Before building the control logic, we want to connect all of the modules to a shared bus and test things out. The modularity of the design makes it easier to test each module by itself so we won’t ever get to a point where we put it all together and nothing works.
The output register is similar to any other register (like the A and B registers) except rather than displaying its contents in binary on 8 LEDs, it displays its contents in decimal on a 7-segment display. Doing that requires some complex logic; luckily there’s an easier way:
The random access memory (RAM) stores the program the computer is executing as well as any data the program needs. Our breadboard computer uses 4-bit addresses which means it will only have 16 bytes of RAM, limiting the size and complexity of programs it can run. This is by far its biggest limitation.
The arithmetic logic unit (ALU) part of a CPU is usually capable of performing various arithmetic, bitwise, and comparison operations on binary numbers. In our simple breadboard CPU, the ALU is just able to add and subtract. It’s connected to the A and B registers and outputs either the sum of A+B or the difference of A-B.
Most CPUs have a number of registers which store small amounts of data that the CPU is processing. In our simple breadboard CPU, we’ll build three 8-bit registers: A, B, and IR. The A and B registers are general-purpose registers. IR (the instruction register) works similarly, but we’ll only use it for storing the current instruction that’s being executed.
The computer’s clock is used to synchronize all operations. The clock we’re building is based on the popular 555 timer IC. The videos go into some detail on the operation of the 555 and use it in three different ways.
Our clock is adjustable-speed (from less than 1Hz to a few hundred Hz). The clock can also be put into a manual mode where you push a button to advance each clock cycle. This will be a really useful feature for debugging the computer later on.
If you want to dive into the details of how the computer works and understand it from first principles, but are a little unsure of how transistors and logic gates work (or just want a refresher), here’s a few videos to serve as an introduction:
Here’s a complete parts list of everything I used to build the breadboard computer. The total cost works out to roughly $150-$200 USD depending on what breadboards you use and how much you end up paying for shipping.
There’s no right way to do this project. There are tons of substitutions and other approaches which will work just as well (or better), so if you want to build something similar and can’t find all the parts, try to figure out what the missing part does and find a different way of doing it. It might not work the first time, but you’ll learn a ton from trying to figure out why.
(If you click through any of the Amazon links, I get a tiny cut, though it won’t cost you any more. I’m a participant in the Amazon Services LLC Associates Program, an affiliate advertising program designed to provide a means for sites to earn advertising fees by advertising and linking to amazon.com.)
Additionally, I used an Arduino Nano and two 74HC595 shift registers to build a simple EEPROM programmer to program the 28C16 EEPROMs used in the output module and control logic.
A note on breadboards: You can get them from lots of places for different prices. The best quality I’ve found is the BB830 by BusBoard Prototype Systems. I get them on Amazon, but they’re not cheap. (If you’re paying less than $7-8 USD each, you’re probably getting a fake.)
Lower quality, cheaper breadboards will probably work just fine (and save a bunch of money if you’re buying ~12 of them). The biggest differences include inadequate funneling on each hole, making it harder to properly insert components (this can vary a lot, from not a big deal to useless); inconsistent coloring (i.e., several breadboards, even ordered at the same time, are different shades of white); confusing labeling (e.g., numbers not lining up with holes); and warping (i.e., the breadboard doesn’t sit completely flat). Most of those aren’t deal-breakers, and if something doesn’t work right, look on the bright side: you get to troubleshoot it and learn more 🙂