Thanks for your comments and taking the time to read this article! In the upcoming weeks I will be finalizing the application note which will contain details such as schematics and source files. I am also studying different venues to having these boards available for purchasing on some sort of an eStore.
With regards to the USB, I will soon be posting a completely different CNC solution which revolves around USB. It is the one I am using on my 3D printer. However, the truth is as perfect as this solution is for a 3D printer, I would not use it with a router, mill, lathe, plasma CNC table. Any of the later, operate much better when using a CNC controller such as MACH3 and USB solutions have not been able to pair up with their parallel counterpart. In my experience, adding a PCI parallel port to any PC out there works perfectly fine. I have done it with 3 completely different computers (the ones I use for my CNC Mill, CNC Plasma and CNC Router) and as of today have had no problems.
Let me know if there is anything else I can help you with!
I'd like a source for this board too. I've considered doing somthing like this myself so I can let my lathe do the work accurately while I drink coffee. My lathe did not come with change gears to enable it to cut threads. After spending lote of hundreds of dollars, I still can't cut metric! On the internet there is a website concerned with "electronic lead screw" kits, a single stepper controller to cut any pitch (coordinated lead screw movement). So many things to do!
Please note that parallel is not serial, but 8 bits wide, and bidirectional. I use old machines running under DOS and one would be amazed how smoking hot these machines really run as far as pure processing horsepower.
USB, while a high through put, are bogged down by multitasking. For example you can buy a USB to parallel converter to run an older printer. But to run high speed on this bus, you can't. Connect a scope and repeatedly toggle one bit. Very poor performance overall.
Ahh, yes. About 20 years ago my son and I built a robot using the stepper motors, power supply, and motor driver board from big industrial-grade daisywheel printer. We discarded the logic board and designed and built a simple interface board to interface the motor drivers to..a parallel port.
We used an eight-bit control word, where three bits allowed us to control up to eight motors (two implemented), four bits were used to control individual motor phases, and one bit indicated whether the driver should be at full power (to step) or half-power (to hold position). This design, of course, permitted forward and reverse motion, and half-stepping by energizing two phases at once.
A friend who's an engineer & runs a small prototype shop tells me that none of the serial options can function quickly enough to handle the 'feedback loop' in starting, stopping, & moving the tool. (He's rebuilding a German 5 axis mill & currently dealing with that issue.)
I couldn't find a link about where I can get one. I want to use that CNC setup for some home projects (CNC mill and lathe).
On another note, I see it uses a parallel port, serial communication. That is becoming a problem with CNC setups these days. Most new desktop computers, laptops, micro-computers, and the like, do not have parallel ports onboard. In many cases, a parallel port card would need to be installed. And hopefully, the system has an expansion slot available.
What most people do is buy old, or surplus, computers from somewhere. My current CNC mill runs off of a PC I found in the garbage many years ago (Celeron 700MHz Compaq desktop). I think it is time to change how these CNC drive systems work. USB is the only way to go. So, built in support for USB to serial in a good stop-gap solution.
In an age of globalization and rapid changes through scientific progress, two of our societies' (and economies') main concerns are to satisfy the needs and wishes of the individual and to save precious resources. Cloud computing caters to both of these.
For industrial control applications, or even a simple assembly line, that machine can go almost 24/7 without a break. But what happens when the task is a little more complex? That’s where the “smart” machine would come in. The smart machine is one that has some simple (or complex in some cases) processing capability to be able to adapt to changing conditions. Such machines are suited for a host of applications, including automotive, aerospace, defense, medical, computers and electronics, telecommunications, consumer goods, and so on. This discussion will examine what’s possible with smart machines, and what tradeoffs need to be made to implement such a solution.