later on down the road. PCI Express cards can draw up to 75 watts through the motherboard connector so adding an expansion card can substantially increase power draw through the main power cable. Many PCI Express video cards which have the 6 pin or 8 pin PCI Express power cable still draw a substantial portion of their 12 volt load through the PCI Express slot. The extra 4 pins doubled the current capacity of the 12 volt rail so that one is easy to overload when only using a 20 pin main power cable.

The picture above shows an adapter which allows you to plug a 20 pin power supply into a 24 pin motherboard. These do not solve the problems mentioned above. In fact, they usually make things worse. You still have only the same old 20 wires and pin&socket connectors that you would have if you plugged it directly into the motherboard. But with the adapter you also have longer wires and another set of pins&sockets so you have a higher voltage drop and more things which can go wrong. All the adapter does is remove the problem from the 24 pin motherboard connector and move it to the 20 pin connector on the adapter. About the only good thing it does is to make sure the 20 pin connector on the adapter melts rather than the 24 pin connector on the motherboard. You shouldn't underestimate the potential problems which come from adding another connector between the power supply and the motherboard. The resistance of connectors can increase due to being plugged and unplugged. Increasing the resistance makes the connector drop more voltage and dissipate more heat. Any number of physical changes can also cause higher connector resistance which causes more problems. You shouldn't put an extra connector in a high current path unless you've got a good reason. That's a good rule for power cables in general but it goes doubly for the high current draws you sometimes find through motherboard main power cables. The best practice is to avoid these 20 to 24 pin adapters and get a real 24 pin power supply.

ATX 24 pin main power cable

The 24 pin main power connector was added in ATX12V 2.0 to provide extra power needed by PCI Express slots. The older 20 pin main power cable only has one 12 volt line. The new 24 pin connector added one line apiece for ground, 3.3, 5, and 12 volts. The extra pins made the auxiliary power cable unnecessary so most ATX12V 2.x power supplies don't have them. The 24 pin connector is polarized so it can only be plugged in pointing in the correct direction.

Pinout Pins 1 through 12 Pins 13 through 24 Description Wire color Pin number Pin number Wire color Description +3.3 volts orange 1 13 orange +3.3 volts +3.3 volts orange 2 14 blue -12 volts ground black 3 15 black ground +5 volts red 4 16 green PS_ON# ground black 5 17 black ground +5 volts red 6 18 black ground ground black 7 19 black ground PWR_OK gray 8 20 white -5 volts (optional) VSB +5 volts purple 9 21 red +5 volts +12 volts yellow 10 22 red +5 volts +12 volts yellow 11 23 red +5 volts +3.3 volts orange 12 24 black ground

Some of the voltage lines on the connector may have smaller sense wires which allow the power supply to sense what voltage is actually seen by the motherboard. These are pretty common on the 3.3 volt line in pin 13 but are sometimes used for other voltages too. The -5 volt line on pin 20 was made optional in ATX12V 1.3 (introduced in 2003) because -5 had been rarely used for years. Newer motherboards virtually never require -5 volts but many older motherboards do. Most newer power supplies don't provide -5 volts in which case the white wire is missing.

Connector part numbers Motherboard connector Cable connector Terminals Maximum current per circuit Molex 39-28-1243 Molex 39-01-2240 Molex 39-00-0168,

Molex 44476-1111 6 amps

Unofficial cable/connector maximum wattage delivery for main rails Voltage rail Number of lines Maximum current Maximum wattage +3.3 volts 4 24 amps 79.2 watts +5 volts 5 30 amps 150 watts +12 volts 2 12 amps 144 watts

If you have an ATX power supply with a 24 pin main cable, it's okay to plug it into a motherboard with a 20 pin connector. It was designed to work that way. You can see an example in the picture above. The extra 4 pins on the cable just hang over the end of the motherboard connector. The 24 pin cable only fits into a 20 pin socket at one end so you can't plug it in incorrectly. The extra 4 pins were added to the 24 pin version of the cable to provide one extra wire for ground, 3.3, 5, and 12 volts. But it's okay to leave those 4 pins disconnected because a motherboard with a 20 pin connector doesn't need them. The only problem you can bump into (literally) is if there is something blocking the spot where the 24 pin cable hangs over the end. Or sometimes the end of the 20 pin motherboard connector is too thick to fit between the pins of the 24 pin cable. You can solve that problem by carefully shaving down one end of the 20 pin motherboard connector. It's just plastic. You won't miss it. If you can't get them to fit together then you can get an adapter cable which will make it work. The 24 pin cable plugs into one end of the adapter and then the adapter plugs into the 20 pin motherboard. But you should avoid using that kind of adapter if you can because the extra wire and connector are just more things which can go wrong. Adapters also slightly increase the voltage drop which is something worth avoiding. It's better to first see if you can get a 24 pin cable to fit into a 20 pin motherboard before resorting to an adapter.

