Ulanzi TC001 is an LED pixel clock consisting of 256 individual addressable RGB LEDs (8x32) with built-in battery, buzzer, light, temperature and humidity sensor. The integrated rechargeable battery offers a runtime of up to 5 hours. The WiFi connection to the clock is made via an ESP32 chip. Ulanzi TC001 uses an ESP32-WROOM-32D module.
Features
Pixelated message display
Simultaneous Display of the Number of Followers: Fan growth is immediately visible, suitable for YouTube, Bilibili, and Weibo.
Pomodoro Clock Design: Manage your own time more scientifically.
Explore unlimited possibilities: Multiple programs need to be installed through the control server to achieve more functions.
Awtrix Makes it Better: Awtrix simulator in TC001’s firmware simulates an Awtrix matrix and allows you to control the clock using a standard Awtrix host.
Hi-tech and stunning appearance: Modeling simple atmosphere, LED full-color pixel screen with better imaging.
Built-in 4400 mAh battery with up to 5 hours of battery life.
Specifications
Number of LEDs: 256 (8x32)
Operating voltage: 3.7 V
Power: 3 W
Battery capacity: 4400 mAh
Interface: USB-C
Dimensions: 200.6 x 70.3 x 31.9 mm
Weight: 283 g
Inbegrepen
Ulanzi TC001 Smart Pixel Clock
USB cable
Manual
Downloads
Firmware
Enter the world of robotics without any complications and at a reasonable price with the Car Kit 01 for Arduino. This is a kit that can be used as a basic framework for a car/robot. The set is very easy to assemble and ready to go in no time. The supplied geared motors (with double-ended shaft) can be operated in a voltage range of 3 to 9 volts. The speed varies between 90 and 300 revolutions per minute. The torque (gf/cm) between 800 and 1200. The Car Kit is compatible with all Arduino boards. Note: You will also need to add other components such as a power source (batteries) and a controller such as an Arduino with a motor controller. The base plate already contains the holes for mounting an Arduino. User Manual
The HuskyLens AI Camera intuitive design allows the user to control different aspects of the camera just by pressing buttons. You can start and stop learning new objects and even switch between algorithms from the device.
To further reduce the need to be connected to a PC the HuskyLens AI Camera comes with a 2-inch display so you can see what's going on in real time.
Specifications
Processor: Kendryte K210
Image Sensor: OV2640 (2.0 Megapixel Camera)
Supply Voltage: 3.3~5.0 V
Current Consumption (TYP): 320 mA @ 3.3 V, 230 mA @ 5.0 V (face recognition mode; 80% backlight brightness; fill light off)
Connection Interface: UART, I²C
Display: 2.0-inch IPS screen with 320x240 resolution
Built-in Algorithms: Face Recognition, Object Tracking, Object Recognition, Line Tracking, Color Recognition, Tag Recognition
Dimension: 52 x 44.5 mm (2.05 x 1.75')
Included
1x HuskyLens Mainboard
6x M3 Screws
6x M3 Nuts
1x Small Mounting Bracket
1x Heightening Bracket
1x Gravity 4-Pin Sensor Cable
YDLIDAR SDM18 is a high-performance single-point LiDAR. Based on the principle of ToF, it is equipped with related optics, electricity, and algorithm design to achieve high-precision laser distance measurement and outputting high frame rate point cloud data of the scanning environment. It can be used for UAV alt-hold, robot obstacle avoidance and navigation, etc.
