Monitoring system for electric vehicles (log various sensors, such as consumed power, solar production, speed, slope, apparent wind, etc.)
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#include <Arduino.h>
#include <WiFi.h>
#include <WiFiMulti.h>
#include <FS.h>
#include <SPIFFS.h>
#include <ESPAsyncWebServer.h>
#include <Dps310.h>
#include "ADC.h"
#include "OTA.h"
#include "DataLogger.h"
#include "utils.h"
#include "wifi-credentials.h"
#include <limits>
#define DUMMY_DATA 0
AsyncWebServer server(80);
ADC currentSensor(36);
ADC batterySensor(39);
Dps310 pressureSensor = Dps310();
const int8_t speedSensorPin = 13;
const int8_t debugLedPin = 2;
const int8_t I2C_SDA = 15;
const int8_t I2C_SCL = 4;
const float wheelDiameterInches = 20;
const int numImpulsesPerTurn = 2;
const float wheelCircumferenceMeters = wheelDiameterInches * 0.0254f * 3.1415f / (float)numImpulsesPerTurn;
uint16_t batteryVoltage = 0; // in mV
uint16_t batteryOutputCurrent = 0; // in mV
int16_t temperature = 0; // in tenth of °C
int32_t altitude = 0; // in mm above sea level (can be negative if below sea level, or depending on atmospheric conditions)
WiFiMulti wifiMulti;
wl_status_t wifi_STA_status = WL_NO_SHIELD;
unsigned long wifiConnexionBegin = 0;
const unsigned long retryWifiConnexionDelay = 60000; // in milliseconds
unsigned long stoppedSince = -1;
volatile bool debugLedState = true;
volatile bool speedSensorState = false;
volatile unsigned long speedSensorRiseTime = 0;
volatile unsigned long speedSensorLastImpulseTime = 0;
volatile unsigned long speedSensorLastImpulseInterval = (unsigned long)-1; // in milliseconds
void IRAM_ATTR onSpeedSensorChange(bool newState)
{
if(speedSensorState == newState) return;
unsigned long now = millis();
speedSensorState = newState;
bool magnetDetected = !speedSensorState; // the magnet closes the contact which pulls the pin low
if(magnetDetected)
{
speedSensorRiseTime = now;
}
else
{
unsigned long impulseDuration = utils::elapsed(speedSensorRiseTime, now);
if(impulseDuration > 500) return; // impulse was too long, ignore it (maybe magnet stopped near the sensor)
unsigned long timeSinceLastImpulse = utils::elapsed(speedSensorLastImpulseTime, now);
if(timeSinceLastImpulse < 30)
{
// too little time between impulses, probably some bouncing, ignore it
}
else if(timeSinceLastImpulse < 4000)
{
speedSensorLastImpulseTime = now;
speedSensorLastImpulseInterval = timeSinceLastImpulse;
}
else
{
// too much time between impulses, can't compute speed from that
speedSensorLastImpulseTime = now;
speedSensorLastImpulseInterval = (unsigned long)-1;
}
}
}
void IRAM_ATTR onSpeedSensorChange() { onSpeedSensorChange(digitalRead(speedSensorPin) == HIGH); }
float getSpeed()
{
#if DUMMY_DATA
{
float result = max(0.0f, sinf((float)millis()/30000.0f)) * 7.0f;
return result < 0.25f ? 0.0f : result;
}
#endif
unsigned long now = millis();
noInterrupts();
unsigned long lastImpulseInterval = speedSensorLastImpulseInterval;
unsigned long lastImpulseTime = speedSensorLastImpulseTime;
interrupts();
unsigned long timeSinceLastImpulse = utils::elapsed(lastImpulseTime, now);
unsigned long interval = timeSinceLastImpulse > lastImpulseInterval * 10 / 9 ? timeSinceLastImpulse : lastImpulseInterval;
float speed = wheelCircumferenceMeters / (float)interval * 1000.0f; // in meters per second
if(speed < 0.25f)
{
return 0.0f; // if speed is very low (less than 1km/h) it probably means we've stopped
}
return speed;
}
void connectWifi()
{
wifiMulti = WiFiMulti();
