Reorder the channels

Fix overflow issue

git-svn-id: https://arducopter.googlecode.com/svn/trunk@449 f9c3cf11-9bcb-44bc-f272-b75c42450872

libraries/APM_ADC/APM_ADC.cpp

@@ -2,6 +2,12 @@
 	APM_ADC.cpp - ADC ADS7844 Library for Ardupilot Mega
 	Code by Jordi Muñoz and Jose Julio. DIYDrones.com
 
+	Modified by John Ihlein 6/19/2010 to:
+	1)Prevent overflow of adc_counter when more than 8 samples collected between reads.  Probably
+	  only an issue on initial read of ADC at program start.
+	2)Reorder analog read order as follows:
+	  p, q, r, ax, ay, az
+
 	This library is free software; you can redistribute it and/or
     modify it under the terms of the GNU Lesser General Public
     License as published by the Free Software Foundation; either
@@ -21,15 +27,19 @@
 		Init() : Initialization of interrupts an Timers (Timer2 overflow interrupt)
 		Ch(ch_num) : Return the ADC channel value
 
-	On Ardupilot Mega Hardware:
-	Channel 1 : Gyro Z
-	Channel 2 : Gyro X
-	Channel 3 : Gyro Y
-	Channel 4 : Acc  X
-	Channel 5 : Acc  Y
-	Channel 6 : Acc  Z
-	Channel 7 : Differential pressure sensor
-		
+	// HJI - Input definitions.  USB connector assumed to be on the left, Rx and servo
+	// connector pins to the rear.  IMU shield components facing up.  These are board
+	// referenced sensor inputs, not device referenced.
+	On Ardupilot Mega Hardware, oriented as described above:
+	Chennel 0 : yaw rate, r
+	Channel 1 : roll rate, p
+	Channel 2 : pitch rate, q
+	Channel 3 : x/y gyro temperature
+	Channel 4 : x acceleration, aX
+	Channel 5 : y acceleration, aY
+	Channel 6 : z acceleration, aZ
+	Channel 7 : Differential pressure sensor port
+
 */
 extern "C" {
   // AVR LibC Includes
@@ -40,10 +50,13 @@ extern "C" {
 
 #include "APM_ADC.h"
 
+// HJI - changed read order to p, q, r, ax, ay, az, gyro temperature, JP5 pin 3
 // Commands for reading ADC channels on ADS7844
-const unsigned char adc_cmd[9]=  { 0x87, 0xC7, 0x97, 0xD7, 0xA7, 0xE7, 0xB7, 0xF7, 0x00 };
-volatile long adc_value[8];
-volatile unsigned char adc_counter[8];
+// Note change in read order              pRate  qRate  rRate  aX     aY     aZ     temp   JP5
+// ADC Input Channel                      Ch1    Ch2    Ch0    Ch4    Ch5    Ch6    Ch3    Ch7
+const unsigned char    adc_cmd[9]     = { 0xC7,  0x97,  0x87,  0xA7,  0xE7,  0xB7,  0xD7,  0xF7,  0x00 };
+volatile long          adc_value[8]   = { 0, 0, 0, 0, 0, 0, 0, 0 };
+volatile unsigned char adc_counter[8] = { 0, 0, 0, 0, 0, 0, 0, 0 };
 
 unsigned char ADC_SPI_transfer(unsigned char data)
 {
@@ -62,20 +75,25 @@ ISR (TIMER2_OVF_vect)
 {
   uint8_t ch;
   unsigned int adc_tmp;
-  
-  //bit_set(PORTL,6); // To test performance
-  bit_clear(PORTC,4);             // Enable Chip Select (PIN PC4)
-  ADC_SPI_transfer(adc_cmd[0]);       // Command to read the first channel
+
+  //bit_set(PORTL,6);                                 // To test performance
+  bit_clear(PORTC,4);                                 // Enable Chip Select (PIN PC4)
+  ADC_SPI_transfer(adc_cmd[0]);                       // Command to read the first channel
   for (ch=0;ch<8;ch++)
       {
-      adc_tmp = ADC_SPI_transfer(0)<<8;    // Read first byte
-      adc_tmp |= ADC_SPI_transfer(adc_cmd[ch+1]);  // Read second byte and send next command
-      adc_value[ch] += adc_tmp>>3;     // Shift to 12 bits
-      adc_counter[ch]++;               // Number of samples
+      if (adc_counter[ch] >= 17)                        // HJI - Added this to prevent
+      {                                                //       overflow of adc_value
+	    adc_value[ch] = 0;
+	    adc_counter[ch] = 0;
+	  }
+	  adc_tmp = ADC_SPI_transfer(0)<<8;               // Read first byte
+      adc_tmp |= ADC_SPI_transfer(adc_cmd[ch+1]);     // Read second byte and send next command
+      adc_value[ch] += adc_tmp>>3;                    // Shift to 12 bits
+      adc_counter[ch]++;                              // Number of samples
       }
-  bit_set(PORTC,4);                // Disable Chip Select (PIN PC4)
-  //bit_clear(PORTL,6); // To test performance
-  TCNT2 = 104;        // 400 Hz
+  bit_set(PORTC,4);                                   // Disable Chip Select (PIN PC4)
+  //bit_clear(PORTL,6);                               // To test performance
+  TCNT2 = 104;                                        // 400 Hz
 }
 
