C8051F340的ADC差分输入测量值偏小是怎么回事？-第2页回答 - 平头弟

C8051F340的ADC差分输入测量值偏小是怎么回事？

2020-01-16 18:30发布

站内问答 / 51单片机

12432 12

先说一下情况：
单端测量的时候，即P1.1作为输入的时候，测量是准确的
差分测量的时候，P1.1是AIN+，P1.2是AIN-， P1.1 = 2V，P1.2 = 1V
测量结果mv = 498mv

测量条件：
参考电压是内部参考电压=2.44V，SAR CLOCK = 3MHZ，采用内部时钟=12MHZ

请帮忙看一下程序，是哪里出问题了呢？
主要是看ADC初始化和ADC中断函数

程序如下：
//-----------------------------------------------------------------------------
// Includes
//-----------------------------------------------------------------------------

#include "c8051F340.h"                // SFR declarations
#include <stdio.h>

//-----------------------------------------------------------------------------
// 16-bit SFR Definitions for 'F34x
//-----------------------------------------------------------------------------

sfr16 TMR2RL = 0xca;                // Timer2 reload value
sfr16 TMR2    = 0xcc;                // Timer2 counter
sfr16 ADC0    = 0xbd;                // ADC0 result

//-----------------------------------------------------------------------------
// Global CONSTANTS
//-----------------------------------------------------------------------------

#define SYSCLK    12000000       // SYSCLK frequency in Hz
#define BAUDRATE    115200          // Baud rate of UART in bps

sbit LED = P2^2;                      // LED='1' means ON

//-----------------------------------------------------------------------------
// Function PROTOTYPES
//-----------------------------------------------------------------------------

void SYSCLK_Init (void);
void PORT_Init (void);
void Timer2_Init(void);
void ADC0_Init(void);
void UART0_Init (void);

//-----------------------------------------------------------------------------
// MAIN Routine
//-----------------------------------------------------------------------------

void main (void)
{
PCA0MD &= ~0x40;                   // WDTE = 0 (clear watchdog timer
                                    // enable)

SYSCLK_Init ();                   // Initialize system clock to
                                    // 24.5MHz
PORT_Init ();                      // Initialize crossbar and GPIO
Timer2_Init();                   // Init Timer2 to generate
                                    // overflows to trigger ADC
UART0_Init();                      // Initialize UART0 for printf's
ADC0_Init();                      // Initialize ADC0

EA = 1;          // enable global interrupts
while (1) {                      // spin forever
}
}

//-----------------------------------------------------------------------------
// Initialization Subroutines
//-----------------------------------------------------------------------------

//-----------------------------------------------------------------------------
// SYSCLK_Init
//-----------------------------------------------------------------------------
//
// Return Value:  None
// Parameters: None
//
// This routine initializes the system clock to use the internal 12MHz
// oscillator as its clock source.  Also enables missing clock detector reset.
//
//-----------------------------------------------------------------------------
void SYSCLK_Init (void)
{
OSCICN = 0x83;                   // configure internal oscillator for
                                    // 12MHz / 1
RSTSRC = 0x04;                   // enable missing clock detector
}

//-----------------------------------------------------------------------------
// PORT_Init
//-----------------------------------------------------------------------------
//
// Return Value:  None
// Parameters: None
//
// Configure the Crossbar and GPIO ports.
// P0.4 - UART TX (push-pull)
// P0.5 - UART RX
// P1.1 - ADC0 analog input
// P2.2 - LED (push-pull)
//
//-----------------------------------------------------------------------------
void PORT_Init (void)
{
XBR0    = 0x01;                   // Enable UART0
XBR1    = 0x40;                   // Enable crossbar and weak pull-ups
P0MDOUT |= 0x10;                   // Set TX pin to push-pull
P2MDOUT |= 0x04;                   // enable LED as a push-pull output
P1MDIN &= ~0x06;                   // set P1.1 as an analog input
P1SKIP  &= ~0x06;                   //datasheet上说要skip
}

//-----------------------------------------------------------------------------
// Timer2_Init
//-----------------------------------------------------------------------------
//
// Return Value:  None
// Parameters: None
//
// Configure Timer2 to 16-bit auto-reload and generate an interrupt at 100uS
// intervals.  Timer 2 overflow automatically triggers ADC0 conversion.
//
//-----------------------------------------------------------------------------

void Timer2_Init (void)
{
TMR2CN  = 0x00;                   // Stop Timer2; Clear TF2;
                                    // use SYSCLK as timebase, 16-bit
                                    // auto-reload
CKCON  |= 0x10;                   // select SYSCLK for timer 2 source
TMR2RL  = 65535 - (SYSCLK / 10000); // init reload value for 100uS
TMR2 = 0xffff;                // set to reload immediately
TR2    = 1;                      // start Timer2
}

//-----------------------------------------------------------------------------
// ADC0_Init
//-----------------------------------------------------------------------------
//
// Return Value:  None
// Parameters: None
//
// Configures ADC0 to make single-ended analog measurements on pin P1.1
//
//-----------------------------------------------------------------------------

void ADC0_Init (void)
{
ADC0CN = 0x02;                   // ADC0 disabled, normal tracking,
                                    // conversion triggered on TMR2 overflow

REF0CN = 0x03;                   // Enable on-chip VREF and buffer

AMX0P = 0x13;                      // ADC0 positive input = P1.1
AMX0N = 0x14;                      // ADC0 negative input = P1.2
                                    //  Differential mode

ADC0CF = ((SYSCLK/3000000)-1)<<3; // set SAR clock to 3MHz

ADC0CF &= ~0x04;                   // right-justify results

EIE1 |= 0x08;                      // enable ADC0 conversion complete int.

