Make Your Bookshelf Clickable

February 15, 2024 by 21 Comments

We’ll confess that we have a fondness for real books and plenty of them. So does [James], and he decided he needed a way to take a picture of his bookshelves and make each book clickable to find more information. This is one of those things that sounds fairly simple until you decide to do it. You can try an example of the results and then go back and read about the journey it took to get there.

There are several subtasks involved. First, you want to identify each book’s envelope. It wouldn’t do to click on the Joy of Cooking and get information about Remembrance of Things Past.

The next challenge is reading the title of the book. This can be tricky. Fonts differ. The book could be upside down. Some titles go cross the spine, but most go vertically. The remainder of the task is fairly easy. If you know the region and the title, you can easily find a link (for Google Books, in this case) and build an SVG overlay that maps the areas for each book to the right link.

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Lift Those Pins With Ease

February 15, 2024 by 16 Comments

Reworking is one of the regular tasks of anyone who is involved in an electronic design process, because try as we might, it’s rare to get a design perfectly right the first time. Some reworking tasks are more difficult than others though, and we have to admit that lifting an IC pin doesn’t always result in success. But with this video from [Mr. SolderFix] there’s hope for conquering the technique, as he takes us through the best pin-raising technique on a variety of packages.

The trick it seems is to lift the pin first without attempting to disengage it from the molten solder, then returning to it with some copper braid to remove the solder and leave it raised. Once the secret is revealed it’s so easy, something a Hackaday scribe should be able to do. He does sound a note of caution though, as some packages are prone to disintegrating when stressed. A broken SOT-23 is not something anyone likes to see through their magnifier.

His channel is full of such no-nonsense soldering advice, and should be a fascinating browse for many readers. Meanwhile we’ve covered quite a bit of rework technique ourselves, such as last year when we looked at BGA work.

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Developing In Pascal On The Commodore 64 With Abacus Super Pascal 64

February 14, 2024 by 8 Comments
Abacus Super Pascal 64 for the Commodore 64.

Most people associate the Commodore 64 with Commodore BASIC and precompiled applications, but it also had a number of alternative development environments produced for it. One of these was Super Pascal 64 by Abacus. A solid introduction to this software package is provided in a video tutorial by [My Developer Thoughts] on YouTube. This uses the Abacus Super Pascal 64 software and manual from the [Lyon Labs] website, which incidentally has a lot more development environments and operating systems for the C64 listed for your perusal.

Abacus’ Super Pascal supports the official Pascal language, requiring nothing more than a Commodore 64 and two Commodore 1541 floppy disk drives to get started. One FDD is for the Super Pascal software, which boots into the development environment, the other FDD and the disks in it are the target for the current project’s source code and compiled binary. Although the lack of support for FDDs other than the 1541 is somewhat odd, this comes presumably from the operating system nature of the development environment and the 1541 being by far the most common FDD for the C64.

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Shuji Nakamura: The Man Who Gave Us The Blue LED Despite All Odds

February 14, 2024 by 68 Comments

With the invention of the first LED featuring a red color, it seemed only a matter of time before LEDs would appear with other colors. Indeed, soon green and other colors joined the LED revolution, but not blue. Although some dim prototypes existed, none of them were practical enough to be considered for commercialization. The subject of a recent [Veritasium] video, the core of the problem was that finding a material with the right bandgap and other desirable properties remained elusive. It was in this situation that at the tail end of the 1980s a young engineer at Nichia in Japan found himself pursuing a solution to this conundrum.

Although Nichia was struggling at the time due to the competition in the semiconductor market, its president was not afraid to take a gamble on a promise, which is why this young engineer – [Shuji Nakamura] – got permission to try his wits at the problem. This included a year long study trip to Florida to learn the ins and outs of a new technology called metalorganic chemical vapor deposition (MOCVD, also metalorganic vapor-phase epitaxy). Once back in Japan, he got access to a new MOCVD machine at Nichia, which he quickly got around to heavily modifying into the now well-known two-flow reactor version which improves the yield.

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FLOSS Weekly Episode 770: 10% More Internet

February 14, 2024 by 7 Comments

This week, Jonathan Bennett and Doc Searls talk with David Taht about the state of the Internet and, specifically, IPv4 exhaustion. We’re running out of IPv4 addresses! But we’ve been running out for something like ten years now. What gives? And why are nearly 20% of the world’s IPv4 addresses sitting unused? David has a hack that would give the world 10% more Internet, but Amazon might have something to say about it.

There’s even more, like Kessler Syndrome, some musing on what the Interplanetary Internet will look like, the worth of real paper books, and a long-term bet for some IPv4 addresses to come to fruition in 2038.

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Ring Around The Inverter

February 14, 2024 by 19 Comments

[Dr. Shane] asks the question: what happens if you connect the output of an inverter logic gate back to the input? In theory, it doesn’t make sense, but depending on the gate’s physical construction, you’ll get into a strange state. The transistors within the gate will behave differently than they normally would, and you’ll wind up with an amplifier or an oscillator. You can see the results in the video below. In the second video, you can see what the odd connection does to the thermal properties of the inverter, too.

The CMOS inverter becomes biased in the active region, so it makes sense that it settles at the halfway point. The TTL inverter is slightly different, but the delay through the gate isn’t enough to produce a good oscillation. However, an odd number of inverters connected in a ring like this is one way to create a simple oscillator.

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How Different Are SpaceX Thermal Tiles From The Space Shuttle’s?

February 14, 2024 by 8 Comments

When SpaceX first showed off the thermal tiles on its Starship spacecraft that should keep it safe when re-entering the Earth’s atmosphere towards the loving embrace of the chopsticks on the launch tower, some similarity to the thermal tiles on NASA’s now retired Space Shuttle Orbiter was hard to miss.

Electron microscope image of the fibrous part of a Starship thermal tile, showing very large fibers. (Credit: Breaking Taps, YouTube)
Electron microscope image of the fibrous part of a Starship thermal tile, showing very large fibers. (Credit: Breaking Taps, YouTube)

Yet how similar are they really? That’s what the [Breaking Taps] channel on YouTube sought to find out, using an eBay-purchased chunk of Shuttle thermal tile along with bits of Starship tiles that washed ashore following the explosive end to the vehicle’s first integrated test last year.

To answer the basic question: the SpaceX engineers responsible for the Starship thermal tiles seem to have done their homework. An analysis of not only the structure of the fibrous material, but also the black IR-blocking coating, shows that the Starship tiles are highly reminiscent of the EATB (introduced in 1996) tiles with TUFI (toughened unipiece fibrous insulation) coatings with added molybdenum disilicide, which were used during the last years of the Shuttle program.

TUFI is less fragile than the older RCG (reaction cured glass) coating, but also heavier, which is why few TUFI tiles were used on the Shuttles due to weight concerns. An oddity with the Starship tiles is that they incorporate many very large fibers, which could be by design, or indicative of something else.

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