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Necroware's S7-VRM

This project is a Voltage Regulator Module for the Socket 7 mainboards as defined by Intel in it's Pentium® Processor Flexible Motherboard Design Guidelines. You can upgrade VRM capable Socket 7 mainboards with this module to be able to use dual-voltage CPUs like Intel Pentium MMX, AMD K6, AMD K6-2 etc.

Disclaimer: this VRM can damage your mainboard, CPU or both. Please use at your own risk.

WARNING: inserting the module the wrong way around would put +12V on all critical lanes. It would destroy the mainboard, the CPU, the memory and all expansion cards. This can't happen on mainboards with VRM socket, because there it is not possible to insert it in reverse. On free standing VRM pin header, it is probably a good idea to cut +12V pin 5 and the unused pin 22 to use them as a key.

S7-VRM

Youtube Videos:

CPU Voltage Type Selection (J1)

There are two kind of socket 7 CPUs, single-voltage and dual-voltage CPUs. Dual-voltage CPUs are designed to use different voltages for the internal core and for the I/O. The I/O voltage is specified at 3.3-3.5V, but the core voltage can be much lower. For the very power efficient AMD K6-III+EE the core voltage is just 1.6V.

From revision 0.6 and higher the S7-VRM supports both types of CPUs, where for the single-voltage CPUs the voltage is completely generated on the module and for dual-voltage CPUs the I/O voltage is generated by a linear voltage regulator on the mainboard, where core voltage is generated on the VRM module.

To make this work you have to set the jumper J1 accordingly. Please read which kind of CPU you have before using this module.

Voltage Type J1 Pos. CPU examples
Single 1-3, 2-4 Intel Pentium, AMD K5, Winchip C6, Cyrix M1
Dual 1-2, 3-4 Intel Pentium MMX, AMD K6, Cyrix M1L/MII

CPU Voltage Selection (SW1)

WARNING: Single voltage CPUs are designed to run at 3.3-3.5V everything below that value could potentially make your system unstable. Everything above that can damage your mainboard or CPU or both. Dual-voltage CPUs usually need core voltages far below 3.0V, AMD K6-2 for example expects only 2.2V core voltage and everything above that can potentially damage the CPU. Always pay attention to the CPU type you use and apply voltages out of spec only if you really know what you are doing.

WARNING: different revisions can have different voltage settings, please always pay attention and look into the proper documentation for the revision you have.

Various voltages can be set using the SW1 switch on the module (0=off, 1=on):

Voltage Switches CPU Examples
1.4V 00000 Probably too low for any S7 CPU
1.5V 10000
1.6V 01000 AMD K6-2E+ / K6-3E+ / Mobile K6-2
1.7V 11000
1.8V 00100
1.9V 10100
2.0V 01100 Cyrix MII (0,18µm version)
2.1V 11100
2.2V 00010 AMD Mobile K6 / K6-2(+) / K6-3(+)
2.3V 10010
2.4V 01010 AMD K6-2
2.5V 11010
2.6V 00110
2.7V 10110
2.8V 01110 Intel Pentium MMX, IBM 6x86L, Rise MP6
2.9V 11110 AMD K6, IBM 6x86MX
3.0V 00011
3.1V 10011
3.2V 01011 AMD K6@233
3.3V 11011 Pentium 66-200 (Single Voltage)
3.4V 00111
3.5V 10111 AMD K5, Winchip C6
3.6V 01111
3.7V 11111 Danger: probably to high for any S7 CPU

Important remarks

The transistor Q1 with integrated pull-up resistor is optional. It is used for enable/disable signal and is unused on most mainbards.

The PCB is made for a through hole inductor, but if you have only SMD it is also possible to solder that instead. Keep in mind that the inductor has to stand the required current. Also slightly different inductors are allowed, everything between 2µH and 4,7µH should work as well. With the higher inductance you get less current ripple, also voltage ripple can look better, but the maximum possible current will decrease. Playing with different inductors will also influence the compensation network.

