Cartridge connector: Difference between revisions

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== Pinout of 60-pin Famicom consoles and cartridges ==
== Pinout of 60-pin Famicom consoles and cartridges ==


This diagram represents a top-down view looking directly into the connector. Pins 01-30 are on the label side of the cartridge, left to right.
This diagram represents a top-down view looking directly into the connector. Pins 01–30 are on the label side of the cartridge, left to right.


            -------
The pitch, or pin spacing, of this connector is 2.5<u>4</u>mm.  This corresponds to 0.1 inch.
       GND |01  31| +5V
 
   PRG A11 |02  32| M2
  (front)                (back)
   PRG A10 |03  33| PRG A12
  Famicom    | Cart  |    Famicom
     PRG A9 |04  34| PRG A13
              -------
     PRG A8 |05  35| PRG A14
       GND -- |01  31| -- +5V
     PRG A7 |06  36| PRG D7
   CPU A11 -> |02  32| <- M2
     PRG A6 |07  37| PRG D6
   CPU A10 -> |03  33| <- CPU A12
     PRG A5 |08  38| PRG D5
     CPU A9 -> |04  34| <- CPU A13
     PRG A4 |09  39| PRG D4
     CPU A8 -> |05  35| <- CPU A14
     PRG A3 |10  40| PRG D3
     CPU A7 -> |06  36| <> CPU D7
     PRG A2 |11  41| PRG D2
     CPU A6 -> |07  37| <> CPU D6
     PRG A1 |12  42| PRG D1
     CPU A5 -> |08  38| <> CPU D5
     PRG A0 |13  43| PRG D0
     CPU A4 -> |09  39| <> CPU D4
   PRG R/W |14  44| PRG /CE (/A15 + /M2)
     CPU A3 -> |10  40| <> CPU D3
       /IRQ |15  45| Audio from 2A03
     CPU A2 -> |11  41| <> CPU D2
       GND |16  46| Audio to RF
     CPU A1 -> |12  42| <> CPU D1
   CHR /RD |17  47| CHR /WR
     CPU A0 -> |13  43| <> CPU D0
  CIRAM A10 |18  48| CIRAM /CE
   CPU R/W -> |14  44| <- /ROMSEL (/A15 + /M2)
     CHR A6 |19  49| CHR /A13
       /IRQ <- |15  45| <- Audio from 2A03
     CHR A5 |20  50| CHR A7
       GND -- |16  46| -> Audio to RF
     CHR A4 |21  51| CHR A8
   PPU /RD -> |17  47| <- PPU /WR
     CHR A3 |22  52| CHR A9
  CIRAM A10 <- |18  48| -> CIRAM /CE
     CHR A2 |23  53| CHR A10
     PPU A6 -> |19  49| <- PPU /A13
     CHR A1 |24  54| CHR A11
     PPU A5 -> |20  50| <- PPU A7
     CHR A0 |25  55| CHR A12
     PPU A4 -> |21  51| <- PPU A8
     CHR D0 |26  56| CHR A13
     PPU A3 -> |22  52| <- PPU A9
     CHR D1 |27  57| CHR D7
     PPU A2 -> |23  53| <- PPU A10
     CHR D2 |28  58| CHR D6
     PPU A1 -> |24  54| <- PPU A11
     CHR D3 |29  59| CHR D5
     PPU A0 -> |25  55| <- PPU A12
       +5V |30  60| CHR D4
     PPU D0 <> |26  56| <- PPU A13
            -------
     PPU D1 <> |27  57| <> PPU D7
     PPU D2 <> |28  58| <> PPU D6
     PPU D3 <> |29  59| <> PPU D5
       +5V -- |30  60| <> PPU D4
              -------


== Pinout of 72-pin NES consoles and cartridges ==
== Pinout of 72-pin NES consoles and cartridges ==


This diagram represents a top-down view looking directly into the connector. On a front-loader, pins 01-36 are the top side of the connector. Pins 36-01 are on the label side of the cartridge, left to right.
This diagram represents a top-down view looking directly into the connector. On a front-loader, pins 01–36 are the top side of the connector. Pins 36–01 are on the label side of the cartridge, left to right.


