SIMPLE-68008

Features

68008 CPU
- 20 bit address space (1MB total)
10 MHz clock
128KB/512KB SRAM
- Runs with zero wait states
Up to 448KB EPROM/EEPROM
- Runs with zero wait states
68681 Dual Serial Port (ACIA)
- Headers for FTDI
- 38,400 baud (other rates are programmable)
- Connected to FTDI-49MM card
  - FTDI-49MM card drives 5V to the card
  - Run serial terminal program on the PC
Reset switch with optional Power Supervisor
5V operation
- 375 mA nominal
95x95mm card
(4) 6-32 mounting holes

Memory Map

0x00000-0x7FFFF 512KB SRAM
0x80000-0xEFFFF Up to 448KB EPROM (minus DUART I/O space)
0x80000 write with D0 = 1 to unmap the EPROM from the SRAM space
0x80000-0x87FFF 27C256 (322KB)
0x80000-0x8FFFF 27C512 (64KB)
0xF0000-0xFFFFF Serial (ACIA)

Alternate Memory Map

Other memory maps could be done
For instance, the Teeside memory map could be used
The memory map depends on two things
- Mapping in the PLDs
- The firmware that is being run on the card has to match the memory map

Chip Set

On Ebay
- $20 plus $9 shipping (2024-08)

Parts in "Kit"

Only the MC68000P10 and TMP68681P are used by this card
MC68000P10 - 68K CPU with 16-bit data bus and 24-bit address bus
TMP68681P - Dual UART, 8-bit I/O, 6-bit I/O
MC68230P8 - Parallel I/O bits, timer
MC68901P - Multifunction (8 I/O pins, interrupt controller, (4) timers, UART
AM8511A - Floating Point Unit
MC68008P10 - 68K CPU with 8-bit data bus and 20-bit address bus
65B50P - ACIA (Serial interface)

Design

CPU

The Motorola 68008 is an 8/32-bit microprocessor introduced by Motorola in 1982
- It is a version of 1979's Motorola 68000 with an 8-bit external data bus, as well as a smaller address bus
- This card uses a 68008 with 20 address lines (48-pin package) which allowed 1 MB address space versus the 16 MB addressable on the 68000
Rev 1 needs a wire jumper U5-39 to U5-40 to pull up VPA*

CPU Timing

Function Code

EPROM

SST27C256 EEPROM
- 32 KB part
- 28 pin part, 32 pin socket
SST27C512 EEPROM
- 64 KB part
- 28 pin part, 32 pin socket

Flash Memory (EEPROM) Programming

Program using TL-866ii plus programmer
Select device type
File Open
Select file = S68K_001.hex
File format: INTEL_HEX
To Region: Default
Set EPROM offset when file is loaded to accommodate memory map offsets for EPROM space
- Set From File Start Addr(Hex) to 80000
- To Buffer Start Addr(Hex) to 00000 (should be already that value)

Got Device ID error
- Turn off ID checkbox in the Options section (bottom left of window)
- Using SST 27SF512 part (Part is 64 KB)
  - Parts are actually Winbond parts remarked as SST
  - Looking up device ID showed the parts are actually Winbond parts
  - Can set programmer to Winbond part and it programs without error
Device programmed/verified
Memory Buffer should look like

Device ID Mysteries

Ebay has parts with SST marking
EPROM Programmer says the parts are WinBond (Manufacturer ID 0xDA)
- Manufacturers ID list
Part marked as 27SF512 and it's a 27C512 (Part ID 0x08)
Windbond 27C512 qty 10 are cheaper than SST part on ebay

SRAM

Using 512 KB SRAM
- Wire jumper H6-2 to H6-3 on rear of card

Dual UART

Reset

Clock

Test and works with 8 MHZ and 10 MHz crystal oscillator

PLDs

Two ATF16V8B PLDs (Datasheet)
WinCupl compiler used to write PLD "code"
- WinCupl Download link
Program using TL-866ii plus programmer
Part = ATF16V8B

PLD_001

PLD_001 Source Listing

Source file
JEDEC Programming file
WAIT1 and WAIT2 are not used since the DUART has a DTACK* out and the EPROM/SRAM run at zero wait states