ATX 20+4 pin main power cable

Motherboards can come with either a 20 pin main power connector or a 24 pin main power connector. Many power supplies come with a 20+4 cable which is compatible with both 20 and 24 pin motherboards. A 20+4 power cable has two pieces: a 20 pin piece, and a 4 pin piece. If you leave the two pieces separate then you can plug the 20 pin piece into a 20 pin motherboard and leave the 4 pin piece unplugged. Be sure to leave the 4 pin piece unplugged even if it fits into another connector. The 4 pin piece is not compatible with any other connectors. If you plug the two pieces of a 20+4 power cable together then you have a 24 pin power cable which can be plugged into a 24 pin motherboard.

4 pin ATX +12 volt power cable

Older computers put most of their load on 3.3 and 5 volts. As time passed, computers drew more and more of their load from 12 volts (see here). Before this power cable was introduced there was just one 12 volt line provided to the motherboard. This cable added two more 12 volt lines so more of the load could be shifted to 12 volts. The power coming from this connector is usually used to power the CPU but some motherboards use it for other things as well. The presense of this connector on a motherboard means it's an ATX12V motherboard. For dual 12 volt rail power supplies, this connector provides the voltage refered to as 12V2. The power cable which plugs into the 4 pin connector has two black wires and two yellow wires. This cable is sometimes called an "ATX12V" cable or "P4" cable although neither of those are technically accurate descriptions.

If you have one of these connectors on a motherboard then you must plug a power cable into it or your CPU won't get any power. The one exception is that when this connector was new, some motherboards shipped with a socket into which you could plug a 4 pin peripheral power cable as an alternative. That helped people who had older power supplies which didn't have the 4 pin 12 volt cable.

The 4 pin 12 volt cable is polarized so it can only be plugged into the 4 pin motherboard connector correctly. If you look carefully at the picture above you can see that two of the pins are square and the other two have rounded corners. The motherboard connectors also have the same square and rounded arrangement so the power cable only fits in one way. At least that's true unless you try really hard to force it into the connector. With enough force you can sometimes get a cable with a small number of pins into a connector which doesn't match. If you look carefully you can also see that the square and rounded pattern matches various positions on other motherboard connectors like the 20 pin main power connector and 24 pin main power connector. Do yourself a favor and only plug the 4 pin 12 volt cable into the motherboard connector where it belongs (unless you enjoy smoke and fried components).

If your power supply doesn't have a 4 pin 12 V cable then you can provide one with the adapter shown above. It converts a 4 pin peripheral cable into a 4 pin 12 V cable.

Pinout Pins 1, 2 Pins 3, 4 Description Wire color Pin number Pin number Wire color Description ground black 1 3 yellow +12 volts ground black 2 4 yellow +12 volts

Connector part numbers Motherboard connector Cable connector Terminals Maximum current per circuit Molex 39-28-1043 Molex 39-01-2040 Molex 39-00-0168,

Molex 44476-1111 8 amps

Unofficial cable/connector maximum wattage delivery Voltage rail Number of lines Maximum current Maximum wattage +12 volts 2 16 amps 192 watts

You can plug a 4 pin 12 volt power cable into an 8 pin EPS motherboard connector but there's no guarantee that it will work. If the motherboard expects only one 12 volt rail then a 4 pin 12 volt cable may work. If the motherboard expects two 12 volt rails (many dual CPU motherboards require one 12 volt rail per CPU) then it won't work. Even if the motherboard works with a 4 pin 12 volt cable, you are still only providing half of the current carrying capacity which would be provided by an 8 pin EPS cable. That can overheat both the motherboard connector and 4 pin cable. Scorched or melted connectors can be a result. A motherboard which has the 8 pin EPS connector expects a lot of current and you are taking a serious risk by plugging in a 4 pin cable. The 4 pin cable only fits at one end of the 8 pin EPS motherboard connector so you can't plug it in improperly. That is, it only fits into one end of the motherboard connector unless you force it. If the cable doesn't go into the socket easily then you're probably trying to plug it into the wrong end. But then again, it's not a good idea to try to run with a 4 pin cable in an 8 pin motherboard anyway.

