15-08039
/
Fundamentos_de_IoT_USB
1
0
Fork 0
Code Issues Pull Requests Projects Releases Wiki Activity

Compare commits

base: 15-08039:4ce0244bd7e862810244848a362ad09c3a5f590d
Branches Tags
15-08039:master
...
compare: 15-08039:61fd8a4c453dc73a3bf0c2df88c57583d5386f10
Branches Tags
15-08039:master

3 Commits
4ce0244bd7 ... 61fd8a4c45

Author SHA1 Message Date
Frannell Foti 61fd8a4c45 Aun no funciona la conexion entre el MQTT y el esp 2021-04-10 00:20:11 -04:00
Frannell Foti d89bf5b0a6 Actualizaciones de las valvulas, el sensor de ph y la bomba de agua 2021-04-10 00:18:22 -04:00
Frannell Foti d97cb1f9b0 Acualizaciones del codigo para el DHT11 y la fotocelda 2021-04-10 00:15:49 -04:00
5 changed files with 410 additions and 0 deletions
Show Stats Expand all files Collapse all files

109
Conexion_mosquitto-esp8266/Conexion_mosquitto-esp8266V1.0b/Conexion_mosquitto-esp8266V1.0b.ino Normal file
View File

@ -0,0 +1,109 @@
#include <ESP8266WiFi.h>
#include <PubSubClient.h>
// Update these with values suitable for your network.
const char* ssid = "TP-LINK_F621EA";
const char* password = "Caracas01.";
const char* mqtt_server = "192.168.1.108";
WiFiClient espClient;
PubSubClient client(espClient);
unsigned long lastMsg = 0;
#define MSG_BUFFER_SIZE (50)
char msg[MSG_BUFFER_SIZE];
int value = 0;
void setup_wifi() {
delay(10);
// We start by connecting to a WiFi network
Serial.println();
Serial.print("Connecting to ");
Serial.println(ssid);
WiFi.mode(WIFI_STA);
WiFi.begin(ssid, password);
while (WiFi.status() != WL_CONNECTED) {
delay(500);
Serial.print(".");
}
randomSeed(micros());
Serial.println("");
Serial.println("WiFi connected");
Serial.println("IP address: ");
Serial.println(WiFi.localIP());
}
void callback(char* topic, byte* payload, unsigned int length) {
Serial.print("Message arrived [");
Serial.print(topic);
Serial.print("] ");
for (int i = 0; i < length; i++) {
Serial.print((char)payload[i]);
}
Serial.println();
// Switch on the LED if an 1 was received as first character
if ((char)payload[0] == '1') {
digitalWrite(BUILTIN_LED, LOW); // Turn the LED on (Note that LOW is the voltage level
// but actually the LED is on; this is because
// it is active low on the ESP-01)
} else {
digitalWrite(BUILTIN_LED, HIGH); // Turn the LED off by making the voltage HIGH
}
}
void reconnect() {
// Loop until we're reconnected
while (!client.connected()) {
Serial.print("Attempting MQTT connection...");
// Create a random client ID
String clientId = "ESP8266Client-";
clientId += String(random(0xffff), HEX);
// Attempt to connect
if (client.connect(clientId.c_str())) {
Serial.println("connected");
// Once connected, publish an announcement...
client.publish("invernadero_inteligente", "hello world");
// ... and resubscribe
client.subscribe("invernadero_inteligente");
} else {
Serial.print("failed, rc=");
Serial.print(client.state());
Serial.println(" try again in 5 seconds");
// Wait 5 seconds before retrying
delay(5000);
}
}
}
void setup() {
pinMode(BUILTIN_LED, OUTPUT); // Initialize the BUILTIN_LED pin as an output
Serial.begin(115200);
setup_wifi();
client.setServer(mqtt_server, 1883);
client.setCallback(callback);
}
void loop() {
if (!client.connected()) {
reconnect();
}
client.loop();
unsigned long now = millis();
if (now - lastMsg > 2000) {
lastMsg = now;
++value;
snprintf (msg, MSG_BUFFER_SIZE, "hello world #%ld", value);
Serial.print("Publish message: ");
Serial.println(msg);
client.publish("invernadero_inteligente", msg);
}
}

