New Part Day

41 Articles

New Part Day: Pynq Zynq

November 4, 2016 by 47 Comments

FPGAs are the future, and there’s a chip out there that brings us the future today. I speak, of course, of the Xilinx Zynq, a combination of a high-power ARM A9 processor and a very capable FPGA. Now the Zynq has been made Pynq with a new dev board from Digilent.

The heart of this board, is, of course, the Xilinx Zynq packing a Dual-core ARM Cortex A9 processor and an FPGA with 1.3 Million reconfigurable gates. This is a dev board, though, and with that comes memory and peripherals. To the board, Digilent added 512MB of DDR3 RAM, a microSD slot, HDMI in and out, Ethernet, USB host, and GPIOs, some of which match the standard Arduino configuration.

This isn’t the first Zynq board out there by any measure. Last year, [antti] had a lot of fun with the Zynq and created the ZynqBerry, a Zynq in a Raspberry Pi form factor, and a Zynq Arduino shield. Barring that, we’ve seen the Zynq in a few research projects, but not so much in a basic dev board. The Pynq Zynq is among the first that will be produced in massive quantities.

There is, of course, one downside to the Pynq Zynq, and that is the price. It’s $229 USD, or $65 with an educational discount. That’s actually not that bad for what you’re getting. FPGAs will always be more expensive than an SoC stolen from a router or cell phone, no matter how powerful it is. That said, putting a powerful ARM processor and a hefty FPGA in a single package is an interesting proposition. Adding HDMI in and out even more so. Already we’ve seen a few interesting applications of the Zynq like synthesizers, quadcopters, and all of British radio. With this new board, hopefully a few enterprising FPGA gurus will pick one up and tell the rest of us mere mortals how to do some really cool stuff.

NextThingCo Introduces C.H.I.P. Pro, GR8 System On Module

October 12, 2016 by 71 Comments

NextThingCo, makers of the very popular C.H.I.P. single board Linux computer, have released the latest iteration of their hardware. It’s the C.H.I.P. Pro, an SBC designed to be the embedded brains of your next great project, product, or Internet of Things thing.

The C.H.I.P. Pro features an Allwinner R8 ARMv7 Cortex-A8 running at 1 GHz, a MALI-400 GPU, and either 256 MB or 512 MB of NAND Flash. The Pro also features 802.11 b/g/n WiFi, Bluetooth 4.2, and is fully certified by the FCC. This board will be available in December at supposedly any quantity for $16.

The design of the C.H.I.P. Pro is a mix between a module designed to be installed in a product and a single board computer designed for a breadboard. It features castellated edges like hundreds of other modules, but the design means that assembly won’t be as simple as throwing down some paste and reflowing everything. The C.H.I.P. Pro features parts on two sides, making reflow questionable and either 0.1″ headers or a cutout on a PCB necessary. As a single board computer, this thing is small, powerful, and a worthy competitor to the Raspberry Pi Zero. A C.H.I.P. Pro development kit, consisting of two C.H.I.P. Pro units, a ‘debug’ board, and headers for breadboarding, is available for $49, with an estimated ship date in December.

A $16 Linux module with WiFi, Bluetooth, and no NDA is neat, but perhaps a more interesting announcement is that NextThingCo will also be selling the module that powers the C.H.I.P. Pro.

The GR8 module includes an Allwinner R8 ARMv7 Cortex-A8 running at 1 GHz, a MALI-400 GPU, and 256 MB of DDR3 SDRAM. Peripherals include TWI, two UARTS, SPI (SD cards support is hacked onto this), two PWM outputs, a single 6-bit ADC, I2S audio, S/PDIF, one USB 2.0 Host and one USB 2.0 OTG, and a parallel camera interface. This isn’t really a chip meant for video out, but it does support TV out and a parallel LCD interface. A limited datasheet for the GR8 is available on the NextThingCo GitHub.

Putting an entire Linux system on a single BGA module must draw comparisons to the recent release of the Octavo Systems OSD355X family, best known to the Hackaday audiences as the Beaglebone on a chip. Mechanically, the Octavo chip will be a bit easier to solder. Even though it has almost twice as many balls as the GR8, 400 on the Octavo and 252 on the GR8, the Octavo has a much wider pitch between the balls, making escape routing much easier.

Comparing peripherals between the OSD355X and GR8, it’s a bit of a wash, with the OSD coming out slightly ahead with Ethernet, more RAM and fancy TI PRUs. Concerning pricing, the GR8 wins hands down at $6 per chip in any quantity. That’s significantly less than the OSD355X.

