Temperature Controller

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==== X9241A - Digital Potentiometer ====
 
==== X9241A - Digital Potentiometer ====
  
There are basically only two functions that I am after right now which are both three byte instructions: (So far this is failing miserably)
+
There are basically only two functions that I am after right now which are both three byte instructions:  
  
* Read WCR(Wiper Control Register) for the four potentiometers 0-3  
+
* Read WCR(Wiper Control Register) for the four potentiometers 0-3 (So far this is failing miserably)
 
** Send 1st byte - Address (my circuit - 01011010 or 0x2D)(binary - 0101 A3 A2 A1 A0) A values are actual pins set to high or low for an address.
 
** Send 1st byte - Address (my circuit - 01011010 or 0x2D)(binary - 0101 A3 A2 A1 A0) A values are actual pins set to high or low for an address.
 
** Send 2nd byte - Instruction (binary - 1001 (1/0)(1/0) 00) - The two bits are used to choose the potentiometer
 
** Send 2nd byte - Instruction (binary - 1001 (1/0)(1/0) 00) - The two bits are used to choose the potentiometer
 
** Read WCR requested Byte
 
** Read WCR requested Byte
* Write WCR for the four potentiometers 0-3
+
* Write WCR for the four potentiometers 0-3 (This works)
 
** Send 1st byte - Address (my circuit - 01011010 or 0x2D)(binary - 0101 A3 A2 A1 A0) A values are actual pins set to high or low for an address.
 
** Send 1st byte - Address (my circuit - 01011010 or 0x2D)(binary - 0101 A3 A2 A1 A0) A values are actual pins set to high or low for an address.
 
** Send 2nd byte - Instruction (binary - 1010 (1/0)(1/0) 00) - The two bits are used to choose the potentiometer
 
** Send 2nd byte - Instruction (binary - 1010 (1/0)(1/0) 00) - The two bits are used to choose the potentiometer

Revision as of 23:20, 10 September 2008

Welcome to Combustory


Any questions or comments:

  • Send them to - combustor@combustory.com

Contents

Warning

This page is in progress and none of the code can be considered good or complete. I am just using this as an alternate storage of the code for right now.

Summary

Functional Description of the Method

Requirements

Example of Method

Quick Guide:

Detailed Guide:

I2C

X9241A - Digital Potentiometer

There are basically only two functions that I am after right now which are both three byte instructions:

  • Read WCR(Wiper Control Register) for the four potentiometers 0-3 (So far this is failing miserably)
    • Send 1st byte - Address (my circuit - 01011010 or 0x2D)(binary - 0101 A3 A2 A1 A0) A values are actual pins set to high or low for an address.
    • Send 2nd byte - Instruction (binary - 1001 (1/0)(1/0) 00) - The two bits are used to choose the potentiometer
    • Read WCR requested Byte
  • Write WCR for the four potentiometers 0-3 (This works)
    • Send 1st byte - Address (my circuit - 01011010 or 0x2D)(binary - 0101 A3 A2 A1 A0) A values are actual pins set to high or low for an address.
    • Send 2nd byte - Instruction (binary - 1010 (1/0)(1/0) 00) - The two bits are used to choose the potentiometer
    • Send WCR Byte - Potentiometer value (binary - 00 D5 D4 D3 D2 D1 D0) - D values are the 0-63 potentiometer positions

DS1307 - Real Time Clock

The code for this very useful chip came from the [Glacial Wanderer]

A/C_Control_v.01 code

While this says v.01, don't count on it being a released v.01, I am still working on v.01, this is a back up

