gps modülümüz ile lora modülümüz aynı anda çalıştırıldığında gps verilerini diğer lora’ya veri aktarımı yapılamıyor.
#include <TinyGPS++.h><br />#include <MPU9255.h><br />#include <SoftwareSerial.h><br />#include "LoRa_E22.h"<br />// #include <SimpleKalmanFilter.h><br />#include<Servo.h><br />#include <Wire.h><br />#include <SPI.h><br />#include <Adafruit_BMP280.h><br />SoftwareSerial mySerial(10, 11);<br />int servo_port = 9;<br />#define SERIAL_BAUD 9600<br />#define BMP_SCK (13)<br />#define BMP_MISO (12)<br />#define BMP_MOSI (11)<br />#define BMP_CS (10)<br />#define g 9.81<br /> /*SimpleKalmanFilter irtifaKalmanFilter(1, 540, 0.01);<br />SimpleKalmanFilter axKalmanFilter(1, 1, 0.01);<br />SimpleKalmanFilter ayKalmanFilter(1, 1, 0.01);<br />SimpleKalmanFilter azKalmanFilter(1, 1, 0.01);<br />SimpleKalmanFilter gxKalmanFilter(1, 1, 0.01);<br />SimpleKalmanFilter gyKalmanFilter(1, 1, 0.01);<br />SimpleKalmanFilter gzKalmanFilter(1, 1, 0.01);*/<br />LoRa_E22 E22(&mySerial);<br />Adafruit_BMP280 bmp;<br />MPU9255 mpu;<br />TinyGPSPlus gps;<br />Servo servom;<br />int pos = 90; <br />struct Signal {<br /> char type[15] = "Urfa63";<br /> float irtifa;<br /> float sicaklik;<br /> float gps_1;<br /> float gps_2;<br /> float ax[3];<br /> float gx[3];<br /> float ldr;<br />} data;<br /> #define M0 7<br />#define M1 6<br />#define BTN 2<br />#define LED 9<br /> static const int RXPin = 4, TXPin = 3;// Here we make pin 4 as RX of arduino & pin 3 as TX of arduino <br />static const uint32_t GPSBaud = 9600;<br /> SoftwareSerial ss(RXPin, TXPin);<br />float gps_1 = 0,gps_2 = 0;<br /> float ax[3] = {0.0,0.0,0.0};<br />float gx[3] = {0.0,0.0,0.0};<br /> float first_pres = 0,h = 0,irtifa = 0,max_irtifa = 0,min_irtifa = 0,sicaklik = 0,isik = 0;<br />bool aviyonik_durum = false;<br /> double process_acceleration(int input, scales sensor_scale )<br />{<br /> /*<br /> To get acceleration in 'g', each reading has to be divided by :<br /> -> 16384 for +- 2g scale (default scale)<br /> -> 8192 for +- 4g scale<br /> -> 4096 for +- 8g scale<br /> -> 2048 for +- 16g scale<br /> */<br /> double output = 1;<br /> //for +- 2g<br /> if(sensor_scale == scale_2g)<br /> {<br /> output = input;<br /> output = output/16384;<br /> output = output*g;<br /> }<br /> //for +- 4g<br /> if(sensor_scale == scale_4g)<br /> {<br /> output = input;<br /> output = output/8192;<br /> output = output*g;<br /> }<br /> //for +- 8g<br /> if(sensor_scale == scale_8g)<br /> {<br /> output = input;<br /> output = output/4096;<br /> output = output*g;<br /> }<br /> //for +-16g<br /> if(sensor_scale == scale_16g)<br /> {<br /> output = input;<br /> output = output/2048;<br /> output = output*g;<br /> }<br /> return output;<br />}<br /> double process_angular_velocity(int16_t input, scales sensor_scale )<br />{<br /> /*<br /> To get rotation velocity in dps (degrees per second), each reading has to be divided by :<br /> -> 131 for +- 250 dps scale (default value)<br /> -> 65.5 for +- 500 dps scale<br /> -> 32.8 for +- 1000 dps scale<br /> -> 16.4 