The original C.H.I.P. has been exceptionally well received by the community NextThingCo is marketing to, despite the community’s distaste for Allwinner CPUs, cringeworthy PR, and questions concerning the true price of the C.H.I.P.. The C.H.I.P. Pro will surely see more than a few uses, but the GR8 is the real story here. A jellybean part that contains an entire Linux system has been the fevered dream of a madman for years now. The GR8 makes putting the power of open software into any project much easier, and we can’t wait to see the applications it allows.

New Part Day: Wireless BeagleBones On A Chip

September 27, 2016 by 27 Comments

The BeagleBone is a very popular single board computer, best applied to real-time applications where you need to blink LEDs really, really fast. Over the years, the BeagleBone has been used for stand-alone CNC controllers, the brains behind very large LED installations, and on rare occasions has been used to drive CRTs. If you just want a small Linux board, get a Pi. If you want to do something interesting with hardware, get a BeagleBone.

The BeagleBone ecosystem has grown a lot in the last year, from the wireless and Grove connector equipped BeagleBone Green, the robotics-focused BeagleBone Blue, the Zoolander-inspired Blue Steel. Now there’s a new BeagleBone, built around a very interesting System on Module introduced earlier this year.

The new board is called the BeagleBone Black Wireless, and it brings to the table all you know and love about the BeagleBone. There’s a 1GHz ARM355x with two 32-bit 200MHz PRUs for the real-time pin toggling. RAM is set at 512MB, with 4GB of eMMC Flash and Debian pre-installed, and a microSD card for larger storage options. The new feature is wireless connectivity: a TI WiFi and Bluetooth module with provisions for 802.11s replaces the old Ethernet connector.

Taken at face value, the new BeagleBone Black Wireless deserves a mention — it’s a BeagleBone with wireless — but isn’t particularly noteworthy. But when you get to the gigantic brick of resin dropped squarely in the middle of the board does the latest device in the BeagleBone family become very, very interesting. The System on Module for this version of the BeagleBone is the BeagleBone On A Chip released a few months ago. The Octavo Systems OSD335x is, quite literally, a BeagleBone on a chip. It’s a BGA with big balls, making it solderable with hand-applied solder paste and a toaster oven reflow conversion. In fact, the BeagleBone Wireless was designed by [Jason Kridner] in Eagle as a 6-layer board. It’s still a bit beyond the standard capabilities of OSHPark, but the design can still be cut down, and shows how this BeagleBone on a Chip can be applied to other Open Hardware projects.

New Part Day: The ESP32 Has Been Released

September 5, 2016 by 92 Comments

A few years ago, a strange little chip showed up on Seeed Studio one day. It was the ESP8266, originally sold as a serial to WiFi adapter. Since then, the microcontroller in this wee WiFi module was discovered, and the ESP8266 has been the breakout module for hundreds of Internet of Thing modules, and other wireless baubles.

The company behind the ESP8266, Espressif, wasn’t sitting on their laurels for the last few years. They’ve been working on a followup to the ESP8266. It’s the ESP32, and it’s faster, has more peripherals, better WiFi, and Bluetooth LE. Since Christmas, we’ve been ogling this chip. Now, it’s finally out. You can buy an ESP32 right now. Consider the ESP32 released.

Almost exactly two years ago, the forerunner of the ESP32 was released, allowing anyone to blink a LED from the Internet for five dollars. There was a catch with the release of the ESP8266, and that was documentation. Documentation in English did not exist, and it took Espressif a while to realize the hit they had on their hands. Even now, with a proper English datasheet from Espressif, we don’t know if the ESP8266 has 5V tolerant pins. Documentation was an issue for the ESP8266, but it didn’t really matter because someone on the Internet figured it out.

History doesn’t repeat itself, but it is the franchise with the most reboots. There’s some documentation for the ESP32, but it’s far from complete. There’s a CAN bus peripheral in the ESP32, but no one knows what pins it’s attached to. There are some secrets hidden away, but no one is at liberty to discuss them. No one outside Espressif has any idea if the specs are real. This will, of course, change in the next month or so, but only due to the tireless work of electronics enthusiasts the world over.

