Converting a Star Wars to an Empire Strikes Back arcade game.
Version 1.1, Copyright Cliff Koch, 1996
Revision log:
1.0 Original Posting
1.1 Added the data bus wires on the daughterboard netlist (oops).
I. Disclaimer
Doing this conversion requires reasonable soldering skills. Incorrect
wiring could cause damage to the game boards. You do these modifications
at your own risk. I did my best to be accurate at describing the
conversion, but could have made an error. If any errors are found I
would like to hear about them. I will not be liable for any damage
caused to game boards by anyone attempting this conversion.
You are responsible for obtaining any copyrighted material
(EPROMs/PROMs) necessary for the conversion.
This file, including the 22V10 PAL JEDEC information at the end is
Copyrighted by me (Cliff Koch). I grant permission for personal,
non-commercial use of the information in this file. I do not grant
permission for the sale of this information or the use of information
in this file in the sale of a product or information from this file
being used in a commercial application without prior consent of myself.
Please ask my permission before redistributing this file. This file
may only be redistributed in its full, unaltered form.
Ok, enough of the legalese. I'm sure the above proves I'm no lawyer.
The gist of this is I did this because ESB conversion sets are rare and
expensive (though after getting a little ways into it it also became a
challenge). I'm allowing people to use this information for fun, but I
don't want anyone trying to make money off of my work without my consent
(and possibly cutting me in :-). So don't go making and selling ESB
games without talking to me first, OK?
This file contains detailed instructions on how to convert an Atari Star
Wars arcade game board set to play the Empire Strikes Back game. All
information necessary to do the conversion (including how to make your
own Slapstic clone!) should be here except for the EPROM/PROM images,
which are available via ftp. I've included instructions on how to do a
simple conversion to Empire Strikes Back and how to convert a game board
to play both Star Wars and Empire Strikes Back via a switch mounted on
the game service panel.
The Empire Strikes Back conversion kit made by Atari includes a small
daughtercard which contains two EPROMs, a socket to plug into the
Star Wars/ESB main CPU board, and a "Slapstic" chip. In order to do the
conversion you will have to build a daughterboard. This is not hard,
but it's a bit tedious and time consuming.
The Slapstic chip is used as both a security chip and memory expander.
This has apparently been the elusive part of converting to an ESB game
in the past. I'm afraid I may be stepping on a few toes by supplying
this information openly. Oh, well. I have included a JEDEC file used
for programming a 22V10 PAL to emulate the function of the slapstic
chip.
The PAL is *not* pin compatible with the slapstic, so a daughterboard
using this PAL will be wired differently than an Atari daughterboard.
I understand the ESB slapstic was also compatible with the Tetris
slapstic (or vice-versa). I would not count on my clone also working
for Tetris. It's quite probable that the algorithm I came up with to
get ESB to function will not work for Tetris.
If you don't have access to a PAL programmer, I'll supply a
pre-programmed PAL for a nominal fee (email me for info,
[email protected]). I will not directly supply the preprogrammed
EPROMs/PROMs for the game, as that is copyrighted Atari material. If
you're stuck trying to get some of the parts, let me know and I'll
help you come up with them. I've toyed with designing a circuit board
for the daughtercard, but that's dependent on spare time, which I have
very little of at the moment.
If any errors are found in the conversion information, please let me
know. I'd also be interested in hearing how it works if you give this
a shot (email: [email protected]). Let me know if you did an ESB
conversion or a Star Wars/ESB conversion and if any problems were
encountered.
Thanks to Rick Schieve and Mark Woodward for their help in this. Mark
gave me some initial info on slapstic operation that gave me a big push
into starting work on this quite a bit earlier than I had originally
planned. Rick loaned a real ESB boardset to me which sped up the
reverse engineering task on some of the tricky bits by quite a bit.
1 Breadboard
3 28 pin .600" sockets (see notes below)
1 24 pin .300" socket (see notes below)
1 22V10 PAL prgrammed with information at the end of this file.
I recommend a 25nS or faster CMOS PAL, though virtually any
22V10 should work.
2 27128 or 27256+ EPROMs (see later sections for exact type)
The daughtercard I wired up looks very much like the one Atari
originally
supplied for ESB conversions. The board outline looks like:
U2 and U3 are 28 pin sockets containing EPROMs. U2 contains Atari
part number 136031.106 and U3 contains part number 136031.105.
