The Midwest RepRap Festival is the best 3D printer con on the planet. In the middle of Indiana, you’ll find the latest advances for CNC hot glue guns and the processes that make squirting filament machines better, more accurate, and more efficient. There’s more to 3D printing than just filament-based machines, though, and for the last few MRRFs we’ve been taking a look at resin-based machines.
While most of the current crop of resin printers use either DLP projectors or LCDs and a big, bright backlight [Mark Peng]’s Moai printer uses a 150 mW laser diode and galvos. This is somewhat rare in the world of desktop 3D printers, thanks in no small part to the ugliness between Formlabs and 3D Systems. Still, it’s a printer that looks fantastic and produces prints that are far beyond what’s possible with a filament-based machine.
With the side panels off, the Moai printer looks very simple. The enclosure is made from aluminum extrusion, the electronics are what you would expect in any RepRap, and apart from the laser galvo setup, this looks like something that could be knocked out in a well-equipped shop in a weekend.
The simple construction of the Moai stands in stark contrast to the prints coming out of this thing. These prints are the best you could ever expect from a 3D printer; they’re difficult to photograph even with a macro lens (note to other resin printer builders: don’t use transparent green resin if you want the media to take pictures of your prints). As far as specs go, the build volume is 130 mm x 130 mm x 180 mm, it prints via G-code and Cura, and can use Open resins.
[Mark] launched a Kickstarter for this printer last week, with the standard reward of a printer kit going for $1,000. According to [Mark], the kit only takes four hours to assemble, making the Moai a very interesting printer for anyone who wants to get into resin printing.
Like every Kickstarter campaign, we must remind you caveat emptor does not apply because ēmptor translates to ‘buyer’. You’re not buying anything on Kickstarter.
Filed under: 3d Printer hacks, news
What makes [mwagner1]’s Raspberry Pi Zero-based WiFi camera project noteworthy isn’t so much the fact that he’s used the hardware to make a streaming camera, but that he’s taken care to document every step in the process from soldering to software installation. Having everything in one place makes it easier for curious hobbyists to get those Pi units out of a drawer and into a project. In fact, with the release of the Pi Zero W, [mwagner1]’s guide has become even simpler since the Pi Zero W now includes WiFi.
Using a Raspberry Pi as the basis for a WiFi camera isn’t new, but it is a project that combines many different areas of knowledge that can be easy for more experienced people to take for granted. That’s what makes it a good candidate for a step-by-step guide; a hobbyist looking to use their Pi Zero in a project may have incomplete knowledge of any number of the different elements involved in embedding a Pi such as basic soldering, how to provide appropriate battery power, or how to install and configure the required software. [mwagner1] plans to use the camera as part of a home security system, so stay tuned.
If Pi Zero camera projects catch your interest but you want something more involved, be sure to check out the PolaPi project for a fun, well-designed take on a Pi Zero based Polaroid-inspired camera.
Filed under: how-to, Raspberry Pi
PoC||GTFO 14 is now out. It’s a 40 MB PDF that’s also a Nintendo Entertainment System ROM, and a Zip archive. Pastor Laphroaig Screams High Five To The Heavens As The Whole World Goes Under. Download this, but don’t link – host it yourself. Bitrot will be the end of us all.
[Photonicinduction] is back. The guy best known for not starting an electrical fire in his attic has been working through some stuff recently. He got married, went to India, and he’s going to try to blow a five thousand amp fuse. Good on him.
There’s a certain segment of the Internet that believes the Raspberry Pi Zero doesn’t exist. The logic goes something like this: because I can’t buy a Ferrari right now, Ferraris don’t exist. Now there’s a new and improved website that checks if the Pi Zero and Pi Zero W are in stock: thepilocator.com. It checks a dozen or so online stores for the Pi Zero and Pi Zero W. Guess what? They’re mostly in stock.
[bxcounter] built a PC case and holy crap this thing is incredible. This case is made out of Paulownia wood, and is made up out of fifty pieces held together with magnets. This thing is hand-carved and looks fantastic. Inside is a Mini-ITX motherboard, an i3, a Gigabyte ITX-sized 1060, and an SSD. It’s no powerhouse, but then again it’s not overkill, either. This is a fantastic addition to any battlestation.
