LWL01 is powered by a CR2032 coin battery, in a good LoRaWAN Network Coverage case, it can transmit as many as 12,000 uplink packets (based on SF 7, 14 dB). In poor LoRaWAN network coverage, it can transmit ~ 1,300 uplink packets (based on SF 10, 18.5 B). The design goal for one battery is up to 2 years. User can easily change the CR2032 battery for reuse. The LWL01 will send periodically data every day as well as for water leak event. It also counts the water leak event times and also calculates last water leak duration. Each LWL01 is pre-load with a set of unique keys for LoRaWAN registration, register these keys to local LoRaWAN server and it will auto connect after power on. Features LoRaWAN v1.0.3 Class A SX1262 LoRa Core Water Leak detect CR2032 battery powered AT Commands to change parameters Uplink on periodically and water leak event Downlink to change configure Applications Wireless Alarm and Security Systems Home and Building Automation Industrial Monitoring and Control
This LR1302 module is a new generation LoRaWAN gateway module. It adopts a mini-PCIe form factor design and features low power consumption and high performance. Based on Semtech Network's SX1302 LoRaWA baseband chip, the LR1302 gateway module provides gateway products with potential capacity for long-distance wireless transmission. Compared to the previous SX1301 and SX1308 LoRa chips, the SX1302 chip has higher sensitivity, lower power consumption and lower operating temperature. It supports 8-channel data transmission, improves communication efficiency and capacity, and supports the connection and data transmission of more devices. It reserves two antenna interfaces, one for transmitting and receiving LoRa signals and one U.FL (IPEX) interface for independent transmission. It also has a metal shield to protect against external interference and provide a reliable communications environment. Designed specifically for the IoT space, the LR1302 is suitable for a variety of IoT applications. Whether used in smart cities, agriculture, industrial automation or other fields, the LR1302 module can provide reliable connections and efficient data transmission. Features Uses Semtech SX1302 baseband LoRa chip with extremely low power consumptionand excellent performance Mini-PCIe form factor and compact design make it easier to integrate into various gateway devices, suitable for space-constrained application scenarios, and provide flexible deployment options Support 8-channeldata transmission, provide more efficient communication efficiency and capacity Ultra-low operating temperatureeliminates the need for additional cooling and reduces the size of the LoRaWAN gateway Uses SX1250 TX/RX front end with sensitivity down to -139 dBm@SF12; TX power up to 26 dBm @3.3 V Specifications Frequency 863-870 MHz (EU868) Chipset Semtech SX1302 Chip Sensitivity -125 dBm @125K/SF7-139 dBm @125K/SF12 TX Power 26 dBm (with 3.3 V power supply) Bandwidth 125/250/500 kHz Channel 8 channel LEDs Power: GreenConfig: RedTX: GreenRX: Blue Form Factor Mini PCIe, 52-pin Golden Finger Power Consumption (SPI version) Standby: 7.5 mATX maximum power: 415 mARX: 40 mA Power Consumption (USB version) Standby: 20 mATX maximum power: 425 mARX: 53 mA LBT(Listen Before Talk) Support Antenna Connector U.FL Operating Temperature -40 to 85°C Dimensions (W x L) 30 x 50.95 mm Note LR1302 LoRaWAN Gateway Module is not included. Downloads Wiki SX1302 Datasheet Schematic Diagram
The Grove DHT11 Temperature & Humidity Sensor is a high-quality, low-cost digital temperature, and humidity sensor based on the DHT11 module. It is the most common temperature and humidity module for Arduino and Raspberry Pi. It is widely favored by hardware enthusiasts for its many advantages such as low power consumption and excellent long-term stability. Relatively high measurement accuracy can be obtained at a very low cost. The single-bus digital signal is output through the built-in ADC, which saves the I/O resources of the control board. Features Dimensions: 40 x 20 x 8 mm Weight: 10 g Battery: Exclude Input Voltage: 3.3 V & 5 V Measuring Current: 1.3 mA- 2.1 mA Measuring Humidity Range: 5% - 95% RH Measuring Temperature Range: -20 ℃ - 60 ℃
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
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 Grove SCD30 is an Arduino-compatible 3-in-1 environmental sensor for precise CO₂, temperature, and humidity measurements. Powered by the Sensirion SCD30 and advanced Non-Dispersive Infrared (NDIR) technology, it delivers high accuracy across a wide measurement range. The sensor also determines humidity and temperature through smart algorithms that model and compensate for external heat sources.
