FireBeetle 2 ESP32-E IoT Microcontroller with Header (Supports Wi-Fi & Bluetooth)

MEPA CODE: 0123144761
BRAND: DFRobot
MANUFACTURER CODE: DFR0654-F
SKU CODE: DF-DFR0654-F
Availability: 770 Availability (legend)
15,84 (excl. VAT)
Full description
Introduction

FireBeetle 2 ESP32-E, specially designed for IoT, is an ESP-WROOM-32E-based main controller board with dual-core chips.

DFR0654-F supports WiFi and Bluetooth dual-mode communication and features a small size, ultra-low power consumption, onboard charging circuit, and easy-to-use interface, which can be conveniently used for smart home IoT, industrial IoT applications, wearable devices, and so on. You can easily create your own IoT smart home system when connecting it with an IoT platform like IFTTT.

FireBeetle 2 ESP32-E supports Arduino programming and will support Scratch graphical programming and MicroPython programming very soon. We provide you with detailed online tutorials and application cases, and there are thousands of sensors with welding-free Gravity interfaces and actuators to help you get started easily. Besides, the stamp hole design makes it able to be easily embedded in your PCB, greatly saving your costs and time to build and test a prototype.

We sell two versions of Firebeetle 2 ESP32-E, unsoldered version and with header version. If you want to plug the Firebeetle shield into your Firebeetle mainboard, the Firebeetle 2 Board ESP32-E(Pre-soldered) is better for you.

Note: FireBeetle 2 and FireBeetle pins and sizes are not compatible, and neither are the expansion boards.

Figure 1. Board Overview

Figure 2.Pinout


Features
  • ESP32 dual-core low-power main controller with power consumption as low as 2mA
  • WiFi+Bluetooth 4.0 Dual-mode Module
  • GDI Display Port, easy to connect
  • Onboard Charging Circuit and PH2.0 lithium Battery Interface
  • Specification

    Power Parameters

  • Input Voltage
  • USB-C Port: 5V DC
  • PH2.0 Connector: 3.7~4.2V Li-ion
  • VCC Pin: 5V DC
  • MCU Parameters

  • Processor: Xtensa Dual-Core 32-bit LX6 Microprocessor
  • Clock Speed: 240 MHz
  • SRAM: 520 KB
  • ROM: 448 KB
  • Flash Memory: 4 MB
  • Wireless Parameters - Wi-Fi Protocol:

  • IEEE 802.11 b/g/n (Data rate up to 150 Mbps in 802.11n mode)
  • Supports A-MPDU and A-MSDU aggregation
  • Supports 0.4 μs guard interval
  • Operating Channel Center Frequency Range: 2412~2484 MHz
  • Bluetooth Protocol:
  • Bluetooth V4.2 BR/EDR and Bluetooth LE standards
  • Bluetooth CVSD and SBC audio
  • Bluetooth Frequency Range: 2402~2480 MHz
  • Peripheral Parameters

  • Digital Pins × 18: IO0, IO1, IO2, IO3, IO4, IO12, IO13, IO14, IO15, IO16, IO17, IO18, IO19, IO21, IO22, IO23, IO25, IO26
  • Analog Pins × 11: IO0, IO2, IO4, IO12, IO13, IO14, IO15, IO25, IO26, I34, I35
  • UART Interfaces: × 2
  • SPI Interface: × 1
  • I2C Interface: × 1
  • I2S Interface: × 1
  • DAC Interfaces: × 2
  • Touch Interfaces: × 7
  • LED PWM Channels: × 16
  • RGB_LED: WS2812
  • Display Interface: GDI
  • Other Parameters

  • Module Size: 25.4mm × 60mm
  • Mounting hole size: hole diameter 2.0mm
  • Weight: 23g
  • Shipping List
  • FireBeetle 2 Board ESP32-E with Header x1
  • 18pin-2.54mm Pitch Pin x1
  • 18pin-2.54mm Pitch Pin Female x1
  • 14pin-2.54mm Pitch Pin x1
  • 14pin-2.54mm Pitch Pin Female x1
  • Documents
  • Product wiki
  • Projects

    Project 1. Make a Home-made Network Clock with ESP32-E

    Introduction: This production will be very simple, getting the time from the internet via the wifi of the ESP32, and then you need to find a screen that displays the time. There are many options for the screen, LCD1602 or LED monochrome dot matrix for splicing. I accidentally saw a VFD fluorescent screen before, it was green-blue when it was lit, and it glowed with white light, which makes the whole screen a mottled beauty. So, I am going to use it here.

     


    Project 2. DIY 3D Printed IoT Weather Station Using an ESP32

    Introduction: Today we’re going to be building a wireless outdoor weather station that takes temperature, humidity, barometric pressure, light and wind speed readings, and uses WiFi to post the data to the cloud which can then be accessed through a Thingspeak dashboard.


    Project 3. Smart Compost Bin Monitoring System -Based on 4G IoT and SHT20

    Introduction:

    The other day my friend asked me to help him remake his compost bin, he wants a device that allows him to remotely get the real-time temperature and humidity inside. So I add some electronic parts on it.