As most hackerspaces do, the Omaha Maker Group had a storage problem. Previously, members used plastic totes someone picked up as surplus, but these totes were in short supply. Banker’s Boxes are a better idea, but how to store them? A box case. This ‘bookcase for boxes’ holds 21 standard Banker’s Boxes and only uses two full sheets of MDF in its construction.
Filed under: Hackaday Columns, Hackaday links
3D printing has evolved to a point where dual extrusion isn’t really that special anymore. A few years ago, a two-color frog print would have been impressive, but this isn’t the case anymore. The Midwest RepRap Festival is all about the bleeding edge of what 3D printers are capable of, and this year is no exception. This year, we were graced with a few true multicolor filament-based 3D printers. The biggest and best comes from [Daren Schwenke]. His Arcus 3D printer is a full color, CMYKW mixing printer that’s able to print in any color imaginable.The bizarre mixing hotend, powered by a brushless motor
The electronics for this printer are, to say the least, very weird. The controller board is a CRAMPS with a few extra bits to control six stepper motors. The hotend is bizarre, feeding six PTFE tubes into a weird water-cooled assembly that mixes and squirts filament out of the nozzle with the help of a small brushless motor. Thanks to a clever design, the end effector of the hotend weighs only about 150 grams – about the same as any other delta printer out there – and this printer is able to move very fast.
Over the last year, we’ve seen a lot of improvements in the state of multi-material and multi-color extrusion for 3D printers. At last year’s Maker Faire NY, Prusa’s i3 quad extruder made an appearance alongside the ORD Solutions RoVa4D printer. These are two completely different approaches to multicolor 3D printing, with the RoVa mixing filament, and the Prusa merely extruding multiple colors. Both approaches have their merits, but mixing extruders are invariably harder to build and the software stack to produce good prints isn’t well-defined.
Even though we’re still in the early years of full-color filament-based printing, this is still an awesome result. In a few years, we’ll be able to look back on [Daren]’s efforts and see where our full-color 3D printers came from – open source efforts to create the best hardware possible.
[Daren] has been working on this printer for a while, and he’s been uploading all his project updates to hackaday.io. You can check out the build log here.
Filed under: 3d Printer hacks, cons
The most brilliant hacks we see aren’t always the thousand-dollar, multi-year projects spanning every facet of engineering. Rather, the most ingenious projects are ones that take an everyday thing and use it in a simple but revolutionary way. By that measure, it’ll be hard to top [Robert]’s latest hack which uses the controller board from an everyday oscillating fan to build a three-way remote-controlled relay board.
Most oscillating fans have a speed selector switch. What that does might be somewhat different between different types of fan, but in general it will select either a smaller portion of the fan’s motor to energize or switch in a resistor which will have the same speed-lowering effect. [Robert]’s fan had little more than a triple-throw switch on the control board, so when he decided the fan wasn’t worth keeping anymore, he was able to re-purpose the control board into a general-use relay. As a bonus, the fan could be controlled by infrared, so he can also remote control whatever he decides to plug into his new piece of equipment.
While this simple hack might not change the world, it may give anyone with an old fan some ideas for other uses for its parts. If you want to do a little more work and get the fan itself running again, though, it is possible to rebuild the whole thing from the ground up as well.
Filed under: home hacks
[apollocrowe] at Carbide 3D (a company that does desktop CNC machines) shared a project of his that spent years being not-quite-there, but recently got dusted off and carried past the finish line. His soda can robot action figures were originally made by gluing a paper design to aluminum from a soda can, but [apollocrowe] was never really able to cut the pieces as reliably or as accurately as he wanted and the idea got shelved. With a desktop CNC machine to take care of accurate cutting, the next issue was how to best hold down a thin piece of uneven metal during the process. His preferred solution is to stick the metal to an acrylic wasteboard with hot glue, zero high enough and cut deep enough to account for any unevenness, and afterwards release the hot glue bond with the help of some rubbing alcohol.
Assembly involves minor soldering and using a few spare resistors. A small spring (for example from a retractable pen) provides the legs with enough tension for the figure to stand by itself. The results look great, and are made entirely from a few cents worth of spare parts and recycled materials. A video of the process is embedded below, and the project page contains the design files.
We’ve seen empty soda cans CNC milled into a solder stencil before, but that project didn’t get into how they were securing the notoriously uneven material to the bed. If reuse of empty soda cans is your gig but you lack fancy CNC, projects like this decorative box show that great results can be obtained even with simple tools.