Right now, there are several listings on the usual online outlets including Espressif’s Taobao shop and Seeed Studio offering either bare ESP32 chips or modules based on this WiFi Bluetooth wonder. These modules include the ESP-Wroom-32 (PDF) that is seemingly based on the ESP31 test modules released late last year and the ESP3212, a module based on the popular ESP8266-12. There are also bare chips floating about.

As far as any new information regarding the ESP32 is concerned, don’t expect much. It’s released, though, and in a month or so the work of documenting this supposed wonderchip will begin.

Although they’re not available to everyone quite yet, we have two ESP-32 modules in hand, and [Elliot] is currently slogging through installing the toolchain and getting everything working. Watch this space, because we’re going to have an Introduction to the ESP-32 post up shortly.

New Part Day: ATtiny102 And 104

August 1, 2016 by 89 Comments

Atmel put out some new, small microcontroller chips early this year, and we’re just now starting to think about how we’d use them. The ATtiny102 and ATtiny104 (datasheet) sell for about a buck (US) and come in manageable SOIC packages with eight and fourteen pins respectively. It’s a strange chip though, with capabilities that fit somewhere between the grain-of-rice-sized ATtiny10 and the hacker-staple ATtiny25-45-85 series.

The ATtiny104 has a bunch of pins for not much money. It’s got a real hardware USART, which none of the other low-end AVRs do, and it’s capable of SPI in master mode. It has only one counter, but it’s a 16-bit counter, and it’s got the full AVR 10-bit ADC instead of the ATtiny10’s limited 8-bit ADC. The biggest limitation, that it shares with the ATtiny10, is that it has only 1 KB of program flash memory and 32 bytes (!) of RAM. You’re probably going to want to program this beast in assembler.

Read on for more reviews, and check out [kodera2t]’s video review at the end.

Continue reading “New Part Day: ATtiny102 And 104”

New Part Day: Tiny, Tiny Bluetooth Chips

September 30, 2015 by 87 Comments

The future of tiny electronics is wearables, it seems, with companies coming out with tiny devices that are able to check your pulse, blood pressure, and temperature while relaying this data back to your phone over a Bluetooth connection. Intel has the Curie module, a small System on Chip (SoC) meant for wearables, and the STM32 inside the Fitbit is one of the smallest ARM microcontrollers you’ll ever find. Now there’s a new part available that’s smaller than anything else and has an integrated Bluetooth radio; just what you need when you need an Internet of Motes of Dust.

The Atmel BTLC1000 is a tiny SoC designed for wearables. The internals aren’t exceptional in and of themselves – it’s an ARM Cortex M0 running at 26 MHz. There’s a Bluetooth 4.1 radio inside this chip, and enough I/O, RAM, and ROM to connect to a few sensors and do a few interesting things. What makes this chip so exceptional is its size – a mere 2.262mm by 2.142mm. It’s a chip that can fit along the thickness of some PCBs.

To provide some perspective: the smallest ATtiny, the ‘tiny4/5/9/10 in an SOT23-6 package, is 2.90mm long. The smallest PICs are similarly sized, and both have a tiny amount of RAM and Flash space. The BTLC1000 is surprisingly capable, with 128kB each of RAM and ROM.

The future of wearable devices is smaller, faster and more capable devices, and with a tiny chip that can fit on the head of a pin, this is certainly an interesting chip for applications where performance can be traded for package size. If you’re ready to dive in with this chip the preliminary datasheets are now available.

New Part Day: The ESP8266 Killer

July 13, 2015 by 183 Comments

Around this time last year we first heard of the ESP8266 WiFi module. It’s still a great little module, providing WiFi connectivity for all those Internet of Things things at a price point of just $5. It’s an attractive price for a great module with a huge community pumping out a lot of projects for the platform.

Now there’s a new kid on the block. It’s called the EMW3165, and like the ESP it provides WiFi connectivity for a bunch of wireless projects. It’s much, much more capable with an STM32F4 ARM Coretex M4 microcontroller, a ‘self hosted’ networking library, more RAM, more Flash, and more GPIOs. How much, you’re probably asking yourself. It’s a dollar more than the ESP8266.

The datasheet for the module goes over all the gritty details. While this chip has 3.6V I/Os, there are some 5V tolerant pins – a boon for the Arduino crowd. It’s also surprisingly low power for something that connects to an 802.11n network. The real bonus here is the STM32F4 core – that’s a very, very powerful microcontroller, and if you want a 2-component WiFi webcam build, this is the part you should use. There will be a lot of interesting builds using this part. It’s also passed FCC certification. Very cool.