[资料分享] MSP430 G2553 Launchpad电容测量测试代码

fish001 2018-9-21 20:31 楼主

四、测试代码
main.c程序：

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  1 // C meter 2015.9.26
  2 //
  3 // P1.5(TA0.0) --[||||]----------- P1.4(CA3)
  4 //          R=10kOhm    |
  5 //                      -----
  6 //                cap -----
  7 //                      |
  8 //                      GND
  9 //  http://zlbg.cnblogs.com
10 /////////////////////////////////////////
11
12 #include "io430.h"
13
14 #define LED1 BIT0 // P1.0, red led
15 #define LED2 BIT6 // P1.6, green led
16
17 #define VMEAS BIT4 // P1.4(CA4) for voltage measurement of the cap
18 #define VCTRL BIT5 // P1.5(TA0.0) for voltage control
19 #define PUSH2 BIT3 // P1.3, button
20
21 #define RXD BIT1 //P1.1
22 #define TXD BIT2 //P1.2
23
24 #define READY 0
25 #define CHARGING 1
26 #define DISCHARGING 2
27 #define FINISH_DC 3
28
29 #define R_SERIES 10000 //10kOhm
30 #define LN4 1.3863
31
32 //functions for C meter
33 void P1Init(void);
34 void TA0Init(void);
35 void CAInit(void);
36
37 void setReadyStatus(void);
38
39 //functions for printf()
40 void sendByte(unsigned char);
41 void printf(char *, ...);
42 void initUART(void);
43
44 char state = READY;
45 unsigned char overflowsCharging = 0;
46 unsigned char overflowsDischarging = 0;
47 unsigned char i = 0;
48 float capacitance = 0; // unit: nF
49
50 void main(void)
51 {
52    // Stop watchdog timer to prevent time out reset
53    WDTCTL = WDTPW + WDTHOLD;
54
55    // DCO setup
56    BCSCTL1 = CALBC1_1MHZ; //running at 1Mhz
57    DCOCTL = CALDCO_1MHZ;
58
59    // P1 setup
60    P1Init();
61
62    // Timer0 setup
63    TA0Init();
64
65    // CA setup
66    CAInit();
67
68    // UART setup
69    initUART();
70
71    setReadyStatus();
72
73    __enable_interrupt();
74
75    // enter LP mode
76    LPM0;
77
78 }
79
80
81 void P1Init(void)
82 {
83    P1OUT = 0;
84
85    // set P1.3 (PUSH2) as input with pullup
86    P1OUT |= PUSH2;
87    P1REN |= PUSH2;
88
89    // set P1.0, P1.6, P1.5 as output
90    P1DIR |= LED1 + LED2 + VCTRL;
91
92    // enable P1.3 interrupt
93    P1IES |= PUSH2; // high -> low transition
94    P1IFG &= ~PUSH2; // clear the flag
95    P1IE |= PUSH2;
96 }
97
98 void TA0Init(void)
99 {
100    // use SMCLK (1MHz), no div, clear, halt
101    TA0CTL = TASSEL_2 + ID_0 + MC_0 + TACLR;
102
103    // TA0CCTL0: compare mode, enable interrupt
104    TA0CCTL0 = CCIE;
105
106    // TA0CCTL1: capture mode, no capture, CCI1B(CAOUT) input, syn capture
107    // interrupt enabled
108    TA0CCTL1 = CCIS_1 + SCS + CAP + CCIE;
109 }
110
111 void CAInit(void)
112 {
113    //0.25 Vcc ref on V+, halt
114    CACTL1 = CAREF_1 + CAIES;
115    // input CA4 (P1.4), remove the jumper) on V-, filter on
116    CACTL2 = P2CA3 + CAF;
117 }
118
119 void setReadyStatus(void)
120 {
121    state = READY;
122    // light led2 and turn off led1 to indicate ready
123    P1OUT &= ~LED1;
124    P1OUT |= LED2;
125
126    //stop and clear timer, stop T0_A1 capture & CA+
127    TA0CTL = TASSEL_2 + ID_0 + MC_0 + TACLR;
128    TA0CCTL1 &= ~CM_3;
129    CACTL1 &= ~CAON;
130
131    overflowsCharging = 0;
132 }
133
134 void initUART(void) {
135       //config P1.1 RXD, P1.2 TXD
136       P1SEL |= TXD + RXD;
137       P1SEL2 |= TXD + RXD;
138
139       //reset UCA0, to be configured
140       UCA0CTL1 = UCSWRST;
141       //config
142       UCA0CTL1 |= UCSSEL_2; //SMCLK
143       UCA0BR0 = 104;
144       UCA0BR1 = 0;//1MHz baut rate = 9600 8-N-1
145       UCA0MCTL = UCBRS0; // Modulation UCBRSx = 1
146       //make UCA0 out of reset
147       UCA0CTL1 &= ~UCSWRST;
148 }
149
150
151 void sendByte(unsigned char byte )
152 {
153    while (!(IFG2&UCA0TXIFG));          // USCI_A0 TX buffer ready?
154    UCA0TXBUF = byte;             // TX -> RXed character
155 }
156
157 #pragma vector = PORT1_VECTOR
158 __interrupt void P1_ISR(void)
159 {
160    if((P1IFG & PUSH2) == PUSH2)
161    {
162       P1IFG &= ~PUSH2; //clear the flag
163       switch(state)
164       {
165       case READY:
166          state = CHARGING;
167          // light LED1 and turn off LED2, indicate a busy status
168          P1OUT |= LED1;
169          P1OUT &= ~LED2;
170          //start timer, continuous mode
171          TACTL |= MC_2;
172          //start charging
173          P1OUT |= VCTRL;
174          break;
175       default:
176          break;
177       }
178
179    }
180    else
181    {
182       P1IFG = 0;
183    }
184 }
185
186 #pragma vector = TIMER0_A0_VECTOR
187 __interrupt void CCR0_ISR(void)
188 {
189    switch(state)
190    {
191    case CHARGING:
192       if (++overflowsCharging == 50) // wait 6.5535*50 = 3.28s
193       {
194          state = DISCHARGING;
195          CACTL1 |= CAON; // turn on CA+
196          TA0CCTL1 |= CM_1; // start TA1 capture on rising edge
197          P1OUT &= ~VCTRL; // start discharging
198          overflowsDischarging = 0;
199       }
200       break;
201    case DISCHARGING:
202       overflowsDischarging++;
203    default:
204       break;
205
206    }
207
208 }
209
210 #pragma vector = TIMER0_A1_VECTOR
211 __interrupt void CCR1_ISR(void)
212 {
213    TA0CTL &= ~MC_3; //stop timer
214    TA0CCTL1 &= ~CCIFG; // clear flag
215    switch(state)
216    {
217    case DISCHARGING:
218       state = FINISH_DC;
219       capacitance = (overflowsDischarging*65536 + TA0CCR1)*1000 / (R_SERIES*LN4); //nF
220       //send result to PC
221       printf("Capatitance:  %n", (long unsigned)capacitance);
222       printf(" nF\r\n");
223
224       setReadyStatus();
225       break;
226    default:
227       break;
228    }
229 }
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