The pitch, or pin spacing, of this connector is 2.5<u>0</u>mm.  This does ''NOT'' correspond to 0.1 inch.
{{mbox
| type = warning
| text = '''PPU A10 and PPU A11 (pins 63 and 62) are in reverse order (i.e. not sequential/linear) on the NES!'''
}}
{{mbox
{{mbox
| type = warning
| type = warning
| text = '''CHR A10 and CHR A11 (pins 63 and 62) are in reverse order (i.e. not sequential/linear) on the NES!'''
| text = '''The pitch, or pin spacing, of this connector is 2.5<u>0</u>mm.  This does ''NOT'' correspond to 0.1 inch. Typical female board edge connectors are not compatible.'''
}}
}}


  (front/top)          (back/bottom)
      NES    | Cart  |    NES
               -------
               -------
       +5V -- |36  72| -- GND
       +5V -- |36  72| -- GND
   CIC toMB   |35  71| <- CIC CLK
   CIC toMB <- |35  71| <- CIC CLK
  CIC toPak   |34  70| <- CIC RST
  CIC toPak -> |34  70| <- CIC +RST
     CHR D3 <> |33  69| <> CHR D4
     PPU D3 <> |33  69| <> PPU D4
     CHR D2 <> |32  68| <> CHR D5
     PPU D2 <> |32  68| <> PPU D5
     CHR D1 <> |31  67| <> CHR D6
     PPU D1 <> |31  67| <> PPU D6
     CHR D0 <> |30  66| <> CHR D7
     PPU D0 <> |30  66| <> PPU D7
     CHR A0 -> |29  65| <- CHR A13
     PPU A0 -> |29  65| <- PPU A13
     CHR A1 -> |28  64| <- CHR A12
     PPU A1 -> |28  64| <- PPU A12
     CHR A2 -> |27  63| <- CHR A10
     PPU A2 -> |27  63| <- PPU A10
     CHR A3 -> |26  62| <- CHR A11
     PPU A3 -> |26  62| <- PPU A11
     CHR A4 -> |25  61| <- CHR A9
     PPU A4 -> |25  61| <- PPU A9
     CHR A5 -> |24  60| <- CHR A8
     PPU A5 -> |24  60| <- PPU A8
     CHR A6 -> |23  59| <- CHR A7
     PPU A6 -> |23  59| <- PPU A7
  CIRAM A10 <- |22  58| <- CHR /A13
  CIRAM A10 <- |22  58| <- PPU /A13
   CHR /RD -> |21  57| -> CIRAM /CE
   PPU /RD -> |21  57| -> CIRAM /CE
     EXP 4    |20  56| <- CHR /WR
     EXP 4    |20  56| <- PPU /WR
     EXP 3    |19  55|    EXP 5
     EXP 3    |19  55|    EXP 5
     EXP 2    |18  54|    EXP 6
     EXP 2    |18  54|    EXP 6
Line 68: Line 80:
     EXP 0    |16  52|    EXP 8
     EXP 0    |16  52|    EXP 8
       /IRQ <- |15  51|    EXP 9
       /IRQ <- |15  51|    EXP 9
   PRG R/W -> |14  50| <- PRG /CE (/A15 + /M2)
   CPU R/W -> |14  50| <- /ROMSEL (/A15 + /M2)
     PRG A0 -> |13  49| <> PRG D0
     CPU A0 -> |13  49| <> CPU D0
     PRG A1 -> |12  48| <> PRG D1
     CPU A1 -> |12  48| <> CPU D1
     PRG A2 -> |11  47| <> PRG D2
     CPU A2 -> |11  47| <> CPU D2
     PRG A3 -> |10  46| <> PRG D3
     CPU A3 -> |10  46| <> CPU D3
     PRG A4 -> |09  45| <> PRG D4
     CPU A4 -> |09  45| <> CPU D4
     PRG A5 -> |08  44| <> PRG D5
     CPU A5 -> |08  44| <> CPU D5
     PRG A6 -> |07  43| <> PRG D6
     CPU A6 -> |07  43| <> CPU D6
     PRG A7 -> |06  42| <> PRG D7
     CPU A7 -> |06  42| <> CPU D7
     PRG A8 -> |05  41| <- PRG A14                  
     CPU A8 -> |05  41| <- CPU A14
     PRG A9 -> |04  40| <- PRG A13  
     CPU A9 -> |04  40| <- CPU A13
   PRG A10 -> |03  39| <- PRG A12
   CPU A10 -> |03  39| <- CPU A12
   PRG A11 -> |02  38| <- M2
   CPU A11 -> |02  38| <- M2
       GND -- |01  37| <- SYSTEM CLK
       GND -- |01  37| <- SYSTEM CLK
               -------
               -------
Line 86: Line 98:
== Additional pinout notes ==
== Additional pinout notes ==