Filed under: cnc hacks, how-to
Downing] is no stranger to building portable consoles, employing all manner of techniques in the process. However, when it came time to start on this commission, [Downing] decided to take a different tack – employing a Form 2 SLA printer in this Nintendo 64 portable build.
Modifying home consoles to become portables often involves tricks like Frankencasing – hacking together original factory parts such as controllers, cases, and accessories, and using body filler and a lot of sanding to create a template for vacuum moulding, which then results in a seamless final product. It’s possible to get some really impressive results, but it does limit the builder to relying on existing parts.
By using the Form 2, [Downing] was able to take advantage of the SLA printer’s ability to create parts with good surface finish that would normally require a lot of post-print finishing when 3D printed with more common FDM technology. This was particularly useful as it allowed the creation of custom buttons and small parts that “just fit” – normally such parts are made from stock pieces that are then modified.
The build also features a few other cool features – there’s a breakout box which allows the connection of extra controllers, as well as hosting AV out for hooking up to a television. The breakout box connects to the portable over an HDMI cable. It’s a tidy choice – it’s a standard cable that has an abundance of conductors available so you don’t have to be particularly tricky to get 3 controllers and a few analog signals talking over it.
In the end, [Downing] wouldn’t use SLA printing again for the case itself – the process was too slow and expensive. In this respect, FDM may require more work after printing but it still comes out ahead in terms of time and money. But for small custom parts like buttons and structural brackets, the Form 2 is the machine for the job.
Video after the break.
Filed under: 3d Printer hacks, nintendo hacks
Stringed instruments make noise from the vibrations of tuned strings, using acoustic or electronic means to amplify those vibrations to the point where they’re loud enough to hear. The strings are triggered in a variety of ways – piano strings are hit with hammers, guitar strings are plucked, while violin strings are bowed. Meanwhile, [Martin] from the band [Wintergatan] is using marbles to play a bass guitar.
[Martin] starts out with a basic setup. The bass guitar is placed on the workbench, while a piece of wood is taped to a tripod. The wood has a hole drilled through it, and marbles are dropped through the aperture in an attempt to get them to land on the string. Plastic containers are used to easily alter the angle the bass guitar sits at, relative to the bench, while an acrylic guide sits around the string to try to guide the marbles in the desired direction. These guides are important to make sure the marbles hit the top of the string, and bounce cleanly in the desired direction afterwards.
The initial setup is too inconsistent, so [Martin] places a notch in the wood and builds a lever system to hold the marbles and then release them in a controlled manner. [Martin] then checks that the system works by analysing footage of the marble drop with slow motion video.
The video covers the CAD design of an eight-slot guide so the four strings of the bass can be played more rapidly than in their previous build. Two guides per string allow each string to play two notes in quick succession without having to worry about marble collisions from playing too quickly.
It’s a great build, and we’ve seen [Wintergatan]’s work before – namely, the incredible build that was the original Marble Machine.
Thanks to [Tim Trzepacz] for the tip!
Filed under: musical hacks
Since the beginning of time, or 2006, the ‘hot glue gun’ part of our CNC hot glue guns have had well-defined parts. The extruder is the bit that pushes plastic through a tube, and the hot end is where all the melty bits are. These are separate devices, even though a shorter path from the extruder to hotend is always better. From Wade’s gear extruder to a nozzle made from an acorn nut, having the hotend and extruder as separate devices has become the standard.
This week at the Midwest RepRap Festival, E3D unveiled the Titan Aero. It’s an extruder and hotend rolled into one that provides better control over the filament, gives every printer more build height, and reduces the mass of a 3D printer toolhead.
The aluminum thermal block of the Titan Aero
The Titan Aero, revealed on the E3D blog yesterday, is the next iteration of E3D’s entry into the extruder market. It’s a strange mashup of their very popular V6 hotend, with the heat break coupled tightly to the extruder body. A large fan provides the cooling, and E3D’s thermal simulations show this setup will work well.
The core component of the Aero extruder is a fancy and complex piece of milled aluminum. This is the heatsink for the extruder and provides the shortest path possible between the hobbed gear and the nozzle. This gives the Aero better control over the extrusion of molten plastic and makes this the perfect extruder and hotend setup for hard to print materials.
