The Mechanical CPU Clock shows the basic building blocks of a CPU (ALU, buses,RAM,registers, and a Control Unit). It executes a set of instructions which will emulate a simple wall clock.
The inspiration for this project came from trying to teach my son and daughter about how a computer works (in reality, I was always fascinated with mechanical computers and clocks, but I had to give a better excuse to my wife for buying a laser cutter specifically for this project). After looking around the web at various mechanical computers, I could not find something that represented all the components of CPU. However, I draw my inspiration from the following projects (and their derivatives):
Marble adding machine: www.youtube.com/watch?v=GcDshWmhF4A
Ball Logic: http://brain.wireos.com/?p=2207
In the following sections I will attempt to explain how everything works as it is being built. I am not going to go deep into the subject of computer science and will purposely try to avoid some terms, so to not confuse the novice reader. If I do use any terms, I will try to explain them simply. However, there might be some needed background information that I will miss, so please do not hesitate to contact me about trying to explain the concepts in more details (I don't promise anything, but I will do my best). Even if you are not going to build the clock, going through the sections will help in the understanding of how the clock/CPU works (the build sections will go over the concepts of ALU,RAM,register,control unit and buses). Again, one of the motivations for this project was to get people to understand how a CPU (the heart of a computer) works.
More details about the clock can be found here: http://www.liorelazary.com/index.php?option=com_content&view=article&id=46:mechanical-cpu-clock&catid=10:clocks&Itemid=15
Step 1: CPU instructions
Here are the basic instructions (assembly language) that we will use:
INCRMENT: Increment register A by adding 1 to it.
EQUAL: If register A is equal to a specific number, then skip the next instruction.
CLEAR: set register A to 0, set DTD to false
JUMP: jump to a specific instruction at a given line number
SET_DTD: set DTD to true
CHECK_DTD: if DTD is true, then skip the next instruction.
Here is the assembly language code for the clock (register A will hold the hours).
2: JUMP 5
4: JUMP 1
6: EQUAL 11
7: JUMP 1
9: JUMP 1
Line 1 checks to see if DTD is set to true (this is used to indicate if we need to reset the hour). If its true the we jump to line 3 and set the hour to 0 and the DTD to false. If DTD is false then we continue with the next instruction and jump to line 5. Line 5 increments the hour (register A), while line 6 check to see if it equal to 11. If register A is equal to 11, then we jump to line 8 and set the DTD to true and jump back to the beginning (line 1). Otherwise, we go to the beginning. If we run though this code once an hour, then by reading register A, we can tell what is the current hour.