Welcome back to Elektor Lab Notes! Every few weeks, our engineers and busy editors post a few lab notes and updates about new DIY electronics projects, industry news, and helpful engineering tips. In this edition of Lab Notes, we present updates about eXpansion Boards, LoRa, Raspberry Pi, wireless loudspeakers, a few notes about the upcoming Circuit Special edition, and more. Please share your thoughts in the Discussion section at the bottom of this page. You can post your own lab notes and let us know what you are working on at your electronics workbench!

Saad Imtiaz (Senior Engineer, Elektor)

New Developments in Expansion Boards and LoRaWAN Projects

Elektor's eXpansion Board: I've been busy developing Elektor's eXpansion Board, designed to enhance the capabilities of the Seeed Studio XIAO microcontrollers. This board significantly expands the XIAO's I/O options, offering six I2C connections (four with Grove connectors and two Qwiic), as well as all the IOs provided by the XIAO, including SPI and UART connectors. This expansion board is set to become my go-to tool for future projects due to its versatility and comprehensive connectivity options. Detailed coverage of this board will be featured in the upcoming editions of Elektor Magazine, so stay tuned for more information.
 


LoRaWAN Project: I've also started an exciting new project I've been eager to tackle: a Solar-Powered LoRaWAN node designed for agriculture and greenhouse applications. This project aims to create a versatile base LoRaWAN sensor node that can be easily expanded with additional sensors as needed. All electronics will be housed in custom 3D-printed enclosures to ensure durability and adaptability. The primary goal is to develop a robust and flexible LoRaWAN solution that can be tailored for various applications, providing a powerful tool for modern agriculture.

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Jean-François Simon (Engineer, Elektor)


LoRa Without LoRa Hardware: LoRa is an advanced wireless communication protocol, coupled with complex transceivers that generate “chirps”, which are variable-frequency signals (moving either upwards or downwards) used to encode several bits at a time while spreading the spectrum, resulting in a better combination of throughput and range. So, to communicate with commercial LoRa equipment, you need to use an official compatible transceiver... Right? In this video, CNLohr does the opposite.
 
 

He set himself the challenge of exploring how far LoRa packets can be broadcast without a proper LoRa chip, with just a standard microcontroller. When a square wave is generated by toggling a pin between its high and low states, a fundamental signal is generated at frequency f, but also harmonics at frequencies 3*f, 5*f, 7*f, etc. What if one of these harmonics falls right into the LoRa band? By carefully toggling a pin, Charles successfully sent LoRaWAN messages to a commercial LoRa gateway several hundred meters away. His experiment involved various microcontrollers, including the CH32V203 and ESP32-S2, and tested in multiple environments to achieve different distances. The amount of trial and error, reverse engineering, and creative problem-solving skills needed is absolutely insane. Thank you, Charles — a truly inspirational video.

Transforming A Raspberry Pi Into A Remote: The previous project reminded me of the rpitx project developed by F5OEO. It’s a library that lets you do the same kind of thing on a Raspberry Pi, also exploiting the principle of harmonic generation. It’s very interesting from a scientific and technical point of view, but obviously it’s an experimental project. No need to remind you that it is forbidden to transmit without an amateur radio license and without a highly selective bandpass filter, so as to transmit only in the authorized band, at a power lower than the maximum threshold authorized by law. It’s up to every reader to make sure they’re using their Raspberry Pi legally. The creator of the River’s Educational Channel on Youtube uses it in his excellent two-part project. In the first part, he decodes the data frames used to control a ceiling fan using a cheap SDR dongle, and in the second part he uses rpitx to control the fan directly from the Raspberry Pi. A fun, well-documented project. You can also find related articles on his site here and here.
 
Warning: Don't do this!
Clone or not? When you buy, for example, an “Arduino” (Pro Mini, Nano, etc) on eBay, Amazon, Aliexpress, etc for just a few dollars, there’s a very high probability that it doesn’t contain a genuine ATmega328p (for example) from Microchip, but a clone from another Chinese company. The LGT8F328P is one example, but there are probably others. Functionally, they’re hard to spot because they behave in every way like the original component, and the Arduino IDE can’t tell the difference. Only a few details can sometimes tip you off, such as a current in deep sleep that’s different from what you expected, for example. 
 
Are all Pro Minis created equal?
So, how can you tell? Unless you decap the IC with nitric acid (don’t try this at home, kids) and have a good microscope to inspect the die, it's not easy. Kevin Darrah proposes an interesting method. Using the boot_signature_byte_get() function defined in avr/boot.h, he can read the specific memory containing the microcontroller’s signature. It turns out that all the bytes in this memory sector can actually be read between addresses 0x00 and 0x1F. In the case of a cloned component (even if functionally identical), three specific “signature bytes” are identical to that of a genuine ATmega328, but not the other neighboring values. I’ve reproduced the experiment, and here’s the “extended signature” of a genuine ATmega328 from an official Arduino Pro Mini from SparkFun. My other “Arduino compatible” boards (branded Robotdyn, from 2019) had similar signatures, so it looks like they have genuine parts too.
 