Combine the Aero with a smaller ‘pancake’ stepper motor, and you have a very small, very light hotend and extruder. This makes it perfect for the small printers we’re so fond of and for printers built for fast acceleration. I can easily see a few end effectors for Delta-style printers built around this extruder in the near future.E3D’s Volcano nozzle sock
Also at the E3D booth were a few prototypes of nozzle socks. Late last year, E3D released silicone nozzle covers – we’re calling them nozzle socks – for their V6 hotend. These are small silicone covers designed to keep that carbonized crap off of your fancy, shiny hotend. It’s not something that’s necessary for a good print, but it does keep filament from sticking to your hotend, and you get the beautiful semantic satiation of saying the words nozzle socks.
E3D’s other hotend, the Volcano, a massive and powerful hotend designed to push a lot of plastic out fast, did not get its own nozzle sock at the time. Now, the prototypes are out, and the E3D guys expect them to be released, ‘in about a month’.
Filed under: 3d Printer hacks, cons
What is hacking and what is network engineering? We’re not sure where exactly to draw the lines, but [Artem]’s writeup of pivoting is distinctly written from the (paid) hacker’s perspective.
Once you’re inside a network, the question is what to do next. “Pivoting” is how you get from where you are currently to where you want to be, or even just find out what’s available. And that means using all of the networking tricks available. These aren’t just useful for breaking into other people’s networks, though. We’ve used half of these tools at one time or another just running things at home. The other half? Getting to know them would make a rainy-day project.
Is there anything that ssh and socat can’t do? Maybe not, but there are other tools (3proxy and Rpivot) that will let you do it easier. You know how clients behind a NAT firewall can reach out, but can’t be reached from outside? ssh -D will forward a port to the inside of the network. Need to get data out? There’s the old standby iodine to route arbitrary data over DNS queries, but [Artem] says dnscat2 works without root permissions. (And this code does the same on an ESP8266.)
Once you’ve set up proxies inside, the tremendously useful proxychains will let you tunnel whatever you’d like across them. Python’s pty shell makes things easier to use, and tsh will get you a small shell on the inside, complete with file-transfer capabilities.
Again, this writeup is geared toward the pen-testing professional, but you might find any one of these tools useful in your own home network. We used to stream MP3s from home to work with some (ab)use of netcat and ssh. We keep our home IoT devices inside our own network, and launching reverse-proxies lets us check up on things from far away without permanently leaving the doors open. One hacker’s encrypted tunnel is another man’s VPN. Once you know the tools, you’ll find plenty of uses for them. What’s your favorite?
Thanks [nootrope] for the indirect tip!
Filed under: security hacks
Today at the Midwest RepRap Festival, Lulzbot and IC3D announced the creation of an Open Source filament.
While the RepRap project is the best example we have for what can be done with Open Source hardware, the stuff that makes 3D printers work – filament, motors, and to some extent the electronics – are tied up in trade secrets and proprietary processes. As you would expect from most industrial processes, there is an art and a science to making filament and now these secrets will be revealed.
IC3D Printers is a manufacturer of filament based in Ohio. This weekend at MRRF, [Michael Cao], founder and CEO of IC3D Printers announced they would be releasing all the information, data, suppliers, and techniques that go into producing their rolls of filament.
According to [Michael Cao], there won’t be much change for anyone who is already using IC3D filament – the materials and techniques used to produce this filament will remain the same. In the coming months, all of this data will be published and IC3D is working on an Open Source Hardware Certification for their filament.
This partnership between IC3D and Lulzbot is due in no small part to Lulzbot’s dedication to Open Source Hardware. This dedication is almost excessive, but until now there has been no option for Open Source filament. Now it exists, and the value of Open Source hardware is again apparent.
Filed under: 3d Printer hacks, cons
Before we dig into this one, a bit of a history lesson is in order. In 2010, MakerBot released the Automated Build Platform for the MakerBot Cupcake. This build platform was like nothing seen before or since. It’s a combination build platform and a conveyor belt for a 3D printer, allowing the Cupcake to become a completely automated production machine. Start a print, let the machine run, and when the print is finished it’s rolled off the bed into a bin, allowing a second print to start. If you’re using 3D printers for production in a manufacturing context – like Makerbot was – this is a phenomenal invention.
The Automated Build Platform was released under an Open Source license, then quickly patented by Makerbot. Since 2010, the idea of an automated build platform has been dead. No one is working on a similar device, lest they draw the ire of a few MakerBot lawyers.