for +- 2000 dps scale<br /> */<br /> //for +- 250 dps<br /> if(sensor_scale == scale_250dps)<br /> {<br /> return input/131;<br /> }<br /> //for +- 500 dps<br /> if(sensor_scale == scale_500dps)<br /> {<br /> return input/65.5;<br /> }<br /> //for +- 1000 dps<br /> if(sensor_scale == scale_1000dps)<br /> {<br /> return input/32.8;<br /> }<br /> //for +- 2000 dps<br /> if(sensor_scale == scale_2000dps)<br /> {<br /> return input/16.4;<br /> }<br /> return 0;<br />}<br /> void setup()<br />{<br /> pinMode(8,OUTPUT);<br /> Serial.begin(SERIAL_BAUD);<br /> ss.listen();<br /> ss.begin(GPSBaud);<br /> while(!Serial) {} // Wait<br /> Wire.begin();<br /> pinMode(M0, OUTPUT);<br /> pinMode(M1, OUTPUT);<br /> digitalWrite(M0, LOW);<br /> digitalWrite(M1, LOW);<br /> E22.begin();<br /> mySerial.listen();<br /> char* source = "urfa başlat";<br /> strcpy(data.type, source);<br /> ResponseStatus rs = E22.sendFixedMessage(0, 46, 18, &data, sizeof(Signal));<br /> if (!bmp.begin(BMP280_ADDRESS_ALT, BMP280_CHIPID)) {<br /> if (!bmp.begin()) {<br /> Serial.println(F("Could not find a valid BMP280 sensor, check wiring or "<br /> "try a different address!"));<br /> }<br /> /* Default settings from datasheet. */<br /> bmp.setSampling(Adafruit_BMP280::MODE_NORMAL, /* Operating Mode. */<br /> Adafruit_BMP280::SAMPLING_X2, /* Temp. oversampling */<br /> Adafruit_BMP280::SAMPLING_X16, /* Pressure oversampling */<br /> Adafruit_BMP280::FILTER_X16, /* Filtering. */<br /> Adafruit_BMP280::STANDBY_MS_500); /* Standby time. */<br />}<br /> if(mpu.init())<br /> {<br /> Serial.println("MPU9255 çalıştırılamadı");<br /> }<br /> else<br /> {<br /> Serial.println("MPU9255 çalıştırıldı");<br /> }<br /> digitalWrite(8,HIGH);<br /> delay(1500);<br /> digitalWrite(8,LOW);<br /> isik = analogRead(A3);<br />}<br /> //////////////////////////////////////////////////////////////////<br />void loop()<br />{<br /> mpu.read_acc();<br /> mpu.read_gyro();<br /> Serial.print("GPS: ");<br /> Serial.print(gps_1, 6);<br /> Serial.print(F(" , "));<br /> Serial.print(gps_2, 6);<br /> Serial.print(" ");<br /> while (ss.available() > 0)<br /> if (gps.encode(ss.read()))<br /> displayInfo();<br /> if (millis() > 5000 && gps.charsProcessed() < 10)<br /> {<br /> } <br /> printMPU9255();<br /> printBME280();<br /> if (avyonik(irtifa) == true && aviyonik_durum == false){<br /> aviyonik_durum = true;<br /> Serial.print("irtifaya ulaşıldı");<br /> digitalWrite(8,HIGH);<br /> servom.write(pos);<br /> pos = 0;<br /> delay(1000);<br /> digitalWrite(8,LOW);<br /> }<br /> lora();<br /> delay(50);<br />}<br /> void printMPU9255(){<br /> ax[0] = process_acceleration(mpu.ax,scale_2g);<br /> //ax[0] = axKalmanFilter.updateEstimate(ax[0]);<br /> ax[1] = process_acceleration(mpu.ay,scale_2g);<br /> //ax[1] = ayKalmanFilter.updateEstimate(ax[1]);<br /> ax[2] = process_acceleration(mpu.az,scale_2g);<br /> //ax[2] = azKalmanFilter.updateEstimate(ax[2]);<br /> gx[0] = process_angular_velocity(mpu.gx,scale_250dps);<br /> //gx[0] = gxKalmanFilter.updateEstimate(gx[0]);<br /> gx[1] = process_angular_velocity(mpu.gy,scale_250dps);<br /> //gx[1] = gyKalmanFilter.updateEstimate(gx[1]);<br /> gx[2] = process_angular_velocity(mpu.gz,scale_250dps);<br /> //gx[2] = gzKalmanFilter.updateEstimate(gx[2]);<br /> Serial.print(" AX: ");<br /> Serial.print(ax[0]);<br /> //Y axis<br /> Serial.print(" AY: ");<br /> Serial.print(ax[1]);<br /> //Z axis<br /> Serial.print(" AZ: ");<br /> Serial.print(ax[2]);<br /> ////process and print gyroscope data////<br /> //X axis<br /> Serial.print(" GX: ");<br /> Serial.print(gx[0]);<br /> //Y axis<br /> Serial.print(" GY: ");<br /> Serial.print(gx[1]);<br /> //Z axis<br /> Serial.print(" GZ: ");<br /> Serial.print(gx[2]);<br />}<br /> //////////////////////////////////////////////////////////////////<br />void printBME280()<br />{<br /> irtifa = bmp.readAltitude(1013.25);<br /> //irtifa = irtifaKalmanFilter.updateEstimate(irtifa);<br /> sicaklik = bmp.readTemperature();<br /> Serial.print(F(" Sicaklik: "));<br /> Serial.print(sicaklik);<br /> Serial.print(" *C");<br /> Serial.print(F(" İrtifa: "));<br /> Serial.print(irtifa);<br /> Serial.print(" m ");<br /> Serial.println(analogRead(A3));<br />}<br /> void displayInfo()<br />{<br /> ss.listen();<br /> if (gps.location.isValid())<br /> {<br /> gps_1 = gps.location.lat();<br /> gps_2 = gps.location.lng();<br /> }<br /> else<br /> {<br /> //Serial.print(F("VERİ ALİNAMADİ "));<br /> }<br />}<br />bool avyonik(float irtifas){<br /> if (max_irtifa - irtifas >= 0.15 && ax[1] > -2.3 && analogRead(A3) <= isik+150){<br /> return true; <br /> }else if (irtifas > max_irtifa){<br /> max_irtifa = irtifas;<br /> return false;<br /> }else{<br /> return false;<br /> }<br />}<br />void lora(){<br /> mySerial.listen();<br /> if (E22.available() > 1) {<br /> // Gelen mesaj okunuyor<br /> ResponseStructContainer rsc = E22.receiveMessage(sizeof(Signal));<br /> struct Signal data = *(Signal*) rsc.data;<br /> rsc.close();<br /> char* source = "maraşa selam";<br /> strcpy(data.type, source);<br /> data.irtifa = irtifa;<br /> data.sicaklik=sicaklik;<br /> data.gps_1 = gps_1;<br /> data.gps_2 = gps_2;<br /> data.ax[0] = ax[0];<br /> data.ax[1] = ax[1];<br /> data.ax[2] = ax[2];<br /> data.gx[0] = gx[0];<br /> data.gx[1] = gx[1];<br /> data.gx[2] = gx[2];<br /> data.ldr = analogRead(A3);<br /> ResponseStatus rs = E22.sendFixedMessage(0, 46, 18, &data, sizeof(Signal));<br /> }<br /> }
#include <TinyGPS++.h>
#include <MPU9255.h>
#include <SoftwareSerial.h>
#include “LoRa_E22.h”
// #include <SimpleKalmanFilter.h>
#include<Servo.h>
#include <Wire.h>
#include <SPI.h>
#include <Adafruit_BMP280.h>
SoftwareSerial mySerial(10, 11);
int servo_port = 9;
#define SERIAL_BAUD 9600
#define BMP_SCK (13)
#define BMP_MISO (12)
#define BMP_MOSI (11)
#define BMP_CS (10)
#define g 9.81
/*SimpleKalmanFilter irtifaKalmanFilter(1, 540, 0.01);
SimpleKalmanFilter axKalmanFilter(1, 1, 0.01);
SimpleKalmanFilter ayKalmanFilter(1, 1, 0.01);
SimpleKalmanFilter azKalmanFilter(1, 1, 0.01);
SimpleKalmanFilter gxKalmanFilter(1, 1, 0.01);