Capacitors C7 and C8 are used in so called compensation network and are responsible for DC-DC converter activation and stability. Those parts are very delicate and dependent on the ESR and values of the output capacitors C9-C12, and the inductor L1. If your regulator shows stability issues or not starting at all, try to remove the capacitor C8. If you change any other parts C7, C8 and R1 have to be adapted accordingly.

Bill of materials

Part Count LCSC# Comment
C1, C15 2 C13585 10u capacitor SMD 1206
C2, C14 2 C51205 4.7u capacitor SMD 1206
C3, C6, C13 3 C696845 0.1u capacitor SMD 1206
C4, C5 2 C407963 2200u capacitor TH Radial D10.0mm, P5.00mm
C7 1 C107186 242n capacitor SMD 1206
C8 1 C577176 39p capacitor SMD 1206
C9-C12 4 C407858 1000u capacitor TH Radial D8.0mm, P3.5mm
D1 1 C109000 Switching diode
J1 1 C2897435 Connector angled 02x15 pins 2.54mm
J2 1 N/A 2x2 jumper
L1 1 N/A 3.3µH inductor
Q1 1 C13871 NPN-BEC biased transistor
Q2, Q3 2 C496603 N-MOSFET GDS at least 15A
Q4 1 C454937 PNP-BEC biased transistor
R1, R2, R6 3 C136874 15K resistor SMD 1206
R3, R8, R9 3 C706412 3,75K resistor SMD 1206
R4 1 C870818 5K resistor SMD 1206
R5 1 C137314 30K resistor SMD 1206
R7 1 C137115 7,5K resistor SMD 1206
SW1 1 C5299506 DIP-10 Switch THT 5 buttons 2.54mm
U1 1 C382017 ISL6545 DC-DC Controller

The inductor doesn't need to be very exact, anything between 2.5µH and 4.7µH should work, but the sweet point is at around 3.3µH. The inductor can be self made by using a T50 ferrite toroid. For example T50-26 with permeability 75µ wrapped in 10 loops of 1.3 mm coper.

Tested mainboards

This module should run with all mainboards, which provide the VRM module header as specified in Intel Pentium Mainboard Design Guidelines. Most of such boards were based on Intel Triton (i430FX) and VIA Apolo Master (MV series) chipsets, but there were also quite a lot of later boards with newer chipsets (f.e. i430VX), which supported such an external VRM as well.

Most of the mainboards which were equipped with a VRM option, were produced before Intel Pentium MMX, AMD K6 and other dual-voltage CPUs were officially available. However those CPUs have changed the multiplier selection behavior of CPU pins BF0/1. Not only a new pin was introduced for higher multipliers, but also pin BF0 was not pulled up internally anymore as it has been done on single-voltage CPUs before. This ended up in wrong multiplier detection on newer CPUs like Pentium MMX 200, which would be suddenly detected as 166MHz one. This can be fixed by adding a 10k pull-up resistor to the CPU between pin BF0 I/O VCC. In the following table of tested mainboards you can find a column R+BF0 which tells if such a pull-up resistor had to be added to properly support the multiplier settings.

Faster Super Socket 7 CPUs, like AMD K6-2 and newer added another multiplier selection pin BF2, which is not supported on those old mainboards at all. It can be added using another mod, but is actually not necessary. If the CPU multiplier is set to 2x, those newer CPUs would interpret it as 6x and for 66MHz FSB go directly to 400MHz. However to be able to detect the CPU properly you would need to mod the BIOS. This is however optional, the system should work also with outdated BIOS. In such a case the CPU just would not be reported properly.

With that in mind this VRM was tested using various CPUs and voltages on following mainboards:

Manufacturer Model Chipset R+BF0 BIOS Mod VRM Compatible
Asus P/I-P55TP4XE(G) i430FX Yes Yes Yes
Gigabyte GA-586-ATE/P i430FX Yes Yes Yes

License

This work is licensed under the Creative Commons Attribution-ShareAlike 4.0 International License.

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