Button Debouncing With Smart Interrupts

January 4, 2025 by Bryan Cockfield 47 Comments

Debouncing button or switch inputs on microcontrollers can be a challenging problem for those first starting to program these devices. Part of the reason for this difficulty is that real-world buttons don’t behave like the idealized textbook components we first learn about, and therefore need special consideration to operate like one would expect. There are simple ways to debounce inputs like adding a delay after a button is pressed, but for more efficient use of computer resources as well as adding some other capabilities to inputs you might want to look at this interrupt service routine (ISR) method from [Lee] aka [stockvu].

The strategy with this debounce method is not simply to use a single ISR for the button input, but to activate a second timer-based ISR at that time that runs at a certain interval which timestamps any button press and checks the amount of time the button has been active. If it’s under a certain threshold the ISR assumes it’s caused by bounce and blocks the bounce. If the timestamp ages past another longer threshold it knows the button has been released. This method allows on-the-fly adaptation between long button presses and rapid button presses and is capable of debouncing both types.

For those wanting to try this out, [stockyu] has included some example Arduino code for others to use. It’s an interesting take on a solution for a common problem, and puts very little load on the microcontroller. There are about as many ways to debounce inputs as there are microcontroller platforms, though, and you can even use a 555 timer to get this job done which frees up 100% of the microcontroller’s CPU.

A New Life For A Conference Badge, Weighing Bees

January 4, 2025 by Jenny List 3 Comments

We love electronic conference badges here at Hackaday, but it’s undeniable that many of them end up gathering dust after the event. Most of them are usable as development boards though, so it’s nice to see them appear in projects from time to time. [Benjamin Blundell] has a good one, he’s using an EMF Camp 2014 badge to power a set of load cells in a bee scale.

Not being skilled in the art of apiary here at Hackaday we’re thankful for his explanation. Beekeepers weigh their hives as a means of gauging their occupancy, and the scale for this purpose has a few application specific features. The EMF 2014 badge (known as the TiLDA MKe) meanwhile is an Arduino Due compatible ARM Cortex M0 board with an LCD display, making it perfect for the job. He devotes quite some time to describing the load cells, mounting them on extrusion, and calibration, all of which should be of use to anyone making a scale.

The software for the badge is an odd mix of Arduino and FreeRTOS, and he takes one of the stock apps and modifies it for the scale. It’s very much a badge of its era, being programmable but not with a built-in interpreter for MicroPython or similar. You can see the whole project at work in the video below the break.

If you’ve not seen a TiLDA MKe before, we wrote about it when it was released.

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High Performance RISC-V

January 3, 2025 by Al Williams 9 Comments

From the Institute of Computing Technology division of the Chinese Academy of Sciences and Peng Cheng Laboratory comes a high-performance and well-documented RISC-V core called XiangShan.

In the Git repository, you’ll find several branches including at least two stable branches: Yanqihu and Nanhu. The currently developed architecture, Kunminghu, is impressive, with a sophisticated instruction fetch unit, a reorder buffer, and a register renaming scheme.

The point of these types of circuits in a CPU is to allow multiple instructions to process at once. This also implies that instructions can be executed out of order. A cursory glance didn’t show any branch prediction logic, but that may be a limitation of the documentation. If there isn’t one, that would be an interesting thing to add in a fork if you are looking for a project.

On the computing side, the processor contains an integer block, a floating point unit, and a vector processor. Clearly, this isn’t a toy processor and has the capability to compete with serious modern CPUs.

There is a separate GitHub for documentation. It looks like they try to keep documentation in both Mandarin and English. You can also find some of the academic papers about the architecture there, too.

We love CPU design, and this is an interesting chance to contribute to an open CPU while there are still interesting things to do. If you need to start with something easier, plenty of small CPUs exist for educational purposes.

Math On A Checkerboard

January 3, 2025 by Bryan Cockfield 2 Comments

The word “algorithm” can sometimes seem like a word designed to scare people away from math classes, much like the words “calculus”, “Fourier transform”, or “engineering exam”. But in reality it’s just a method for solving a specific problem, and we use them all the time whether or not we realize it. Taking a deep dive into some of the ways we solve problems, especially math problems, often leads to some surprising consequences as well like this set of algorithms for performing various calculations using nothing but a checkerboard.

This is actually a demonstration of a method called location arithmetic first described by [John Napier] in 1617. It breaks numbers into their binary equivalent and then uses those representations to perform multiplication, division, or to take the square root. Each operation is performed by sliding markers around the board to form certain shapes as required by the algorithms; with the shapes created the result can be viewed directly. This method solves a number of problems with other methods of performing math by hand, eliminating other methods like trial-and-error. The video’s creator [Wrath of Math] demonstrates all of these capabilities and the proper method of performing the algorithms in the video linked below as well.

While not a “hack” in the traditional sense, it’s important to be aware of algorithms like this as they can inform a lot of the way the world works on a fundamental level. Taking that knowledge into another arena like computer programming can often yield some interesting results. One famous example is the magic number found in the code for the video game Quake, but we’ve also seen algorithms like this used to create art as well.

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Custom Firmware Adds Capabilities To Handie Talkie

January 3, 2025 by Bryan Cockfield 51 Comments

Although ham radio can be an engaging, rewarding hobby, it does have a certain reputation for being popular among those who would fit in well at gated Florida communities where the preferred mode of transportation is the golf cart. For radio manufacturers this can be a boon, as this group tends to have a lot of money and not demand many new features in their technology. But for those of us who skew a bit younger, there are a few radios with custom firmware available that can add a lot of extra capabilities.

The new firmware is developed by [NicSure] for the Tidradio TD-H3 and TD-H8 models and also includes a browser-based utility for flashing it to the radio without having to install any other utilities. Once installed, users of these handheld radios will get extras like an improved S-meter and detection and display of CTCSS tones for repeater usage. There’s also a programmer available that allows the radio’s memory channels to be programmed easily from a computer and a remote terminal of sorts that allows the radio to be operated from the computer.

One of the latest firmware upgrades also includes a feature called Ultra Graph which is a live display of the activity on a selected frequency viewable on a computer screen. With a radio like this and its upgraded firmware, a lot of the capabilities of radios that sell for hundreds of dollars more can be used on a much more inexpensive handheld. All of this is possible thanks to an on-board USB-C interface which is another feature surprisingly resisted by other manufacturers even just for charging the batteries.

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Front and rear views of a lander circuit sculpture that retrieves weather data and displays it on a screen.

Landing Soon: This Beautiful Weather Display

January 3, 2025 by Kristina Panos 4 Comments

All wiring is beautiful, except when it isn’t. But is there anything more lovely to behold than circuit sculpture? Once again, [Mohit Bhoite] has made this process look easy like Sunday morning. This time, he’s created a weather display in the form of a lander.

This lander runs on the Particle Photon 2, which connects over Wi-Fi and retrieves the weather forecast for the day, along with sunrise and sunset times and wind conditions. Everything is beautifully displayed on a vertically-oriented Adafruit 170×320 TFT screen.

There’s also a pulse-density microphone (PDM) breakout board and a buzzer, and the build is capped off with a red 0805 LED. We’re not sure what the feet are made of, but they sure make this lander cute (and accurate).

All the project logs are picture-rich, which is really the most we could ask for when trying to imitate this level of greatness. This is apparently an ongoing project, and we’re excited for the end result, although it looks fairly complete from here.

Do you want to bend it like Bhoite? Then be sure to check out his Hackaday Supercon talk on the subject.