DSP的ADC设置与使⽤详解--以F28069为例该解决的问题早晚都要解决的。
ADC of F28069 Overview
single 12-bit converter fed by two sample and hold circuits
The basic principle of operation is centered around the configurations of individual conversions, called SOC’s, or Start-Of-Conversions.
特性
12-bit ADC core with built-in dual sample-and-hold (S+H)
Simultaneous sampling or sequential sampling modes
Full range analog input: 0 V to 3.3 V fixed, or VREFHI/VREFLO ratiometric
Up to 16-channel, multiplexed inputs
16 SOC’s, configurable for trigger, sample window, and channel
16 result registers (individually addressable) to store conversion values
Multiple trigger sources
S/W - software immediate start
ePWM 1-8
GPIO XINT2
CPU Timers 0/1/2
ADCINT1/2
9 flexible PIE interrupts, can configure interrupt request after any conversion
SOC Principle of Operation
3 configurations — the trigger source that starts the conversion, the channel to convert, and the acquisition (sample)
window size.
Each SOC is independently configured and can have any combination of the trigger, channel, and sample window size available
The trigger source for SOCx is configured by a combination of the TRIGSEL field in the ADCSOCxCTL
register and the appropriate bits in the ADCINTSOCSEL1 or ADCINTSOCSEL2 register. Software can
also force an SOC event with the ADCSOCFRC1 register. The channel and sample window size for SOCx are configured with the CHSEL and ACQPS fields of the ADCSOCxCTL register.
⼲货在这⾥
1. 预先配置单个SOC的3个配置:the trigger source (触发源), the channel to convert (采样转换频道ADC 16个任选), and
the acquisition (sample) window size(采样窗⼝长度,根据硬件电路计算)
2. 假设,我们将EPWM4A 作为 ADCINB0 和 ADCINB1共同的触发源。则应该:
AdcRegs.ADCSOC0CTL.bit.CHSEL =8;//SOC0 to sample ADCB0, see at the datasheet page 548
AdcRegs.ADCSOC1CTL.bit.TRIGSEL =11;// set SOC1 start trigger on EPWM1A, due to round-robin SOC0 converts first then SOC1
AdcRegs.ADCSOC1CTL.bit.CHSEL =9;//SOC0 to sample ADCB0, see at the datasheet page 548
AdcRegs.ADCSOC1CTL.bit.TRIGSEL =11;// set SOC1 start trigger on EPWM1A, due to round-robin SOC0 converts first then SOC1
AdcRegs.ADCSOC0CTL.bit.ACQPS =6;// set SOC0 S/H Window to 7 ADC Clock Cycles
AdcRegs.ADCSOC1CTL.bit.ACQPS =6;// set SOC1 S/H Window to 7 ADC Clock Cycles
3. TRIGSEL的11值,对应的是EPWM4 的ADCSOCA。如何设置EPWM4如何发出ADCSOCA呢? EPwm1Regs.ETSEL.bit.SOCAEN =0;// Disable SOC on A group
EPwm1Regs.ETSEL.bit.SOCASEL =1;// Select SOC on up-count
EPwm1Regs.ETSEL.bit.SOCAEN =0;// enable SOC on A group
4. 当EPWM4A发出其SOCA时,SOC0开始接收信号,并经过ACQPS+1个ADC Clock后开始进⾏模数转换。默认情况下,由于 SOC0和SOC1公⽤同⼀个触发源,SOC0先开始。
5. 当模数转换结束后,ADC模块应当告诉DSP(发出中断信号),使其开始进⾏相关的中断程序;由于SOC0和SOC1⽤了同⼀个触发 源,并且采样执⾏顺序为SOC0 - SOC1,故中断信号应该让SOC1的结束信号EOC1发出。
AdcRegs.INTSEL1N2.bit.INT1E =1;// Enabled ADCINT1
AdcRegs.INTSEL1N2.bit.INT1CONT =0;// Disable ADCINT1 Continuous mode
AdcRegs.INTSEL1N2.bit.INT1SEL =1;// setup EOC1 to trigger ADCINT1 to fire
然后,在主程序中规定ADCINT1所对应的中断服务程序应该是什么,此处为ISR1(⾃⼰定义的函数)
EALLOW;
PieVectTable.ADCINT1 =&ISR1;//function for ADCA interrupt 1