SimpleKalmanFilter gyKalmanFilter(1, 1, 0.01);
SimpleKalmanFilter gzKalmanFilter(1, 1, 0.01);*/
LoRa_E22 E22(&mySerial);
Adafruit_BMP280 bmp;
MPU9255 mpu;
TinyGPSPlus gps;
Servo servom;
int pos = 90;
struct Signal {
char type[15] = “Urfa63”;
float irtifa;
float sicaklik;
float gps_1;
float gps_2;
float ax[3];
float gx[3];
float ldr;
} data;
#define M0 7
#define M1 6
#define BTN 2
#define LED 9
static const int RXPin = 4, TXPin = 3;// Here we make pin 4 as RX of arduino & pin 3 as TX of arduino
static const uint32_t GPSBaud = 9600;
SoftwareSerial ss(RXPin, TXPin);
float gps_1 = 0,gps_2 = 0;
float ax[3] = {0.0,0.0,0.0};
float gx[3] = {0.0,0.0,0.0};
float first_pres = 0,h = 0,irtifa = 0,max_irtifa = 0,min_irtifa = 0,sicaklik = 0,isik = 0;
bool aviyonik_durum = false;
double process_acceleration(int input, scales sensor_scale )
{
/*
To get acceleration in ‘g’, each reading has to be divided by :
-> 16384 for +- 2g scale (default scale)
-> 8192 for +- 4g scale
-> 4096 for +- 8g scale
-> 2048 for +- 16g scale
*/
double output = 1;
//for +- 2g
if(sensor_scale == scale_2g)
{
output = input;
output = output/16384;
output = output*g;
}
//for +- 4g
if(sensor_scale == scale_4g)
{
output = input;
output = output/8192;
output = output*g;
}
//for +- 8g
if(sensor_scale == scale_8g)
{
output = input;
output = output/4096;
output = output*g;
}
//for +-16g
if(sensor_scale == scale_16g)
{
output = input;
output = output/2048;
output = output*g;
}
return output;
}
double process_angular_velocity(int16_t input, scales sensor_scale )
{
/*
To get rotation velocity in dps (degrees per second), each reading has to be divided by :
-> 131 for +- 250 dps scale (default value)
-> 65.5 for +- 500 dps scale
-> 32.8 for +- 1000 dps scale
-> 16.4 for +- 2000 dps scale
*/
//for +- 250 dps
if(sensor_scale == scale_250dps)
{
return input/131;
}
//for +- 500 dps
if(sensor_scale == scale_500dps)
{
return input/65.5;
}
//for +- 1000 dps
if(sensor_scale == scale_1000dps)
{
return input/32.8;
}
//for +- 2000 dps
if(sensor_scale == scale_2000dps)
{
return input/16.4;
}
return 0;
}
void setup()
{
pinMode(8,OUTPUT);
Serial.begin(SERIAL_BAUD);
servom.attach(9);
ss.listen();
ss.begin(GPSBaud);
while(!Serial) {} // Wait
Wire.begin();
pinMode(M0, OUTPUT);
pinMode(M1, OUTPUT);
digitalWrite(M0, LOW);
digitalWrite(M1, LOW);
E22.begin();
mySerial.listen();
char* source = “urfa başlat”;
strcpy(data.type, source);
ResponseStatus rs = E22.sendFixedMessage(0, 46, 18, &data, sizeof(Signal));
if (!bmp.begin(BMP280_ADDRESS_ALT, BMP280_CHIPID)) {
if (!bmp.begin()) {
Serial.println(F(“Could not find a valid BMP280 sensor, check wiring or ”
“try a different address!”));
}
/* Default settings from datasheet. */
bmp.setSampling(Adafruit_BMP280::MODE_NORMAL, /* Operating Mode. */
Adafruit_BMP280::SAMPLING_X2, /* Temp. oversampling */
Adafruit_BMP280::SAMPLING_X16, /* Pressure oversampling */
Adafruit_BMP280::FILTER_X16, /* Filtering. */
Adafruit_BMP280::STANDBY_MS_500); /* Standby time. */
}
if(mpu.init())
{
Serial.println(“MPU9255 çalıştırılamadı”);
}
else
{