This year’s Midwest RepRap Festival saw a device that’s an even better idea than MakerBot’s Automated Build platform. Yes, it’s a continuous factory of 3D printed parts, but there’s an even better reason for you to build one of these things: this printer has an infinite build volume.
This printer – it doesn’t have a name; this is just a one-off project – is the work of [Bill Steele] of Polar3D. The core of the build is just a hacked up MakerBot Replicator, but with one important difference. This printer has an Automated Build Platform tilted away from the nozzle at a 45-degree angle. What’s the benefit of this setup? Continuous printing and an infinite build volume.
Despite being downright bizarre, the mechanics for this printer are actually pretty simple. The bed is a standard MakerBot heated bed, rotated 90 degrees in the axis you would expect, then rotated 45 degrees in the axis you wouldn’t. A conveyor belt made of Kapton-coated paper is strung between two rollers and connected to a motor.
To produce a print, this printer starts at the very back and the very top of this conveyor belt. The first layer is added, the conveyor belt rolls forward a bit, and the second layer is added on top. The effect for each print is that the layer lines are 45 degrees from what you would expect.
When the print is finished, the belt just rolls forward until the part falls into a bin. Of course, since there’s nothing stopping this printer from producing a meter-long part on this build platform. [Bill] has already produced a 3D printed chain using this printer that was four feet long. Each segment of the chain just fell off the end of the printer when it was done.
There’s still some work to do with this idea. There isn’t a way to tension the belt on this printer, and [Bill] is looking for a material that’s better than Kapton coated paper. Still, this is the most innovative printer you can find at the Midwest RepRap Festival, and it’s not encumbered by the MakerBot patent on the automated build platform. You can check out a video of this printer below.
Filed under: 3d Printer hacks, cons
Hands up if you’ve ever used a machine running CP/M. That’s likely these days to only produce an answer from owners of retrocomputers. What was once one of the premier microcomputer operating systems is now an esoteric OS, a piece of abandonware released as open source by the successor company of its developer.
In the 1970s you’d have seen CP/M on a high-end office wordprocessor, and in the 1980s some of the better-specified home computers could run it. And now? Aside from those retrocomputers, how about running CP/M on an ESP8266? From multi-thousand-dollar business system to two-dollar module in four decades, that’s technological progress.
[Matseng] has CP/M 2.2 running in a Z80 emulator on an ESP8266. It gives CP/M 64K of RAM, a generous collection of fifteen 250K floppy drives, and a serial port for communication. Unfortunately it doesn’t have space for the ESP’s party piece: wireless networking, but he’s working on that one too. If you don’t mind only 36K of RAM and one less floppy, that is. All the code can be found on a GitHub repository, so if you fancy a 1970s business desktop computer the size of a postage stamp, you can have a go too.
There’s something gloriously barmy about running a 1970s OS on a two-dollar microcontroller, but if you have to ask why then maybe you just don’t understand. You don’t have to have an ESP8266 though, if you want you can run a bare-metal CP/M on a Raspberry Pi.
Filed under: classic hacks, Microcontrollers
Control boards for 3D printers are a dime a dozen on the usual online marketplaces, and you usually get what you pay for. These boards can burn down your house thanks to a few terrible design choices. [Scott Rider] aka [Crow] took a look at the popular Melzi board, and what he found was horrifying. These boards overheat right at the connector for the heated bed, but the good news is these problems are easily fixed.
The Melzi board has a few problems with its PCB design. The first and most glaring issue is the use of thermals on the pads for the heated bed connector. In low-power applications, thermals — the method of not connecting the entire top or bottom layer to a hole or pad — are a great idea. It makes it easier to solder, because heat isn’t transmitted as easily to the entire copper layer. Unfortunately, this means heat isn’t transmitted as easily to the entire copper layer. In high-power applications, like a connection to a heated bed, these thermals can heat up enough to melt a plastic connector. Once that happens, it’s game over.
Other problems were found in the Melzi board, although you wouldn’t know it just by looking at the Eagle file of the PCB. [Scott]’s Chinesium Melzi board used 1-ounce copper, where 2-ounce copper would be more appropriate. The connector, too, should be rated above the design power loading.
[Scott] made a few tweaks to the board and also added a tiny DS1822Z temperature sensor to the high-current area of his version of a Melzi. Imagine that, 3D printer electronics with a temperature sensor. Slowly but surely, the state of 3D printer electronics is clawing its way to the present.