/*
 * A/C Control v.01
 * by <http://www.combustory.com> John Vaughters
 * Credit to:
 * Maurice Ribble - http://www.glacialwanderer.com/hobbyrobotics for RTC DS1307 code
 *
 * Turns on an LED for temperatures from analog pins 1-5 on
 * digital pins 2-6 when the temperature rises above the THRESHOLDS 1-5.
 * The program also implements a 
 * Serial Communication method that utilizes a leading CHAR for each command Described below. 
 * Commands:
 * T(1-4) - Temp1-5 Status ex. T1, T2, etc
 * C(1-4)(0-9) - Increment THRESHOLD1-4 by (1-9) ex. C15 increments THRESHOLD1 BY 5 (Note: C40 will give you a status of THRESHOLD4)
 * D(1-4)(0-9) - Decrement THRESHOLD1-4 by (1-9) ex. D59 decrements THRESHOLD5 BY 9 (Note: D10 will give you a status of THRESHOLD1)
 * A(0-1) - Manual AC on command A1 is AC on, A0 is AC off
 * F(0-1) - Manual AC on command A1 is FAN on, A0 is FAN off 
 * Q - Q Sets the date of the RTC DS1307 Chip
 */

#include "Wire.h"
#define DS1307_I2C_ADDRESS 0x68

// Global Variables
int val_cnt = 0;               // counter for the temp_val                   
int temp1Pin = 0;    // select the input pin for the Thermistor
int temp2Pin = 1;    // select the input pin for the Thermistor
int temp3Pin = 2;    // select the input pin for the Thermistor
int temp4Pin = 3;    // select the input pin for the Thermistor
int temp1_val[5] = {0,0,0,0,0};       // variable to store the value coming from the sensor
int temp2_val[5] = {0,0,0,0,0};       //           
int temp3_val[5] = {0,0,0,0,0};       //
int temp4_val[5] = {0,0,0,0,0};       //
int temp1_avg;                   // average over poll time of the temp values
int temp2_avg;
int temp3_avg;
int temp4_avg;
int duct1 = 2;                   // Ducts open or close using a digital output
int duct2 = 3;
int duct3 = 4;
int duct4 = 5;
int THRESHOLD1 = 580;    // Default theshold values
int THRESHOLD2 = 580;
int THRESHOLD3 = 580;
int THRESHOLD4 = 580;
int ac_on = 13;
int fan_on = 12;
int command = 0;       // This is the command char, in ascii form, sent from the serial port     
long polltime = 1000;  // The time to Poll the tempPins
long previousMillis = 0;        // will store last time Temp was updated
long ac_on_start = 0;     // Start A/C delay timer
long ac_on_delay = 10000;   // Time to wait before checking the ducts again
byte second, minute, hour, dayOfWeek, dayOfMonth, month, year;

  
// Convert normal decimal numbers to binary coded decimal
byte decToBcd(byte val)
{
  return ( (val/10*16) + (val%10) );
}

// Convert binary coded decimal to normal decimal numbers
byte bcdToDec(byte val)
{
  return ( (val/16*10) + (val%16) );
}

// 1) Sets the date and time on the ds1307
// 2) Starts the clock
// 3) Sets hour mode to 24 hour clock
// Assumes you're passing in valid numbers
// Watch for scope issues with Global Variables
/*void setDateDs1307(byte second,        // 0-59
                   byte minute,        // 0-59
                   byte hour,          // 1-23
                   byte dayOfWeek,     // 1-7
                   byte dayOfMonth,    // 1-28/29/30/31
                   byte month,         // 1-12
                   byte year)          // 0-99*/
void setDateDs1307()                
{
   Wire.beginTransmission(DS1307_I2C_ADDRESS);
   Wire.send(0);
   Wire.send(decToBcd(second));    // 0 to bit 7 starts the clock
   Wire.send(decToBcd(minute));
   Wire.send(decToBcd(hour));      // If you want 12 hour am/pm you need to set
                                   // bit 6 (also need to change readDateDs1307)
   Wire.send(decToBcd(dayOfWeek));
   Wire.send(decToBcd(dayOfMonth));
   Wire.send(decToBcd(month));
   Wire.send(decToBcd(year));
   Wire.endTransmission();
}

// Gets the date and time from the ds1307 and prints result
// Watch for scope issues with Global Variables
void getDateDs1307()
{
  // Reset the register pointer
  Wire.beginTransmission(DS1307_I2C_ADDRESS);
  Wire.send(0);
  Wire.endTransmission();

  Wire.requestFrom(DS1307_I2C_ADDRESS, 7);

