Since LVL1 got a better laser cutter a lot of neat projects have been piling up. [Brian] based his clock around two cheap stepper motors driven by a freeduino. A chronodot was used to keep accurate time. Making the gears, though, presented a few problems. While prototyping the gear clock face, it was apparent that the numbers should be oriented along a line coming from the center of the gear. The prototype also used 100 teeth and that didn’t translate well into a clock design. [Brian] designed the minute gear with 60 teeth, and the hour gear with 144 teeth so that each tooth would equal 5 minutes.
[Brian]’s clock is functionally similar to this $2500 gem, and certainly much less expensive even after the cost of the laser cutter is taken into account. Of course, the Spirograph clock keeps track of minutes so it may be worth upwards of $5k.
The Agnewgraph I can turn out a pretty nice Spirograph drawing. Instead of relying on meticulously acurate CNC hardware, it uses a Spirograph stencil similiar to that business card we’re so fond of. The key to the [Mpark’s] design is an analog joystick which is attached to the pen. As the pen follows the plastic guide around, a Propeller microcontroller calculates the angle of travel based on that joystick. These measurements are used to decide how to move the two stepper motors that provide horizontal and vertical motion to the frame. We’ve attached a video after the break just in case our rough description didn’t do it for you.
If I could name one thing which has been the most transformative for our community over the last couple of decades, it would have to be the proliferation of hackerspaces. Ostensibly a place which provides access to tools and machinery, these organisations have become so much more. They bring together like-minded people, and from such a meeting of minds have come a plethora of high quality projects, events, and other good things.
Just What Is A Hackerspace?
A Hacky Racer takes shape in the MK Makerspace workshop
Hackerspaces loosely come in many forms, from co-working spaces or libraries who have invested in a 3D printer and imagine themselves to be a hackerspace, through to anarchist collectives in abandoned warehouses who support their city’s alternative communities with technology. For me, hackerspaces must be community organisations rather than for-profit ones, so for the purposes of this article I’m not referring to closely-allied commercial spaces such as FabLabs.
So a good hackerspace for me is a group of tech enthusiasts who’ve come together, probably formed a non-profit association, and rented a dilapidated basement or industrial unit somewhere. The tools and machines inside aren’t shiny and new but they mostly work, and round that fridge stocked with Club-Mate you’ll find a community of friends, people who don’t think it’s odd to always want to know how things work. In a good hackerspace you’ll have found your place, and you can be much more than you would have been alone.
I visit plenty of hackerspaces across Europe as I wander the continent on an Interrail pass. I’m a member of three of them at the moment, though my main home in the UK is at Milton Keynes Makerspace. I’ve sat on recycled sofas drinking caffeinated beverages in more cities than I can count, and along the way I’ve seen close-up the many different ways a hackerspace can be run. I’ve seen spaces falling apart at the seams, I’ve seen ones a little too regimented for my taste, and others with too much of an emphasis on radical ideology, but mostly I’ve seen spaces that get it about right and I feel at home in. So perhaps it’s time to sit down and talk about what I think makes a good hackerspace. What is my space?
One of the first logic circuits most of us learn about is the humble flip-flop. They’re easy enough to build with just a couple of NOR or NAND gates, and even building one up from discrete components isn’t too much of a chore. But building a flip-flop from chemicals and lasers is another thing entirely.
That’s the path [Markus Bindhammer] took for his photochromic molecular switch. We suspect this is less of an attempt at a practical optical logic component and more of a demonstration project, but either way, it’s pretty cool. Photochromism is the property by which molecules reversibly rearrange themselves and change color upon exposure to light, the most common example being glass that darkens automatically in the sun. This principle can be used to create an optical flip-flop, which [Markus] refers to as an “RS” type but we’re pretty sure he means “SR.”
The electronics for this are pretty simple, with two laser modules and their drivers, a power supply, and an Arduino to run everything. The optics are straightforward as well — a beam splitter that directs the beams from each laser onto the target, which is a glass cuvette filled with a clear epoxy resin mixed with a photochromic chemical. [Markus] chose spiropyran as the pigment, which when bathed in UV light undergoes an intramolecular carbon-oxygen bond breakage that turns it into the dark blue pigment merocyanine. Hitting the spot with a red laser or heating the cuvette causes the C-O bond to reform, fading the blue spot.
The video below shows the intensely blue dot spot developing under UV light and rapidly fading thanks to just the ambient temperature. To make the effect last longer, [Markus] cools the target with a spritz from a CO2 cartridge. We imagine other photochromic chemicals could also be employed here, as could some kind of photometric sensor to read the current state of the flip-flop. Even as it is, though, this is an interesting way to put chemistry and optics to work.
Sometimes you just have to throw your hat in the ring, and throw it hard. Here is [mkdxdx]’s rockin’ EVH 5150-esque take on the keyboard business. The Mriya foldable keyboard aims to be and sport a number of things, and it does all of them in great style. I could totally see my fingers flying over this thing somewhere in the wild, with robots fighting in the distance.
Image by [mkdxdx] via Hackaday.IOI have to say I really like the fact that [mkdxdx] uses thumb keys here for what I can only assume are Enter, Space, and Backspace. It’s a nice compromise between compactness and ergonomics. I also really like the totally impractical but quite cool-looking connector that runs between the top and bottom.
If the color scheme looks familiar, you’re probably remembering [mkdxdx]’s first-place-winning entry into the 2023 Cyberdeck Contest. This RP2040-based keyboard might just end up as part of a larger project, but it’s already an outstanding peripheral. We can’t wait to see the next phase, should there be one for this keyboard.
The fun part of security audits is that everybody knows that they’re a good thing, and also that they’re rarely performed prior to another range of products being shoved into the market. This would definitely seem to be the case with fingerprint sensors as found on a range of laptops that are advertised as being compatible with Windows Hello. It all began when Microsoft’s Offensive Research and Security Engineering (MORSE) asked the friendly people over at Blackwing Intelligence to take a poke at a few of these laptops, only for them to subsequently blow gaping holes in the security of the three laptops they examined.
In the article by [Jesse D’Aguanno] and [Timo Teräs] the basic system and steps they took to defeat it are described. The primary components are the fingerprint sensor and Microsoft’s Secure Device Connection Protocol (SDCP), with the latter tasked with securing the (USB) connection between the sensor and the host. Theoretically the sensitive fingerprint-related data stays on the sensor with all matching performed there (Match on Chip, MoC) as required by the Windows Hello standard, and SDCP keeping prying eyes at bay.
Interestingly, the three laptops examined (Dell Inspiron 15, Lenovo ThinkPad T14 and Microsoft Surface Pro X) all featured different sensor brands (Goodix, Synaptics and ELAN), with different security implementations. The first used an MoC with SDCP, but security was much weaker under Linux, which allowed for a fake user to be enrolled. The Synaptics implementation used a secure TLS connection that used part of the information on the laptop’s model sticker as the key, and the ELAN version didn’t even bother with security but responded merrily to basic USB queries.
To say that this is a humiliating result for these companies is an understatement, and demonstrates that nobody in his right mind should use fingerprint- or similar scanners like this for access to personal or business information.