* For the Famicom: most chips and components appear <ins>on the opposite side</ins> of the PCB from the label in Famicom cartridges.
* For the Famicom: most chips and components appear <ins>on the opposite side</ins> of the PCB from the label in Famicom cartridges. (Nintendo boards follow this convention, but third party boards vary.)
* For the NES: most chips and components appear on the label side of the PCB in NES cartridges.
* For the NES: most chips and components appear on the label side of the PCB in NES cartridges.
* Active-Low signals are indicated by a / (slash) symbol.
* Active-Low signals are indicated by a / (slash) symbol.
Line 102: Line 114:
* '''GND''' : 0V power supply.
* '''GND''' : 0V power supply.
* '''SYSTEM CLK''' : Main oscillator frequency output. It is only available on 72-pin connectors, and its speed varies between NTSC (21MHz) and PAL (27MHz) machines.
* '''SYSTEM CLK''' : Main oscillator frequency output. It is only available on 72-pin connectors, and its speed varies between NTSC (21MHz) and PAL (27MHz) machines.
* '''M2''' : Also called PHI2 (φ2) in official docs (however, see the [[CPU_pin_out_and_signal_description#Signal_description|CPU M2 and CLK description]] for additional details). This is the CPU clock output. When this signal is high, this means the PRG bus address and data lines are in a stable state and can be latched by external hardware. On reads, the data must be stable until this signal goes low.
* '''M2''' : Also called PHI2 (φ2) in official docs (however, see the [[CPU_pin_out_and_signal_description#Signal_description|CPU M2 and CLK description]] for additional details). This is the CPU clock output. When this signal is high, this means only that the CPU bus address is in a stable state. For both reads and writes, data is only guaranteed or required to be valid at the falling edge of this signal.
* '''PRG R/W''' : The Read/Write signal output from the CPU. This signal is high on during CPU reads and low during CPU writes (switches from one mode to another only when M2 is low).
* '''CPU R/W''' : The Read/Write signal output from the CPU. This signal is high during CPU reads and low during CPU writes (switches from one mode to another only when M2 is low).
* '''PRG A0..A14''' : Also called just A0..A14 in official docs, or CPU A0..A14 (to not confuse with address outputs of [[mappers]] sharing the same number). This is the CPU address bus. It is stable when M2 is high. Note that A15 exists, but is not directly available on the connector.
* '''CPU A0..A14''' : Also called just A0..A14 in official docs, or CPU A0..A14 (to not confuse with address outputs of [[mapper]]s sharing the same number). This is the CPU address bus. It is stable when M2 is high. Note that A15 exists, but is not directly available on the connector.
* '''PRG D0..D7''' : Also called just D0..D7 in official docs, or CPU D0..D7. This is the CPU bidirectional data bus. It goes high impedance on reads, allowing external memory chips to place their data here.
* '''CPU D0..D7''' : Also called just D0..D7 in official docs, or CPU D0..D7. This is the CPU bidirectional data bus. It goes high impedance on reads, allowing external memory chips to place their data here.
* '''PRG /CE''' : Also called /ROMSEL in official docs (not to be confused with PRG /CE output of mappers). This pin outputs the logical NAND of M2 and PRG A15. It is low when the CPU reads or writes to $8000-$FFFF and when the address is stable, allowing to enable ROM chips directly. [[:Category:ASIC mappers|Advanced mappers]] use more logic between this pin and the actual PRG /CE (to avoid [[bus conflict]]s, for example). Using this signal is the only way to determine the state of A15, so it's needed for any mappers doing any address decoding.
* '''/ROMSEL''': This pin outputs the logical NAND of M2 and CPU A15. It is low when the CPU reads or writes to <tt>$8000</tt>–<tt>$FFFF</tt> and when the address is stable, allowing to enable ROM chips directly. [[:Category:ASIC mappers|Advanced mappers]] use more logic between this pin and the actual PRG /CE (to avoid [[bus conflict]]s, for example). Using this signal is the only way to determine the state of A15, so it's needed for any mappers doing any address decoding.
* '''/IRQ''' : Interrupt request input. Pull low to trigger an interrupt to the CPU. Can only be connected to an open collector cartridge output (there is an internal pullup resistor in the NES/Famicom). Can be left floating if interrupts aren't used.
* '''/IRQ''' : Interrupt request input. Pull low to trigger an interrupt to the CPU. There is an internal pull-up resistor in the NES/Famicom, so it can be left floating if interrupts aren't used. NES hardware can safely pull the pin high or low, but [[PlayChoice-10]] modules must treat it as an open-collector input.
* '''Audio from 2A03''' : Audio output from the 2A03's sound generation hardware, already amplified. Only exists with 60-pins connectors.
* '''Audio from 2A03''' : Audio output from the 2A03's sound generation hardware, already amplified. Only exists with 60-pins connectors.
* '''Audio to RF''' : Usually just tied to the audio from 2A03. This one goes directly to the sound output of the console. This allows cartridges to mix audio with their own audio sources. This is not directly present on 72-pins connectors.
* '''Audio to RF''' : Usually just tied to the audio from 2A03. This one goes directly to the sound output of the console. This allows cartridges to mix audio with their own audio sources. This is not directly present on 72-pins connectors.