  // A few of these need masks because certain bits are control bits
  second     = bcdToDec(Wire.receive() & 0x7f);
  minute     = bcdToDec(Wire.receive());
  hour       = bcdToDec(Wire.receive() & 0x3f);  // Need to change this if 12 hour am/pm
  dayOfWeek  = bcdToDec(Wire.receive());
  dayOfMonth = bcdToDec(Wire.receive());
  month      = bcdToDec(Wire.receive());
  year       = bcdToDec(Wire.receive());
  
  Serial.print(hour, DEC);
  Serial.print(":");
  Serial.print(minute, DEC);
  Serial.print(":");
  Serial.print(second, DEC);
  Serial.print("  ");
  Serial.print(month, DEC);
  Serial.print("/");
  Serial.print(dayOfMonth, DEC);
  Serial.print("/");
  Serial.print(year, DEC);

}


void setup() {
  Wire.begin();
  Serial.begin(57600);
  pinMode(duct1, OUTPUT);
  pinMode(duct2, OUTPUT);
  pinMode(duct3, OUTPUT);
  pinMode(duct4, OUTPUT);
  pinMode(ac_on, OUTPUT);
  pinMode(fan_on, OUTPUT);
  // Initialize Date/Time to update RTC DS1307 - You need to run the Q command right after you download this program
  // This is temporary until a more complex date time command is finished
  second = 15;
  minute = 41;
  hour = 12;
  dayOfWeek = 5;
  dayOfMonth = 5;
  month = 9;
  year = 8;
}