EDIS;
在中断函数中,不要忘了给ADCINT1的标志位清零,以便接受开始下⼀次的SOC。
AdcRegs.ADCINTFLGCLR.bit.ADCINT1 =1;//Clear ADCINT1 flag reinitialize for next SOC
6. 在ADC结束之后,转换完成的数据存储到哪⾥了呢?在F28069中,有这样⼀个寄存器AdcResult,⽤于保存ADC的结果。相关的结
构体定义如下:
struct ADC_RESULT_REGS {
Uint16 ADCRESULT0;// Conversion Result Buffer 0
Uint16 ADCRESULT1;// Conversion Result Buffer 1
Uint16 ADCRESULT2;// Conversion Result Buffer 2
Uint16 ADCRESULT3;// Conversion Result Buffer 3
Uint16 ADCRESULT4;// Conversion Result Buffer 4
Uint16 ADCRESULT5;// Conversion Result Buffer 5
Uint16 ADCRESULT6;// Conversion Result Buffer 6
Uint16 ADCRESULT7;// Conversion Result Buffer 7
Uint16 ADCRESULT8;// Conversion Result Buffer 8
Uint16 ADCRESULT9;// Conversion Result Buffer 9
Uint16 ADCRESULT10;// Conversion Result Buffer 10
Uint16 ADCRESULT11;// Conversion Result Buffer 11
Uint16 ADCRESULT12;// Conversion Result Buffer 12
Uint16 ADCRESULT13;// Conversion Result Buffer 13
Uint16 ADCRESULT14;// Conversion Result Buffer 14
Uint16 ADCRESULT15;// Conversion Result Buffer 15
};
此处,ADCRESULTx的编号和SOC是对应的。也即SOC0的数据会存到AdcResult.ADCRESULT0中
7. 另外,有⼀个容易忽视的设置,也即,在此例中,我们需要⽤到ADC的中断源ADCINT1,很明显,DSP⾃⾝是不会默认把所有的可
⽤中断源都开启的,因此我们需要将我们要⽤到的中断源告诉DSP。
参见page175由中断表我们可以知道,ADCINT1在终端表中对应的位置为INT1.1,ADCINT2对应INT1.2。我们只⽤到了
ADCINT1,因此,将对应的中断源开启。
PieCtrlRegs.PIEIER1.bit.INTx1 =1;
⽬前,我们将group1中的INT1.1使能了,但是,我们怎么样将Group1使能呢?
IER |= M_INT1;// Enable group 1 interrupts
⾸先,|=操作符为 按位或并赋值运算符 。C |= 2 等同于 C = C | 2。
IER为Interrupt Enable Register,为group的使能位。M_INT1 = 0x0001,相应地,如果要使能其他group,则需:
#define M_INT1 0x0001
#define M_INT2 0x0002
#define M_INT3 0x0004
#define M_INT4 0x0008
#define M_INT5 0x0010
#define M_INT6 0x0020
#define M_INT7 0x0040
#define M_INT8 0x0080
#define M_INT9 0x0100
#define M_INT10 0x0200
#define M_INT11 0x0400
#define M_INT12 0x0800
8导#define M_INT13 0x1000
#define M_INT14 0x2000
#define M_DLOG 0x4000
#define M_RTOS 0x8000
这样,group1使能,group1中的int1.1也被使能,这时候DSP就可以产⽣我们需要的中断信号了。
另外,再加上两句
EINT;// Enable Global interrupt INTM
ERTM;// Enable Global realtime interrupt DBGM
这两句代码没看懂,但是代码的注释还是挺简单的。
⼲货结束,开始愉快灌⽔。
TI例程
// Configure ADC
//>>>>>>>>>>>>>>> // Description://! \addtogroup f2806x_example_list
//! <h1> ADC Start of Conversion (adc_soc)</h1>
//!
//! This ADC example uses ePWM1 to generate a periodic ADC SOC - ADCINT1.
//! Two channels are converted, ADCINA4 and ADCINA2.
//!
//! \b Watch \b Variables \n
//! - Voltage1[10] - Last 10 ADCRESULT0 values
//! - Voltage2[10] - Last 10 ADCRESULT1 values
//! - ConversionCount - Current result number 0-9
//! - LoopCount - Idle loop counter
//
//
//>>>>>>>>>>>>>>> // $TI Release: F2806x C/C++ Header Files and Peripheral Examples V151 $// $Release Date: February 2, 2016 $
// $Copyright: Copyright (C) 2011-2016 Texas Instruments Incorporated -
// www.ti/ ALL RIGHTS RESERVED $
//>>>>>>>>>>>>>>> #include"DSP28x_Project.h"// Device Headerfile and Examples Include File// Prototype statements for functions found within this file.