* '''EXP0..9''' : Pins that goes to the [[NES expansion port pinout|expansion port]] on the bottom of the NES units (not present on Famicoms). Have various uses.
* '''EXP0..9''' : These connect to the [[Expansion_port#NES|expansion port]] on the bottom of the NES-001 and have no predefined meaning, so they can be used by any cartridge and expansion device pair for whatever purpose. EXP6 has become the standard for expansion audio. See [[EXP pins]] for detailed pin usage.
** '''EXP 0''' : Used by CopyNES in its cartridge reprogramming mode.
* '''PPU /WR''' : Also called /WE in official docs. This signal is low when the PPU is writing. On its falling edge, the address and data are stable.
** '''EXP 2''' : Used by some Famicom to NES converters as audio input, because this pin is just straight ahead of the Audio In pin. The NES has to be modified to mix that with the normal audio.
* '''PPU /RD''' : Also called /RD in official docs. This signal is low when the PPU is reading. On its falling edge, the address is stable, and the data should be stable until its rising edge.
** '''EXP 5''' : Used by [[MMC5]] cartridges as an open emitter input to the cartridge. Pulling this pin high will force the PRG RAM to be transparent to all reads from it, bypassing any state of the MMC5. Writes aren't disabled in this mode, though. Leave this pin unconnected or tie it to ground will have the PRG RAM working normally (MMC5 carts have their internal pulldown resistor). Only a device that plugs in the [[NES expansion port pinout|expansion port]] under the NES could make an use of this pin.
* '''PPU A0..A13''' : Also called PA0..13 in official docs. This is the PPU's address bus. Most boards tie PA13 directly to the /CE of CHR ROM or CHR RAM to map it into [[PPU pattern tables|pattern table]] space (<tt>$0000</tt>–<tt>$1FFF</tt>) without any extra logic.
** '''EXP 6''' : Used by PowerPak to output expansion audio. Used by MMC5 cartridges as a Audio In pin. A device that plugs into the [[NES expansion port pinout|expansion port]] under the NES could allow those cartridge to use the [[MMC5 audio]] on a NES without using a screwdriver.
* '''PPU D0..D7''' : Also called PD0..7 in official documentation. This is the PPU's bidirectional data bus. Goes high impedance when PPU /RD goes low allowing memory devices to place their data here.
** '''EXP 9''' : Top-loader users wishing to audio-mod for PowerPak expansion audio will often bridge EXP6 to EXP9, because EXP6 is missing on that model NES.
* '''PPU /A13''' : The inverted form of PPU A13. Typically used to map [[PPU nametables|nametables]] and [[PPU attribute tables|attribute tables]] to <tt>$2000</tt>–<tt>$3FFF</tt>.
* '''CHR /WR''' : Also called /WE in official docs. This signal is low when the PPU is writing. On its falling edge, the address and data are stable.
* '''CIRAM /CE''' : Also called VRAM /CS. This signal is used as an input to enable the internal 2k of VRAM (used for name table and attribute tables typically, but could be made for another use). This signal is usually directly connected with PPU /A13, but carts using their own RAM for name table and attribute tables will have their own logic implemented.
* '''CHR /RD''' : Also called /RD in official docs. This signal is low when the PPU is reading. On its falling edge, the address is stable, and the data should be stable until its rising edge.
* '''CIRAM A10''' : Also called VRAM A10. This is the 1k bank selection input for internal VRAM. This is used to control how the name tables are banked; in other words, this selects [[mirroring#Nametable Mirroring|nametable mirroring]]. Connect to PPU A10 for vertical mirroring or PPU A11 for horizontal mirroring. Connect it to a software operated latch to allow bank switching of two separate name tables in single-screen mirroring (as in [[AxROM]]). Many mappers have software operated mirroring selection: they multiplex PPU A10 and PPU A11 into this pin, selected by a latch.
* '''CHR A0..A13''' : Also called PA0..13 in official docs, or PPU A0..13 not to confuse with address outputs of mappers sharing the same numbers. This is the PPU's address bus. Most boards tie PA13 directly to the /CE of CHR ROM or CHR RAM to map it into [[PPU pattern tables|pattern table]] space ($0000-$1FFF) without any extra logic.
* '''CIC +RST''' and '''CIC CLK''' : On the top-loading NES-101, these two are connected to +5V and PPU D4 respectively. The other two CIC pins float.
* '''CHR D0..D7''' : Also called PD0..7 in official documentation, or PPU D0..7. This is the PPU's bidirectional data bus. Goes high impedance when CHR /RD goes low allowing memory devices to place their data here.
* '''CHR /A13''' : The inverted form of CHR A13. Typically used to map [[nametable]]s and [[attribute table]]s to $2000-$3FFF.
* '''CIRAM /CE''' : Also called VRAM /CS. This signal is used as an input to enable the internal 2k of VRAM (used for name table and attribute tables typically, but could be made for another use). This signal is usually directly connected with CHR /A13, but carts using their own RAM for name table and attribute tables will have their own logic implemented.
* '''CIRAM A10''' : Also called VRAM A10. This is the 1k bank selection input for internal VRAM. This is used to control how the name tables are banked, in other word, this selects nametable [[mirroring]]. Connect to CHR A10 for vertical mirroring or CHR A11 for horizontal mirroring. Connect it to a software operated latch to allow bankswitching of two separate name tables in single-screen mirroring (as in [[AxROM]]). Many mappers have software operated mirroring selection: they mux CHR A10 and CHR A11 into this pin, selected by a latch.