void loop() {
  if (millis() - previousMillis > polltime) {
    previousMillis = millis();   // remember the last time
    if (millis() - ac_on_start > ac_on_delay) { 
      if (digitalRead(duct1) || digitalRead(duct2) || digitalRead(duct3) || digitalRead(duct4)){  // If any ducts are turned on turn on the A/C
       if (digitalRead(ac_on) != HIGH) { // Check ac_on state
        digitalWrite(ac_on,HIGH);
        getDateDs1307();
        Serial.println(" - AC ON");
       }
       ac_on_start = millis();
      } 
      else if (digitalRead(ac_on) != LOW){ //Check ac_on state
       digitalWrite(ac_on,LOW);
       getDateDs1307();
       Serial.println(" - AC OFF");
      }
    }
    temp1_val[val_cnt] = analogRead(temp1Pin);    // read the value from the sensors
    temp2_val[val_cnt] = analogRead(temp2Pin);
    temp3_val[val_cnt] = analogRead(temp3Pin);
    temp4_val[val_cnt] = analogRead(temp4Pin);
    val_cnt ++;
    if (val_cnt == 5) {
      val_cnt = 0;
    }
    temp1_avg = (temp1_val[0] + temp1_val[1] + temp1_val[2] + temp1_val[3] + temp1_val[4])/5;
    temp2_avg = (temp2_val[0] + temp2_val[1] + temp2_val[2] + temp2_val[3] + temp2_val[4])/5;
    temp3_avg = (temp3_val[0] + temp3_val[1] + temp3_val[2] + temp3_val[3] + temp3_val[4])/5;
    temp4_avg = (temp4_val[0] + temp4_val[1] + temp4_val[2] + temp4_val[3] + temp4_val[4])/5;
// Check Thresholds against the Temperatures and set the ducts HIGH or LOW    
    if (temp1_avg >= THRESHOLD1) {digitalWrite(duct1, HIGH);}
    else {digitalWrite(duct1, LOW);}
    if (temp2_avg >= THRESHOLD2) {digitalWrite(duct2, HIGH);}
    else {digitalWrite(duct2, LOW);}
    if (temp3_avg >= THRESHOLD3) {digitalWrite(duct3, HIGH);}
    else {digitalWrite(duct3, LOW);}
    if (temp4_avg >= THRESHOLD4) {digitalWrite(duct4, HIGH);}
    else {digitalWrite(duct4, LOW);}
    if (Serial.available()) {      // Look for char in serial que and process if found
      command = Serial.read();
      if (command == 84) {          // If command = "T" 
        command = Serial.read();
        if (command == 49) {          // If command = "1" print the Temp1
         Serial.print("Temp1 = ");
         Serial.print(temp1_avg);           // 
         Serial.print(" ");
        }
        else if (command == 50) {      // If command = "2" print the Temp2
         Serial.print("Temp2 = ");
         Serial.print(temp2_avg);           // 
         Serial.print(" ");
        }
        else if (command == 51) {      // If command = "3" print the Temp3
         Serial.print("Temp3 = ");
         Serial.print(temp3_avg);           // 
         Serial.print(" ");
        }
        else if (command == 52) {      // If command = "4" print the Temp4
         Serial.print("Temp4 = ");
         Serial.print(temp4_avg);           // 
         Serial.print(" ");
         }
       }
      else if (command == 67) {      //If command = "C" Change Temp Threshhold
        if (Serial.available()) {
         command = Serial.read();
         if (command == 49) {        // If command = "1" print the THRESHOLD1
           command = Serial.read();
           if (command > 47 && command < 58) {          // If command is between 0-9 Increment the Threshold by number sent
             THRESHOLD1 += command - 48;                 // ASCII math to get value sent   
                  Serial.print("THRESHOLD1 = ");
                  Serial.print(THRESHOLD1);           // 
                  Serial.print(" ");
           }
         }  
         else if (command == 50) {     // If command = "2" print the THRESHOLD2
           command = Serial.read();
           if (command > 47 && command < 58) {          // If command is between 0-9 Increment the Threshold by number sent
             THRESHOLD2 += command - 48;                 // ASCII math to get value sent   
                  Serial.print("THRESHOLD2 = ");
                  Serial.print(THRESHOLD2);           // 
                  Serial.print(" ");
           }
         }
         else if (command == 51) {             // If command = "3" print the THRESHOLD3
           command = Serial.read();
           if (command > 47 && command < 58) {          // If command is between 0-9 Increment the Threshold by number sent
             THRESHOLD3 += command - 48;                 // ASCII math to get value sent   
                  Serial.print("THRESHOLD3 = ");
                  Serial.print(THRESHOLD3);           // 
                  Serial.print(" ");
           }
         }
         else if (command == 52) {             // If command = "4" print the THRESHOLD4
           command = Serial.read();
           if (command > 47 && command < 58) {          // If command is between 0-9 Increment the Threshold by number sent
             THRESHOLD4 += command - 48;                 // ASCII math to get value sent   
                  Serial.print("THRESHOLD4 = ");
                  Serial.print(THRESHOLD4);           // 
                  Serial.print(" ");
           }
         }          
        }  
      }
      else if (command == 68) {      //If command = "D" Change Temp Threshhold
        if (Serial.available()) {
         command = Serial.read();
         if (command == 49) {           // If command = "1" print the THRESHOLD1
           command = Serial.read();
           if (command > 47 && command < 58) {          // If command is between 0-9 Decrement the Threshold by number sent
             THRESHOLD1 -= command - 48;                 // ASCII math to get value sent   
                  Serial.print("THRESHOLD1 = ");
                  Serial.print(THRESHOLD1);           // 
                  Serial.print(" ");
           }
         }  
         else if (command == 50) {               // If command = "2" print the THRESHOLD2
           command = Serial.read();
           if (command > 47 && command < 58) {          // If command is between 0-9 Decrement the Threshold by number sent
             THRESHOLD2 -= command - 48;                 // ASCII math to get value sent   
                  Serial.print("THRESHOLD2 = ");
                  Serial.print(THRESHOLD2);           // 
                  Serial.print(" ");
           }
         }
         else if (command == 51) {              // If command = "3" print the THRESHOLD3
           command = Serial.read();
           if (command > 47 && command < 58) {          // If command is between 0-9 Decrement the Threshold by number sent
             THRESHOLD3 -= command - 48;                 // ASCII math to get value sent   
                  Serial.print("THRESHOLD3 = ");
                  Serial.print(THRESHOLD3);           // 
                  Serial.print(" ");
           }
         }
         else if (command == 52) {                    // If command = "4" print the THRESHOLD4
           command = Serial.read();
           if (command > 47 && command < 58) {          // If command is between 0-9 Decrement the Threshold by number sent
             THRESHOLD4 -= command - 48;                 // ASCII math to get value sent   
                  Serial.print("THRESHOLD4 = ");
                  Serial.print(THRESHOLD4);           // 
                  Serial.print(" ");
           }
         }           
        }  
      }
//****************  Warning - This is a potential for problem - Consider a manual lock out feature to lock out manual commands 
//****************  Possibly create a command to open up manual commands for a certian time period then shut them off again automatically
      else if (command == 65) {      //If command = "A" Change Temp Threshhold
       if (Serial.available()) {
        command = Serial.read();
        if (command == 49) {        // If command = "1" print the AC ON message
         getDateDs1307();
         Serial.print(" - Manual AC ON ");
         ac_on_start = millis();   // Set the AC to a delay before it can be turned off again
         digitalWrite(ac_on,HIGH);
        }
        else if (command == 48) {        // If command = "0" print the AC OFF message
         getDateDs1307();
         Serial.print(" - Manual AC OFF ");
         digitalWrite(ac_on,LOW);
        }
       } 
      } 
      else if (command == 70) {      //If command = "F" Change Temp Threshhold
       if (Serial.available()) {
        command = Serial.read();
        if (command == 49) {        // If command = "1" print the FAN ON message
         getDateDs1307();
         Serial.print(" - Manual FAN ON ");
         ac_on_start = millis();
         digitalWrite(fan_on,HIGH);
        }
        else if (command == 48) {        // If command = "0" print the FAN OFF message
         getDateDs1307();
         Serial.print(" - Manual FAN OFF ");
         digitalWrite(fan_on,LOW);
        }
       } 
      }
//********************** End of Warning Zone *******************************