Output of Kevin's test program on a genuine ATmega328

Jens Nickel (Editor-in-chief, Elektor Magazine)

Remote control for wireless loudspeakers: My friend Marco and I have made significant progress on our pet project. We have worked on the boxes dedicated to volume control, and built three of them. The box contains an ESP32-S3 controller, a small motor controller PCB, and two custom-designed PCBs: one for the Alps motor potentiometer and another for an external ADC to sense the resistance of the motor potentiometer, thus giving feedback to the ESP32. Additionally, there is a LED bar and an IR receiver at the front side.
 

One box described above, a bicycle battery, an amplifier, and a wireless audio receiver, were housed in a grey outer box with a power switch. To keep costs down, we used a €15 electrical enclosure with minor modifications and used hot-glue to attach the internal components. Believe me, finding a reliable switch for 40 V DC was quite a challenge! 
 


Each of these three large gray boxes can supply power and control the volume of one loudspeaker or subwoofer. To have a high-quality, high-power audio system to showcase, I recently purchased a JBL 218S subwoofer, and I am thrilled with it. We are eagerly awaiting good weather in Cologne to make the first field tests with the entire system!

A current measurement box and a destroyed shunt resistor: The project also involves making other modules, such as one for measuring current, power, and energy to determine the remaining charge of Li-Ion batteries. Each of these modules features its own MQTT-speaking ESP32, allowing for diverse applications (we know that not many typical Elektor readers will need to power loud audio equipment in the field :-) ). For our current measurement module, I initially experimented with an INA169 breakout board and my colleague Saad's AmpVolt PCB, which worked well for 12 V and a relatively small Class-D amplifier. However, when connected to the 36-V battery and the much more powerful Nobsound G2 PRO, the higher currents, especially at power-on, caused issues. After some strange measurements, I discovered that the shunt resistor on the INA169 breakout board had a value of several tens of kΩ. I then ordered a 10-A Hall sensor module from the Grove system, which resolved the issue. With no music playing, the amp draws around 3 W. It's always amazing to me how the volume increases with each additional watt. In fact, in my living room, I risk damaging my ears when the system consumes 6 W of power per loudspeaker—not to mention disturbing the neighbors.

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C. J. Abate (Content Director, Elektor)

Elektor's engineers and editors have been busy since our last Lab Notes update. In particular, we've been working hard on the Circuit Special 2024. We've also been updating our topic pages on the website. Let's consider each one.

Circuit Special Update

Here are some of the circuits and projects you'll find in the issue. 

  • A new Elektor Classic circuit: a surf synthesize! The design is an advanced sea sound generator. It functions as a true analog music synthesizer, adhering to the principles of voltage-controlled subtractive sound synthesis popularized by pioneers like Robert Moog (think of the Elektor Formant). While it lacks a voltage-controlled oscillator (VCO) because it uses a noise generator as its sound source, it features a voltage-controlled filter (VCF), a voltage-controlled amplifier (VCA), and three low-frequency oscillators (LFO).
 
Surf Synthesizer
  • The "Jack-In and Jack-Out Project": In an audio chain, it can be advantageous to have an insertion point for additional signal-conditioning devices, such as a dynamics compressor/expander, reverb generator, or other audio effects. This design simplifies the integration of these devices and ensures loop continuity when they are not in use.
 
Jack-In and Jack-Out Project
 
  • An Arduino-controlled classic code breaking game: Experience the classic Mastermind game like never before! Originally captivating millions since its 1970s debut, Mastermind has been reimagined with the latest technology, featuring Arduino and WS2812 LEDs for a fresh, modern twist. Immerse yourself in a realm of logic and strategy with two innovative new versions, crafted to challenge both seasoned players and newcomers alike. Rediscover the excitement and complexity of this legendary code breaking game in a whole new light.
 
Circuit for Mastermind

We are preparing dozens more. The issue will hit newsstands in August 2024! Until then, you can enjoy last year's Circuit Special.

Topic Pages

We've selected 10 overarching topics to cover year round, and each has its own webpage. On each page, you'll find various content relating to the topic and its subcategories: DIY electronics projects, background articles, engineering tutorials, design tips, interviews, news, and product reviews. Check them out.
 
Bookmark your favorites and tune in for regular updates, new articles, and exciting DIY electronics projects. 

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