8 pin EPS +12 volt power cable

This cable was originally created for workstations to provide 12 volts to power multiple CPUs. But as time has passed many CPUs require more 12 volt power and the 8 pin 12 volt cable is often used instead of a 4 pin 12 volt cable. Depending on the power supply, the connector may contain one 12 volt rail in all 8 pins or two 12 volt rails taking up 4 pins apiece. It is often refered to as an "EPS12V" cable.

The 8 pin 12 volt cable is polarized so it can only be plugged into the 8 pin motherboard connector correctly. If you look carefully at the picture above you can see that four of the pins are square and the other four have rounded corners. The motherboard connectors also have the same square and rounded arrangement so the power cable only fits in one way. At least that's true unless you try really hard to force it into the connector. With enough force you can sometimes get a cable with a small number of pins into a connector which doesn't match. The 8 pin cable has enough pins that it's pretty hard to insert it in the wrong direction but determined people might be able to do it. If you look carefully you can also see that the square and rounded pattern matches various positions on other motherboard connectors like the 20 pin main power connector and 24 pin main power connector. You should only plug the 8 pin 12 volt cable into the motherboard connector where it belongs unless you enjoy the smell of fried electronics.

You can also plug an 8 pin 12 volt cable into a 4 pin 12 volt motherboard connector. I don't have a picture of this one but it looks similar to this. Four of the pins on the 8 pin cable fit into the motherboard connector and the other four pins hang off the end. The 8 pin cable only fits into one end of the 4 pin motherboard connector unless you try hard to force it into the wrong position. The 8 pin cable is electrically compatible but it may not fit into a 4 pin motherboard. There is often a component which blocks the area where the 4 pins would hang off the end. And sometimes the plastic end of the 4 pin connector is too thick to fit between the pins of the 8 pin cable.

Make sure that you don't try to plug an 8 pin 12 volt cable into the 8 Pin PCI Express power connector on a video card. The two cables look very similar so it's easy to get the two confused. 8 Pin PCI Express power cables are usually labeled to distinguish them from 8 pin 12 volt cables. The PCI Express cable usually has "PCI-E" printed on the connector. If there are no labels then you can usually use wire colors to tell the two kinds of cables apart. An 8 pin 12 volt cable has yellow wires on the same side as the connector clip. An 8 Pin PCI Express cable has black wires on the clip side. The two power cables are also keyed differently so you can't plug one kind of power cable into the other kind of connector. But as with this kind of connector, you can sometimes force the wrong kind of cable into a connector if you push hard enough. Make sure you have the right kind of cable before plugging it in. The two are definitely not compatible with each other.

Pinout Pins 1 through 4 Pins 5 through 8 Description Wire color Pin number Pin number Wire color Description ground black 1 5 yellow +12 volts (12V1) ground black 2 6 yellow +12 volts (12V1) ground black 3 7 yellow +12 volts (12V1 or 12V2) ground black 4 8 yellow +12 volts (12V1 or 12V2)

Connector part numbers Motherboard connector Cable connector Terminals Maximum current per circuit Molex 39-28-1083 Molex 39-01-2080 Molex 39-00-0168,

Molex 44476-1111 7 amps

Unofficial cable/connector maximum wattage delivery Voltage rail Number of lines Maximum current Maximum wattage +12 volts 4 28 amps 336 watts

If you don't have an 8 pin 12 volt cable then you can use the adapter shown above. It converts a couple of 4 pin peripheral power cables into an 8 pin 12 volt cable. If you use one of these adapters then be sure to plug the 4 pin peripheral connectors into separate cables coming from the power supply. If you plug them both into the same power supply cable then you are drawing all the power of the 8 pin 12 volt connector through a single 18 gauge wire. You can often get away with that but there's no reason to do it.

4+4 pin +12 volt power cable

Motherboards can come with either a 4 pin 12 volt connector or an 8 pin 12 volt connector. Many power supplies come with a 4+4 pin 12 volt cable which is compatible with both 4 and 8 pin motherboards. A 4+4 power cable has two separate 4 pin pieces. If you plug the two pieces of a 4+4 power cable together then you have a 8 pin power cable which can be plugged into an 8 pin 12 volt connector. If you leave the two pieces separate then you can plug one of the 4 pin pieces into a 4 pin 12 volt connector and leave the other 4 pin piece unplugged.