224
Lector_ph-Bombeo_nutrientes_y_agua/Lector_ph-Bombeo_nutrientes_y_agua_V1.0.ino Normal file
View File

@ -0,0 +1,224 @@
#include <RTClib.h>
#include <Wire.h>
float calibration_value = 21.34;
int phval = 0;
unsigned long int avgval;
int buffer_arr[10], temp;
int relePin1 = 2;
int relePin2 = 3;
RTC_DS3231 rtc;
bool inicio_bombeo = true;
bool fin_bombeo = true;
void setup()
{
Serial.begin(9600);
}
void loop() {
for (int i = 0; i < 10; i++)
{
buffer_arr[i] = analogRead(A0);
delay(30);
}
for (int i = 0; i < 9; i++)
{
for (int j = i + 1; j < 10; j++)
{
if (buffer_arr[i] > buffer_arr[j])
{
temp = buffer_arr[i];
buffer_arr[i] = buffer_arr[j];
buffer_arr[j] = temp;
}
}
}
avgval = 0;
for (int i = 2; i < 8; i++)
avgval += buffer_arr[i];
float volt = (float)avgval * 5.0 / 1024 / 6;
float ph_act = -5.70 * volt + calibration_value;
if (ph_act >= 6.50){
digitalWrite (relePin1, HIGH);
}else {
digitalWrite (relePin1, LOW);
DateTime horario = rtc.now();
//Riego de las 00:00
if (relePin1, LOW && horario.hour() == 0 && horario.minute() == 0){
if (inicio_bombeo = true){
digitalWrite (relePin2, HIGH);
Serial.println("00:00 ON");
inicio_bombeo = false;
}
}
if (relePin1, LOW && horario.hour() == 0 && horario.minute() == 5){
if (fin_bombeo = true){
digitalWrite (relePin2, LOW);
Serial.println("00:05 OFF");
fin_bombeo = false;
}
}
//Riego de las 06:00
if (relePin1, LOW && horario.hour() == 6 && horario.minute() == 0){
if (inicio_bombeo = true){
digitalWrite (relePin2, HIGH);
Serial.println("06:00 ON");
inicio_bombeo = false;
}
}
if (relePin1, LOW && horario.hour() == 6 && horario.minute() == 5){
if (fin_bombeo = true){
digitalWrite (relePin2, LOW);
Serial.println("06:05 OFF");
fin_bombeo = false;
}
}
//Riego de 08:00
if (relePin1, LOW && horario.hour() == 8 && horario.minute() == 0){
if (inicio_bombeo = true){
digitalWrite (relePin2, HIGH);
Serial.println("08:00 ON");
inicio_bombeo = false;
}
}
if (relePin1, LOW && horario.hour() == 8 && horario.minute() == 5){
if (fin_bombeo = true){
digitalWrite (relePin2, LOW);
Serial.println("08:05 OFF");
fin_bombeo = false;
}
}
//Riego de 10:00
if (relePin1, LOW && horario.hour() == 10 && horario.minute() == 0){
if (inicio_bombeo = true){
digitalWrite (relePin2, HIGH);
Serial.println("10:00 ON");
inicio_bombeo = false;
}
}
if (relePin1, LOW && horario.hour() == 10 && horario.minute() == 5){
if (fin_bombeo = true){
digitalWrite (relePin2, LOW);
Serial.println("10:05 OFF");
fin_bombeo = false;
}
}
//Riego de 11:00
if (relePin1, LOW && horario.hour() == 11 && horario.minute() == 0){
if (inicio_bombeo = true){
digitalWrite (relePin2, HIGH);
Serial.println("11:00 ON");
inicio_bombeo = false;
}
}
if (relePin1, LOW && horario.hour() == 11 && horario.minute() == 5){
if (fin_bombeo = true){
digitalWrite (relePin2, LOW);
Serial.println("11:05 OFF");
fin_bombeo = false;
}
}
//Riego de 12:00
if (relePin1, LOW && horario.hour() == 12 && horario.minute() == 0){
if (inicio_bombeo = true){
digitalWrite (relePin2, HIGH);
Serial.println("12:00 ON");
inicio_bombeo = false;
}
}
if (relePin1, LOW && horario.hour() == 12 && horario.minute() == 5){
if (fin_bombeo = true){
digitalWrite (relePin2, LOW);
Serial.println("12:05 OFF");
fin_bombeo = false;
}
}
//Riego de 13:00
if (relePin1, LOW && horario.hour() == 13 && horario.minute() == 0){
if (inicio_bombeo = true){
digitalWrite (relePin2, HIGH);
Serial.println("13:00 ON");
inicio_bombeo = false;
}
}
if (relePin1, LOW && horario.hour() == 13 && horario.minute() == 5){
if (fin_bombeo = true){
digitalWrite (relePin2, LOW);
Serial.println("13:05 OFF");
fin_bombeo = false;
}
}
//Riego de 14:00
if (relePin1, LOW && horario.hour() == 14 && horario.minute() == 0){
if (inicio_bombeo = true){
digitalWrite (relePin2, HIGH);
Serial.println("14:00 ON");
inicio_bombeo = false;
}
}
if (relePin1, LOW && horario.hour() == 14 && horario.minute() == 5){
if (fin_bombeo = true){
digitalWrite (relePin2, LOW);
Serial.println("14:05 OFF");
fin_bombeo = false;
}
}
//Riego de 15:00
if (relePin1, LOW && horario.hour() == 15 && horario.minute() == 0){
if (inicio_bombeo = true){
digitalWrite (relePin2, HIGH);
Serial.println("15:00 ON");
inicio_bombeo = false;
}
}
if (relePin1, LOW && horario.hour() == 15 && horario.minute() == 5){
if (fin_bombeo = true){
digitalWrite (relePin2, LOW);
Serial.println("15:05 OFF");
fin_bombeo = false;
}
}
//Riego de 17:00
if (relePin1, LOW && horario.hour() == 17 && horario.minute() == 0){
if (inicio_bombeo = true){
digitalWrite (relePin2, HIGH);
Serial.println("17:00 ON");
inicio_bombeo = false;
}
}
if (relePin1, LOW && horario.hour() == 17 && horario.minute() == 5){
if (fin_bombeo = true){
digitalWrite (relePin2, LOW);
Serial.println("17:05 OFF");
fin_bombeo = false;
}
}
//Riego de 20:00
if (relePin1, LOW && horario.hour() == 20 && horario.minute() == 0){
if (inicio_bombeo = true){
digitalWrite (relePin2, HIGH);
Serial.println("20:00 ON");
inicio_bombeo = false;
}
}
if (relePin1, LOW && horario.hour() == 20 && horario.minute() == 5){
if (fin_bombeo = true){
digitalWrite (relePin2, LOW);
Serial.println("20:05 OFF");
fin_bombeo = false;
}
}
delay(1000);
}
}