__interrupt void adc_isr(void);
void Adc_Config(void);
// Global variables used in this example:
Uint16 LoopCount;
Uint16 ConversionCount;
Uint16 Voltage1[10];
Uint16 Voltage2[10];
main()
{
// Step 1. Initialize System Control:
// PLL, WatchDog, enable Peripheral Clocks
// This example function is found in the F2806x_SysCtrl.c file.
InitSysCtrl();
// Step 2. Initialize GPIO:
KDYTT// This example function is found in the F2806x_Gpio.c file and
// illustrates how to set the GPIO to it's default state.
// InitGpio(); // Skipped for this example
/
/ Step 3. Clear all interrupts and initialize PIE vector table:
// Disable CPU interrupts
DINT;
// Initialize the PIE control registers to their default state.
// The default state is all PIE interrupts disabled and flags
// are cleared.
// This function is found in the F2806x_PieCtrl.c file.
InitPieCtrl();
// Disable CPU interrupts and clear all CPU interrupt flags:
IER =0x0000;
IER =0x0000;
价格搜索
IFR =0x0000;
// Initialize the PIE vector table with pointers to the shell Interrupt
// Service Routines (ISR).
// This will populate the entire table, even if the interrupt
// is not used in this example. This is useful for debug purposes.
// The shell ISR routines are found in
// This function is found in
InitPieVectTable();
// Interrupts that are used in this example are re-mapped to
// ISR functions found within this file.
EALLOW;// This is needed to write to EALLOW protected register
PieVectTable.ADCINT1 =&adc_isr;
EDIS;// This is needed to disable write to EALLOW protected registers
// Step 4. Initialize all the Device Peripherals:
// This function is found in F2806x_InitPeripherals.c
// InitPeripherals(); // Not required for this example
InitAdc();// For this example, init the ADC
AdcOffsetSelfCal();
// Step 5. User specific code, enable interrupts:
// Enable ADCINT1 in PIE
PieCtrlRegs.PIEIER1.bit.INTx1 =1;// Enable INT 1.1 in the PIE
表面热电阻IER |= M_INT1;// Enable CPU Interrupt 1
EINT;// Enable Global interrupt INTM
ERTM;// Enable Global realtime interrupt DBGM
首饰焊接LoopCount =0;
ConversionCount =0;
// Configure ADC
EALLOW;
AdcRegs.ADCCTL2.bit.ADCNONOVERLAP =1;// Enable non-overlap mode
AdcRegs.ADCCTL1.bit.INTPULSEPOS =1;// ADCINT1 trips after AdcResults latch
AdcRegs.INTSEL1N2.bit.INT1E =1;// Enabled ADCINT1
AdcRegs.INTSEL1N2.bit.INT1CONT =0;// Disable ADCINT1 Continuous mode
AdcRegs.INTSEL1N2.bit.INT1SEL =1;// setup EOC1 to trigger ADCINT1 to fire
AdcRegs.ADCSOC0CTL.bit.CHSEL =4;// set SOC0 channel select to ADCINA4
AdcRegs.ADCSOC1CTL.bit.CHSEL =2;// set SOC1 channel select to ADCINA2
AdcRegs.ADCSOC0CTL.bit.TRIGSEL =5;// set SOC0 start trigger on EPWM1A, due to round-robin SOC0 converts first then SOC1 AdcRegs.ADCSOC1CTL.bit.TRIGSEL =5;// set SOC1 start trigger on EPWM1A, due to round-robin SOC0 converts first then SOC1 AdcRegs.ADCSOC0CTL.bit.ACQPS =6;// set SOC0 S/H Window to 7 ADC Clock Cycles, (6 ACQPS plus 1)
AdcRegs.ADCSOC1CTL.bit.ACQPS =6;// set SOC1 S/H Window to 7 ADC Clock Cycles, (6 ACQPS plus 1)
EDIS;
雨水弃流井// Assumes ePWM1 clock is already enabled in InitSysCtrl();
EPwm1Regs.ETSEL.bit.SOCAEN =1;// Enable SOC on A group
EPwm1Regs.ETSEL.bit.SOCASEL =4;// Select SOC from CMPA on upcount
EPwm1Regs.ETPS.bit.SOCAPRD =1;// Generate pulse on 1st event
EPwm1Regs.CMPA.half.CMPA =0x0080;// Set compare A value
EPwm1Regs.TBPRD =0xFFFF;// Set period for ePWM1
EPwm1Regs.TBCTL.bit.CTRMODE =0;// count up and start
// Wait for ADC interrupt
for(;;)
{
LoopCount++;
}
}