Touch Lamp Tracks ISS With Style

In the comments of a recent article, the question came up as to where to find projects from the really smart kids the greybeards remember being in the 70s. In the case of [Will Dana] the answer is YouTube, where he’s done an excellent job of producing an ISS-tracking lamp, especially considering he’s younger than almost all of the station’s major components.*

There’s nothing ground-breaking here, and [Will] is honest enough to call out his inspiration in the video. Choosing to make a ground-track display with an off-the-shelf globe is a nice change from the pointing devices we’ve featured most recently. Inside the globe is a pair of stepper motors configured for alt/az control– which means the device must reset every orbit, since [Willis] didn’t have slip rings or a 360 degree stepper on hand.  A pair of magnets couples the motion system inside the globe to the the 3D printed ISS model (with a lovely paintjob thanks to [Willis’s girlfriend]– who may or may be from Canada, but did show up in the video to banish your doubts as to her existence), letting it slide magically across the surface. (Skip to the end of the embedded video for a timelapse of the globe in action.) The lamp portion is provided by some LEDs in the base, which are touch-activated thanks to some conductive tape inside the 3D printed base.

It’s all controlled by an ESP32, which fetches the ISS position with a NASA API. Hopefully it doesn’t go the way of the sighting website, but if it does there’s more than enough horsepower to calculate the position from orbital parameters, and we are confident [Will] can figure out the code for that. That should be pretty easy compared to the homebrew relay computer or the animatronic sorting hat we featured from him last year.

Our thanks to [Will] for the tip. The tip line is for hackers of all ages,  but we admit that it’s great to see what the new generation is up to.

*Only the Roll Out Solar Array, unless you only count on-orbit age, in which case the Nakua module would qualify as well.

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A blue 3DBenchy is visible on a small circular plate extending up through a cutout in a flat, reflective surface. Above the Benchy is a roughly triangular metal 3D printer extruder, with a frost-covered ring around the nozzle. A label below the Benchy reads “2 MIN 03 SEC.”

Managing Temperatures For Ultrafast Benchy Printing

Commercial 3D printers keep getting faster and faster, but we can confidently say that none of them is nearly as fast as [Jan]’s Minuteman printer, so named for its goal of eventually printing a 3DBenchy in less than a minute. The Minuteman uses an air bearing as its print bed, feeds four streams of filament into one printhead for faster extrusion, and in [Jan]’s latest video, printed a Benchy in just over two minutes at much higher quality than previous two-minute Benchies.

[Jan] found that the biggest speed bottleneck was in cooling a layer quickly enough that it would solidify before the printer laid down the next layer. He was able to get his layer speed down to about 0.6-0.4 seconds per layer, but had trouble going beyond that. He was able to improve the quality of his prints, however, by varying the nozzle temperature throughout the print. For this he used [Salim BELAYEL]’s postprocessing script, which increases hotend temperature when volumetric flow rate is high, and decreases it when flow rate is low. This keeps the plastic coming out of the nozzle at an approximately constant temperature. With this, [Jan] could print quite good sub-four and sub-thee minute Benchies, with almost no print degradation from the five-minute version. [Jan] predicts that this will become a standard feature of slicers, and we have to agree that this could help even less speed-obsessed printers.

Now onto less generally-applicable optimizations: [Jan] still needed stronger cooling to get faster prints, so he designed a circular duct that directed a plane of compressed air horizontally toward the nozzle, in the manner of an air knife. This wasn’t quite enough, so he precooled his compressed air with dry ice. This made it both colder and denser, both of which made it a better coolant. The thermal gradient this produced in the print bed seemed to cause it to warp, making bed adhesion inconsistent. However, it did increase build quality, and [Jan]’s confident that he’s made the best two-minute Benchy yet.

If you’re curious about Minuteman’s motion system, we’ve previously looked at how that was built. Of course, it’s also possible to speed up prints by simply adding more extruders.

When Is A Synth A Woodwind? When It’s A Pneumatone

Ever have one of those ideas that’s just so silly, you just need to run with it? [Chris] from Sound Workshop ran into that when he had the idea that became the Pneumatone: a woodwind instrument that plays like a synth.

In its 3D printed case, it looks like a giant polyphonic analog synth, but under the plastic lies a pneumatic heart: the sound is actually being made by slide whistles. We always thought of the slide whistle as a bit of a gag instrument, but this might change our minds. The sliders on the synth-box obviously couple to the sliders in the whistles. The ‘volume knobs’ are actually speed controllers for computer fans that feed air into the whistles. The air path is possibly not ideal– there’s a bit of warbling in the whistles at some pitches– but the idea is certainly a fun one. Notes are played by not blocking the air path out the whistle, as you can see in the video embedded below.

Since the fans are always on, this is an example of a drone instrument, like bagpipes or the old hacker’s favourite, the hurdy gurdy. [Chris] actually says in his tip– for which we are very thankful– that this project takes inspiration not from those projects but from Indian instruments like the Shruthi Box and Tanpura. We haven’t seen those on Hackaday yet, but if you know of any hacks involving them, please leave a tip.