Name       SIMPLE-68008_PLD_1;
Partno     ATF16V8B;
Date       07/13/24;
Revision   01;
Designer   DOUG G;
Company    LAND BOARDS LLC;
Assembly   U02;
Location   RUSTBELT, USA;
Device     G16V8;

/*
*/

/* Inputs */
PIN    1   = CLK;
PIN    2   = !CPUAS;
PIN    3   = !CPUDS;
PIN    4   = CPUA16;
PIN    5   = CPUA17;
PIN    6   = CPUA18;
PIN    7   = CPUA19;
PIN    8   = CPUFC0;
PIN    9   = CPUFC1;
PIN    11  = CPUFC2;
PIN    12  = !DDTACK;
PIN    13  = SWAP;

/* Outputs */
PIN    14  = !CPUIACK;
PIN    15  = !DUARTCS;
PIN    16  = !CPUDTACK;
PIN    17  = WAIT1;
PIN    18  = !RAMSEL;
PIN    19  = WAIT2;

CPUIACK = CPUA19 & CPUA18 & CPUA17 & CPUA16 & CPUFC2 & CPUFC1 & CPUFC0 & CPUDS;

DUARTCS = CPUA19 & CPUA18 & CPUA17 & CPUA16 & CPUDS & !CPUFC1 &  CPUFC0;

RAMSEL = !CPUA19 & SWAP & CPUDS & !CPUFC1 &  CPUFC0  		/* User/Super Data */
#        !CPUA19 & SWAP & CPUDS &  CPUFC1 & !CPUFC0; 		/* User/Super Program */

CPUDTACK = CPUA19 & CPUA18 & CPUA17 & CPUA16 & CPUDS & !CPUFC1 & CPUFC0 & DDTACK		/* DUART Data spaces	*/
#	    CPUA19 & CPUA18 & CPUA17 & CPUA16 & CPUDS & CPUFC2 & CPUFC1 & CPUFC0 & DDTACK	/* DUART IACK space */
#          CPUA19 & !CPUA18 & CPUDS								/* EPROM	*/
#          CPUA19 & !CPUA17 & CPUDS								/* EPROM	*/
#          CPUA19 & !CPUA16 & CPUDS								/* EPROM	*/
#          !CPUA19 & CPUDS;									/* RAM 		*/

PLD_002

The SWAP line maps the EPROM to the SRAM space
- EPROM map addresses still work and are mapped to 0x8000-0xEFFFF
- Used to pull the Stack pointer and start address from EPROM
- Set to 0 at power up
- Write to address 0x80000 with D0 = 1 to unmap the EPROM from the SRAM space
- Needs to be set early in the startup code before SRAM is accessed

PLD_002 Source Listing

Name       SIMPLE-68008_PLD_2;
Partno     ATF16V8B;
Date       06/19/24;
Revision   01;
Designer   DOUG G;
Company    LAND BOARDS LLC;
Assembly   U03;
Location   RUSTBELT, USA;
Device     G16V8;

/*
	RESET CONTROLLER, ROM CHIP SELECT
*/

/* Inputs */
PIN    1   = CLK;
PIN    2   = !CPUWR;
PIN    3   = !CPUDS;
PIN    4   = CPUA16;
PIN    5   = CPUA17;
PIN    6   = CPUA18;
PIN    7   = CPUA19;
PIN    8   = !POR;
PIN    9   = CPUD0;

/* Outputs */
PIN	  13  = SWAPADR;
PIN    14  = SWAP;
PIN    15  = !ROMCS;
PIN    16  = !MEMRD;
PIN    18  = !CPUHLT;
PIN    19  = !CPURES;

/* CLEAR SWAP AT POWER UP, RESET	*/
/* SET SWAP BY 1ST WR TO START OF EPROM SPACE		*/
/* SWAP.CK = CLK; */
/* SWAP.AR = POR; */

MEMRD = !CPUWR & CPUDS & !CPUA19
#       !CPUWR & CPUDS &  CPUA19 & !CPUA18
#       !CPUWR & CPUDS &  CPUA19 & !CPUA17
#       !CPUWR & CPUDS &  CPUA19 & !CPUA16;