Serial.println(“MPU9255 çalıştırıldı”);
}
digitalWrite(8,HIGH);
delay(1500);
digitalWrite(8,LOW);
isik = analogRead(A3);
}
//////////////////////////////////////////////////////////////////
void loop()
{
mpu.read_acc();
mpu.read_gyro();
Serial.print(“GPS: “);
Serial.print(gps_1, 6);
Serial.print(F(” , “));
Serial.print(gps_2, 6);
Serial.print(” “);
while (ss.available() > 0)
if (gps.encode(ss.read()))
displayInfo();
if (millis() > 5000 && gps.charsProcessed() < 10)
{
}
printMPU9255();
printBME280();
if (avyonik(irtifa) == true && aviyonik_durum == false){
aviyonik_durum = true;
Serial.print(“irtifaya ulaşıldı”);
digitalWrite(8,HIGH);
servom.write(pos);
pos = 0;
delay(1000);
digitalWrite(8,LOW);
}
lora();
delay(50);
}
void printMPU9255(){
ax[0] = process_acceleration(mpu.ax,scale_2g);
//ax[0] = axKalmanFilter.updateEstimate(ax[0]);
ax[1] = process_acceleration(mpu.ay,scale_2g);
//ax[1] = ayKalmanFilter.updateEstimate(ax[1]);
ax[2] = process_acceleration(mpu.az,scale_2g);
//ax[2] = azKalmanFilter.updateEstimate(ax[2]);
gx[0] = process_angular_velocity(mpu.gx,scale_250dps);
//gx[0] = gxKalmanFilter.updateEstimate(gx[0]);
gx[1] = process_angular_velocity(mpu.gy,scale_250dps);
//gx[1] = gyKalmanFilter.updateEstimate(gx[1]);
gx[2] = process_angular_velocity(mpu.gz,scale_250dps);
//gx[2] = gzKalmanFilter.updateEstimate(gx[2]);
Serial.print(” AX: “);
Serial.print(ax[0]);
//Y axis
Serial.print(” AY: “);
Serial.print(ax[1]);
//Z axis
Serial.print(” AZ: “);
Serial.print(ax[2]);
////process and print gyroscope data////
//X axis
Serial.print(” GX: “);
Serial.print(gx[0]);
//Y axis
Serial.print(” GY: “);
Serial.print(gx[1]);
//Z axis
Serial.print(” GZ: “);
Serial.print(gx[2]);
}
//////////////////////////////////////////////////////////////////
void printBME280()
{
irtifa = bmp.readAltitude(1013.25);
//irtifa = irtifaKalmanFilter.updateEstimate(irtifa);
sicaklik = bmp.readTemperature();
Serial.print(F(” Sicaklik: “));
Serial.print(sicaklik);
Serial.print(” *C”);
Serial.print(F(” İrtifa: “));
Serial.print(irtifa);
Serial.print(” m “);
Serial.println(analogRead(A3));
}
void displayInfo()
{
ss.listen();
if (gps.location.isValid())
{
gps_1 = gps.location.lat();
gps_2 = gps.location.lng();
}
else
{
//Serial.print(F(“VERİ ALİNAMADİ “));
}
}
bool avyonik(float irtifas){
if (max_irtifa – irtifas >= 0.15 && ax[1] > -2.3 && analogRead(A3) <= isik+150){
return true;
}else if (irtifas > max_irtifa){
max_irtifa = irtifas;
return false;
}else{
return false;
}
}
void lora(){
mySerial.listen();
if (E22.available() > 1) {
// Gelen mesaj okunuyor
ResponseStructContainer rsc = E22.receiveMessage(sizeof(Signal));
struct Signal data = *(Signal*) rsc.data;
rsc.close();
char* source = “maraşa selam”;
strcpy(data.type, source);
data.irtifa = irtifa;
data.sicaklik=sicaklik;
data.gps_1 = gps_1;
data.gps_2 = gps_2;
data.ax[0] = ax[0];
data.ax[1] = ax[1];
data.ax[2] = ax[2];
data.gx[0] = gx[0];
data.gx[1] = gx[1];
data.gx[2] = gx[2];
data.ldr = analogRead(A3);
ResponseStatus rs = E22.sendFixedMessage(0, 46, 18, &data, sizeof(Signal));
}
}