Specifications
High Ranging frequency: 50-250 Hz
Range Distance: 0.2-18 m
FDA Class I eye safety standard
Support UART and I²C interfaces
Dimensions: 21 x 15 x 7.87 mm
Weight: 1.35 g
Applications
UAV alt-hold and obstacle avoidance
Robot obstacle avoidance
Intelligent equipment obstacle avoidance
Navigation and obstacle avoidance of home service robots / robot vacuum cleaners
Downloads
Datasheet
User Manual
Development Manual
SDK
Tool
ROS
The AxiDraw MiniKit 2 The AxiDraw MiniKit 2 is a special compact addition to the AxiDraw lineup. Designed for lighter-duty applications, It takes up less desk space and less storage space. It's considerably more portable, too. The AxiDraw MiniKit is also the only DIY kit model of AxiDraw that you get to assemble yourself. All other AxiDraw models ship fully assembled, tested, and ready to use.) A Mini Plotter The AxiDraw MiniKit 2 has a working area of about 6 × 4 inches (150 × 100 mm): Big enough to be useful for a wide range of applications including short notes, postcards, and addressing envelopes. It's also ideally suited for use as a signature machine, for signing checks, letters, books, or artwork. Applications The AxiDraw is an extremely versatile machine, designed to serve a wide variety of everyday and specialized drawing and writing needs. You can use it for almost any task that might normally be carried out with a handheld pen. It allows you to use your computer to produce writing that appears to be handmade, complete with the unmistakable appearance of using a real pen (as opposed to an inkjet or laser printer) to address an envelope or sign one's name. And it does so with precision approaching that of a skilled artist, and – just as importantly – using an arm that never gets tired. Specifications Performance Usable pen travel (inches): 6.3 × 4 inches Usable pen travel (millimeters): 160 × 101 mm Vertical pen travel: 0.7 inch (17 mm) Maximum XY travel speed: 10 inches (25 cm) per second Native XY resolution: 2032 steps per inch (80 steps per mm) Reproducibility (XY): Typically better than 0.005 inches (0.1 mm) at low speeds Physical Major structural components are machined, extruded, or folded aluminum, manufactured and anodized in the USA. Holds pens and other drawing instruments up to 5/8' (16 mm) diameter and 25 g weight. Overall dimensions: Approximately 14.25 × 9.25 × 4.25 inches (36 × 23.5 × 11 cm) Maximum height with cable guides: Approximately 9 inches (23 cm) Footprint: Approximately 13.5 × 1.7 inches (35 x 4.5 cm) Weight: 3.2 Lb (1.5 kg) Software Compatible with Mac, Windows, and Linux Drive directly from within Inkscape, using the AxiDraw extension Comprehensive user guide available for download
Driver software software free to download and open source Internet access is required to download software Additionally, AxiDraw Merge software available at no cost to AxiDraw owners. Programming interfaces Note: Programming is not required to use the AxiDraw Stand-alone command line interface (CLI) Available AxiDraw Python API
RESTful API available for full machine control, stand-alone or accessible by running RoboPaint in the background. Simplified 'GET-only' API available as well, for use in programming environments (such as Scratch, Snap) that permit only retrieval of URLs. Direct EiBotBoard (EBB) command protocol available for use in any programming environment that supports communication with USB-based serial ports. Code that generates SVG files can also be used to (indirectly) control the machine. Included All parts and materials necessary to build the AxiDraw MiniKit 2 writing and drawing machine. Multi-plug power supply with EU adapter USB cable Small Easel (Board and clips) for paper holding Tools needed Scissors or diagonal cutters Small Phillips-head screwdrivers: #0 and #1 sizes Small flat-head screwdriver: 2 mm or 5/64' blade width recommended Miniature pliers (Recommended but not required) Small hobby knife (Recommended but not required) Downloads User Guide
M5Stamp Fly is a programmable open-source quadcopter, featuring the StampS3 as the main controller. It integrates a BMI270 6-axis gyroscope and a BMM150 3-axis magnetometer for attitude and direction detection. The BMP280 barometric pressure sensor and two VL53L3 distance sensors enable precise altitude hold and obstacle avoidance. The PMW3901MB-TXQT optical flow sensor provides displacement detection.
The kit includes a buzzer, a reset button, and WS2812 RGB LEDs for interaction and status indication. It is equipped with a 300 mAh high-voltage battery and four high-speed coreless motors. The PCB features an INA3221AIRGVR for real-time current/voltage monitoring and has two Grove connectors for additional sensors and peripherals.
Preloaded with debugging firmware, the Stamp Fly can be controlled using an Atom Joystick via the ESP-NOW protocol. Users can choose between automatic and manual modes, allowing for easy implementation of functions like precise hovering and flips. The firmware source code is open-source, making the product suitable for education, research, and various drone development projects.