SWAP = CPUDS &  CPUWR & CPUA19 & !CPUA18 & !CPUA17 & !CPUA16 & CPUD0 & !POR
#      SWAP  & !POR;

SWAPADR = CPUDS & CPUWR & CPUA19 & !CPUA18 & !CPUA17 & !CPUA16;

ROMCS = CPUDS & !CPUWR & CPUA19 & !CPUA18
#       CPUDS & !CPUWR & CPUA19 & !CPUA17
#       CPUDS & !CPUWR & CPUA19 & !CPUA16
#       CPUDS & !CPUA19 & !CPUA18 & !CPUA17 & !CPUA16 & !SWAP;

CPUHLT.OE = POR;
CPUHLT = POR;

CPURES.OE = POR;
CPURES = POR;

Headers / Connectors

J1 - 2 port FTDI / TTL Serial

2x6 header
Direct connect to DTE RS-232 card
Flip order to connect to USB to TTL Serial (FTDI)
- TX<>RX
- RTS<>CTS
Pinout

GND
CTS* (in)
+5V
Transmit (out)
Receive (in)
RTS* (out)

Connections to ESP32-TERM Card

ESP32-TERM card

ESP32-TERM		SIMPLE-68008
Pin	Signal	Pin	Signal
1	GND	1	GND
2	RTS (out)	2	CTS (in)
3	+5V	3	+5V
4	RX (in)	4	TX (out)
5	TX (out)	5	RX (in)
6	CTS (in)	6	RTS (out)

J2 - Input Port

Input 2
Input 5
Input 4
Input 3
Vcc
GND

J3 - Output Port

GND
Vcc
Output 7
Output 6
Output 5
Output 4
Output 3
Output 2

H1 - 5V Power

2x4 header

H2-H5 - EPROM/EEPROM Select Jumpers

H2 = EE PIN 31
H3 = EE PIN 3
H4 = EE PIN 30
H5 = EE PIN 29

27SF256

27SF256 is a 28 pin part, socket is 32 pins
- H2 = Not installed
- H3-2 to H3-3 = A15 (Vpp on 27SF256, but pin can be either high or low)
- H4-1 to H4-2 = Vcc
- H5-2 to H5-3 = CPUA14

EEPROM Jumpers

27040	27020	27010	27512	27256	27128	2764	PIN(32)	PIN(28)	PIN(28)	PIN(32)	2764	27128	27256	27512	27010	27020	27040
VPP	VPP	VPP	N/A	N/A	N/A	N/A	1	N/A	N/A	32	N/A	N/A	N/A	N/A	VCC	VCC	VCC
A16	A16	A16	N/A	N/A	N/A	N/A	2	N/A	N/A	31 (H2)	N/A	N/A	N/A	N/A	PGM	PGM	A18
A15	A15	A15	A15	VPP	VPP	VPP	3 (H3)	1	28	30 (H4)	VCC	VCC	VCC	VCC	N/C	A17	A17
A12	A12	A12	A12	A12	A12	A12	4	2	27	29 (H5)	PGM	PGM	A14	A14	A14	A14	A14
A7	A7	A7	A7	A7	A7	A7	5	3	26	28	A13	A13	A13	A13	A13	A13	A13
A6	A6	A6	A6	A6	A6	A6	6	4	25	27	A8	A8	A8	A8	A8	A8	A8
A5	A5	A5	A5	A5	A5	A5	7	5	24	26	A9	A9	A9	A9	A9	A9	A9
A4	A4	A4	A4	A4	A4	A4	8	6	23	25	A11	A11	A11	A11	A11	A11	A11
A3	A3	A3	A3	A3	A3	A3	9	7	22	24	OE*	OE*	OE*	OE*	OE*	OE*	OE*
A2	A2	A2	A2	A2	A2	A2	10	8	21	23	A10	A10	A10	A10	A10	A10	A10
A1	A1	A1	A1	A1	A1	A1	11	9	20	22	CE*	CE*	CE*	CE*	CE*	CE*	CE*
A0	A0	A0	A0	A0	A0	A0	12	10	19	21	D7	D7	D7	D7	D7	D7	D7
D0	D0	D0	D0	D0	D0	D0	13	11	18	20	D6	D6	D6	D6	D6	D6	D6
D1	D1	D1	D1	D1	D1	D1	14	12	17	19	D5	D5	D5	D5	D5	D5	D5
D2	D2	D2	D2	D2	D2	D2	15	13	16	18	D4	D4	D4	D4	D4	D4	D4
GND	GND	GND	GND	GND	GND	GND	16	14	15	17	D3	D3	D3	D3	D3	D3	D3