// ***************  This Section Will list the Staus of the Controller
      else if (command == 83) {      //If command = "S" Print Controller Status
        getDateDs1307();
        Serial.println(" ");
        Serial.println(" ");
        Serial.print("Temp1 = ");
        Serial.println(temp1_avg);   
        Serial.print("Temp2 = ");
        Serial.println(temp2_avg);
        Serial.print("Temp3 = ");
        Serial.println(temp3_avg);   
        Serial.print("Temp4 = ");
        Serial.println(temp4_avg);   
        Serial.println(" ");
        Serial.print("THRESHOLD1 = ");
        Serial.println(THRESHOLD1);   
        Serial.print("THRESHOLD2 = ");
        Serial.println(THRESHOLD2); 
        Serial.print("THRESHOLD3 = ");
        Serial.println(THRESHOLD3); 
        Serial.print("THRESHOLD4 = ");
        Serial.println(THRESHOLD4);
        Serial.println(" ");
        if (digitalRead(duct1) == HIGH) {Serial.println("duct1 ON");}
        else{Serial.println("duct1 OFF");}
        if (digitalRead(duct2) == HIGH) {Serial.println("duct2 ON");}
        else{Serial.println("duct2 OFF");}
        if (digitalRead(duct3) == HIGH) {Serial.println("duct3 ON");}
        else{Serial.println("duct3 OFF");}
        if (digitalRead(duct4) == HIGH) {Serial.println("duct4 ON");}
        else{Serial.println("duct4 OFF");}
        Serial.println(" ");
        if (digitalRead(fan_on) == HIGH) {Serial.println("Fan ON");}
        else{Serial.println("Fan OFF");}
        if (digitalRead(ac_on) == HIGH) {Serial.println("AC  ON");}
        else{Serial.println("AC  OFF");}
        Serial.print("A/C Delay (millisec) = ");
        Serial.println(ac_on_delay);
        Serial.print("Temp Polling (millisec) = ");
        Serial.println(polltime);          
        Serial.println(" ");
        
      }
      else if (command == 81) {      //If command = "Q" Set Date
       setDateDs1307();
       getDateDs1307();
       Serial.println(" ");
      }
      Serial.println(command);     // Echo command char found in serial que
      command = 0;                 // reset command 
    }
  }
}
//*****************************************************The End***********************

A/C_Control_v.01 User Guide

Commands

Troubleshooting

Summary

When Troubleshooting a multi-functional issue, it is best practice to break down the issue into pieces and test each piece as a separate system. However, we will first run through a quick test to see if we can find any obvious issues first.

Quick Test

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