Applications
Education
Research
Drone development
DIY projects
Features
M5StampS3 as the main controller
BMP280 for barometric pressure detection
VL53L3 distance sensors for altitude hold and obstacle avoidance
6-axis attitude sensor
3-axis magnetometer for direction detection
Optical flow detection for hovering and displacement detection
Buzzer
300 mAh high-voltage battery
Current and voltage detection
Grove connector expansion
Specifications
M5StampS3
ESP32-S3@Xtensa LX7, 8 MB Flash, WiFi, OTG\CDC support
Motor
716-17600kv
Distance Sensor
VL53L3CXV0DH/1 (0x52) @ max 3 m
Optical Flow Sensor
PMW3901MB-TXQT
Barometric Sensor
BMP280 (0x76) @ 300-1100hPa
3-axis Magnetometer
BMM150 (0x10)
6-axis IMU Sensor
BMI270
Grove
I²C+UART
Battery
300mAh 1S high-voltage lithium battery
Current/Voltage Detection
INA3221AIRGVR (0x40)
Buzzer
Built-in Passive Buzzer @ 5020
Operating temperature
0-40°C
Dimensions
81.5 x 81.5 x 31 mm
Weight
36.8 g
Included
1x Stamp Fly
1x 300 mAh high-voltage Lithium battery
Downloads
Documentation
The Analog Thing V1.2 (in short THAT) is a high-quality, low-cost, open-source, and not-for-profit cutting-edge analog computer designed for desktop use to solve (sets of) differential equations. With its patch panel instead of keyboard, mouse, and monitor, its user interface differs noticeably from those of its digital stored-program cousins. The patch panel is divided into groups of analog computing elements such as integrators, summers, and multipliers.
THAT allows modeling dynamic systems with great speed, parallelism, and energy efficiency. Its use is intuitively interactive, experimental, and visual. It bridges the gap between hands-on practice and mathematical theory, integrating naturally with design and engineering practices such as speculative trial-and-error exploration and the use of scale models.
Dynamic system modeling on THAT can serve a variety of valuable purposes. It may help understand what is (models of), or it may help bring about what should be (models for). It may be used to explain in educational settings, to imitate in gaming, to predict in the natural sciences, to control in engineering, or it may be pursued for the pure joy of it!
THAT can be used with various kinds of oscilloscopes, such as conventional cathode ray tube oscilloscopes, digital oscilloscopes, and USB oscilloscopes in conjunction with PCs.
Features
5 Integrators – Circuits that perform integration over time.
4 Summers – Circuits that add inputs continously.
2 Comparators – Circuits that compare inputs to support conditional functions.
Master/Minion Ports – Interfaces that allow daisy-chaining multiple THATs to create arbitrarily large programs.
8 Coefficient Potentiometers – Rotary knobs to provide user-defined inputs.
2 Multipliers – Circuits that multiply inputs continously.
Panel Meter – A digital panel meter for precision measurements of values and timing.
Hybrid Port – An interface for controlling THAT digitally to develop analog-digital hybrid programs.
Included
1x RCA-RCA cable
30x Patch cables
6x Adhesive feet
1x Master to minion ribbon cable
1x USB-A to USB-C cable
1x Quick-start manual
Required
USB power supply
BNC adapters/cables to connect an oscilloscope
Downloads
First Steps
Documentation
Programmable Robot Kit with 344 Parts
variAnt runs and acts almost like its natural role model. Its patented walking mechanism was especially developed for the fine-boned anatomy of an insect and is driven by compact micro-geared motors.
The autonomous robot ant explores its entire environment with the help of 12 analogue sensors. This allows it to detect obstacles, markings, movements or light sources based on the slightest differences in brightness.
The control unit in the rear, which is equipped with a nano-board, offers a wide range of flexible connection options in combination with the breadboard in the head. After the exciting setup, ready-made and expandable code modules ensure an easy and quick introduction to Arduino programming up to the first experiments with artificial intelligence.
The kit already comes with a USB rechargeable 9 V Li-Ion battery, which supplies the robot ant with power for at least 5 hours.
Robot ant as a programmable kit
Compatible with Arduino IDE
Patented mechanics and sensors
Features of variAnt
24 high-quality acrylic parts
12 variable environmental sensors
2 reed sensors for step counting
2 freely programmable buttons
8 freely usable digital I/Os
15 pluggable status LEDs
Specifications
Content: 344 parts
Construction time: about 4-8 hours (no soldering required)
Dimensions: 25 x 22.5 x 9 cm (L x W x H)
Weight: 210/232 g (without/with battery)
Necessary tools
PC or tablet, micro-USB and USB-C cable, flat pliers, diagonal pliers, carpet knife, permanent marker
Downloads
Manual
Arduino library
The Challenger RP2040 LoRa is an Arduino/CircuitPython compatible Adafruit Feather format microcontroller board based on the Raspberry Pi Pico (RP2040) chip.The transceiver features a LoRa long range modem that provides ultra-long range spread spectrum communication and high interference immunity whilst minimizing current consumption.LoRaThe integrated module LoRa module (RFM95W) can achieve a sensitivity of over -148 dBm utilizing a low cost crystal and bill of materials. The high sensitivity combined with the integrated +20 dBm power amplifier yields industry leading link budget making it optimal for any application requiring range or robustness. LoRa also provides significant advantages in both blocking and selectivity over conventional modulation techniques, solving the traditional design compromise between range, interference immunity and energy consumption.The RFM95W is connected to the RP2040 via SPI channel 1 and a few GPIO’s that is required for signaling. A U.FL connector is used to attach your LoRa antenna to the board.
