2026-05-03 13:00:31
C-3PO is one of the more famous movie robots out there. However, we don’t see a lot of replicas built, perhaps because in speech and mannerisms, he’s quite hard to replicate. Of course, that feat has become much more achievable with modern AI tech, as [Samuel Potozkin] demonstrates.
We’re not looking at a full C-3PO build here, it’s just the head—but for the project’s purposes, that’s all that was really required. The build relies on a Raspberry Pi 5 as the brains of the droid. It’s running a mic hooked up to a real time speech to text engine, and that text is then sent to a large language model for interpretation. Responses are then generated, passed through a processing layer to capture C-3PO’s general tone and vibe, and then handed off to a text-to-speech synth to imitate the iconic voice, played via speaker. The end result is a C-3PO you can actually talk to, which is something that might have knocked a few socks off when the movie first launched in 1977. In-depth materials for the build can be had via Google Drive and on Github.
This ersatz C-3PO isn’t an exact dupe of the movie ‘bot. The protocol droid is a little slow to respond, and the patter isn’t quite on point, even if the voice synth makes a good effort at mimicking the original. Overall, it’s a little… robotic… something you wouldn’t say of the character in the movies. Still, it’s a great effort, and something we haven’t really seen much of before. If you like more classic droid replicas, though, we’ve featured those too. Video after the break.
2026-05-03 10:00:08
Transistors in some circuit configurations work together and, frequently, need to be matched. This is so common that you can sometimes find ICs that are just a pair of transistors made with the same piece of silicon, so they should be matched very closely by default. But with discrete transistors, two devices of the same type are not always identical. [Learn Electronics Repair] covers the topic and explains how to match devices in the video below.
Depending on the circuit, the matching parameters may be different, but generally, the idea is that you want similar gains or matching saturation characteristics. The reason is that when you have multiple transistors working together, you don’t want one to do more work than the other device. This is inefficient and could drive the “better” component to fail.
The same idea applies in bridge circuits, where you might match resistors or capacitors to make sure that, for example, two 10% resistors are very close to the same value. A 10K resistor could be between 9K and 11K, and you might not care as long as they are both, say, 9.2K or both 10.8K.
This is different, by the way, from impedance matching, where you achieve maximum power transfer by matching a source to a load.
2026-05-03 07:00:15
Once upon a time, someone set up a livestream wherein the messages from Twitch chat could control a game of Pokemon. Since then, we’ve seen Twitch control all sorts of things. If you’d like to have them play with some LEDs in your house, you might like this project from [pfeiffer3000].
The concept is simple enough. The heart of the build is an ESP32 microcontroller, which is easy to integrate with web services thanks to its onboard WiFi capability. It’s hooked upt o a string of WS2812B addressable RGB LEDs. The LEDs themselves are installed within table tennis balls to act as nice, spherical diffusers, and installed in a square frame made of PVC pipes. As for code, the rig uses the WLED library to drive the LED strings, and code from TwitchIO to interface with Twitch chat itself. It’s as simple as rigging up a bit of Python. With everything assembled, [pfeiffer3000] had an attractive LED grid that could be controlled directly by anyone watching their Twitch stream.
We’ve explored how to control things via Twitch before, too. It’s a fun way to add some interactivity to your livestream that really gets viewers involved. If you’ve been building your own audience-controlled projects, we’d love to hear about them on the tipsline!
2026-05-03 04:00:32
Some people love CRTs to a degree that the uninitiated may find obsessive. We all have our thing, and for [Found Tech], it’s absolutely pointing particle accelerators at his face to play video games. He likes modern games, with modern resolutions– none of this 1080p nonsense. Today’s gamers demand 4K! Can a CRT keep up? The answer is a resounding “No, but actually, yes!”
[Found Tech] has an IBM P275 monitor, which is one of the last generation of CRTs. Officially, the resolution maxes out at 1920 dots by 1440 lines. While one might (inaccurately) call that UHD output “2K”, you certainly cannot claim it is 4K. So, what’s the secret? Interlacing. Yes, interlacing, like old analog TV signals.
Apparently, in spite of what the manual says, getting the screen to absorb the 2880×2160 interlaced signal wasn’t the hard part, but generating it was. NVIDIA and AMD graphics cards are absolutely unable to create an interlaced signal, but Intel integrated GPUs are– if you get the right combo of chip and old driver. Sadly, the video doesn’t list exactly what he used. Of course an iGPU isn’t going to give you a very good gaming experience at this high resolution, so [Found Tech] has his games do their rendering on the discrete card before piping that over to the iGPU for display on the CRT.
Technically, you still can’t call the 2880×2160 picture “4K”, as that trademark refers to 2160p at 16:9, and this is both interlaced and 4:3. Still, close enough. In spite of the artifacting that turned us all against interlaced signals back in the day, this apparently has [Found Tech]’s eyes fooled– he says it’s as good as 2160p on his OLED, plus the extra magic that comes with glowing phosphors.
It certainly looks great in a recording, but the monitor in the recording isn’t displayed at a high enough resolution to say for sure if it’s 4K. Still, if you’re into CRT gaming, maybe give this high-res interlacing a try. If you still don’t get what’s so great about CRTs, check here, and remember it could be worse– at least we’re not going on about Plasma TVs.
2026-05-03 01:00:38
There are lots of smart home systems that will let you blast your older dumb appliances with infrared to control them. However, many are tied to ugly cloud systems that can frustrate you on a regular basis. [Steelcuts] whipped up a cloudless solution to this problem instead.
IR2MQTT does pretty much exactly what it says in the name. It allows integrating things like air conditioners and televisions into a Home Assistant setup with the use of an IR blaster and a neat, tidy web app. You use it with an ESP32 or ESP8266 running a firmware based on ESPHome to actually do the IR blasting. In turn, IR2MQTT is a back-end plus a web interface that lets you setup all your IR devices without having to manually capture IR codes and create YAML files to do everything. It’s also integrated with large databases of IR codes for common appliances so in many cases, you can just look up your gear and get it working the easy way.
Sometimes all you need to get the job done is an IR LED and the will to use it. If you’re cooking up your own infrared hacks, don’t hesitate to let us know on the tipsline.
2026-05-02 22:00:51
Custom peripheral projects are among the most rewarding. Especially if you’re like me and you sit at the computer eight hours per day, anything that you can use on a daily basis is super satisfying. This topic of DIY peripherals came up on the podcast while chatting with Kristina, who is no stranger to odd inputs herself.
We were talking about a trackball that had been modified to read twisting gestures, by a clever hijacking of the twin mouse sensors inside. If you do a lot of 3D modeling, you can absolutely get by with just a mouse and shift-ctrl-alt as modifiers, but it’s so much more immediate to use a dedicated 3D input device. (I’ve got an ancient serial Space Mouse just under my left hand as I type this.)
My old favorite, which I haven’t used in ages, is the guts of a 5” hard-drive platter stack that I turned into a scroll wheel. Unfortunately, I don’t have space for it on my desk anymore, but it was just so pleasing to scroll through a document with something that had some real chonky momentum to it.
And it’s easier than ever to make your own. The classic blocky macropad is a great introduction, but as long as you’re doing the design yourself, why not extend it, or at least make it fit your hand? Or take your flights of fancy even further away from the mainstream. Consider the Bluetooth mouse ring, for instance.
Point is, the software side of almost any peripheral device you can imagine is sorted out already, and interfacing with the hardware is equally simple. Peripheral hacks have such a low barrier to entry, but afford so many creative hardware possibilities. And nothing says “Jedi” like building your own lightsaber.