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IR Point And Shoot Has A Raspberry Heart In A 35mm Body

Photography is great, but sometimes it can get boring just reusing the same wavelengths over and over again. There are other options, though and when [Malcolm Wilson] decided he wanted to explore them, he decided to build a (near) IR camera. 

The IR images are almost ethereal.
Image : Malcom Wilson.

The housing is an old Yashica Electro 35 — apparently this model was prone to electrical issues, and there are a lot of broken camera bodies floating around– which hides a Pi NoIR Camera v3. That camera module, paired with an IR pass filter, makes for infrared photography like the old Yashica used to do with special film. The camera module is plugged into a Pi Zero 2 W, and it’s powered by a PiSugar battery. There’s a tiny (0.91″) OLED display, but it’s only for status messages. The viewfinder is 100% optical, as the designers of this camera intended. Point, shoot, shoot again.

There’s something pure in that experience; we sometimes find stopping to look at previews pulls one out of the creative zone of actually taking pictures. This camera won’t let you do that, though of course you do get to skip on developing photos. [Malcom] has the Pi set up to connect to his Wifi when he gets home, and he grabs the RAW (he is a photographer, after all) image files via SSH.  Follow the link above to [Malcom]’s substack, and you’ll get some design details and his python code.

The Raspberry Pi Foundation’s NoIR camera shows up on these pages from time to time, though rarely so artistically. We’re more likely to see it spying on reptiles, or make magic wands work.  So we are quite grateful to [Malcom] for the tip, via Petapixel. Yes, photographers and artists of all stripes are welcome to use the tips line to tell us about their work.

Follow the links in this article for more images like this.
Image: Malcom Wilson

The Hackaday Summer Reading List: No AI Involvement, Guaranteed

If you have any empathy at all for those of us in the journalistic profession, have some pity for the poor editor at the Chicago Sun-Times, who let through an AI-generated summer reading list made up of novels which didn’t exist.  The fake works all had real authors and thus looked plausible, thus we expect that librarians and booksellers throughout the paper’s distribution area were left scratching their heads as to why they’re not in the catalogue.

Here at Hackaday we’re refreshingly meat-based, so with a guarantee of no machine involvement, we’d like to present our own summer reading list. They’re none of them new works but we think you’ll find them as entertaining, informative, or downright useful as we did when we read them. What are you reading this summer? Continue reading “The Hackaday Summer Reading List: No AI Involvement, Guaranteed”

splice-cad assembly

Splice CAD: Cable Harness Design Tool

Cable harness design is a critical yet often overlooked aspect of electronics design, just as essential as PCB design. While numerous software options exist for PCB design, cable harness design tools are far less common, making innovative solutions like Splice CAD particularly exciting. We’re excited to share this new tool submitted by Splice CAD.

Splice CAD is a browser-based tool for designing cable assemblies. It allows users to create custom connectors and cables while providing access to a growing library of predefined components. The intuitive node editor enables users to drag and connect connector pins to cable wires and other pinned connectors. Those familiar with wire harnesses know the complexity of capturing all necessary details, so having a tool that consolidates these properties is incredibly powerful.

Among the wire harness tools we’ve featured, Splice CAD stands out as the most feature-rich to date. Users can define custom connectors with minimal details, such as the number of pins, or include comprehensive information like photos and datasheets. Additionally, by entering a manufacturer’s part number, the tool automatically retrieves relevant data from various distributor websites. The cable definition tool is equally robust, enabling users to specify even the most obscure cables.

Once connectors, cables, and connections are defined, users can export their designs in multiple formats, including SVG or PDF for layouts, and CSV for a detailed bill of materials. Designs can also be shared via a read-only link on the Splice CAD website, allowing others to view the harness and its associated details. For those unsure if the tool meets their needs, Splice CAD offers full functionality without requiring an account, though signing in (which is free) is necessary to save or export designs. The tool also includes a version control system, ideal for tracking design changes over time. Explore our other cable harness articles for more tips and tricks on building intricate wire assemblies.

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This Week In Security: Anthropic, Coinbase, And Oops Hunting

Anthropic has had an eventful couple weeks, and we have two separate write-ups to cover. The first is a vulnerability in the Antropic MCP Inspector, CVE-2025-49596. We’ve talked a bit about the Module Context Protocol (MCP), the framework that provides a structure for AI agents to discover and make use of software tools. MCP Inspector is an Open Source tool that proxies MCP connections, and provides debugging information for developers.

MCP Inspector is one of those tools that is intended to be run only on secure networks, and doesn’t implement any security or authentication controls. If you can make a network connection to the tool, you can control it. and MCP Inspector has the /sse endpoint, which allows running shell commands as a feature. This would all be fine, so long as everyone using the tool understands that it is not to be exposed to the open Internet. Except there’s another security quirk that intersects with this one. The 0.0.0.0 localhost bypass.

The “0.0.0.0 day exploit” is a bypass in essentially all the modern browsers, where localhost can be accessed on MacOS and Linux machines by making requests to 0.0.0.0. Browsers and security programs already block access to localhost itself, and 127.0.0.1, but this bypass means that websites can either request 0.0.0.0 directly, or rebind a domain name to 0.0.0.0, and then make requests.

Continue reading “This Week In Security: Anthropic, Coinbase, And Oops Hunting”