Programming #
The NORVI EC-M11-EG-C4-B95 has a mini USB port for serial connection with the SoC for programming. Any ESP32-supported programming IDE can be used to program the controller. Follow this guide to programming NORVI ESP32-based controllers with the Arduino IDE.
SoC: ESP32-WROOM32
Programming Port: USB UART
8-pin Connector and wire harness #
Pin Description #
| 8P Male | Wire color | I/O Configuration |
| 1 | White | Thermocouple + |
| 2 | Brown | Thermocouple – |
| 3 | Green | – |
| 4 | Yellow | – |
| 5 | Gray | – |
| 6 | Pink | – |
| 7 | Blue | Power+ |
| 8 | Red | Power- |
Thermocouple Input #
| SPI MISO | GPIO19 |
| SPI SCK | GPIO18 |
| CS | GPIO5 |
Programming Thermocouple Inputs #
#include <SPI.h>
#include "Adafruit_MAX31855.h"
#define MAXDO 19
#define MAXCS 5
#define MAXCLK 18 // Initialize the Thermocouple
Adafruit_MAX31855 thermocouple(MAXCLK, MAXCS, MAXDO);
void setup() {
Serial.begin(115200);
Serial.println("MAX31855 test"); // Wait for MAX chip to stabilize
delay(500);
Serial.print("Initializing sensor...");
if (!thermocouple.begin()) {
Serial.println("ERROR.");
while (1) delay(10);
}
Serial.println("DONE.");
}
void loop() {
Serial.print("Internal Temp = ");
Serial.println(thermocouple.readInternal());
double c = thermocouple.readCelsius();
if (isnan(c)) {
Serial.println("Thermocouple fault(s) detected!");
uint8_t e = thermocouple.readError();
if (e & MAX31855_FAULT_OPEN) Serial.println("FAULT: Thermocouple is open - no connections.");
if (e & MAX31855_FAULT_SHORT_GND) Serial.println("FAULT: Thermocouple is short-circuited to GND.");
if (e & MAX31855_FAULT_SHORT_VCC) Serial.println("FAULT: Thermocouple is short-circuited to VCC.");
}
else {
Serial.print("C = ");
Serial.println(c);
}
//Serial.print("F = ");
//Serial.println(thermocouple.readFahrenheit());
Serial.println("");
Serial.print("Analog Read : ");
Serial.print(analogRead(36));
Serial.println("");
delay(1000);
}NB-IoT Module #
| Modem | NB-101 |
| RX | GPIO25 |
| TX | GPIO26 |
| POWER | GPIO22 |
| RESET | GPIO17 |
Programming NB-IoT #
const int GSM_RST = 17; // Define the pin for modem reset
const int GSM_PWR_KEY = 22; // Define the pin for modem power key
const int MODEM_RX = 25; // Define the pin for ESP32's RX to modem's TX
const int MODEM_TX = 26; // Define the pin for ESP32's TX to modem's RX
void setup() {
pinMode(GSM_RST, OUTPUT);
pinMode(GSM_PWR_KEY, OUTPUT);
digitalWrite(GSM_PWR_KEY, HIGH); // Set modem to flight mode
digitalWrite(GSM_RST, HIGH);
delay(1000);
digitalWrite(GSM_RST, LOW);
delay(1000);
digitalWrite(GSM_RST, HIGH);
delay(1000);
Serial.begin(9600); // Initialize the serial monitor
Serial2.begin(9600, SERIAL_8N1, MODEM_RX, MODEM_TX);
// Initialize communication with modem
Serial.println("SIM AT START >>>>>>>>>>>>>>");
delay(2000);
Serial.flush();
Serial2.println("AT+NCONFIG=AUTOCONNECT,TRUE");
delay(2000);
while (Serial2.available()) {
char response = Serial2.read();
Serial.write(response);
}
Serial2.println("AT");
delay(2000);
while (Serial2.available()) {
char response = Serial2.read();
Serial.write(response);
}
Serial2.println("AT+CEREG?");
delay(2000);
while (Serial2.available()) {
char response = Serial2.read();
Serial.write(response);
}
Serial.flush();
}
void loop() {
Serial.print(".");
Serial2.println("AT");
while (Serial2.available()) {
char response = Serial2.read();
Serial.write(response);
}
delay(5000);
Serial2.println("AT+CEREG?");
delay(2000);
while (Serial2.available()) {
char response = Serial2.read();
Serial.write(response);
}
}