U1 is a 22V10 PAL in a 24 pin .300 inch wide socket. See section
V.8.D for more information on U2 and U3 for an ESB/SW combination
conversion.
On the real ESB daughterboard, U4 has long pins on it which plug
directly into the EPROM socket at position 1H/J on the CPU board.
The daughterboard was then sandwiched between the CPU board and
soundboard. There's very little room to do this in. I managed it
with the machine pin socket described later in this section, but
it's not an easy thing to do with a breadboard. Most people will
want to use a normal socket in position at U4 and use a cable to
connect to the socket on the CPU board, which is described later
in this section.
The following is the netlist for the daughterboard. The format for
each connection gives the U# and the pin of the IC to connect to. Each
of the pins listed in a row of the following table are connected
together. I've included the signals name/function for reference. I
recommend adding a .1uF capacitor between power and ground pins of
each IC (pins 12 and 24 of U1, pins 14 and 28 of U2 and U3). The
exact capacitor needs of the daughterboard will depend on the
components used (especially the 22V10).
* This signal is used when making the board operate as a combo Star
Wars/ Empire Strikes Back game. If you choose not to do that, it
still should be left wired this way.
I built a couple of daughterboards. For one of the daughterboards I
used a copper doughnut breadboard and some individual machine socket
pins. These are pins like what are used with machine pin sockets,
except they are individual pins temporarily mounted on an aluminum
frame. The pins are normally meant to be soldered into a board, the
frame removed, and then used as a socket. The pins were .034"
diameter, so I drilled out the perfboard in the pattern of the IC
sockets to .032" diameter, pressed the pins into place, point to point
wired the board, and snipped off the legs of the pins in locations
U1, U2, and U3. I then added a machine pin socket to the pins in
location U4, which allows the daughterboard to be plugged into the
CPU board like the Atari daughterboard. The daughterboard then sits
sandwiched between the CPU board and sound board. If you try this
method to make the daughter board, be carefull of IC spacing. The
lower edge of the board (where U1 resides) needs to fit between the
board EPROM socket and the back edge connector. The other (and
simpler) board I made uses ordinary sockets which I point to point
wired. I then used a ribbon cable connector with a DIP type cable
ends to connect the daughterboard to the CPU board socket. The
daughterboard can then be located at the edge of where the soundboard
covers the CPU board. Unfortunately I couldn't find a cable with 28
pin socket ends, so I used a cable with 40 pin ends and just let extra
pins hang over the ends of the sockets.
IV. Board Modifications for Empire Strikes Back only operation
A) Modifications to the Main CPU card
1) Locate and cut the trace by pin 22 of the EPROM socket at 1H/J. The
trace is located on the solder side of the board.
2) Solder a jumper wire from pin 34 of the socket at 2C to pin 22 of the
socket at 1H/J.
3) Cut the traces on both sides of pin 26 of the sockets located at
1K/L and 1M. Solder a wire between pin 28 and the trace that was
disconnected on the far side of pin 26 at 1K/L and 1M.
4) Cut the trace on the one side of pin 26 at location 1J/K.
5) Connect jumper wires to connect together pins 26 of 1F, 1J/K, 1K/L,
and 1M.
6) Remove the ICs at locations 1H/J, 1J/K, 1K/L, 1M, 1F, 7H, 7J, 7K, and
7L replace them as follows:
136031-101 at location 1F
136031-102 at location 1J/K
136021-203 at location 1K/L
136031-104 at location 1M
136031-110 at location 7H
136031-109 at location 7J
136031-108 at location 7K
136031-107 at location 7L
7) Plug the daughterboard into location 1H/J.
8) If your Star Wars main PCB does not have R59 installed and the game
does not retain high scores or statistics, insert a 10K resistor in
series between pin 10 of 1E and at the intersection of R100, CR3,
and C94.
B) Modifications to the Sound Board
1) Cut the traces going to pin 26 of 1J/K and 1H.
2) Connect pins 23 of 3K, 26 of 1J/K, and 26 of 1H together.
3) Remove ICs at locations 1H and 1J/K.
4) Replace 1H with 136031-112 and 1J/K with 136031-113.
C) Modifications to the AVG board
1) Remove the IC at location 1L and replace with part number 136031-111.
D) Checking game operation
Check your work before powering up the game. Once you start it up I
recommend running the diagnostics. You shouldn't see any ROM errors
and the 'Verisum' should be B735.
