1976 was the year the Apple I was released, one of several computers based on the MOS 6502 chip. MOS itself released the KIM-1 (Keyboard Input Monitor) initially to demonstrate the power of the chip. The single board computer had two connectors on it, one of which could be used for a tape recorder for long-term storage. When [Willem Aandewiel] went to the Apple Museum Nederland in 2016, he saw one and felt nostalgic for his youth. He was able to get a replica, the microKIM, and build it but he wanted to use new technology to interface with this old technology, so he decided to use an ESP8266 as a solid state tape recorder.
One of the reasons the KIM-1 was so popular when it was released was that there was lots of documentation available. [Willem] used this documentation to figure out how the KIM-1 saves data to the recording device. An ATTiny85 is used to decode the pulse stream that the KIM-1 sends when saving because the timing was too tight to both “listen” and decode the bits as well as convert and store them. For loading programs, the data can be sent digitally as 1’s and 0’s to the KIM-1. This means that the ATTiny is only used for decoding and doesn’t have to re-encode the data. Because of this, saving is slow, but loading is very quick.
To complete the project, [Willem] added four buttons, one each for rewind, record, play and fast-forward, and a screen so you can see which program is currently selected and can go from one program to another. As a nice throwback touch, record and play have to be pressed at the same time when saving. For more 6502 projects, check out this 6502 based DIY computer, or this 6502 built from discrete parts.
Continue reading “ESP8266 as a Tape Drive”
So, your smart mirror has been running for a while, but Halloween is coming up and you want to come up with some cool Halloween stuff to display on the mirror. If you’re looking for ideas, check out [Ben Eagan]’s cool Haunted Smart Mirror which connects the mirror via a Raspberry Pi with Amazon Alexa and Phillips Hue lighting.
[Ben] points to another of his blog pages for those readers interested in the nuances of setting up Alexa with a smart mirror, while concentrating on communication with the Hue bridge and creating the setup for a new Alexa command in this post. Dealing with the Phillips Hue API seems fairly straightforward: Get the IP address of your Hue bridge from your router and the ID of your lights from the Hue app and you’re set to send commands via HTTP. [Ben] includes a Python script to make the lights flicker, which you can modify for your own lights as you wish. Once that’s done, you’ll need to set up the intent that Alexa listens for, and then modify the AWS lambda function that sends commands to the Pi. When the command shows up in the queue on the Pi, any commands [Ben] wants to play are fired off – in this case, a video is played and the Hue lights start to flicker.
There’s no mention of security in the article, so that may be worth a little attention with Alexa and the Hue, but with Halloween coming up fast even if you haven’t built a magic mirror yet, if you’ve got Hue lights, this would be a great, quick, Halloween idea. Especially if you could combine it with your outside lights so that Trick-or-Treaters can join in on the fun. Maybe you’d prefer looking up passing planes using Alexa? Or how about getting your fish to talk?
Continue reading “Haunting A Smart Mirror With Hue and Alexa”
Sometimes, you just can’t find something you want, and that’s when you break out the tools and get dirty with a bit of DIY. Reddit user [JaredBanyard] wanted a nice beam light for the dining room/gaming room. He ended up building one that shone both downward, on the table, and upward, adding some light to the room.
Warm white LED strip lighting was chosen, and two aluminum channels were glued together to hold them. After wiring the four LED strips together a diffuser was placed over them and then they were wired up and turned on to check the amount of light. With two strips per channel, even with the diffuser, there was plenty.
Each pair of channels were set into the main housing, which is made from Sirari hardwood. Two long outside side pieces make for a great looking final product, and the end pieces are sandwiched between the two outside pieces. After a bit of sanding and an application of matte polyacrylic, transformers were screwed inside and then the channels were placed on top. The circuitry was wired to a Z-Wave dimmer to control the lights remotely.
[JaredBanyard]’s put together a bill of materials and there are plenty of pictures. It’s a great, unique, light for the room, which includes a Duchess gaming table from boardgametables.com. For more lighting articles, check out this 2017 Hackaday Prize entry article on modular rail lighting, or this article about adding intelligence to your lighting solution.
If you are blind or your vision is impaired, moving around in a new space can be a harrowing experience. A cane helps, but only samples one point at a time, and can’t help that much above a certain height. The Digital White Cane is a haptic feedback device that uses Time of Flight components to detect surrounding objects.