[[Category:Pinouts]]
[[Category:Pinouts]]

Latest revision as of 00:52, 15 January 2023

Pinout of 60-pin Famicom consoles and cartridges

This diagram represents a top-down view looking directly into the connector. Pins 01–30 are on the label side of the cartridge, left to right.

The pitch, or pin spacing, of this connector is 2.54mm. This corresponds to 0.1 inch. 

  (front)                 (back)
  Famicom    | Cart  |    Famicom
              -------
      GND -- |01   31| -- +5V
  CPU A11 -> |02   32| <- M2
  CPU A10 -> |03   33| <- CPU A12
   CPU A9 -> |04   34| <- CPU A13
   CPU A8 -> |05   35| <- CPU A14
   CPU A7 -> |06   36| <> CPU D7
   CPU A6 -> |07   37| <> CPU D6
   CPU A5 -> |08   38| <> CPU D5
   CPU A4 -> |09   39| <> CPU D4
   CPU A3 -> |10   40| <> CPU D3
   CPU A2 -> |11   41| <> CPU D2
   CPU A1 -> |12   42| <> CPU D1
   CPU A0 -> |13   43| <> CPU D0
  CPU R/W -> |14   44| <- /ROMSEL (/A15 + /M2)
     /IRQ <- |15   45| <- Audio from 2A03
      GND -- |16   46| -> Audio to RF
  PPU /RD -> |17   47| <- PPU /WR
CIRAM A10 <- |18   48| -> CIRAM /CE
   PPU A6 -> |19   49| <- PPU /A13
   PPU A5 -> |20   50| <- PPU A7
   PPU A4 -> |21   51| <- PPU A8
   PPU A3 -> |22   52| <- PPU A9
   PPU A2 -> |23   53| <- PPU A10
   PPU A1 -> |24   54| <- PPU A11
   PPU A0 -> |25   55| <- PPU A12
   PPU D0 <> |26   56| <- PPU A13
   PPU D1 <> |27   57| <> PPU D7
   PPU D2 <> |28   58| <> PPU D6
   PPU D3 <> |29   59| <> PPU D5
      +5V -- |30   60| <> PPU D4
              -------