If you look carefully at the image above then you can see the polarization of the pins which prevents you from plugging the cable in improperly. Some of the pins are square and some of them have rounded off corners. The motherboard connectors have matching square and rounded off corners to prevent the cable from being plugged in the wrong way. But if you look really carefully at the right half of this particular cable and then look at the 8 pin 12 volt cable pictured above you'll notice that they don't match. A regular 8 pin cable has four square pins and four rounded ones but the 4+4 cable shown above has two square pins and 6 rounded ones. The left half of the 4+4 matches the left half of an 8 pin cable but the right half is different. Hmmmm... And this isn't some bizarre cable either. I've seen plenty of 4+4s which look like this one. And then there are other 4+4 cables which look just like an 8 pin cable split in two (which makes sense). Since rounded pins fit into square holes in motherboard connectors, this particular cable will fit just fine into an 8 pin 12 volt motherboard connector. But both halves of this 4+4 will fit into a 4 pin 12 volt motherboard connector. You're supposed to use the left half of the cable shown above when plugging it into a 4 pin motherboard connector but the right half will also fit. As it happens, either half will work fine in a 4 pin motherboard because both halves of the 4+4 just provide 12 volts. The pinouts are the same for both halves so either one will work. I'm not sure why they make cables like this one because you'd figure a 4+4 cable would just be an 8 pin cable which splits in two. And you only need one half of a 4+4 cable to plug into a 4 pin motherboard. The other half is unused. But the kind of 4+4 cable shown above is pretty common so don't let it throw you.

6 pin PCI Express power cable

This cable is used to provide extra 12 volt power to PCI Express expansion cards. PCI Express motherboard slots can provide a maximum of 75 watts. Many video cards draw significantly more than 75 watts so the 6 pin PCI Express power cable was created. These high-power cards draw most of their power from the 12 volt rail so this cable provides only 12 volts. These are sometimes called "PCI Express cables". They are also occasionally called "PEG cables" where "PEG" stands for PCI Express Graphics. If your power supply doesn't have a 6 pin PCI Express cable then you can use the adapter shown above on the right to convert two 4 pin peripheral cables into a PCI Express cable. If you use an adapter then be sure to plug the 4 pin peripheral connectors into separate cables coming from the power supply. If you plug them both into the same power supply cable then you are drawing all the power of the PCI Express connector through a single 18 gauge wire. You can usually get away with that but there's no reason to do it. The PCI Express 6 pin connector is polarized so it can only be plugged in pointing in the correct direction. But as with connectors of this type, you can sometimes force them into the wrong kind of socket if you try hard enough. If it doesn't slide in easily then you're probably plugging it into the wrong place.

Some video cards come with the 8 pin PCI Express power connector to support higher wattage than the 6 pin PCI Express connectors. It's okay to plug a 6 pin PCI Express power cable into an 8 pin PCI Express connector. It's designed to work that way but will be limited to the lower wattage provided by the 6 pin version of the cable. The 6 pin cable only fits into one end of the 8 pin connector so you can't insert it incorrectly but you can sometimes force the 6 pin cable in the wrong way if you try hard enough. Video cards can sense whether you have plugged a 6 pin or 8 pin cable into an 8 pin connector so the video card can impose some kind of restriction when running with only a 6 pin power cable. Some cards will refuse to run with only a 6 pin cable in an 8 pin socket. Others will work with a 6 pin cable at normal speeds but will not allow overclocking. Check the video card documentation to get the rules. But if you don't have any other information then just assume that if your video card has an 8 pin connector then you must plug in an 8 pin cable.

Pinout Pins 1 through 3 Pins 4 through 6 Description Wire color Pin number Pin number Wire color Description +12 volts yellow 1 4 black ground +12 volts or not connected yellow or not connected 2 5 black ground +12 volts yellow 3 6 black ground

Connector part numbers Video card connector Cable connector Terminals Maximum current per circuit Molex 45558-0002 Molex 45559-0002 Molex 39-00-0168,

Molex 44476-1111 8 amps

Official cable/connector maximum wattage delivery Voltage rail Number of lines Maximum current Maximum wattage +12 volts 3 2.083 amps 75 watts

