The PCBs for interfacing to our ITECH test equipment arrived today, and @lu_honghong made quick work of the assembly. Now we can get back to testing. If you've got cursed ITECH or BK Precision equipment, you can make your own: https://t.co/fr5NYTujSC pic.twitter.com/5OOoJrgkp1

— Matt Mets (@cibomahto) January 6, 2021

New project from Matt Mets of blinkinlabs.com:

Itech USB-to-Serial adapter

Some ITECH test equipment has a DSUB connector with a standard-breaking 5V TTL connector on it. This is a non-isolatd USB converter for this equipment, for interfacing to a PC.

Shared project: ITECH-USB-ADAPTER

You can order the PCBs direct from the OSH park project, or use the gerbers and order from anywhere. You’ll need the parts listed in the BOM, substituting a USB ‘A’ cable for the 4-pin header. The PCB is designed to be sodlered directly to a NorComp 171-009-103L001 DSUB connector, and the whole thing will fit in a NorComp 977-009-020R121 shroud.

By pretty much any metric you care to use, 2020 has been an unforgettable year. Usually that would be a positive thing, but this time around it’s a bit more complicated. The global pandemic, unprecedented in modern times, impacted the way we work, learn, and gather. Some will look back on their time in lockdown as productive, if a bit lonely. Other’s have had their entire way of life uprooted, with no indication as to when or if things will ever return to normal. Whatever “normal” is at this point.

But even in the face of such adversity, there have been bright spots for our community. With traditional gatherings out of the question, many long-running tech conferences moved over to a virtual format that allowed a larger and more diverse array of presenters and attendees than would have been possible in the past. We also saw hackers and makers all over the planet devote their skills and tools to the production of personal protective equipment (PPE). In a turn of events few could have predicted, the 2020 COVID-19 pandemic helped demonstrate the validity of hyperlocal manufacturing in a way that’s never happened before.

For better or for worse, most of us will associate 2020 with COVID-19 for the rest of our lives. Really, how could we not? But over these last twelve months we’ve borne witness to plenty of stories that are just as deserving of a spot in our collective memories. As we approach the twilight hours of this most ponderous year, let’s take a look back at some of the most interesting themes that touched our little corner of the tech world this year.

Read more… 2020: As The Hardware World Turns — Hackaday

Open-source, drop in controller for the IKEA Bekant standing desk from Greg’s Tinker Town on Tindie:

Megadesk

Megadesk is an AVR based, open source, drop in controller for the IKEA Bekant standing desks.

The Bekant is a relatively inexpensive motorized standing desk. It doesn’t come with memory positions.

I wanted to have memory positions for easily switching between various work positions. I also didn’t want to be limited to just 2 positions. However, as I went through the process, I realized the hardest part was designing the enclosure. 3D Printing is a great option, but lacks that professional look, and limits the availability to those with printers. Additionally, getting custom membrane buttons that would look good was also extremely expensive. Simple push-buttons would take away from the look of the desk.

By targeting the factory enclosure, it keeps the original look and robustness, while adding functionality.

From Anool Mahidharia on the Hackaday blog:

Simple Christmas Tree Christmas Tree Ornament

When the only tool you have is a hammer, every problem looks like a nail. An LED ornament for the Christmas tree can be built in any manner of simple, easy implementations. You certainly don’t need an ARM Cortex M4 CPU running at 120MHz having a mouthful of three letter features like FPU, ETM, ETB, ECC, RWW, TCM, EIC, AES, CAN bus and much, much more. But [Martin Held] built a super simple LED Christmas tree ornament using the ATSAME51 series micro-controller, which he regularly works with and had on hand, and lots of bi-color LEDs. He already had schematic symbols and programmers for the device from other projects where he uses it more extensively, so putting it all together in time for the festive season was that much faster for him, despite the fact that the micro-controller was most likely the cheapest part of the BOM, besides the passives.

From James Lewis on the Hackster blog:

Bridge “Chip” Accesses the PCI-Express Bus on a Raspberry Pi 4

About a year ago, Tomasz Mloduchowski showed the world how to access the PCI-Express bus on a Raspberry Pi 4. By removing the PCI-Express to USB bridge chip, it is possible to connect external PCI-Express devices to a Pi. That hack was a bit of a wiring mess. Zak Kemble has taken the work a step further and created a replacement PCIe Bridge “Chip” to make the Pi’s PCI-Express mod more straightforward than before.

Kemble did not make an actual chip. Instead, it is a PCB with roughly the same dimensions as the Pi 4’s VL805 controller chip. After replacing the existing IC with this PCB, it patches the PCI-Express traces from the SoC to the USB 3 ports.

Out of the OSHPark envelope, the boards are not a perfect fit. The Bridge “Chip” needs a bit of sanding to fit the dimensions of the VL805. This step also exposes some of the copper for soldering the edge connections. (Kemble designed the board with this modification in mind.)