AD0EN = 1;                         // enable ADC0
}

//-----------------------------------------------------------------------------
// UART0_Init
//-----------------------------------------------------------------------------
//
// Return Value:  None
// Parameters: None
//
// Configure the UART0 using Timer1, for <BAUDRATE> and 8-N-1.
//
//-----------------------------------------------------------------------------

void UART0_Init (void)
{
SCON0 = 0x10;                      // SCON0: 8-bit variable bit rate
                                    //       level of STOP bit is ignored
                                    //       RX enabled
                                    //       ninth bits are zeros
                                    //       clear RI0 and TI0 bits
if (SYSCLK/BAUDRATE/2/256 < 1) {
   TH1 = -(SYSCLK/BAUDRATE/2);
   CKCON |=  0x08;                // T1M = 1; SCA1:0 = xx
} else if (SYSCLK/BAUDRATE/2/256 < 4) {
   TH1 = -(SYSCLK/BAUDRATE/2/4);
   CKCON &= ~0x0B;                // T1M = 0; SCA1:0 = 01
   CKCON |=  0x01;
} else if (SYSCLK/BAUDRATE/2/256 < 12) {
   TH1 = -(SYSCLK/BAUDRATE/2/12);
   CKCON &= ~0x0B;                // T1M = 0; SCA1:0 = 00
} else if (SYSCLK/BAUDRATE/2/256 < 48) {
   TH1 = -(SYSCLK/BAUDRATE/2/48);
   CKCON &= ~0x0B;                // T1M = 0; SCA1:0 = 10
   CKCON |=  0x02;
} else {
   while (1);                      // Error.  Unsupported baud rate
}

TL1 = TH1;                         // init Timer1
TMOD &= ~0xf0;                   // TMOD: timer 1 in 8-bit autoreload
TMOD |=  0x20;
TR1 = 1;                         // START Timer1
TI0 = 1;                         // Indicate TX0 ready
}

//-----------------------------------------------------------------------------
// Interrupt Service Routines
//-----------------------------------------------------------------------------

//-----------------------------------------------------------------------------
// ADC0_ISR
//-----------------------------------------------------------------------------
//
// This ISR averages 2048 samples then prints the result to the terminal.  The
// ISR is called after each ADC conversion which is triggered by Timer2.
//
//-----------------------------------------------------------------------------

void ADC0_ISR (void) interrupt 10
{

static  long accumulator = 0;    // Accumulator for averaging
static unsigned int measurements = 2048;  // Measurement counter
unsigned long result=0;
unsigned long mV;                      // Measured voltage in mV

AD0INT = 0;                            // Clear ADC0 conv. complete flag

accumulator += ADC0;
measurements--;

if(measurements==0)
{
   measurements = 2048;
   result = accumulator / 2048;
   accumulator=0;

   // The 10-bit ADC value is averaged across 2048 measurements.
   // The measured voltage applied to P1.4 is then:
   //
   //                         Vref (mV)
   // measurement (mV) = --------------- * result (bits)
   //                      (2^10)-1 (bits)

   mV =  result * 2440 / 1023;
   printf("P1.1 voltage: %ld mV ",mV);
}

LED=~LED;                         // Toggle LED
}

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11条回答

1楼-- · 2020-01-17 20:17

过去好久，忘了来这里说明一下原因了。
问题出在差分输入和单端输入的差别上，单端输入的时候 mV = result * 2440 / 1023; 但差分输入的时候，mV = result * 2440 / 512;（或是/511）。
这个是在查数据手册的时候看到的，单端输入的最大输入值是VREF*1023/1024，差分输入的最大值是VREF*511/512，再算一算上面给的例子，得出的结果就是上一行所说的。
在英文数据手册的第42页

2楼-- · 2020-01-17 20:25

魏道志发表于 2015-5-5 16:28
新龙华的单片机我也刚接触，感觉不怎么地。。。。

还不熟悉的原因，比传统的51强多了，别的不说，就说在线调试这一点，就非常方便

3楼-- · 2020-01-18 00:59

精彩回答 2 元偷偷看……

4楼-- · 2020-01-18 05:00

c8051f 混合信号做的还是不错的就是性价比差

5楼-- · 2020-01-18 09:03

楼主说的二进制补码是什么情况？，新手求指导，我用开发板的测试程序ADC串口输出可以，想用屏12864显示就不行

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