168 dB maximum link budget
+20 dBm – 100 mW constant RF output vs. V supply
+14 dBm high efficiency PA
Programmable bit rate up to 300 kbps
High sensitivity: down to -148 dBm
Bullet-proof front end: IIP3 = -12.5 dBm
Excellent blocking immunity
Low RX current of 10.3 mA, 200 nA register retention
Fully integrated synthesizer with a resolution of 61 Hz
FSK, GFSK, MSK, GMSK, LoRaTM and OOK modulation
Built-in bit synchronizer for clock recovery
Preamble detection
127 dB Dynamic Range RSSI
Automatic RF Sense and CAD with ultra-fast AFC
Packet engine up to 256 bytes with CRC
Specifications
Microcontroller
RP2040 from Raspberry Pi (133 MHz dual-core Cortex-M0)
SPI
Two SPI channels configured (second SPI connected to RFM95W)
I²C
One I²C channel configured
UART
One UART channel configured
Analog inputs
4 analog input channels
Radio module
RFM95W from Hope RF
Flash memory
8 MB, 133 MHz
SRAM memory
264 KB (divided into 6 banks)
USB 2.0 controller
Up to 12 MBit/s full speed (integrated USB 1.1 PHY)
JST Battery connector
2.0 mm pitch
On board LiPo charger
450 mA standard charge current
Dimensions
51 x 23 x 3,2 mm
Weight
9 g
Downloads
Datasheet
Design files
M5Atom Joystick is a versatile programmable dual-joystick remote controller featuring the AtomS3 as the main controller, with an STM32 handling co-processing functions.
It is equipped with two 5-way joysticks with hall sensors, two function buttons, and built-in RGB LEDs for human-machine interaction and status indication.
The device includes two high-voltage battery charging circuits. It comes pre-loaded with the Stamp Fly control firmware and communicates with Stamp Fly via the ESP-NOW protocol. The firmware source code is open-source. This product is suitable for drone control, robot control, smart cars, and various DIY projects.
Applications
Drone control
Robot control
Smart cars
DIY projects
Features
STM32F030F4P6
Equipped with M5AtomS3
Compatible with Atom Lite, Atom Matrix, AtomS3 Lite, AtomS3
Dual joysticks, dual buttons, toggle switch
WS2812 RGB LEDs
Dual high-voltage lithium battery charging circuits
Battery detection
Specifications
MCU
STM32F030F4P6
RGB
WS2812C
Charging IC
TP4067 @ 4.35 V
Battery
300 mAh
Charging Current
500 mA
Button
Left/Right Button
Buzzer
Built-in Passive Buzzer @ 5020
Operating temperature
0-40°C
Dimensions
84 x 60 x 31.5 mm
Weight
63.5 g
Included
1x Atom JoyStick
1x 300 mAh high-voltage Lithium battery
Downloads
Documentation
Build your 3D led cube and create unlimited 3D effects. The unit comes standard loaded with effects. Connect to your computer (USB) and create your own!
Features
LEDs: 5 x 5 x 5 = 125 LEDs
User programmable via USB (creation of animation/scenes)
Large amount of user programmable frames
Frames are separately dimmable
4 transition speeds
Available frames: 3200
5 levels LED dimming available
No coding skills required
Software similar to (3 x 3 x 3)
Specifications
Regulated power supply: 9 VDC (not incl.)
Power consumption: 300 mA max.
Dimensions: 110 x 110 x 150 mm
The T-Deck is a pocket-sized gadget featuring a 2.8-inch IPS LCD display (320 x 240), a mini keyboard, and an ESP32 dual-core processor. While it’s not quite a smartphone, it offers plenty of potential for tech enthusiasts. With some programming know-how, you can transform it into a standalone messaging device or a portable coding platform.
