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Pinouts & Protocol FAQ by JChristy

Version: 1.01 |
Highest Rated Guide

Super Nintendo Entertainment System: pinouts & protocol


•1. About the Author
•2. Introduction
•3. SNES Multi-out cable connector pins.
•4. SNES Controller cable connector pins.
•5. SNES Controller Communication Protocol
•6. SNES Controller Button-to-Clock Pulse Assignment

[Document Version: 1.01] [Last Updated: 3/26/96]


1. About the Author

Author: Jim Christy
Version: 1.01
E-Mail: jchristy@hplred.HP.COM


2. Introduction

For all you game hardware enthusiasts out there, I took the opportunity
this weekend to put a scope on my Super Nintendo connectors and find out
what is going on. Because the standard Multi-out cable connector only has
internal contacts for the audio and video signals, I had to find some more
push-in gold contacts at a local store to fully break out all the signals.
It appears easier to do this than make your own connector.

In short, I found that in addition to S-VHS, the multiout also supports
RGB and sync. I also got the controller pinouts and protocol, which opens
up some interesting possibilities. One could rather easily construct a
"macro recorder" that records your exact button presses for a game sequence
and allows you to play them back. They will be time-accurate by definition
of the protocol, and depending on how random the game plays, you should be
able to replay those sequences that get boring, and then take over control
when you want.

If all of this is already well known, then sorry for the waste of net


3. SNES Multi-out cable connector pins.

These are numbered the way Nintendo did, and the view is looking back "into"
the connector on the CABLE.

        1       3       5       7       9      11

        |       |       |       |       |       |
        |       |       |   _   |       |       |
       --------------------/ \--------------------
     /                                             \
    |                                               |
    |                                               |
     \                                             /
        |       |       |       |       |       |
        |       |       |       |       |       |

        2       4       6       8      10      12

        Pin     Description
        ===     ===========
        1       Red analog video out   (1v DC offset, 1vpp video into 75 
        2       Green analog video out (1v DC offset, 1vpp video into 75 
        3       Composite H/V sync out (1vpp into 75 ohms)
        4       Blue analog video out  (1v DC offset, 1vpp video into 75 
        5       Ground
        6       Ground
        7       Y (luminance) signal for S-VHS (1vpp into 75 ohms)
        8       C (chroma)    signal for S-VHS (1vpp into 75 ohms)
        9       NTSC composite video signal (1vpp into 75 ohms)
        10      +5v (Could be just a high logic signal)
        11      Left channel audio out
        12      Right channel audio out

Additional Notes:

As seen above, the SNES does have RGB capability. I was able to get a stable
raster on my NEC MultiSync "classic" using the RGB and sync pins. However,
the video levels are not RS-170 compatible. The DC offset needs to be 
out with some large capacitors and the peak-to-peak video amplitude may need
to be reduced to 0.7v by using a lower load impedance than 75 ohms. The Y/C
(S-VHS) signals *appear* to be directly usable, but tests cannot be made
until I find the pinouts for the S-VHS connector on my TV.


4. SNES Controller cable connector pins.

I could not find a Nintendo numbering scheme, so I made one up. The view is
looking back "into" the connector on the CABLE.

       ----------------------------- ---------------------
      |                             |                      \
      | (1)     (2)     (3)     (4) |   (5)     (6)     (7) |
      |                             |                      /
       ----------------------------- ---------------------

        Pin     Description             Color of wire in cable
        ===     ===========             ======================
        1       +5v                     White
        2       Data clock              Yellow
        3       Data latch              Orange
        4       Serial data             Red
        5       ?                       no wire
        6       ?                       no wire
        7       Ground                  Brown

Additional notes:

Pins 5 and 6 show a DC voltage of 5v on a DMM. I forgot to look at them
on a scope so there may pulses too. However, they don't connect to
anything at present.