 
@@ -88,42 +106,42 @@ APM_ADC_Class::APM_ADC_Class()
 void APM_ADC_Class::Init(void)
 {
   unsigned char tmp;
-  
+
   pinMode(ADC_CHIP_SELECT,OUTPUT);
-  
-  digitalWrite(ADC_CHIP_SELECT,HIGH); // Disable device (Chip select is active low)
+
+  digitalWrite(ADC_CHIP_SELECT,HIGH);                 // Disable device (Chip select is active low)
 
   // Setup Serial Port2 in SPI mode
-  UBRR2 = 0;   
-  DDRH |= (1<<PH2);  // SPI clock XCK2 (PH2) as output. This enable SPI Master mode
+  UBRR2 = 0;
+  DDRH |= (1<<PH2);                                   // SPI clock XCK2 (PH2) as output. This enable SPI Master mode
   // Set MSPI mode of operation and SPI data mode 0.
-  UCSR2C = (1<<UMSEL21)|(1<<UMSEL20); //|(0<<UCPHA2)|(0<<UCPOL2);
+  UCSR2C = (1<<UMSEL21)|(1<<UMSEL20);                 //|(0<<UCPHA2)|(0<<UCPOL2);
   // Enable receiver and transmitter.
   UCSR2B = (1<<RXEN2)|(1<<TXEN2);
   // Set Baud rate
-  UBRR2 = 2; // SPI clock running at 2.6MHz
+  UBRR2 = 2;                                          // SPI clock running at 2.6MHz
 
 
   // Enable Timer2 Overflow interrupt to capture ADC data
-  TIMSK2 = 0;  // Disable interrupts 
-  TCCR2A = 0;  // normal counting mode 
-  TCCR2B = _BV(CS21)|_BV(CS22);     // Set prescaler of 256
-  TCNT2 = 0;
-  TIFR2 = _BV(TOV2);  // clear pending interrupts; 
-  TIMSK2 =  _BV(TOIE2) ; // enable the overflow interrupt
+  TIMSK2 = 0;                                         // Disable interrupts
+  TCCR2A = 0;                                         // normal counting mode
+  TCCR2B = _BV(CS21)|_BV(CS22);                       // Set prescaler of 256
+  TCNT2  = 0;
+  TIFR2  = _BV(TOV2);                                 // clear pending interrupts;
+  TIMSK2 = _BV(TOIE2) ;                               // enable the overflow interrupt
 }
 
 // Read one channel value
-int APM_ADC_Class::Ch(unsigned char ch_num)
+int APM_ADC_Class::Ch(unsigned char ch_num)         
 {
-  int result;
+  int result;                                      
 
-  cli();  // We stop interrupts to read the variables
+  cli();                                              // We stop interrupts to read the variables
   if (adc_counter[ch_num]>0)
-	result = adc_value[ch_num]/adc_counter[ch_num];
+	result = adc_value[ch_num]/adc_counter[ch_num]);
   else
 	result = 0;
-  adc_value[ch_num] = 0;    // Initialize for next reading
+  adc_value[ch_num] = 0;                              // Initialize for next reading
   adc_counter[ch_num] = 0;
   sei();
   return(result);

libraries/APM_ADC/APM_ADC.h

@@ -1,13 +1,13 @@
 #ifndef APM_ADC_h
 #define APM_ADC_h
 
-#define bit_set(p,m) ((p) |= (1<<m)) 
+#define bit_set(p,m)   ((p) |= ( 1<<m))
 #define bit_clear(p,m) ((p) &= ~(1<<m))
 
 // We use Serial Port 2 in SPI Mode
-#define ADC_DATAOUT 51        // MOSI
-#define ADC_DATAIN  50        // MISO 
-#define ADC_SPICLOCK  52      // SCK
+#define ADC_DATAOUT     51    // MOSI
+#define ADC_DATAIN      50    // MISO
+#define ADC_SPICLOCK    52    // SCK
 #define ADC_CHIP_SELECT 33    // PC4   9 // PH6  Puerto:0x08 Bit mask : 0x40
 
 class APM_ADC_Class
@@ -16,7 +16,7 @@ class APM_ADC_Class
   public:
 	APM_ADC_Class();  // Constructor
 	void Init();
-	int Ch(unsigned char ch_num);
+	float Ch(unsigned char ch_num);     // HJI Changed from int to float
 };
 
 extern APM_ADC_Class APM_ADC;