Filed under: 3d Printer hacks
Musician [Mari Lesteberg] is making music that paints pictures. Or maybe she’s making pictures that paint music. It’s complicated. Check out the video (embedded below) and you’ll see what we mean. The result is half Chinese scroll painting, and half musical score, and they go great together.
Lots of MIDI recorders/players use the piano roll as a model for input — time scrolls off to the side, and a few illuminated pixels represent a note played. She’s using the pixels to paint pictures as well: waves on a cartoon river make an up-and-down arpeggio. That’s a (musical) hack. And she’s not the only person making MIDI drawings. You’ll find a lot more on reddit.
Of course, one could do the same thing with silent pixels — just set a note to play with a volume of zero — but that’s cheating and no fun at all. As far as we can tell, you can hear every note that’s part of the scrolling image. The same can not be said for music of the black MIDI variety, which aims to pack as many notes into a short period of time as possible. To our ears, it’s not as beautiful, but there’s no accounting for taste.
It’s amazing what variations we’re seeing in the last few years on the ancient piano roll technology. Of course, since piano rolls are essentially punch-cards for musical instruments, we shouldn’t be too surprised that this is all possible. Indeed, we’re a little bit surprised that new artistic possibilities are still around. Has anyone seen punch-card drawings that are executable code? Or physical piano rolls with playable images embedded in them?
Filed under: musical hacks
If you’ve played Fallout 4, you’re familiar with the wall-mounted terminals in the game. They’ve got a post-apocalyptic aesthetic and the glowing green screen that calls out to anyone that grew up with computers and hacker movies from the 80s and 90s. Remember the first time you set your command line text to green? Don’t be embarrassed, we were all young once.
[PowerUpProps] liked the Fallout terminal so much they developed a replica. It’s a build that leans heavily on maker standards, a Raspberry Pi and 3D printing form the basis of the terminal. With ready access to such powerful tools, it makes starting such a project much more approachable. The key to the success of this build is the fine attention to detail in the finishing – the paint job looks incredible, and when photographed appropriately, it could be mistaken for the real thing an in-game screenshot.
An interesting touch is the use of a dark green acrylic window in front of the LCD, which gives the display a tinted hue. We’d like to see this compared with a clear glass window with a classic fishbowl curve to it, combined with greening up in software. The creator readily admits that this looks great at the command line, but is somewhat of a letdown when using the GUI.
Perhaps the only thing the prop build could use is some sort of user interface — the keyboard is only 3D printed and there’s no mouse or other pointing device included. There are some creative solutions to this problem, which we often see in other Fallout projects, like the ever popular Pip-Boy replica builds.
[Thanks to Sjoerd for the tip!]
Filed under: 3d Printer hacks, Raspberry Pi
The MITS Altair 8800 occupies a unique place in computing history as the first commercially succesful microcomputer for personal rather than business use. It is famous as the platform upon which the first Microsoft product ran, their first BASIC interpreter.
[Josh Bensadon] has an Altair 8800, and became intrigued by its bootloader. The simplest method of programming the machine is through binary using a set of switches on the front panel, and he remarks that there should be a warning in the manual: “fingers will get sore after repeated use of the small switches on the ALTAIR”.
In the Altair manual there are two listings, one 21 byte, and another in 20 bytes. Bill Gates is on record as saying that their first effort was 46 bytes long, but with more work he managed to create one in 17 bytes. Now [Josh] has beaten that, he’s created an Altair 8800 bootloader in only 14 bytes.
His write-up goes into great detail about how those bytes are shaved off, and provides us with a fascinating insight into the 8800’s architecture. Even if your 8-bit assembler is a little rusty, it’s a fascinating read.
We’ve featured Altair-inspired projects many times here at Hackaday, but rarely the real thing. This Altair PC case with the ability to emulate the original was rather a nice idea, as was this Altair front panel project. If you want the joy without the heartache though, there is an online emulator.
Filed under: classic hacks
Like a lot of people, we’ve been pretty interested in TensorFlow, the Google neural network software. If you want to experiment with using it for speech recognition, you’ll want to check out [Silicon Valley Data Science’s] GitHub repository which promises you a fast setup for a speech recognition demo. It even covers which items you need to install if you are using a CUDA GPU to accelerate processing or if you aren’t.
