current code
Dependencies: mbed Motor TextLCD Keypad Frdmlz25 DHT11
main.cpp
- Committer:
- alex123456
- Date:
- 2018-11-01
- Revision:
- 0:dc0a6c236ec1
- Child:
- 1:c7d87cc6718a
File content as of revision 0:dc0a6c236ec1:
#include "mbed.h" #include "Dht11.h" #include "TSL2561.h" #include "Keypad.h" #include "TextLCD.h" //Setup a new plant1 data float p1_tMin=35.0, p1_tMax=45.0; float p1_lMin=300.0, p1_lMax=50000.0; float p1_hMin=60.0, p1_hMax=70.0; //Setup a new plant2 data float p2_tMin=10.0, p2_tMax=25.0; float p2_lMin=200.0, p2_lMax=50000.0; float p2_hMin=10.0, p2_hMax=40.0; //Setup a new plant3 data float p3_tMin=15.0, p3_tMax=25.0; float p3_lMin=100.0, p3_lMax=50000.0; float p3_hMin=30.0, p3_hMax=70.0; Serial PC(PTE0, PTE1); #define PC_PRINTX(z,x) if(z==1) PC.printf(x); #define PC_PRINTLNX(z,x) if(z==1) {PC.printf(x); PC.printf("\r\n");} #define PC_PRINTXY(z,x, y) if(z==1) PC.printf(x, y); #define PC_PRINTLNXY(z,x, y) if(z==1) {PC.printf(x, y); PC.printf("\r\n");} //Setup a new plant data Dht11 sensor(PTB0); TSL2561 tsl2561(TSL2561_ADDR_FLOAT);// Use the tsl2561 sensor //Setup output DigitalOut output1(PTD3); //Setup output DigitalOut output2(PTD2); //Setup output DigitalOut output3(PTE5); //Setup output DigitalOut output4(PTD5); //Setup output Keypad KeyInput(PTC4,PTC3,PTC0,PTC7,PTC11,PTC10,PTC6,PTC5); TextLCD lcd(PTB8,PTB9,PTB10,PTB11,PTE2,PTE3,TextLCD::LCD16x2); //float output1=0,output2=0,output3=0,output4=0;// lighting// ventilation// watering// heating int main() { int val_hud; char keym; uint16_t val_lig; float val_tmp,t; // int output1,output2,output3,output4; lcd.printf("-----START------"); wait(2); lcd.printf("WELCOME TO 6711"); wait(3); while (1) { lcd.printf("Please input the No. of plant"); wait(0.2); keym=KeyInput.ReadKey(); lcd.cls(); if (keym!='\0') { lcd.printf("The type of plant is %c",keym); wait(3); lcd.cls();; //while(keym!='0') { while(1) { //keym=KeyInput.ReadKey(); // input a key see if it is the key to trun out // if (keym=='\0'){ // release=1; // } // if ((keym!='\0')&&(release==1)) { // release=0; // } // get temperature and humidity data from sensor sensor.read(); t=sensor.getFahrenheit(); val_tmp=(t-32)/1.8; val_hud=sensor.getHumidity(); lcd.printf("T: %2.1fC\n", val_tmp); lcd.printf("H: %d%%\n",val_hud); wait(3); lcd.cls(); // get light data val_lig = tsl2561.getLuminosity(TSL2561_VISIBLE); //option2 x = tsl2561.getLuminosity(TSL2561_FULLSPECTRUM); //option3 x = tsl2561.getLuminosity(TSL2561_INFRARED); lcd.printf("Illu is:%d Lux\n",val_lig); wait(2); lcd.cls(); //keym=KeyInput.ReadKey(); // compare data lcd.printf("key is:%c \n",keym); wait(2); if (keym=='1') { lcd.printf("successfel:\n"); wait(2); if (val_tmp>=p1_tMin && val_tmp<=p1_tMax) { if (val_hud>=p1_hMin && val_hud<=p1_hMax) { if (val_lig>=p1_lMin && val_lig<=p1_lMax) { output1=0; output2=0; output3=0; output4=0; } else if (val_lig<p1_lMin){ output1=1; output2=0; output3=0; output4=0; } } else if (val_hud<=p1_hMin ) { if (val_lig>=p1_lMin && val_lig<=p1_lMax) { output1=0; output2=0; output3=1; output4=0; } else if (val_lig<p1_lMin){ output1=1; output2=0; output3=1; output4=0; } } else { if (val_lig>=p1_lMin && val_lig<=p1_lMax) { output1=0; output2=1; output3=0; output4=0; } else if (val_lig<=p1_lMin){ output1=1; output2=1; output3=0; output4=0; } } } else if (val_tmp<=p1_tMin){ if (val_hud>=p1_hMin && val_hud<=p1_hMax){ if (val_lig>=p1_lMin && val_lig<=p1_lMax) { output1=0; output2=0; output3=0; output4=1; } else if (val_lig<=p1_lMin){ output1=1; output2=0; output3=0; output4=1; } } else if (val_hud<=p1_hMin ) { if (val_lig>=p1_lMin && val_lig<=p1_lMax) { output1=0; output2=0; output3=1; output4=1; } else if (val_lig<=p1_lMin){ output1=1; output2=0; output3=1; output4=1; } } else { if (val_lig>=p1_lMin && val_lig<=p1_lMax) { output1=0; output2=1; output3=0; output4=1; } else if (val_lig<=p1_lMin){ output1=1; output2=1; output3=0; output4=1; } } } else{ if (val_hud>=p1_hMin && val_hud<=p1_hMax){ if (val_lig>=p1_lMin && val_lig<=p1_lMax) { output1=0; output2=1; output3=1; output4=0; } else if (val_lig<=p1_lMin){ output1=1; output2=1; output3=1; output4=0; } } else if (val_hud<=p1_hMin ) { if (val_lig>=p1_lMin && val_lig<=p1_lMax) { output1=0; output2=1; output3=1; output4=0; } else if (val_lig<=p1_lMin){ output1=1; output2=1; output3=1; output4=0; } } else{ if (val_lig>=p1_lMin && val_lig<=p1_lMax) { output1=0; output2=1; output3=0; output4=0; } else if (val_lig<=p1_lMin){ output1=1; output2=1; output3=0; output4=0; } } } //else if (keym=='2') { // Output(keym,val_tmp,val_hud,val_lig,p2_tMin,p2_tMax,p2_hMin,p2_hMax,p2_lMin,p2_lMax); // lcd.printf("%d",output1); // } // else // Output(keym,val_tmp,val_hud,val_lig,p3_tMin,p3_tMax,p3_hMin,p3_hMax,p3_lMin,p3_lMax); } } } } }