M5Station-485 2020 V0.
TABLE OF CONTENTS 1. OUTLINE ................................................................................... 3 2. SPECIFICATIONS ........................................................................... 4 3.FUNCTIONAL DESCRIPTION .......................................................... 5 1.1. CPU AND MEMORY ..................................................................5 1.2. STORAGE DESCRIPTION ..............................................................5 1.2.1. 4. 5.
1. OUTLINE M5Station-485 is a general-purpose IoT workstation in the M5Stack development kit series. It integrates rich interfaces and peripherals and is highly expandable. Large space reserved inside, flexible customization, and more likely to be applicable to various industrial acquisition and control application scenarios.
2. SPECIFICATIONS Resources Parameter ESP32D0WDQ6-V3 240MHz dual core, 600 DMIPS, 520KB SRAM, Wi-Fi, dual mode Bluetooth Flash 16MB LCD screen 1.14" LCD 135x240 ST7789V2 SPI interface RTC BM8563 PMU AXP192 Input power 5V @ 500mA IO G33, G32, G35, G25, G36, G26, G13, G14, G16, G17 Antenna Metal Antenna Battery 18650 x2 Shell material PC Plastic 4 3.
3.FUNCTIONAL DESCRIPTION This chapter describes the ESP32-D0WDQ6-V3 various modules and functions. 1.1. CPU AND MEMORY Xtensa®single-/dual-core32-bitLX6microprocessor(s), upto600MIPS (200MIPSforESP32-S0WD/ESP32-U4WDH, 400 MIPS for ESP32-D2WD): ⚫ 448 KB ROM ⚫ 520 KB SRAM ⚫ 16 KB SRAM in RTC ⚫ QSPI supports multiple flash/SRAM chips 1.2. STORAGE DESCRIPTION 1.2.1.
1.4. RTC MANAGEMENT AND LOW POWER CONSUMPTION ESP32 uses advanced power management techniques may be switched between different power saving modes. (See Table 5). • Power saving mode - Active Mode: RF chip is operating. Chip may receive and transmit a sounding signal. - Modem-sleep mode: CPU can run, the clock may be configured. Wi-Fi / Bluetooth baseband and RF - Light-sleep mode: CPU suspended. RTC and memory and peripherals ULP coprocessor operation.
4. ELECTRICAL CHARACTERISTICS 4.1. LIMIT PARAMETERS Table 8: Limiting values 1. VIO to the power supply pad, Refer ESP32 Technical Specification Appendix IO_MUX, as SD_CLK of Power supply for VDD_SDIO. 4.2.
4.3. LOW-POWER BLUETOOTH RADIO 4.3.1. receiver Table 10: Low-power Bluetooth receiver characteristics 4.3.2.
5. QUICK START 5.1. ARDUINO IDE Visit Arduino's official website(https://www.arduino.cc/en/Main/Software),Select the installation package for your own operating system to download. >1.Open up Arduino IDE, navigate to `File`->`Peferences`->`Settings` >2.Copy the following M5Stack Boards Manager url to `Additional Boards Manager URLs:` https://raw.githubusercontent.com/espressif/arduino-esp32/ghpages/package_esp32_dev_index.json >3.Navigate to `Tools`->`Board:`->`Boards Manager...` >4.
#include "BluetoothSerial.h" #if !defined(CONFIG_BT_ENABLED) || !defined(CONFIG_BLUEDROID_ENABLED) #error Bluetooth is not enabled! Please run `make menuconfig` to and en able it #endif BluetoothSerial SerialBT; void setup() { Serial.begin(115200); SerialBT.
Serial.println("The device started, now you can pair it with bluetoot h!"); } void loop() { if (Serial.available()) { SerialBT.write(Serial.read()); } if (SerialBT.available()) { Serial.write(SerialBT.read()); } delay(20); } 5.3. WIFI SCANNING Open the Arduino IDE and open the example program `File`->`Examples`->`WiFi`->`WiFiScan`. Connect the device to the computer and select the corresponding port to burn.
Serial.begin(115200); // Set WiFi to station mode and disconnect from an AP if it was pre viously connected WiFi.mode(WIFI_STA); WiFi.disconnect(); delay(100); Serial.println("Setup done"); } void loop() { Serial.println("scan start"); // WiFi.scanNetworks will return the number of networks found int n = WiFi.scanNetworks(); Serial.println("scan done"); if (n == 0) { Serial.println("no networks found"); } else { Serial.print(n); Serial.
FCC Statement: Any Changes or modifications not expressly approved by the party responsible for compliance could void the user’s authority to operate the equipment. This device complies with part 15 of the FCC Rules. Operation is subject to the following two conditions: (1) This device may not cause harmful interference, and (2) This device must accept any interference received, including interference that may cause undesired operation.