The controllers have a small circuit board with 2 surface mount 14-pin
ICs, marked by Nintendo as IC-A and IC-B. Although rubber domes are used
to provide the tactile response of the buttons, they are not capacitive
technology as originally thought. Instead they use what appears to be
carbon impregnated rubber on the underside which makes a resistive path
(200 ohms) across 2 carbon coated PCB pads when depressed.

•The red wire goes to pin 2 on IC-A.
•The orange wire goes to pin 8 on both IC-A and IC-B.
•The yellow wire goes to pin 9 on both IC-A and IC-B.

IC-A and IC-B appear to be identical, with a 91 date code and have another
(possible part number) of 545. These are most likely 2 parallel load shift
registers in series. Buttons on the controller pull the parallel load inputs
to ground through the contact formed by pressing a button. IC-B serially
feeds IC-A, which then drives the serial data line to the SNES CPU.


5. SNES Controller Communication Protocol

Every 16.67ms (or about 60Hz), the SNES CPU sends out a 12us wide, positive
going data latch pulse on pin 3. This instructs the ICs in the controller
to latch the state of all buttons internally. Six microsenconds after the
fall of the data latch pulse, the CPU sends out 16 data clock pulses on
pin 2. These are 50% duty cycle with 12us per full cycle. The controllers
serially shift the latched button states out pin 4 on every rising edge
of the clock, and the CPU samples the data on every falling edge.

Each button on the controller is assigned a specific id which corresponds
to the clock cycle during which that button's state will be reported.
The table in section 4.0 lists the ids for all buttons. Note that
multiple buttons may be depressed at any given moment. Also note
that a logic "high" on the serial data line means the button is NOT

At the end of the 16 cycle sequence, the serial data line is driven low
until the next data latch pulse. The only slight deviation from this
protocol is apparent in the first clock cycle. Because the clock is
normally high, the first transition it makes after latch signal is
a high-to-low transition. Since data for the first button (B in this
case) will be latched on this transition, it's data must actually be
driven earlier. The SNES controllers drive data for the first button
at the falling edge of latch. Data for all other buttons is driven at
the rising edge of clock. Hopefully the following timing diagram will
serve to illustrate this. Only 4 of the 16 clock cycles are shown for


                        -->|   |<--

                            ---                               ---
                           |   |                             |   |
        Data Latch      ---     -----------------/ /----------    

        Data Clock      ----------   -   -   -  -/ /----------------   -  
                                  | | | | | | | |                   | | | |
                                   -   -   -   -                     -   -
                                   1   2   3   4                     1   2

        Serial Data         ----     ---     ----/ /           ---
                           |    |   |   |   |                 |
        (Buttons B      ---      ---     ---        ----------
        & Select        norm      B      SEL           norm
        pressed).       low                            low
                             -->|   |<--


6. SNES Controller Button-to-Clock Pulse Assignment

        Clock Cycle     Button Reported
        ===========     ===============
        1               B
        2               Y
        3               Select
        4               Start
        5               Up on joypad
        6               Down on joypad
        7               Left on joypad
        8               Right on joypad
        9               A
        10              X
        11              L
        12              R
        13              none (always high)
        14              none (always high)
        15              none (always high)
        16              none (always high)

Additional notes:

Clock cycles 13-16 are essentially unused. It would be interesting to see
how the SNES responds if we drive low button data during these cycles.
Nintendo may use these for future controllers with more capabilities.

(From the Editor)

NOTE: S-VHS is not means to mean Super-VHS. It stands for Super-Video
(connector and output)

#### Additional Info (From Kevin Horton)

OK, the SNES uses the 65816 processor, which is basically a 16-bit version
of the 6502. It runs at 3.579545 MHz (color-burst), and has an 8-bit data 
It can address up to 16MB.

The carts are nothing more than ROM. To tell you how much data is one,
take the number of 'MegaBits' and divide by 8 to get megabytes. That's
how much data is really in the carts. So, an 8-mbit cart really is only
1 megabyte.

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