V. Board modifications for Empire Strikes Back and Star Wars operation.
These modifications are essentially just programming both the ESB and
Star Wars EPROM data into larger EPROMs and using an address line to
control the image that the processor accesses. I added a wire to an
unused pin on the CPU main board edge connector to connect to a switch
on the maintenance panel which allows game selection inside the coin
door. I also made the board such that it will come up as a Star Wars
if that wire is not present and added a berg pin jumper on the main
board which can select ESB as the game in the absence of an external
switch.
There are different ways to accomplish this. I'm documenting my way
(the right way, of course :). Briefly, the changes I made were: Run
a wire from the edge connector to the input of a 74LS14 IC; add a
pullup resistor to that line; buffer the output of the original
invertor through 3 seperate invertors in the same package; use one to
control address lines on the main CPU board; use a 3 pin right angle
header connector at the edge of the board to get the other two buffered
address signals to the sound board and AVG board.
If you do all of my conversion, including adding the switch up front to
change the game, you can change the game while the game is powered up.
When you flip the switch the main processor will essentially get lost
and crash, the game watchdog timer will go off and reset the board.
The newly selected game will now start running. The one caveat to this
is that the NOVRAM location meanings between games is different. The
game will look at NOVRAM and not find what it expected. It will then
take the settings off of the DIP switches and use those as the default
and rewrite the NOVRAM settings. For me, this works fine, as I use
the same difficulty settings and free play on both games (and you're
using free play, too, if you read my restrictions on use of this
information at the top of the file :). The most noticable problem
with switching the games is that the analog control self adjusting
parameters are lost, so the flight controls may be out of adjustment
after a game switch has been made. This can be corrected by starting
a game and moving the controls through full movements from corner to
corner during the starting round selection screen. The high scores
will also not be retained when the games are switched.
NOTE: When talking about the connections to the IC in the SPARE location,
I am talking about the pin number of the SOCKET. The board can hold
a 16 pin IC at that location, but I'm installing a 14 pin IC.
Therefore I am actually talking about the pin number of the IC to
be installed there. The one exception is in step 15 where the pin
8 being talked about is the one on the board (the ground connection
for the IC).
A) Modifications to the Main CPU board
1) Locate and cut the trace by pin 22 of the EPROM socket at 1H/J. The
trace is located on the solder side of the board.
2) Solder a jumper wire from pin 34 of the socket at 2C to pin 22 of the
socket at 1H/J.
3) Cut all of the traces leading to pins 26 and 27 of ICs located at
1M, 1K/L, and 1J/K.
4) Cut the traces on both sides of pin 27 at location 1H/J.
5) Solder a wire to reconnect the cut traces that were isolated at
locations 1M, 1K/L, and 1H/J to pin 28 of the respective ICs.
6) Cut the trace on the one side of pin 27 at location 1F.
7) Connect jumper wires to connect together pins 26 of 1F, 1J/K, 1K/L,
and 1M.
8) Place a 14 pin IC socket at the SPARE IC location next to 7P. The
socket should be located furthest towards IC 8R.
9) Add a 2 pin berg connector to the main board near J20. This is used
to manually select ESB as the standard game in the absence of an
external switch. I drilled two holes .100" apart near the "Z"
location on connector J20 for the berg pins. Connect one side
of the berg pin to the large ground trace on the component side.
Connect the other side of the berg connector to the 4th edge finger
down from the Z side of J20 and to pin 1 of the SPARE IC. An ugly
ASCII drawing of the mod follows:
| XXXXXXXXXX <- 'X's are traces (ground)
| XXXXXXXXXX
|_ | XXXX <- '|' is connection to ground
| o XXXX <- 'o's are berg pin jumper
| o XXXX <-
_____| XXXX
| Z XXXX
|XXXXXXXXXXXXXX
| XXXX Connector
|XXXXXXX XXXX J20
Edge Connector | XXXX
|XXXX XXXX
| XXXX
|XXXX -- XXXX
| |
| To pin 1 of SPARE and 1 side of berg jumper
|
10) Connect a 1K resistor between pin 14 and pin 1 of the IC socket
at SPARE. Connect a wire from pin 14 to pin 13 and pin 11 of the
socket at the SPARE location.
11) Connect wires between pin 2, pin 3, pin 5, and pin 9 of the socket
at the SPARE location.