H6 - SRAM Configuration

1-2 = 128KB SRAM
2-3 = 512KB SRAM
128KB and 512KB Parts are about the same price so there's not much point (if buying parts anyway) with going with 512KB part
- AS6C4008-55PCN is $6.38 (2024-06)
- AS6C1008-55PCN is $2.91 (2024-06)

SIMPLE-68008 Software

SIMPLE-68008 Code Repository
68000 code development is done with cross assemblers/compilers using GCC tools under Linux
68000 Assembly Language YouTube Playlist

Linux Development Environment

Using Oracle VM VirtualBox
Running Linux Mint
The [m68k assembly code toolchain GNU C-Compiler with Binutils and other useful tools for 68000 cross development
This is a Makefile based approach to build the toolchain to reduce the build time.
The original work was by Steve Moody's page
These tools are build:
- binutils
- gcc with libs for C/C++/ObjC
- vasm
- vbcc
- vlink
- newlib

S Record and Hex file manipulation

Initial Test Code

S68K_001 - Test Code Repo
Uses m68k assembly code toolchain
Set up stack, starting address
68681 DUART code
- 9600 baud
- Initialize DUART
- Input/Output Serial routines
Loop forever

68k-Monitor

S68K_002 - Monitor Code Repo here
Uses m68k assembly code toolchain
Built from ChartreusK 68K monitor = 68901 DUART code
Added S-Record load ('L' on command line)
- S record format
Runs at 38,400 baud with no waits/handshakes on transmit from Host Side
Added improved SRAM test code
Added SRAM fill
Added 60 Hz timer code
Added Serial port hardware handshake from notes
Type 'T' to start timer
- Long word timer at 0x608-0x60b
- Can be used as random number value if code is run from SRAM since the lowest byte s/b continually updated

Hardware Handshake Notes

From this page

*       Set MR2A4 = 1 and MR2A5 = 1 to configure OP0 as RTS output
       MOVE.B #$83,MR1A
       MOVE.B #$27,MR2Aer is ready to
*       receive more data. Note also that the contents of the DUART's
*       output port register are inverted before they are fed to the output
*       pins. That is, to assert RTS* low, it is necessary to load a one
*       into the appropriate bit of the OPR.
*
       MOVE.B #$01,OPR Set OPR0 to assert RTS*

Example Assembly Code

S68K_003 - Assembly Code Example Repo
- 68000 Assembly Programming
Uses m68k assembly code toolchain
Runs out of SRAM
Loops forever
Blinks LED connected to O2 (red LED, 4.7K resistor, wired to ground)
Load and run

SIMPLE-68008 CPU
RAM Test Passed
> L
Load S-Record
+++++>
> R1000

Example C Code

S68K_004 - C Code Example Repo
Uses m68k assembly code toolchain
Runs out of SRAM
Loops forever
Blinks LED connected to O2 (red LED, 4.7K resistor, wired to ground)
Load and run

SIMPLE-68008 CPU
RAM Test Passed
> L
Load S-Record
+++++>
> R2000

String Test C Code

S68K_005 - C Code Example Repo
Uses m68k assembly code toolchain
ASCII code
Runs out of SRAM
Loops forever
Blinks LED connected to O2 (red LED, 4.7K resistor, wired to ground)
Load and run

SIMPLE-68008 CPU
RAM Test Passed
> L
Load S-Record
+++++>
> R2000

Test Transmit Interrupt Code

S68K_006 - Interrupt Test Code Example Repo
Uses m68k assembly code toolchain
Runs out of SRAM
Loops forever
Sends out alphabet forever using Transmit interrupt from 68681
Required jumper U5-39 to U5-40 to always pullup VPA* to Vcc