The PCI Express specification is, unfortunately, not a free, public specification. So most people have never seen it. Including me. ATX specification: freely available to all. PCI Express specification: expensive so hardly anyone has seen it. ATX: good. PCI Express: bad. It's a shame when a widely used standard isn't freely available to the public. Nonetheless, information leaks out from the specification and the 6 pin PCI Express power cable is actually rated at an extremely conservative 75 watts. I have no idea why the wattage is rated so low because the specifications from Molex clearly allow substantially more power. Part of the reason may be that pin 2 (listed above as a 12 volt line) may be listed as not connected in the specification. I've never seen a 6 pin PCI Express power cable with pin 2 not connected. They've all had a 12 volt line connected to pin 2. I've also seen claims that there may be unimplemented sense lines in the specification. Welcome to the uncertainty which happens when you don't have freely available specifications. Even with only two 12 volt lines the standard implementation of PCI Express power cables use large enough gauge wire and a good enough connector to provide much more than the three amps per wire required to provide 75 watts. Nonetheless, the 6 pin PCI Express power cable officially provides only 75 watts. In all likelihood, however, real implementations of this power cable can provide far more than 75 watts.

8 pin PCI Express power cable

The PCI Express 2.0 specification released in January 2007 added an 8 pin PCI Express power cable. It's just an 8 pin version of the 6 Pin PCI Express power cable. Both are primarily used to provide supplemental power to video cards. The older 6 pin version officially provides a maximum of 75 watts (although unofficially it can usually provide much more) whereas the new 8 pin version provides a maximum of 150 watts. It is very easy to confuse the 8 pin version with the very similar-looking EPS 8 pin 12 volt cable.

The 8 pin PCI Express and the EPS 8 pin 12 volt connectors are polarized differently so you won't be able to plug one kind of cable into the other kind of connector. That is, you won't be able to plug the wrong kind of cable in unless you try really hard. Unfortunately, the Molex Mini-fit Jr. connectors used by both kinds of power cables can sometimes be forced into a differently-polarized connector if they only have a few pins and you push hard enough. If the cable won't slide in easily then you're probably trying to insert the wrong kind of cable. The 8 pin PCI Express connector does have a small plastic bridge which prevents it from being plugged into an EPS 8 pin 12 volt motherboard connector. You can see the bridge in the image above between the rightmost two pins in the top row of the connector. But there's no such protection to prevent EPS 8 pin 12 volt cables from being plugged into an 8 pin PCI Express connector on a video card. That combination may fit if you shove hard enough. And if you plug in the wrong kind of cable then expect fireworks. Some of the grounds and 12 volts wires for an EPS 8 pin 12 volt are reversed compared to an 8 pin PCI Express. Fortunately, most 8 pin PCI Express connectors are labeled "PCI-E" so people won't confuse them with EPS 8 pin 12 volt cables. If the connectors aren't labeled then you can tell an 8 pin PCI Express power cable from an EPS 8 pin 12 volt cable by checking the color of the wires which plug into the clip side of the connector. On the EPS 8 pin cable, the yellow wires (the 12 volt wires) go into the clip side of the connector. On the 8 pin PCI Express cable, the wires on the clip side are all black (grounds). That's the same as it is with the 6 Pin PCI Express power cable. Of course, none of this helps you if your cable uses the trendy all-the-same-color-wires design which is popular with high-fashion power supplies. In that case you'll just have to be very careful or hope the connectors are labeled.

Pinout Pins 1 through 3 Pins 4 through 6 Description Wire color Pin number Pin number Wire color Description +12 volts yellow 1 5 black ground +12 volts yellow 2 6 black ground +12 volts yellow 3 7 black ground ground black 4 8 black ground

Connector part numbers Video card connector Cable connector Terminals Maximum current per circuit ? ? ? ?

Official cable/connector maximum wattage delivery Voltage rail Number of lines Maximum current Maximum wattage +12 volts 3 4.167 150 watts

6+2 pin PCI Express power cable

Some video cards have 6 Pin PCI Express power connectors and others have 8 Pin PCI Express power connectors. Many power supplies come with a 6+2 PCI Express power cable which is compatible with both kinds of video cards. The 6+2 PCI Express power cable is made up of two pieces: a 6 pin piece, and a 2 pin piece. If you put the two pieces together then you have a full 8 pin PCI Express power cable. But if you split the connector into two parts then you can plug the 6 pin part into the older 6 pin PCI Express connector and leave the 2 pin part unplugged. That way, your power supply only needs to have one 6+2 cable to be compatible with both 6 pin and 8 pin PCI Express connectors.