12) Connect wires between pin 8 of the socket at SPARE and pin 27 of
locations 1M, 1K/L, 1J/K, 1H/J, 1F.
13) I installed a 3 pin right angle header connector below J17 to get
the address line signal between main board, AVG board, and sound
board. I used a berg connector so the boards could still be easily
disconnected from each other and they were cheap.
14) Connect a wire from pin 4 of the SPARE socket to one side of the
header connector. Connect a wire from pin 6 of the SPARE socket
to the other side of the header connector.
15) Connect a wire from pin 7 of the socket at location SPARE and the
hole for pin 8 of the spare position on the board.
16) Section D) covers the firmware replacement for this board.
B) Modifications to the sound board
1) Cut the traces between pins 26, 27, and 28 of 1J/K and 1H.
2) Connect pins 23 of 3K, 26 of 1J/K, and 26 of 1H together.
3) I installed a 3 pin right angle header connector on this board
which lined up with the one on the main CPU board. Connect 1
side of the connector to pin 27 of 1J/K and pin 27 of 1H.
4) Section D) covers the firmware replacement for this board.
C) Modifications to the AVG board
The AVG modifications are a bit different because you need to
replace a 24 pin EPROM at 1L with a 28 pin EPROM. I used a 28 pin
socket plugged into the 24 pin socket on the board. Connect
pins 1, 28, 27, and 26 of the socket together, leaving enough
room on pin 26 so the socket can still be plugged into the boards
socket.
I installed a 3 pin right angle header connector on this board which
lined up with the one on the main CPU board. I ran a wire from one
side of this connector to pin 2 of the 28 pin socket. The 28 pin
socket should then be plugged into the board so that pins 1, 2, 27,
and 28 are hanging over the end of the 24 pin socket in the board.
D) Board firmware creation
You need to come up with the ESB PROMs at locations 7H, 7J, 7K, and 7L
of the main CPU board with 136031-110, 136031-109, 136031-108, and
136031-107 respectively. These PROMs are compatible with both ESB and
Star Wars.
The EPROM images between Star Wars and ESB need to be merged. The
EPROMs
used need to be 27256 or 27512 EPROMs except for the AVG board, which
can use a 2764, 27128, 27256, or 27512 EPROM. I used 27C512 EPROMs
on everything except the AVG board, where I used a 2764. The following
table shows where each ROM image needs to be copied for each type of
EPROM. Several of the Star Wars EPROMs I show being copied to multiple
places. This is REQUIRED for the daughterboard EPROMs. The second
image on all others are just because I haven't checked to insure where
the game expects the image to reside.
You need to make a cable to get the extended address line from the
main CPU board to the sound board and AVG board. I used three 3 pin
female header connectors to mate with the male connectors I installed
on the 3 PC boards. One of the outputs from the main CPU board goes
to the sound board and one goes to the AVG board.
F) Cabinet wiring
If you're this far, you're almost done. If this wiring is not in
place, the board will play like a Star Wars. If you installed the berg
jumper in section A.9, then installing that jumper will make the board
become an ESB. This wasn't good enough for me, which is why I made the
connection to the board edge connector. I took a pin from an edge
connector off of an old harness and placed it in the same unused
location I connected to on the main board. I then connected this to
a wire and ran it with the wiring harness to the connector which goes
to the service panel. I added pins to an unused location on the
service panel connectors and added a SPST toggle switch to the service
panel. Connect one side of the switch to ground (black common wire
going to other switches on service panel) and the other side to the
new wire. Make sure there is no berg jumper on the added berg
connector on the main board or the game will be continuously ESB.
Now when the switch is closed the game will play ESB and when open
it will play Star Wars.
This is the JEDEC file for the 22V10 PAL which emulates the
functionality
of the Atari Slapstic. It actually does not work *exactly* like the
slapstic, but program flow is not affected by the differences. This
design does tighten the timing constraints of memory accesses to the
EPROMs a bit, but the cycle times for the 6809 are so slow you're not
likely to find EPROMs slow enough to make a difference. I originally
designed this in a 22V10, outgrew it and used a 26V12. I finally
figured out everything needed to get it working and optimized it back
into a 22V10 because they're a lot more common. If you happen to have
26V12 PALs laying around instead of 22V10s, let me know and I'll email
out that JEDEC file. The actual devices I used for this were 25
nanosecond Lattice GAL22V10s and GAL26CV12s, though any 22V10 should
work.