const int numSSIDs = sizeof(wifi_STA_credentials)/sizeof(wifi_STA_credentials[0]);
if(numSSIDs > 0)
{
Serial.println("Connecting to wifi...");
for(int idx = 0; idx < numSSIDs; ++idx)
{
wifiMulti.addAP(wifi_STA_credentials[idx].SSID, wifi_STA_credentials[idx].password);
}
wifiConnexionBegin = millis();
wifiMulti.run();
}
}
void setup()
{
pinMode(debugLedPin, OUTPUT);
digitalWrite(debugLedPin, HIGH);
pinMode(speedSensorPin, INPUT_PULLUP);
attachInterrupt(speedSensorPin, &onSpeedSensorChange, CHANGE);
Serial.begin(115200);
if(!SPIFFS.begin(false)){
Serial.println("SPIFFS Mount Failed");
return;
}
// Set WiFi mode to both AccessPoint and Station
WiFi.mode(WIFI_AP_STA);
// Create the WiFi Access Point
if(wifi_AP_ssid != nullptr)
{
Serial.println("Creating wifi access point...");
WiFi.softAP(wifi_AP_ssid, wifi_AP_password);
Serial.print("Wifi access point created, SSID=");
Serial.print(wifi_AP_ssid);
Serial.print(", IP=");
Serial.println(WiFi.softAPIP());
}
// Also connect as a station (if the configured remote access point is in range)
connectWifi();
OTA.begin();
Wire.begin(I2C_SDA, I2C_SCL);
pressureSensor.begin(Wire);
server.on("/api/status", HTTP_GET, [](AsyncWebServerRequest *request){
int v = batteryVoltage;
int c = batteryOutputCurrent;
int s = (int)(getSpeed() * 1000.0f + 0.5f);
int t = temperature;
int alt = altitude;
const char* logFileName = DataLogger::get().currentLogFileName();
if(String(logFileName).startsWith("/log/")) logFileName += 5;
int totalSize = (int)(SPIFFS.totalBytes() / 1000);
int usedSize = (int)(SPIFFS.usedBytes() / 1000);
char json[128];
sprintf(json, "{\"v\":%d,\"c\":%d,\"s\":%d,\"t\":%d,\"alt\":%d,\"log\":\"%s\",\"tot\":%d,\"used\":%d}", v, c, s, t, alt, logFileName, totalSize, usedSize);
request->send(200, "text/json", json);
});
server.on("/api/log/list", HTTP_GET, [](AsyncWebServerRequest *request){
String json;
json = "{\"files\":[";
auto logFolder = SPIFFS.open("/log");
auto file = logFolder.openNextFile();
bool first = true;
while(file)
{
if(!first) json += ",";
json += "{\"n\":\"/api";
json += file.name();
json += "\",\"s\":";
json += file.size();
json += "}";
first = false;
file = logFolder.openNextFile();
}
json += "]}";
request->send(200, "text/json", json.c_str());
});
// Special case to send index.html without caching
server.on("/", HTTP_GET, [](AsyncWebServerRequest *request){ request->send(SPIFFS, "/www/index.html", "text/html"); });
server.serveStatic("/index.html", SPIFFS, "/www/index.html");
// Log files (not cached)
server.serveStatic("/api/log", SPIFFS, "/log/");
// Other static files are cached (index.html knows whether to ignore caching or not for each file)
server.serveStatic("/", SPIFFS, "/www/").setCacheControl("max-age=5184000");
server.begin();
Serial.println("HTTP server started");
digitalWrite(debugLedPin, LOW);
}
void handle_wifi_connection()
{
wl_status_t newWifiStatus = WiFi.status();
if(newWifiStatus != wifi_STA_status)
{
if(newWifiStatus == WL_CONNECTED)
{
Serial.print("Connected to wifi (");
Serial.print(WiFi.SSID().c_str());
Serial.print("), ip=");
Serial.println(WiFi.localIP());
}
else if(newWifiStatus == WL_DISCONNECTED)
{
char codeStr[16];
sprintf(codeStr, "%d", (int)newWifiStatus);
Serial.print("Lost wifi connexion (");
Serial.print(codeStr);
Serial.println(")");
connectWifi();
}
else
{
char codeStr[16];
sprintf(codeStr, "%d", (int)newWifiStatus);
Serial.print("Wifi state: ");
Serial.println(codeStr);
}
wifi_STA_status = newWifiStatus;
}
if(wifi_STA_status != WL_CONNECTED)
{
unsigned long now = millis();