The Digital White Cane uses a type of LIDAR known as Time of Flight (ToF) sensing. Rather than a point by point scan by a laser, ToF sensors capture an entire scene with each pulse. These sensors are actually somewhat new and designed for the latest generation of robotics and hand detection for soap dispensers. The good news is that they’re small and cheap, just what you want for a wearable.
The sensors allow detection of objects within 2m (about 6 feet) from all directions. Haptic feedback allows the wearer to determine where the object is around the wearer. Because it’s head-mounted, it detects objects at head height as well as floor height. A Teensy LC is used as the main processor and is connected to the ToF sensors as well as small motor board for the haptic feedback.
This project has a lot of potential to help people with vision impairment and is a great entry into the 2017 Hackaday Prize. Check out the video after the break to see it in action. If you’re looking for some more applications of this small, cheap ToF sensor, check out this cat food dispenser, and here’s a ball-balancing robot – both pretty cool projects in their own right.
Continue reading “Hackaday Prize Entry: Digital White Cane”
[Danman] got an ESP32 with built-in OLED display, and in the process of getting a clock up and running and trying to get a couple of NodeMCU binaries installed on it, thought he’d try rolling his own.
[Danman] used PlatformIO to write the code to his ESP. PlatformIO allowed [Danman] to browse for a NTP library and load it into his project. After finding the NTP library, [Danman] wrote a bit of code and was able to upload it to the ESP. When that was uploaded [Danman] noticed that nothing was being displayed on the OLED, but that was just a simple matter of tracking down the right address to use when setting up the library for his OLED. Lastly, [Danman] created a large font to display the time with and his mini-clock was done!
It’s always nice to see someone be able to go from buying a board to having a demo put together, and it’s getting easier and easier. Check out this OLED watch, and this pocket watch doesn’t use OLEDs, but it still looks pretty cool.
A teleprinter is, at its heart, an automatic typewriter. It’s electrically controlled and has some smarts to be able to decode an incoming message and has something that will move the keys. These printers have been in use since the late 1800’s and [AethericLtd] have refurbished an old 1930’s design and given it a bit of steampunk flair.
As is common with older mechanical devices that have been sitting for extended periods of time, the first thing this machine needed was a bath. The machine was separated into its three main parts and soaked in a degreasing solvent. The keyboard was the dirtiest, so it got an overnight soak. Since little of the mechanism was electrical, most of it could be submerged which helped with the cleaning.
The next step in the restoration was lubrication. In order to do a proper job, the manuals (which were available online) were consulted and synthetic motor oil used for lubrication. Once all the hundreds of parts were oiled, [AethericLtd] started working on the wiring. The original wiring in this machine was called Deltabeston – a type of wire by General Electric which uses asbestos insulation. To play it safe, that wire was left alone. The selector magnet required only 4 volts to pull up, but 4 volts wasn’t enough to run the machine. The power supply used was a 120 VDC, 200 mA supply through a 2 KΩ, 10 W resistor.
Once everything was back together and working, [AethericLtd] could take machine out and show it off. The website describes not only the restoration process but also the setup, how to connect to the machine and how to communicate with the machine. Great work! If you are interested in these machines, there have been a few Teleprinter projects on the site before: this one has been modified to connect to a modern modem, and this one prints out tweets.
Continue reading “Teletype Machine Resurrected”
Any display can be connected to a microcontroller and used as a display if you know the protocol to use and have enough power in your micro. Sometimes, an odd display is used just “because it’s there.” This seems to be the case for Reddit user [phckopper], who has used a STM32 and a PS2 joystick to play a version of a Mario game on an oscilloscope.
There’s not many technical details but [phckopper] lets us know that the rendering is done using the SPI on the STM, transferred via DMA, which is synchronized to two saw-tooth waves that are fed in to the X and Y axes of the oscilloscope. The Z axis, which controls the brightness of the dot, is fed from the MOSI. By making the oscilloscope range all over the screen, similar to the way a CRT’s gun does,  is able to draw sprites, rather than vector graphics. The display has a resolution of 400×400 and each sprite is 16×16. The input is from a PS2 joystick connected to [phckopper]’s PC, with the information communicated over UART using a simple protocol.
We don’t get to see much of the game in the video after the break, but it’s a pretty impressive job nonetheless, especially when you realize that [phckopper] did this project when he was just sixteen! There are a couple of other oscilloscope projects here at Hackaday, like this one, a great version of pong played on the ‘scope, or this one, showing off some great graphics.
Continue reading “Playing Mario on an Oscilliscope”