Pinout of 72-pin NES consoles and cartridges

This diagram represents a top-down view looking directly into the connector. On a front-loader, pins 01–36 are the top side of the connector. Pins 36–01 are on the label side of the cartridge, left to right.

The pitch, or pin spacing, of this connector is 2.50mm. This does NOT correspond to 0.1 inch.

PPU A10 and PPU A11 (pins 63 and 62) are in reverse order (i.e. not sequential/linear) on the NES!
The pitch, or pin spacing, of this connector is 2.50mm. This does NOT correspond to 0.1 inch. Typical female board edge connectors are not compatible. 
 (front/top)           (back/bottom)
      NES    | Cart  |    NES
              -------
      +5V -- |36   72| -- GND
 CIC toMB <- |35   71| <- CIC CLK
CIC toPak -> |34   70| <- CIC +RST
   PPU D3 <> |33   69| <> PPU D4
   PPU D2 <> |32   68| <> PPU D5
   PPU D1 <> |31   67| <> PPU D6
   PPU D0 <> |30   66| <> PPU D7
   PPU A0 -> |29   65| <- PPU A13
   PPU A1 -> |28   64| <- PPU A12
   PPU A2 -> |27   63| <- PPU A10
   PPU A3 -> |26   62| <- PPU A11
   PPU A4 -> |25   61| <- PPU A9
   PPU A5 -> |24   60| <- PPU A8
   PPU A6 -> |23   59| <- PPU A7
CIRAM A10 <- |22   58| <- PPU /A13
  PPU /RD -> |21   57| -> CIRAM /CE
    EXP 4    |20   56| <- PPU /WR
    EXP 3    |19   55|    EXP 5
    EXP 2    |18   54|    EXP 6
    EXP 1    |17   53|    EXP 7
    EXP 0    |16   52|    EXP 8
     /IRQ <- |15   51|    EXP 9
  CPU R/W -> |14   50| <- /ROMSEL (/A15 + /M2)
   CPU A0 -> |13   49| <> CPU D0
   CPU A1 -> |12   48| <> CPU D1
   CPU A2 -> |11   47| <> CPU D2
   CPU A3 -> |10   46| <> CPU D3
   CPU A4 -> |09   45| <> CPU D4
   CPU A5 -> |08   44| <> CPU D5
   CPU A6 -> |07   43| <> CPU D6
   CPU A7 -> |06   42| <> CPU D7
   CPU A8 -> |05   41| <- CPU A14
   CPU A9 -> |04   40| <- CPU A13
  CPU A10 -> |03   39| <- CPU A12
  CPU A11 -> |02   38| <- M2
      GND -- |01   37| <- SYSTEM CLK
              -------

Additional pinout notes

  • For the Famicom: most chips and components appear on the opposite side of the PCB from the label in Famicom cartridges. (Nintendo boards follow this convention, but third party boards vary.)
  • For the NES: most chips and components appear on the label side of the PCB in NES cartridges.
  • Active-Low signals are indicated by a / (slash) symbol.
  • The NES and Famicom connectors have a similar arrangement; the connector on the NES is mostly a mirror image of the Famicom's.
  • Most cartridge PCBs made by Nintendo are numbered the same way as indicated in these diagrams.

