After winning an online auction for an 1980s vintage Compaq Portable PC, [leadacid44] discovered why it only cost him $5USD – the keyboard was shot. Not willing to accept having forked out $45USD to ship a brick, he tore into the ancient machine and came up with a found-material solution to the wonky keyboard.
[leadacid44]’s very detailed writeup of the fix for his Compaq includes a thorough examination of the guts of the machine. He got it to boot to MS-DOS 5.0 off of a 20MB ISA hard drive card and began probing the keyboard problem. It turns out the Compaq keyboard has much in common with a modern touchscreen, in that it’s a capacitive keyboard. Unfortunately the foam disks used as springs under each key cap had degraded over the last 30 years, so [leadacid44] began a quest to replace them. After much experimentation and a few false starts, he created a sandwich of transparency film, closed-cell polyethylene foam, and a Mylar antistatic bag. Many discs were punched out with a leather punch and tediously placed in the body of each key switch, and the quick brown fox was soon jumping flawlessly over the lazy dog.
When you want to control an external device (like a lamp) from your computer, you might reach for a USB enabled micro. Looking for an inexpensive and quick option to control two lamps [Pete] wanted to control a couple 12 volt halogen lamps, he reached for his keyboard and used a little bit of python.
Desktop PC keyboards have 3 LED’s indicating lock functions, hardly anyone uses the scroll lock, and on a laptop with no keypad, numlock is no big loss as well. Adding wires to the little PCB out of a USB keyboard the numlock and scroll lock LED’s 5 volt output was redirected to a switching circuit.
That switching circuit takes the output of either LED, inverts it with a PNP transistor, then connects to the gate of a FQP30N06L, “logic level” mosfet transistor to handle the heavy lifting. Once the wiring is in place a fairly simple Python script can take over turning on and off the two chosen lock keys, giving control of up to 32 amps with the touch of a button.
[Ido Gendel] was thinking about new and interesting ways to send data between devices, when he realized that the answer was right in his hand. Literally: he decided to try sending data using the mouse pointer. What he came up with was an interesting hack that uses small movements of the mouse pointer to send data at up to 1200bps, or about 150 bytes per second.
The way he did this was very, very clever. He used an Arduino Leonardo that is set to emulate a mouse, working alongside his existing mouse. This setup means that he can use his existing mouse: the system just sees the Arduino as a second mouse, and the pointer just looks a little jerky when you zoom in. That is because the Arduino is just sending tiny movements, each of which is a code that represents a nybble (4 binary bits) of data. By using both a combination of three left-right or up-down movements, he was able to create 16 movements, each of which can encode 4 bits of data. Each of these encoding movements also returns the mouse to its origin point, so the mouse doesn’t mysteriously scroll off the screen when data is being sent.
Is your keyboard too quiet? Is your Cherry MX Blue board not driving your coworkers crazy enough? If the machine gun fire of a buckling spring keyboard isn’t enough for you, there’s only one solution: [Russell]’s typewriter turned into a mechanical keyboard.
Converting typewriters into keyboards has been done for a very long time; teletypes, the first computer keyboards, were basically typewriters, and the 1970s saw a number of IBM Selectrics converted into a keyboard with serial output. Even in recent years, typewriters have been converted into keyboards with the help of some switches and an ATMega. [Russell]’s mechanical keyboard improves on all of these builds by making the electronic interface dead simple, and a project that can be done by anyone.
Instead of installing switches underneath every key or futzing about with the weird mechanics of a Selectric typewriter, [Russell] is only installing a touch-sensitive position sensor into the frame of the typewriter. When a key is pressed, it strikes a crossbar in the frame of the typewriter. With a single ADC chip and a Raspberry Pi, [Russell] can determine which key was pressed and use that information to output a character to a terminal.
It’s a very simple solution for an electrical interface to a mechanical device, and the project seems to work well enough. [Russell] is using his new keyboard with Vim, even, something you can check out in the video below.
Tablet computers have come a long way, long way. It finally seems like they’ve found their niche in the market, and now maybe they can catch up to more traditional computers. The Microsoft Applied Sciences division came up with a cool prototype design for a new tablet, one with a secondary e-ink input display.
The tablet interface makes use of e-ink strip above the keyboard. While it might not seem like much, this frees up a bunch of screen real estate, allowing you to have various icons and shortcuts off screen. It makes a ton of sense for digital artists as they can draw on the screen, but also have their toolkit open right below them — almost like real painting/drawing.
One of the other great uses for something like this is a signature pad — with everything going digital, when is the last time you had to print, sign, and scan a document back to someone? They even developed a dedicated email app you can use solely on the e-ink screen, allowing you to maximize the use of your main screen for something like a video chat.
The demo is pretty cool, and we often wonder why there aren’t more phones with e-ink displays integrated into them — is this just the beginning?
[Garrett Greenwood] plays Smash Brothers, and apparently quite seriously. So seriously that he needed to modify his controller with five Neopixels so that it flashed different color animations according to the combo he’s playing on the controller; tailored to match the colors of the moves of his favorite character, naturally.
All of this happens with an ATtiny85 as the brains, which we find quite ambitious. Indeed, [Garrett] started out thinking he could simply read each of the inputs from the controller directly into the microcontroller at the heart of the whole thing, but then counted up how many wires that would be, and looked at how many pins he had free (six), and thought up a better solution.
[Garrett]’s routine instead reads the single line that the Gamecube controller uses to send back to the console. The protocol is well understood, using long-short and short-long signals to encode bits. The only trick is that each bit is sent in four microseconds, so the decoding routine has to be fairly speedy. To make it work he had to do quite a bit of work. More about that, and the demo video, after the break.
I see the disturbing trend of moving away from keyboards as input devices — and I’m talking about a real, physical keyboard. This isn’t a matter of one decision that kills the keyboard, but an aggregate that is slowly changing the landscape. If you blink, you’ll miss it. We will not find ourselves in a world without keyboards, but in one where most of the available keyboards suck.
Rise of the Virtual Keyboard Generation
Tablets are great for screwing around, but when you want to get real work done in a reasonable amount of time, you grab a physical keyboard. In this scenario I don’t see the problem being those in the workforce going away from keyboards; it’s how the younger generations are learning to interact with technology that is troubling. The touchscreen is baby’s first computer. Families gather and the kids are handed their parent’s tablets while the grown-ups watch the game. More and more schools are outfitting classrooms with tablets, and for this I’m an advocate. Getting kids involved early in technology is imperative; knowledge evolves much more rapidly than printed textbooks. The tablet is a powerful tool in both of these areas. But most of the screen time kids get is with touchscreens and no physical keyboard.
How much time are K-12 kids spending in front of a physical keyboard? In the United States, if keyboard (typing) classes exist at all in a public school’s curriculum they’re usually only one-semester. Students who spend half of Elementary school using a tablet, and just one semester at a keyboard, are bound to prefer touchscreen-based entry over a physical keyboard.
We’ve already seen a strong push into touch-screens on laptops as the tablet market has grown. This is not necessarily a bad thing. Think of the computer mouse, it didn’t replace the keyboard, but augmented it and now is seen as a tool that itself is a necessity.