Specifications
Microcontroller
ESP32-S3FN16R8 Dual-core LX7 microprocessor
Wireless Connectivity
2.4 GHz Wi-Fi & Bluetooth 5 (LE)
Development
Arduino, PlatformlO, MicroPython
Flash
16 MB
PSRAM
8 MB
Battery ADC Pin
IO04
Onboard functions
Trackball, Microphone, Speaker
Display
2.8" ST7789 SPI Interface IPS
Resolution
320 x 240 (Full viewing angle)
Transmit power
+22 dBm
SX1262 LoRa Transceiver (Frequency)
868 Mhz
Dimensions
100 x 68 x 11 mm
Included
1x T-Deck ESP32-S3 LoRa
1x FPC antenna (868 MHz)
1x Male pin (6-pin)
1x Power cable
Downloads
GitHub
If you are looking for a simple way to learn soldering, or just want to make a small gadget that you can carry, this set is a great opportunity. Reaction game is an educational kit which teaches you how to solder, and in the end, you get to have your own small game. The goal of the game is to press the button next to the LED as soon as it turns on. With every correct answer, the game gets a bit harder – the time you have to press the button shortens. How many correct answers can you get?
It’s based on ATtiny404 microcontroller, programmed in Arduino. At its back, you’ll find CR2032 battery which makes the kit portable. There’s keychain holder as well. Soldering process is easy enough based on the mark on the PCB.
Included
1x PCB
1x ATtiny404 microcontroller
4x LEDs
4x Pushbuttons
1x Switch
4x Resistors (330 ohm)
1x CR2032 battery holder
1x Battery CR2032
1x Keychain holder
This outdoor antenna made of fiberglass is optimized for the reception of ADS-B signals on the 1090 MHz frequency. The antenna consists of a half-wave dipole with 5 dBi gain, encapsulated inside a fiberglass radome with an aluminum mounting base.
With a Raspberry Pi, an RTL-SDR and this antenna, you can receive position data from aircraft in your area for apps such as Flightradar24 or FlightAware.
Specifications
Frequency
1090 MHz
Antenna type
Dipole 1/2 wave
Connector
N female
Installation type
Mast Diam 35-60 mm (mounting bracket included)
Gain
5 dBi
SWR
≤1.5
Type of Polarization
Vertical
Maximum power
10 W
Impedance
50 Ohms
Dimensions
62.5 cm
Tube diameter
26 mm
Base antenna
32 mm
Operating temperature
−30°C to +60°C
Included
ADS-B antenna (1090 Mhz)
Mast bracket (for installation on a 35 to 60 mm diameter mast)
If you enjoy DIY electronics, projects, software and robots, you’ll find this book intellectually stimulating and immediately useful. With the right parts and a little guidance, you can build robot systems that suit your needs more than overpriced commercial systems can.
20 years ago, robots based on simple 8-bit processors and touch sensors were the norm. Now, it’s possible to build multi-core robots that can react to their surroundings with intelligence. Today’s robots combine sensor readings from accelerometers, gyroscopes and computer vision sensors to learn about their environments. They can respond using sophisticated control algorithms and they can process data both locally and in the cloud.
This book, which covers the theory and best practices associated with advanced robot technologies, was written to help roboticists, whether amateur hobbyist or professional, take their designs to the next level. As will be seen, building advanced applications does not require extremely costly robot technology. All that is needed is simply the knowledge of which technologies are out there and how best to use each of them.
Each chapter in this book will introduce one of these different technologies and discuss how best to use it in a robotics application. On the hardware side, we’ll cover microcontrollers, servos, and sensors, hopefully inspiring you to design your own awe-inspiring, next-generation systems. On the software side, we’ll cover programming languages, debugging, algorithms, and state machines. We’ll focus on the Arduino, the Parallax Propeller, Revolution Education PICAXE and projects I’ve with which I’ve been involved, including the TBot educational robot, the PropScope oscilloscope, the 12Blocks visual programming language, and the ViewPort development environment. In addition, we’ll serve up a comprehensive introduction to a variety of essential topics, including output (e.g. LEDs, servo motors), and communication technologies (e.g. infrared, audio), that you can use to develop systems that interact to stimuli and communicate with humans and other robots. To make these topics as accessible as possible, handy schematics, sample code and practical tips regarding building and debugging have been included.
Hanno Sander
Christchurch, New Zealand
Pico Cube is a 4x4x4 LED cube HAT for Raspberry Pi Pico with 5 VDC operating voltage. Pico cube, a monochromatic Green with 64 LEDs, is a fun way to learn programming. It is designed to perform incandescent operations with low energy consumptions, robust outlook, and easy installation that make people/kids/users learn the effects of LED lights with a different pattern of colors via the combination of software and hardware i.e. Raspberry Pi Pico.