SIMPLE-68008 CPU V1.00
RAM Test Passed
> l
Load S-Record
++++++++++++++++++++>
> r1000
SIMPLE-68008 CPU V1.00
RAM Test Passed
> r1100
42345678S:;<I>?@ABMDPFGHLJKE-6O8QRS00VW8 Z[\C^_`PbUd fghijkVm1o.qrst0vwx0z2
]R7AM:; =>T@ABeDEsGt JKLPNaPsRSsUVWXed[ >` bcdefghijklmnopqrstuvwxyz
23456789:;<=>?@ABCDEFGHIJKLMNOPQRSTUVWXYZ[\]^_`abcdefghijklmnopqrstuvwxyz
23456789:;<=>?@ABCDEFGHIJKLMNOPQRSTUVWXYZ[\]^_`abcdefghijklmnopqrstuvwxyz
23456789:;<=>?@ABCDEFGHIJKLMNOPQRSTUVWXYZ[\]^_`abcdefghijklmnopqrstuvwxyz
23456789:;<=>?@ABCDEFGHIJKLMNOPQRSTUVWXYZ[\]^_`abcdefghijklmnopqrstuvwxyz
23456789:;<=>?@ABCDEFGHIJKLMNOPQRSTUVWXYZ[\]^_`abcdefghijklmnopqrstuvwxyz

Receive Interrupt Test Code

S68K_007 GitHub Repository
Test interrupt from DUART
- Using receive character interrupt
Runs from RAM
Echos back character typed
Downloaded as S Records
- Loaded with L command in S68K_002 monitor
R1000 to run program

60 Hz timer

S68K_008 GitHub Repository
Make a 60 Hz Counter in memory
Use timer in DUART
3.6864 MHz / 16 = 23400
23,400 / 60 (Hz) / 2 per cycle = 1920 count = 0x780
Increment a long in 0x604(-0x607)
60 Hz is 0x780 divisor
Stop timer to clear timer
Restart timer to set up interrupt on next timer edge

Guess a Number Game Code

S68K_GAME_01
- Game to guess a number from 1-99
  - Missing random number generator
- Structures string and DUART I/O code into separate files
S68K_GAME_02
- Game to guess a number from 1-99
  - Version adds random number generator
- Slightly less clumsy includes (added a main() stub and moved includes to right after that)

Sample Game with ANSI screen control

S68K_GAME_03
Move an object around the screen using arrow keys
To load it into the S68K_002 monitor you can run the command "L" and then send the run (S record) .run file to the serial port
Run the program from the S68K_002 monitor using R2000
- Output should look like the following:

SIMPLE-68008 CPU

RAM Test Passed

 > l

Load S-Record

++++++++++++++++++++++++++++>

 > r2000

Scrren should clear and a '*' will be at the center
Arrow keys to move around the '*'
Q to quit

ANSI Terminal Driver

nncurses
- Similar to ncurses
  - nncurses is not ncurses
    - n curses is not curses
Drive ANSI/VT terminal
- Terminal apps under Linux/Windows putty or Tera Term
Double buffered implementation
- Write to fromBuffer[][]
- Copy to screenBuffer[][]
- Send out delta as ANSI sequences to the Serial Terminal
ASCII code table
ANSI.SYS
ANSI/VY-xxx ESC sequences

Sample Game

S68K_GAME_04
Game framework with basic game elements
Written in C
Writes to ANSI screen
- Uses cursor position commands
Draws border on the screen
Status line at the bottom of the screen
Puts '*' at center of the screen
Arrow keys move '*' around the playfield

First Person Shooter Game

S68K_GAME_06
Runs on ANSI/VT terminal
First person shooter
Scores of hits/misses
Elapsed time since game start
Target random movement based on modulo of timer

Enhanced BASIC (Running from SRAM)

Lee Davidson's Enhanced BASIC
38,400 baud serial connection (monitor and BASIC)
Running BASIC from card reset

SIMPLE-68008 CPU
RAM Test Passed

L for Load

> l
Load S-Record
+++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++
+++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++
+++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++
+++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++
+++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++
+++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++
+++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++
+++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++
++++++++++++++++++++++++++++++++++++++++++++++++++++++++++>