1
lector_de_sensor_DHT11/Lector_de_sensor_DHT11_v1.0 Submodule

@ -0,0 +1 @@
Subproject commit 97c1a18cfd6f125cad9e1483a302f8c9e928f3ce

38
lector_de_sensor_DHT11/Lector_de_sensor_DHT11_v2.0/Lector_de_sensor_DHT11_v2.0/Lector_de_sensor_DHT11_v2.0.ino Normal file
View File

@ -0,0 +1,38 @@
#include <DHT.h>
#include <DHT_U.h>
DHT SenHumTemp (1, DHT11);
float tempc, hume;
int temp_limite = 29;
int ventiladores = 3;
bool ventiladores_activados = false;
unsigned long start_time = 0;
void leerDatos(){
tempc = SenHumTemp.readTemperature();
hume = SenHumTemp.readHumidity();
Serial.println("Temperatura: " + String(tempc)+ "Humedad: " + String (hume));
}
void setup() {
Serial.begin(115200);
SenHumTemp.begin();
pinMode (ventiladores, OUTPUT);
}
void loop() {
if(millis() - start_time >= 2000){
leerDatos();
start_time = millis();
}
if (tempc >= temp_limite){
digitalWrite (ventiladores, HIGH);
ventiladores_activados = true;
Serial.println ("Los ventiladores se han activado");
}else {
digitalWrite (ventiladores, LOW);
ventiladores_activados = false;
Serial.println ("Los ventiladores se han desactivado");
}
}

38
lector_de_sensor_DHT11/Lector_de_sensor_DHT11_v3.0/Lector_de_sensor_DHT11_V3.0/Lector_de_sensor_DHT11_V3.0.ino Normal file
View File

@ -0,0 +1,38 @@
#include <DHT.h>
#include <DHT_U.h>
DHT SenHumTemp (1, DHT11);
float tempc, hume;
int temp_limite = 29;
int ventiladores = 3;
bool ventiladores_activados = false;
unsigned long start_time = 0;
void leerDatos(){
tempc = SenHumTemp.readTemperature();
hume = SenHumTemp.readHumidity();
Serial.println("Temperatura: " + String(tempc)+ "Humedad: " + String (hume));
}
void setup() {
Serial.begin(115200);
SenHumTemp.begin();
pinMode (ventiladores, OUTPUT);
}
void loop() {
if(millis() - start_time >= 2000){
leerDatos();
start_time = millis();
}
if (tempc >= temp_limite){
digitalWrite (ventiladores, HIGH);
ventiladores_activados = true;
Serial.println ("Los ventiladores se han activado");
}else {
digitalWrite (ventiladores, LOW);
ventiladores_activados = false;
Serial.println ("Los ventiladores se han desactivado");
}
}