Signal descriptions

 Unless otherwise specified, these signals are from the console's viewpoint. So an input is a signal driven by the cartridge to the console, and an output is a signal driven by the console to the cartridge connector.
  • +5V : 5V Power supply from the main voltage regulator.
  • GND : 0V power supply.
  • SYSTEM CLK : Main oscillator frequency output. It is only available on 72-pin connectors, and its speed varies between NTSC (21MHz) and PAL (27MHz) machines.
  • M2 : Also called PHI2 (φ2) in official docs (however, see the CPU M2 and CLK description for additional details). This is the CPU clock output. When this signal is high, this means only that the CPU bus address is in a stable state. For both reads and writes, data is only guaranteed or required to be valid at the falling edge of this signal.
  • CPU R/W : The Read/Write signal output from the CPU. This signal is high during CPU reads and low during CPU writes (switches from one mode to another only when M2 is low).
  • CPU A0..A14 : Also called just A0..A14 in official docs, or CPU A0..A14 (to not confuse with address outputs of mappers sharing the same number). This is the CPU address bus. It is stable when M2 is high. Note that A15 exists, but is not directly available on the connector.
  • CPU D0..D7 : Also called just D0..D7 in official docs, or CPU D0..D7. This is the CPU bidirectional data bus. It goes high impedance on reads, allowing external memory chips to place their data here.
  • /ROMSEL: This pin outputs the logical NAND of M2 and CPU A15. It is low when the CPU reads or writes to $8000$FFFF and when the address is stable, allowing to enable ROM chips directly. Advanced mappers use more logic between this pin and the actual PRG /CE (to avoid bus conflicts, for example). Using this signal is the only way to determine the state of A15, so it's needed for any mappers doing any address decoding.
  • /IRQ : Interrupt request input. Pull low to trigger an interrupt to the CPU. There is an internal pull-up resistor in the NES/Famicom, so it can be left floating if interrupts aren't used. NES hardware can safely pull the pin high or low, but PlayChoice-10 modules must treat it as an open-collector input.
  • Audio from 2A03 : Audio output from the 2A03's sound generation hardware, already amplified. Only exists with 60-pins connectors.
  • Audio to RF : Usually just tied to the audio from 2A03. This one goes directly to the sound output of the console. This allows cartridges to mix audio with their own audio sources. This is not directly present on 72-pins connectors.
  • EXP0..9 : These connect to the expansion port on the bottom of the NES-001 and have no predefined meaning, so they can be used by any cartridge and expansion device pair for whatever purpose. EXP6 has become the standard for expansion audio. See EXP pins for detailed pin usage.
  • PPU /WR : Also called /WE in official docs. This signal is low when the PPU is writing. On its falling edge, the address and data are stable.
  • PPU /RD : Also called /RD in official docs. This signal is low when the PPU is reading. On its falling edge, the address is stable, and the data should be stable until its rising edge.
  • PPU A0..A13 : Also called PA0..13 in official docs. This is the PPU's address bus. Most boards tie PA13 directly to the /CE of CHR ROM or CHR RAM to map it into pattern table space ($0000$1FFF) without any extra logic.
  • PPU D0..D7 : Also called PD0..7 in official documentation. This is the PPU's bidirectional data bus. Goes high impedance when PPU /RD goes low allowing memory devices to place their data here.
  • PPU /A13 : The inverted form of PPU A13. Typically used to map nametables and attribute tables to $2000$3FFF.
  • CIRAM /CE : Also called VRAM /CS. This signal is used as an input to enable the internal 2k of VRAM (used for name table and attribute tables typically, but could be made for another use). This signal is usually directly connected with PPU /A13, but carts using their own RAM for name table and attribute tables will have their own logic implemented.
  • CIRAM A10 : Also called VRAM A10. This is the 1k bank selection input for internal VRAM. This is used to control how the name tables are banked; in other words, this selects nametable mirroring. Connect to PPU A10 for vertical mirroring or PPU A11 for horizontal mirroring. Connect it to a software operated latch to allow bank switching of two separate name tables in single-screen mirroring (as in AxROM). Many mappers have software operated mirroring selection: they multiplex PPU A10 and PPU A11 into this pin, selected by a latch.
  • CIC +RST and CIC CLK : On the top-loading NES-101, these two are connected to +5V and PPU D4 respectively. The other two CIC pins float.
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