Features
Standard 40 Pins Raspberry Pi Pico Header
GPIO Based Communication
64 High-Intensity Monochromatic LEDs
Individual LED access
Each Layer Access
Specifications
Operating Voltage: 5 V
Color: Green
Communication: GPIO
LEDs: 64
Included
1x Pico Cube Base PCB
4x Layer PCB
8x Pillar PCB
2x Male Berg (1 x 20)
2x Female Berg (1 x 20)
70 LEDs
Note: Raspberry Pi Pico is not included.
Downloads
GitHub
Wiki
USB-C to LoRa Dongle is a powerful and versatile LoRa device that lets you connect beyond boundaries. With its exceptional range and easy connectivity, it allows you to seamlessly communicate with devices up to 5 km away. LoRa Dongle is the perfect solution for anyone looking to establish long-range wireless communication in a variety of applications.
This dongle provides direct USB interface control, eliminating the need for a deep understanding of LoRa transmission concepts. They seamlessly connect with devices like Raspberry Pi, SBCs, PCs, and laptops, simplifying the creation of IoT LoRa gateways. The USB LoRa Dongles function as transmitters and receivers, accommodating various message formats, including text, hexadecimal, and decimal.
Features
Device with the most recent LoRa module, offering up to a 5-kilometer data transmission range and higher speeds.
Use new generation LoRa spread spectrum to ensure stable communication
Type C interface for LoRa configuration/Power
Status LED for power and data transmission
Serial TX/RX pin breakout in Header and Screw terminal form
Onboard jumper for operating mode selection
Specifications
Carrier Frequency (License Free ISM): 868 MHz
Chip: Based on SX1262 RF chip
Range: 5Km
Transmitting Power: 22 dBm
Receiving Sensitivity: -147 dbm
Data Rate: Up to 62.5 kbps
Interface: Type C
Communication Port: UART serial
Supply Voltage: 5 V
Operating Voltage: 3.3 V
Operating Temperature: -20 to 70°C
Included
1x USB-C to LoRa Dongle
1x Antenna (868 MHz)
This air monitor is specifically used for monitoring greenhouses. It detects:
Air temperature & Humidity
CO2 concentration
Light intensity
Then transmit the data via LoRa P2P to the LoRa receiver (on your desk in the room) so that the user can monitor the field status or have it recorded for long-term analysis.
This module monitors the greenhouse field status and sends all sensor data regularly via LoRa P2P in Jason format. This LoRa signal can be received by the Makerfabs LoRa receiver and thus displayed/recorded/analyzed on the PC. The monitoring name/data cycle can be set with a phone, so it can be easily implemented into the file.
This air monitor is powered by an internal LiPo battery charged by a solar panel and can be used for at least 1 year with the default setting (cycle 1 hour).
Features
ESP32S3 module onboard with the WiFi and Bluetooth
Ready to use: Power it on directly to use
Module name/signal interval settable easily by phone
IP68 water-proof
Temperature: -40°C~80°C, ±0.3
Humidity: 0~100% moisture
CO2: 0~1000 ppm
Light intensity: 1-65535 lx
Communication distance: Lora: >3 km
1000 mAh battery, charger IC onboard
Solar panel 6 W, ensure system works
Downloads
Manual
BH1750 Datasheet
SGP30 Datasheet
The LSN50 wireless part is based on SX1276/SX1278 allows the user to send data and reach extremely long ranges at low data rates. It provides ultra-long range spread spectrum communication and high interference immunity whilst minimizing current consumption. It targets professional wireless sensor network applications such as irrigation systems, smart metering, smart cities, smartphone detection, building automation, and so on.
The LSN50 MCU part uses STM32l0x chip from ST, STML0x is the ultra-low-power STM32L072xx microcontrollers incorporate the connectivity power of the universal serial bus (USB 2.0 crystal-less) with the high-performance ARM® Cortex®-M0+ 32-bit RISC core operating at a 32 MHz frequency, a memory protection unit (MPU), high-speed embedded memories (192 Kbytes of Flash program memory, 6 Kbytes of data EEPROM and 20 Kbytes of RAM) plus an extensive range of enhanced I/Os and peripherals.