Run at 800

> R800
457232 Bytes free

Enhanced 68k BASIC Version 3.52

Ready

Test with short program

10 PRINT "HI"
RUN
HI

Ready

68K Monitor Plus Enhanced BASIC (Running from ROM)

Puts S68K_002 - Monitor Code and Enhanced BASIC into a single 32KB ROM
Build steps
- Run make for S68K_002
Run make for the Enhanced BASIC which pulls in the S68K_002 code
- Result is a .hex file
EPROM base address = 0x80000
- 0x80000-0x83FFF - First 16KB reserved addresses for monitor (plenty of room for expansion)
  - Code is from 0x80400-0x80caf (Less than 4KB)
- 0x84000-0x87FFF - Second 16KB reserves addresses for BASIC (plenty of room for expansion)
  - Code is from 0x84800-0x87D1F (Less than 16KB)
Boots into the monitor
Run BASIC with 'B' on command line
Runs at 38,400 baud

SIMPLE-68008 CPU V1.00
RAM Test Passed
> b
12
490032 Bytes free

Enhanced 68k BASIC Version 3.52

Ready

68000 fig-FORTH V1.0

Source Repository
Runs from SRAM
Run at 3648
From reset

SIMPLE-68008 CPU V1.00
RAM Test Passed
> l
Load S-Record
++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++
++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++
++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++
++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++
+++++++++++++++++++++++++++>
> r3648

68000 fig-FORTH V1.0
    OK
    OK
    OK
1 2 3     OK
+    OK
+    OK
. 6    OK

Mechanicals

Rev 1 card

Checkout

Rev 2 Card

Fixed DUART TXB and RXA connections (see Rev 1 rework)
Added pullup to VPA* line (to make interrupts work - see Rev 1 rework)
Add some silkscreen annotations for memory configuration header connections to rear of card
Moved R6 up and added more silkscreen near CPU
Added R7 resistor and LED to ground on U3-12
- Access with a write of but D0 to EEPROM address (similar to SWAP bit)
Ordered a batch of 10 cards (2024-08-18)

Rev 1 Card

VPA needs to be pulled up
- Add wire U5-39 to U5-40
Reset working
- Reset switch and monitor working
Clock working
- Checked at 8 and 10 MHz
EPROM working
SRAM working
Checked Serial port
- Not using any XTAL capacitors
Serial transmit/receive lines swapped
- TXB and RXA are swapped on DUART
- U6 pins 11 and 31 need to be swapped

Easiest cuts (on bottom of board)

Cuts as seen from the top side Silkscreen

2 Jumpers

Alternative cut (harder due to space and being on top of board)

SIMPLE-68008

Contents

Features

Memory Map

Alternate Memory Map

Chip Set

Parts in "Kit"

Design

CPU

CPU Timing

Function Code

EPROM

Flash Memory (EEPROM) Programming

Device ID Mysteries

SRAM

Dual UART

Reset

Clock

PLDs

PLD_001

PLD_001 Source Listing

PLD_002

PLD_002 Source Listing

Headers / Connectors

J1 - 2 port FTDI / TTL Serial

Connections to ESP32-TERM Card

J2 - Input Port

J3 - Output Port

H1 - 5V Power

H2-H5 - EPROM/EEPROM Select Jumpers

27SF256

EEPROM Jumpers

H6 - SRAM Configuration

SIMPLE-68008 Software

Linux Development Environment

S Record and Hex file manipulation

Initial Test Code

68k-Monitor

Hardware Handshake Notes

Example Assembly Code

Example C Code

String Test C Code

Test Transmit Interrupt Code

Receive Interrupt Test Code

60 Hz timer

Guess a Number Game Code

Sample Game with ANSI screen control

ANSI Terminal Driver

Sample Game

First Person Shooter Game

Enhanced BASIC (Running from SRAM)

68K Monitor Plus Enhanced BASIC (Running from ROM)

68000 fig-FORTH V1.0

Mechanicals

Checkout

Rev 2 Card

Rev 1 Card

Assembly Sheet

Rev 1

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