unsigned long elapsed = utils::elapsed(wifiConnexionBegin, now);
if(elapsed > retryWifiConnexionDelay)
connectWifi();
}
}
void handle_ADC_measures()
{
const int numSamples = 100;
float averageV = 0.0f;
float averageC = 0.0f;
for(int sample = 0; sample < numSamples; ++sample)
{
delay(1);
float v = batterySensor.read();
float c = currentSensor.read();
averageV += v;
averageC += c;
}
averageV /= (float)numSamples;
averageC /= (float)numSamples;
if(averageV < 0.2f) averageV = 0.0f;
averageV *= 27.000f; // account for voltage divider to retrieve the input voltage
averageC = std::max(0.0f, averageC - 2.5f) / 0.0238f; // convert voltage to current, according to the sensor linear relation
batteryVoltage = (uint16_t)(averageV * 1000.0f + 0.5f);
batteryOutputCurrent = (uint16_t)(averageC * 1000.0f + 0.5f);
#if DUMMY_DATA
batteryVoltage = (uint16_t)((float)random(4000, 4020) / 100.0f * 1000.0f + 0.5f);
batteryOutputCurrent = (uint16_t)(max(0.0f, sinf((float)millis()/30000.0f)) * 25.0f * 1000.0f + 0.5f);
#endif
}
void handle_pressure_measure()
{
const uint8_t oversampling = 7;
int16_t ret;
float temp; // in Celcius degrees
ret = pressureSensor.measureTempOnce(temp, oversampling);
if(ret != 0)
{
Serial.print("Failed to measure temperature: "); Serial.println(ret);
return;
}
temperature = (int16_t)(temp * 10.0f + 0.5f);
float pressure; // in Pa
pressureSensor.measurePressureOnce(pressure, oversampling);
if(ret != 0)
{
Serial.print("Failed to measure pressure: "); Serial.println(ret);
return;
}
struct PressureToAltitude
{
float pressure; // in Pa
float altitude; // in meters above sea level
};
const PressureToAltitude altitudeTable[] =
{
{ 101325.0f, 0.0f },
{ 100000.0f, 111.0f },
{ 95000.0f, 540.0f },
{ 90000.0f, 989.0f },
{ 85000.0f, 1457.0f },
{ 80000.0f, 1949.0f },
{ 75000.0f, 2466.0f },
{ 70000.0f, 3012.0f },
{ 65000.0f, 3591.0f },
{ 60000.0f, 4206.0f },
{ 55000.0f, 4865.0f },
};
const int8_t altitudeTableNumValues = sizeof(altitudeTable)/sizeof(altitudeTable[0]);
float alt = -std::numeric_limits<float>::max();
for(int8_t i = 0; i < altitudeTableNumValues - 1; ++i)
{
if(i == altitudeTableNumValues - 2 || pressure >= altitudeTable[i+1].pressure)
{
const auto& p = altitudeTable[i];
const auto& n = altitudeTable[i+1];
alt = (pressure - p.pressure) / (n.pressure - p.pressure) * (n.altitude - p.altitude) + p.altitude;
break;
}
}
altitude = (int32_t)(alt * 1000.0f + 0.5f);
/*Serial.print("temperature="); Serial.print(temp); Serial.print("°C");
Serial.print(" pressure="); Serial.print(pressure); Serial.print("Pa");
Serial.print(" altitude="); Serial.print(altitude); Serial.println("mm");*/
}
void loop()
{
OTA.handle();
handle_wifi_connection();
handle_ADC_measures();
handle_pressure_measure(); // also measures temperature
unsigned long now = millis();
static DataLogger::Entry entry;
entry.batteryVoltage = (float)batteryVoltage / 1000.0f;
entry.batteryOutputCurrent = (float)batteryOutputCurrent / 1000.0f;
entry.speed = getSpeed();
entry.temperature = (float)temperature / 10.0f;
entry.altitude = (float)altitude / 1000.0f;
if(entry.speed > 0.0f)
{
stoppedSince = -1;
if(!DataLogger::get().isOpen())
{
Serial.println("Starting DataLogger");
DataLogger::get().open();
}
}
else
{
if(stoppedSince == -1)
{
stoppedSince = now;
}
else if(utils::elapsed(stoppedSince, now) > 5 * 60 * 1000)
{
if(DataLogger::get().isOpen())
{
Serial.println("Stopping DataLogger");
DataLogger::get().close();
}
}
}
DataLogger::get().log(now, entry);
delay(DataLogger::get().isOpen() ? 10 : 1000);
}