Features
NDIR CO2 sensor technology: embedded with Sensirion SCD30
Multi-function: Integrates temperature and humidity sensor on the same sensor module
High precision and wide measurement accuracy: ±(30 ppm + 3%) between 400 ppm to 10000 ppm
Superior stability: Dual-channel detection
Easy project operation: Digital interface I²C, Breadboard-friendly, Grove-compatible
Best performance-to-price ratio
Application Ideas
Air Purifier
Environmental Monitoring
Plant Environmental Monitoring system
Arduino weather station
Ready-to-use devices and self-built Arduino nodes in the 'The Things Network' LoRaWAN has developed excellently as a communication solution in the IoT. The Things Network (TTN) has contributed to this. The Things Network was upgraded to The Things Stack Community Edition (TTS (CE)). The TTN V2 clusters were closed towards the end of 2021. This book shows you the necessary steps to operate LoRaWAN nodes using TTS (CE) and maybe extend the network of gateways with an own gateway. Meanwhile, there are even LoRaWAN gateways suitable for mobile use with which you can connect to the TTN server via your cell phone. The author presents several commercial LoRaWAN nodes and new, low-cost and battery-powered hardware for building autonomous LoRaWAN nodes. Registering LoRaWAN nodes and gateways in the TTS (CE), providing the collected data via MQTT and visualization via Node-RED, Cayenne, Thingspeak, and Datacake enable complex IoT projects and completely new applications at very low cost. This book will enable you to provide and visualize data collected with battery-powered sensors (LoRaWAN nodes) wirelessly on the Internet. You will learn the basics for smart city and IoT applications that enable, for example, the measurement of air quality, water levels, snow depths, the determination of free parking spaces (smart parking), and the intelligent control of street lighting (smart lighting), among others.
The HT-M00 is a dual-channel gateway that is specifically designed to cater to smart family LoRa applications that work with less than 30 LoRa nodes. The gateway has been built around two SX1276 chips that are driven by ESP32. To enable monitoring of 125 KHz SF7~SF12 spreading factor, a software mixer has been developed, which is commonly referred to as a baseband simulation program.
The software mixer is a critical component that enables the HT-M00 gateway to operate with high efficiency. It is designed to simulate baseband signals, which are then mixed with the radio frequency signals to produce the desired output. The software mixer has been developed with great care and precision, and has undergone rigorous testing to ensure that it is capable of delivering accurate and reliable results.
Features
ESP32 + SX1276
Emulates LoRa demodulators
Automatic adaptive spread spectrum factor, SF7 to SF12 for each channel is optional
Maximum output: 18 ±1dBm
Support for LoRaWAN Class A, Class C protocol
Specifications
MCU
ESP32-D0WDQ6
LoRa Chipset
SX1276
LoRa Band
863~870 MHz
Power Supply Voltage
5 V
Receiving Sensitivity
-110 dBm @ 300 bps
Interface
USB-C
Max. TX Power
17dB ±1dB
Operating Temperature
−20~70°C
Dimensions
30 x 76 x 14 mm
Included
1x HT-M00 Dual Channel LoRa Gateway
1x Wall bracket
1x USB-C cable
Downloads
Manual
Software
Documentation
Lo-Fi (ESP32 + LoRa combination) is the perfect solution for anyone looking to establish long-range wireless communication in a variety of applications with WiFi capabilities. LoRa offers exceptional range and easy connectivity, it allows you to seamlessly communicate with devices up to 5 km away.
Devices provide an efficient and trustworthy choice for long-range wireless communication in addition to WiFi access to link internet clouds best suited for Internet of Things applications, enabling connectivity in remote and challenging settings.
Features
Device powered by powerful ESP32 S3 WROOM-1 which is having Xtensa dual-core 32-bit LX7 microprocessor, up to 240 MHz
Inbuilt Wi-Fi & Bluetooth LE for wireless connectivity
Type C interface for Programming/Power
1.14" TFT display for visual interactions
GPIO breakouts for interfacing additional peripherals
Breadboard compatible for easy DIY breadboarding projects
2 separate user programmable buttons along with Reset and Boot buttons
3.7 V Lithium Battery connector for a portable use case with an onboard charging option
Use new generation LoRa spread spectrum to ensure stable communication
For LoRa, faster speed and a longer data transmission range of up to 5 km
Applications
Internet of Things (IoT)
Smart Home Automation
Agricultural Automation
Emergency Services
Environmental Monitoring
Industrial Automation
Specifications
Microcontroller: ESP32 S3 WROOM-1
Wireless Interface: WiFi, BLE, LoRa
Protocol: 802.11b/g/n, Bluetooth 5.0
Memory Size: 16 MB Flash, 384 kB ROM, 8 MB SRAM
Supply Voltage: 5 V
Operating Voltage: 3.3 V
Display Size: 1.14”
Display Type: TFT
Display resolution: 135 x 240 pixels
Display driver: ST7789V
Display Appearance: RGB
Display color: 4k/65k/252k
Display Luminance: 400 Cd/m²
Operating Temperature: -20 to 70°C
Storage Temperature: -30 to 80°C
LoRa Module Specs:
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
Communication Port: UART serial
Downloads
Getting started guide
Hardware design files
Included
1x Lo-Fi Board
1x Antenna (868 MHz)
Ready-to-use devices and self-built Arduino nodes in the 'The Things Network' LoRaWAN has developed excellently as a communication solution in the IoT. The Things Network (TTN) has contributed to this. The Things Network was upgraded to The Things Stack Community Edition (TTS (CE)). The TTN V2 clusters were closed towards the end of 2021. This book shows you the necessary steps to operate LoRaWAN nodes using TTS (CE) and maybe extend the network of gateways with an own gateway. Meanwhile, there are even LoRaWAN gateways suitable for mobile use with which you can connect to the TTN server via your cell phone. The author presents several commercial LoRaWAN nodes and new, low-cost and battery-powered hardware for building autonomous LoRaWAN nodes. Registering LoRaWAN nodes and gateways in the TTS (CE), providing the collected data via MQTT and visualization via Node-RED, Cayenne, Thingspeak, and Datacake enable complex IoT projects and completely new applications at very low cost. This book will enable you to provide and visualize data collected with battery-powered sensors (LoRaWAN nodes) wirelessly on the Internet. You will learn the basics for smart city and IoT applications that enable, for example, the measurement of air quality, water levels, snow depths, the determination of free parking spaces (smart parking), and the intelligent control of street lighting (smart lighting), among others.