Another interesting thing is the use of TensorBoard to visualize the resulting neural network. This tool offers up a page in your browser that lets you visualize what’s really going on inside the neural network. There’s also speech data in the repository, so it is practically a one-stop shop for getting started. If you haven’t seen TensorBoard in action, you might enjoy the video from Google, below.
This demo might be a good second step after you complete the very simple tutorial we covered earlier. This isn’t the first time we’ve looked at neural nets and speech, but it may be the simplest one we’ve seen.
Filed under: software hacks
[Thomas] wanted to try baking some carbon fiber 3D printing filament because the vendor had promised higher strength and rigidity after the parts were annealed in the oven. Being of a scientific mindset, he did some controls and found that annealing parts printed with the carbon fiber-bearing filament didn’t benefit much from the treatment. However, parts printed with standard PLA became quite a bit stronger and more rigid.
The downside? The parts (regardless of material) tend to shrink a bit in the X and Y axis. They also tend to expand in the Z direction. However, the dimension changes were not that much. The test parts shrunk by about 5% and grew by 2%. He didn’t mention if this was repeatable, which is a shame because if it is repeatable, it isn’t a big deal to adjust part dimensions before printing. Of course, if it isn’t repeatable, it will be difficult to get a particular finished size after the annealing process.
The resulting PLA parts were 40% stronger and 25% more rigid than the same part before treatment. In addition, the parts had better resistance to heat, which is a common issue with PLA parts. The heating process is as simple as putting the parts in a 110° C oven for an hour, so it shouldn’t require any special equipment to replicate the test.
We’d be interested to see how fine details survive the heating and cooling. However, even if this isn’t for every part, it could be another trick in your arsenal for making 3D printed parts.
If you have the urge to try different filament types, this earlier post will keep you busy for at least a month. The vendor [Thomas] used for the carbon fiber filament makes a lot of different exotic blends.
Filed under: 3d Printer hacks
If you wanted to invoke American farming with colour, which colours would you pick? The chances are they would be the familiar green and yellow of a John Deere tractor. It’s a name that has been synonymous with US agriculture since the 1830s, when the blacksmith whose name appears on the tractors produced his first steel plough blade. The words “American icon” are thrown around for many things, but in the case of John Deere there are few modern brands with as much history to back up their claim to it.
A trip across the prairies then is to drive past Deere products in use from most of the last century. They will still supply parts for machines they made before WW2, and farmers will remain loyal to the brand throughout their lives.
Well… That used to be the case. In recent years a new Deere has had all its parts locked down by DRM, such that all maintenance tasks on the tractors must be performed by Deere mechanics with the appropriate software. If your tractor breaks in the field you can fit a new part as you always have done, but if it’s a Deere it then won’t run until a Deere mechanic has had a look at it. As a result, Motherboard reports that American farmers are resorting to Ukrainian-sourced firmware updaters to hack their machines and allow them to continue working. An icon of American farming finds itself tarnished in its heartland.
We’ve reported on the Deere DRM issue before, it seems that the newest development is a licence agreement from last October that prohibits all unauthorised repair work on the machines as well as insulating the manufacturer from legal action due to “crop loss, lost profits, loss of goodwill, loss of use of equipment … arising from the performance or non-performance of any aspect of the software”. This has sent the farmers running to illicit corners of the internet to spend their dollars on their own Deere electronic updating kits rather than on call-out fees for a Deere mechanic. Farmers have had centuries of being resourceful, this is simply the twenty-first century version of the hacks they might have performed decades ago with baler twine and old fertiliser sacks.
You might ask what the hack is here, as in reality they’re just buying a product online, and using it. But this is merely the latest act in a battle in one industry that could have ramifications for us all. Farmers are used to the model in which when they buy a machine they own it, and the Deere DRM is reshaping that relationship to one in which their ownership is on the manufacturer’s terms. How this plays out over the coming years, and how it affects Deere’s bottom line as farmers seek tractors they can still repair, will affect how other manufacturers of products non-farmers use consider DRM for their own business models.
Outside the window where this is being written is a Deere from the 1980s. It’s a reliable and very well-screwed-together tractor, though given the subject of this piece it may be our last green and yellow machine. Its dented badge makes a good metaphor for the way at least for us the brand has been devalued.
Thanks [Jack Laidlaw] for the tip.
Filed under: transportation hacks