The LSN50 is an open-source product, it is based on the STM32Cube HAL drivers and lots of libraries can be found on the STM site for rapid development.
Features
STM32L072CZT6 MCU
SX1276/78 LoRa Wireless Modem
Pre-load with ISP bootloader
I2C,LPUSART1,USB
18 x Digital I/Os
2 x 12bit ADC; 1 x 12bit DAC
MCU wakes up by UART or Interrupt
LoRa™ Modem
Preamble detection
Baud rate configurable
LoRaWAN 1.0.2 Specification
Software base on STM32Cube HAL drivers
Open-source hardware / software
IP66 Waterproof Enclosure
Ultra-Low power consumption
AT Commands to setup parameters
4000mAh Battery for Long term use
Applications
Wireless Alarm and Security Systems
Home and Building Automation
Automated Meter Reading
Industrial Monitoring and Control
Long-range Irrigation Systems
LoRa Spec
168 dB maximum link budget.
+20 dBm - 100 mW constant RF output vs.
+14 dBm high-efficiency PA.
Programmable bit rate up to 300 kbps.
High sensitivity: down to -148 dBm.
Bullet-proof front end: IIP3 = -12.5 dBm.
Excellent blocking immunity.
Low RX current of 10.3 mA, 200 nA register retention.
Fully integrated synthesizer with a resolution of 61 Hz.
FSK, GFSK, MSK, GMSK, LoRaTM and OOK modulation.
Built-in bit synchronizer for clock recovery.
Preamble detection.
127 dB Dynamic Range RSSI.
Automatic RF Sense and CAD with ultra-fast AFC.
Packet engine up to 256 bytes with CRC.
Built-in temperature sensor and low battery indicator.
MCU Spec
MCU: STM32L072CZT6
Flash: 192KB
SRAM: 20KB
EEPROM: 6KB
Clock Speed: 32Mhz
Absolute Maximum Ratings
VCC: 0.5 V ~ 3.9 V
Operating Tempature: -40°C ~ 85°C
I/O pins: 0.5 V ~ VCC+0.5 V
Common DC Characteristics
Supply Voltage: 1.8 V ~ 3.6 V
Operating Tempature: -40°C ~ 85°C
I/O pins: STM32L072CZT6 datasheet
Power Consumption
STOP Mode: 2.7 μA @ 3.3 V
RX Mode: 7.2 mA
TX Mode: 125 mA@ 20 dbm
Battery
Li/SOCI2 unchargable battery
Capacity: 4000 mAh
Self Discharge: < 1% / Year @ 25°C
Max continuously current: 130 mA
Max boost current: 2 A, 1 second
The FNIRSI NVS-20 is a versatile monocular night vision device, ideal for clear observation in complete darkness or low light. It offers unlimited range in weak light and up to 300 m in total darkness.
Featuring a USB port and TF card slot, it supports firmware updates and media storage. With a color screen, it performs seamlessly day or night, enabling photo capture, video recording, playback, and up to 6x electronic zoom. The NVS-20 is the ultimate tool for enhancing night vision capabilities.
Specifications
Electronic Zoom
6x
Objective Lens Diameter
25 mm
Low Light or Daytime Observation Distance
2 m~∞
Full Black Observation Distance
300 m (max)
Video Resolution
4K (3840x2160) / 2K (2560x1440) / 1080FHD (1920x1080) / 720P (1280x720) / VGA (640x480) / QVGA (320x240)
Photo Resolution
36MP / 32MP / 30MP / 24MP / 20MP / 16MP / 12MP / 10MP / 8MP / 5MP / 3MP / VGA
IR Wavelength
850 nm
Water Resistance Level
IPX6
White Balance
Automatic, Daylight, Cloudy, Tungsten Filament, Fluorescent
ISO
Auto, 100, 200, 400, 800
LCD Brightness Adjustment
High, medium, and low levels
Light Source Frequency
50 Hz / 60 Hz
Storage
32 GB TF memory card
Voltage
3.7 V
Power supply
18650 internal battery
Charging
USB-C (5 V/1 A)
Display
1.54 inch HD IPS screen
Temperature
−5~40°C
Humidity
0-80%
Languages
Chinese / Traditional / English / Japanese / Italian / French / German / Russian / Spanish / Portuguese
Dimensions
152 x 42 x 82 mm
Weight
240 g
Included
1x NVS-20 Night Vision Monocular
1x 18650 Lithium battery
1x TF memory card (32 GB)
1x USB cable
1x Manual
Downloads
Manual
Firmware FW96675
The iCEBreaker FPGA board is an open-source educational FPGA development board.