The CubeCell series is designed primarily for LoRa/LoRaWAN node applications.
Built on the ASR605x platform (ASR6501, ASR6502), these chips integrate the PSoC 4000 series MCU (ARM Cortex-M0+ Core) with the SX1262 module. The CubeCell series offers seamless Arduino compatibility, stable LoRaWAN protocol operation, and straightforward connectivity with lithium batteries and solar panels.
The HTCC-AB02S is a developer-friendly board with an integrated AIR530Z GPS module, ideal for quickly testing and validating communication solutions.
Features
Arduino compatible
Based on ASR605x (ASR6501, ASR6502), those chips are already integrated the PSoC 4000 series MCU (ARM Cortex M0+ Core) and SX1262
LoRaWAN 1.0.2 support
Ultra low power design, 21 uA in deep sleep
Onboard SH1.25-2 battery interface, integrated lithium battery management system (charge and discharge management, overcharge protection, battery power detection, USB/battery power automatic switching)
Good impendence matching and long communication distance
Onboard solar energy management system, can directly connect with a 5.5~7 V solar panel
Micro USB interface with complete ESD protection, short circuit protection, RF shielding, and other protection measures
Integrated CP2102 USB to serial port chip, convenient for program downloading, debugging information printing
Onboard 0.96-inch 128x64 dot matrix OLED display, which can be used to display debugging information, battery power, and other information
Using Air530 GPS module with GPS/Beidou Dual-mode position system support
Specifications
Main Chip
ASR6502 (48 MHz ARM Cortex-M0+ MCU)
LoRa Chipset
SX1262
Frequency
863~870 MHz
Max. TX Power
22 ±1 dBm
Max. Receiving Sensitivity
−135 dBm
Hardware Resource
2x UART1x SPI2x I²C1x SWD3x 12-bit ADC input8-channel DMA engine16x GPIO
Memory
128 Kb FLASH16 Kb SRAM
Power consumption
Deep sleep 21 uA
Interfaces
1x Micro USB1x LoRa Antenna (IPEX)2x (15x 2.54 Pin header) + 3x (2x 2.54 Pin header)
Battery
3.7 V lithium battery (power supply and charging)
Solar Energy
VS pin can be connected to 5.5~7 V solar panel
USB to Serial Chip
CP2102
Display
0.96" OLED (128 x 64)
Operating temperature
−20~70°C
Dimensions
55.9 x 27.9 x 9.5 mm
Included
1x CubeCell HTCC-AB02S Development Board
1x Antenna
1x 2x SH1.25 battery connector
Downloads
Datasheet
Schematic
GPS module (Manual)
Quick start
GitHub
Take control of your smart environment with the compact and powerful 4-inch ESP32-S3 IPS Touchscreen Control Panel. Designed for high performance and versatility, this sleek 86-box format panel integrates advanced connectivity, intuitive touch control, and real-time environmental sensing.
Features
Powerful Core Module WT32-S3-WROVER-N16R8
4-inch IPS full-screen display
Resolution: 480 x 480 pixels (RGB565 format)
Screen Driver IC: GC9503V
Touch Controller IC: FT6336U
Equipped with an SHT20 Temperature and Humidity Sensor for real-time monitoring of environmental conditions.
RS485 Interface using an automatic transceiver circuit
Built-in WiFi and Bluetooth
Applications
Smart Home Control Panels
Industrial Automation Interfaces
Environmental Monitoring Systems
IoT Projects and Custom Smart Solutions