Once the Bridge “Chip” is in place, the Raspberry Pi’s USB 3.0 port is now carrying PCI-Express traffic. A PCIe expansion board kit is an ideal companion to this mod. They connect a x1 slot to a x16 riser card over a USB 3.0 cable. These cables easily carry up to 5 Gb/s traffic between the Pi 4’s USB 3.0 port and an external PCI-Express slot.

We should point out that once you modify a Raspberry Pi for PCI-Express access, you lose USB functionality. This loss is from removing the VL805 USB bridge chip. Ironically, one of the first external devices Kemble attached to his modified Pi was a VL805 based adapter. It is an excellent choice to make sure the link works since Raspbian has drivers for that chip.

Overall, this approach is a relatively easy way to get access to PCI-Express on an inexpensive consumer-grade device. If you’d like to convert your Raspberry Pi 4 to use external PCI-Express cards, check out the RPi4-PCIe-Bridge GitHub repo. There you can find pinout information on the VL085 and the EAGLE design files for the Bridge “Chip.”

From  Christina Ramsey on the Tindie blog:

Who’s ready for 2021!?

It’s time to celebrate the New Year! There are a ton of great kits and products available on Tindie to get 2021 started on the right foot.

Why not celebrate New Year’s Eve with an awesome and overly sized LED! This novelty Giant LED is ten times the scale model of a regular LED.

If you can’t wait until the clock strikes midnight on New Year’s Eve, why not create a clock so you’ll know exactly when to celebrate! This IV11 VFD Tube Clock DIY Soldering KIT can be purchased as a kit or preassembled and can be used to display the time, date, or Lunar date.

Happy New Year from all of us here at Tindie! We hope the next year is filled with good times and all the projects you could ever want to create!

I've seen a few people talking about an "Advent" calendar of making.

I wonder if it's feasible to design a new PCB each day for a month…

My biggest concern is if I even have 31 PCB ideas… 😬😅

— Greg (@GregDavill) December 1, 2020

The talented Greg Davill took on the challenge of designing an average of 1 circuit board design and layout per day for 31 days in December.

Advent Calendar of Circuits 2020

1. gdpi SYZYGY pod featuring 2x digital video ports
2. resonance Addon board for card10 to add video output
3. meiji-led-ring Illuminator to fit around the front of a microscope
4. pcie_x4 SYZYGY pod creating a PCIe x4 add-in card
5. icebreaker++ icebreaker FPGA board, upgraded with an ECP5
6. pcie_x1 SYZYGY pod creating a compact PCIe x1 add-in card
7. arm-watch New ARM based controller for the Casio CA-53W watch
8. syzygy-sgmii Gigabit ethernet using an SGMII based PHY
9. hdmi-si HDMI breakout board
10. quad-7segment PMOD with a quad 7segment
11. syzygy-breakout Breakout board for a standard SYZYGY connector
12. icebreaker++-ram icebreaker FPGA board, upgraded with an ECP5 (+extra RAM)
13. sd-dummy Dummy SD card to connect to a host system via SDIO
14. gpdi-serdes GPDI using the serdes
15. rpi-hq-camera Connector for the Raspberry Pi HQ camera
16. syzygy-pmod SYZYGY to PMOD adapter
17. pmod-gnss GNSS PMOD, GPS + Glonass
18. led-panel Breakout for some White LEDs
19. syzygy-txr-breakout SYZYGY TXR4 to SMA connectors
20. syzygy-dual-atto320 SYZYGY to dual Atto320 LWIR sensors
21. syzygy-rgb888-lcd SYZYGY 5″ 800×480 LCD panel
22. memory-lcd-wing minimal wing for OrangeCrab
23. syzygy-flir-tau2 SYZYGY tau2 LWIR core
24. syzygy-flir-boson SYZYGY boson LWIR core
25. SCD30-3d-model 3d model for the SCD30 CO2 Sensor
26. esp32s2-co2-monitor ESP32s2 + Sharp memory LCD + CO2 Monitor
27. jtag-programmer FT232H based JTAG programmer
28. ECPBreaker ECP5 based icebreaker update, FX2 HS USB + SYZYGY
29. esp32s2-lepton Small ESP32 based thermal camera
30. esp32s2-breakout ESP32S2 + Sharp memory LCD
31. syzygy-epc901 SYZYGY breakout with an EPC901 CCD + 50MSps ADC

Day 28: ECPBreaker?
I'm still not sure about the name.

Another variant of the icebreaker, but with an ECP5, this time it uses an FX2 USB controller, and includes HyperRAM and a SYZYGY connector with adjustable VCCIO.https://t.co/oDLDTol9OL pic.twitter.com/I23INgpPXd

— Greg (@GregDavill) December 28, 2020

Day 5: icebreaker++, the icebreaker fpga design upgraded with an ECP5.https://t.co/KHi8CAm621 pic.twitter.com/7pB2vewsmk

— Greg (@GregDavill) December 5, 2020