The iCEBreaker is great for classes and workshops teaching the use of the open source FPGA design flow through Yosys, nextpnr, IceStorm, Icarus Verilog, Amaranth HDL and others. This means the board is low cost and has a nice set of features to allow for the design of interesting classes and workshop exercises. At the same time it allows the user to use the proprietary vendor tools if they choose to.
After the workshop the boards can be easily used as a development board as most GPIO are exposed, broken out and configurable through jumpers on the back of the board. There is only a minimal amount of buttons and LED that can't be disconnected and used for your own purposes.
Documentation
Workshop
Plug a reader into the headers, use a Qwiic cable, scan your 125kHz ID tag, and the unique 32-bit ID will be shown on the screen. The unit comes with a read LED and buzzer, but don't worry, there is a jumper you can cut to disable the buzzer if you want. Utilizing SparkFun's handy Qwiic system, no soldering is required to connect it to the rest of your system. However, we still have broken out 0.1"-spaced pins if you prefer to use a breadboard.
Utilizing the onboard ATtiny84A, the Qwiic RFID takes the six byte ID tag of your 125kHz RFID card, attaches a timestamp to it, and puts it onto a stack that holds up to 20 unique RFID scans at a time. This information is easy to get at with some simple I²C commands.
This portable WiFi weather station is the perfect blend of functionality and style, offering real-time updates on temperature, humidity, and time – all at a single glance.
Featuring a clear digital display, the station ensures that weather and time data are always easy to read and understand. Its minimalist design integrates seamlessly into any environment, adding a touch of modern sophistication without drawing unnecessary attention.
Features
Multi-Function Display: Shows weather, atmospheric pressure, min/max temperature, wind speed, city, country/region, date, day of the week, outdoor temperature & humidity – all at a glance.
Custom GIF Animations: Upload your own GIFs for a personalized display experience.
WiFi Connectivity: Automatically connects to the Internet to retrieve real-time weather and time data.
Power Supply: USB-C
Durable Plastic Casing
Dimensions: 45 x 35 x 40 mm
The SparkFun JetBot AI Kit V3.0 is a great launchpad for creating entirely new AI projects for makers, students, and enthusiasts interested in learning AI and building fun applications. It’s straightforward to set up and use and is compatible with many popular accessories.
Several interactive tutorials show you how to harness AI's power to teach the SparkFun JetBot to follow objects, avoid collisions, and more. The Jetson Nano Developer Kit (not included in this kit) offers useful tools like the Jetson GPIO Python library and is compatible with standard sensors and peripherals; including some new python compatibility with the SparkFun Qwiic ecosystem.
Additionally, the included image is delivered with the advanced functionality of JetBot ROS (Robot Operating System) and AWS RoboMaker Ready with AWS IoT Greengrass already installed. SparkFun’s JetBot AI Kit is the only kit currently on the market ready to move beyond the standard JetBot examples and into the world of connected and intelligent robotics.
This kit includes everything you need to get started with JetBot minus a Phillips head screwdriver and an Ubuntu desktop GUI. If you need these, check out the includes tabs for some suggestions from our catalogue. Please be aware that the ability to run multiple neural networks in parallel may only be possible with a full 5V-4A power supply.
Features
SparkFun Qwiic ecosystem for I²C communication
The ecosystem can be expanded using 4x Qwiic connectors on GPIO header
Example Code for Basic Motion, Teleoperation, Collision avoidance, & Object Following
Compact form factor to optimize existing neural net from NVIDIA
136° FOV camera for machine vision
Pre-flashed MicroSD card
Chassis assembly offers expandable architecture
No soldering required
Included
64 GB MicroSD card - pre-flashed SparkFun JetBot image:
Nvidia Jetbot base image with the following installed: SparkFun Qwiic python library package
Driver for Edimax WiFi adapter
Greengrass
Jetbot ROS
Leopard Imaging 136FOV wide-angle camera & ribbon cable
EDIMAX WiFi Adapter
SparkFun Qwiic Motor Driver
SparkFun Micro OLED Breakout (Qwiic)
All hardware & prototyping electronics needed to complete your fully functional robot!
Required
NVIDIA Jetson Nano Developer Kit
Downloads
Assembly Guide
This category offers a wide spectrum of platforms to choose from. They all have different features and you can choose the platform that best suits your needs or project.
