PRG RAM circuit

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The iNES format implies 8 KiB of PRG RAM at $6000-$7FFF, which may or may not be battery backed, even for discrete boards such as NROM and UxROM that never actually had SRAM there. This inspired some people on the nesdev.org BBS to come up with circuits to add PRG RAM to the original boards, so that games relying on it can run on an NES.

kyuusaku's circuit

On the forum, kyuusaku has suggested an SRAM decoder circuit[1] to approximate this behavior in an NES cartridge board. It can be built from 7400 series parts: a 74HC00 (4 NANDs) and a 74HC04 (6 inverters), or from two 74HC00s (because a NAND with both inputs equal acts as an inverter).

NES cart edge                     SRAM chip
                       ___
R/W ----+-------------|   `.
        |             |     )o--------- /OE
Phi2 ---(----------+--|___,'
        |          |
        |          |   ___
        |          `--|   `.
        |  |`.        |     )o--------- /WE
        `--|  >o------|___,'
           |,'

           ___
/ROMSEL --|   `.    |`.       ___
          |     )o--|  >o----|   `.
A14 ------|___,'    |,'      |     )o-- /CE
                          ,--|___,'
A13 ---------------------'

kyuusaku also pointed out that a 74HC138 or 74HC139 can decode the address using one spare inverter, leaving the details as an exercise for the reader.

Bregalad's circuit

Bregalad suggested an even simpler circuit using one 74HC08, 74HC20, or 74HC21 chip, which exploits the 6264 SRAM's /WE behavior:[2]

AND A13, A14, /ROMSEL and PHI2 together (it shouldn't matter in which order) and feed the output to positive chip enable pin, ground the negative chip enable pin and connect /WE to R/W and /OE to ground and that should to it.

One side of a 74HC21 (dual 4-input AND) or 74HC20 (dual 4-input NAND) could compute the same function.

kyuusaku's second circuit

kyuusaku found potential timing problems with Bregalad's circuit and suggested a refinement of his own circuit based on a 7410 (triple 3-input NAND):[3]

NES cart edge                  RAM

              ____
/ROMSEL -----|    `-.
             |       \
A14 ---------|        )o------ /CS
             |       /
A13 ---------|____,-'

              ____
R/W ---------|    `-.
             |       \
Phi2 -----+--|        )o--+--- /OE
          |  |       /    |
          +--|____,-'     |
          |               |
          |   ____        |
          +--|    `-.     |
          |  |       \    |
          +--|        )o--(--- /WE
             |       /    |
          ,--|____,-'     |
          |               |
          `---------------'

On each of the NANDs that produce /OE and /WE, one Phi2 input can be replaced with Vdd (constant +5 V) if it simplifies routing.

More suggestions from kyuusaku

kyuusaku found "a race condition that could trigger unintentional writes" in the second circuit. Then he figured how to stick a pulldown on CE2 to take advantage of Phi2 going high-impedance during reset in order to "offer some write protection".[4]

           ,-------------- ROM /CE
          |   ____
/ROMSEL --+--|    `-.
             |       \
A14 ---------|        )o-- RAM /CE
             |       /
A13 ---------|____,-'

              ____
+5V ------+--|    `-.
          |  |       \
          `--|        )o-- ROM /OE
             |       /
R/W ------+--|____,-'
          |
          `--------------- RAM /WE

Phi2 ---------+----------- RAM CE2
              |
              <
              < "big R"
              <
              |
GND ----------+----------- RAM /OE

He also suggested a circuit based on a 74HC20 (double 4-input NAND):

Or you could just use a NAND4 to decode any active low memory, also using the /WE priority method. If this is done with a two gate 7420, the second gate could be used to invert r/w to prevent bus conflicts as in the circuit above. This is probably the *final* best way unless you happen to need the extra AND3 from the 7410 and have a positive CE.