示例#1
0
文件: adc.c 项目: ibilisim/io
void
adc_read(unsigned char *buf)
{
	unsigned char i;

	cli();
	for (i = 0; i < 8; i++) {
		buf[0] = adc_value[i] >> 8;
		buf[1] = adc_value[i] & 0x00ff;
		buf += 2;
	}
	sei();
#if 0
	unsigned char leftover;
	unsigned int value;

	leftover = 0;
	for (i = 0; i < 4; i++) {
		value = adc_sample(i);
		*buf++ = value & 0xff;
		leftover |= ((value & 0x0300) >> ((i + 1) * 2));
	}
	*buf++ = leftover;
	leftover = 0;
	for (i = 4; i < 8; i++) {
		value = adc_sample(i);
		*buf++ = value & 0xff;
		leftover |= ((value & 0x0300) >> ((i - 3) * 2));
	}
	*buf = leftover;
#endif
}
示例#2
0
文件: adcpoll.c 项目: fjrti/remix
int main(void) {
    int key;
    adc_setup();
    draw_text();
    char temp[5];
    while (1) {
        for (i = 0; i < 4; i++) {
            if (adc_isdone(adcchannels[i]) == 1)
                adc_sample(adcchannels[i], 128);
            tsample = adc_getsample(adcchannels[i]);
            if (! tsample == 0) {
                sprintf(temp, "%d", adcchannels[i]);
                term_puts(1, i + 4, temp);
                sprintf(temp, "%d", adcsmoothing[i]);
                term_puts(5, i + 4, temp);
                sprintf(temp, "%d", tsample);
                term_puts(11, i + 4, temp);
            }
        }
        key = term_getchar(NOWAIT);
        if (key != -1) {
            if (handle_kbd((int)key))
                break;
        }
    }
    term_clrscr();
    term_moveto(1, 1);
    return 0;
}
示例#3
0
//----------------------------------------------------------
//SYSTICK --> INTERRUPT call every 1ms 
//----------------------------------------------------------
void SysTick_Handler(void)
{
	
	timestamp++;
	
    if(timestamp%10==0)
        adc_sample();
    
    
    //temp control goes in here
    //temp0 = chan 5 = adc_read(5) etc (returns unsigned absolute millivolt value).
    //temp1 = chan 3
    //temp2 = chan 1
    //temp3 = chan 2
    
    //if(timestamp%1000==0)//every 1 second
	//{
	//  for(i=1;i<9;i++)
    //  	printf("Channel %u : %u mV\n", i,adc_read(i));
    //	
	
	if(timestamp%250==0) //every 100 ms
    {
		manage_heaters();
    }
	    
}
示例#4
0
文件: main.c 项目: AdamRLukaitis/RIOT
int main(void)
{
    uint32_t last = xtimer_now();
    int sample = 0;

    puts("\nRIOT ADC peripheral driver test\n");
    puts("This test will sample all available ADC lines once every 100ms with\n"
         "a 10-bit resolution and print the sampled results to STDIO\n\n");

    /* initialize all available ADC lines */
    for (int i = 0; i < ADC_NUMOF; i++) {
        if (adc_init(ADC_LINE(i)) < 0) {
            printf("Initialization of ADC_LINE(%i) failed\n", i);
            return 1;
        } else {
            printf("Successfully initialized ADC_LINE(%i)\n", i);
        }
    }

    while (1) {
        for (int i = 0; i < ADC_NUMOF; i++) {
            sample = adc_sample(ADC_LINE(i), RES);
            if (sample < 0) {
                printf("ADC_LINE(%i): 10-bit resolution not applicable\n", i);
            } else {
                printf("ADC_LINE(%i): %i\n", i, sample);
            }
        }
        xtimer_usleep_until(&last, DELAY);
    }

    return 0;
}
示例#5
0
uint16_t adc_sampleAverage(uint8_t pin, uint8_t samples) {
    uint32_t total = 0;
    for (int i = 0; i < samples; i++) {
        total = total + adc_sample(pin);
        _delay_us(100);
    }
    return (uint16_t)(total/(uint32_t)samples);
}
示例#6
0
static int read_adc(void *dev, phydat_t *res)
{
    const saul_adc_params_t *params = *((const saul_adc_params_t **)dev);
    res->val[0] = adc_sample(params->line, params->res);
    memset(&(res->val[1]), 0, 2 * sizeof(res->val[1]));
    /* Raw ADC reading has no unit */
    res->unit = UNIT_NONE;
    res->scale = 0;
    return 1;
}
示例#7
0
文件: main.c 项目: adjih/riot-apps
int main(void)
{
    printf("Testing ADC measurements\n");
    
    adc_init(ADC_DEVICE_NUMBER, ADC_RESOLUTION);
    
    for (;;) {
        int value = adc_sample(ADC_DEVICE_NUMBER, ADC_CHANNEL_NUMBER);
        printf("adc=%d\n", value);
    }
}
示例#8
0
void ADCC0_IrqHandler(void)
{
    status = ADC12_GetStatus(AT91C_BASE_ADC);
    
    for(i=0;i<7;i++) {

      if ((enchan&(1<<chns[i]) )&&ADC12_IsChannelInterruptStatusSet(status, chns[i])) {
            advalue[i] = ConvHex2mV(ADC12_GetConvertedData(AT91C_BASE_ADC, chns[i]));
            conversionDone |= 1<<chns[i];
        }
    }

	if(autosample)
        adc_sample();
}
示例#9
0
文件: app.c 项目: rmull/mittens
void
app_demo(void)
{
    uint16_t adc_result = avg_get(&(app.adc_avg)) << 4;

    if (tick_is_expired(&(app.adc_tick))) {
        app.adc_tick = tick_from_ms(1);

        avg_moving(&(app.adc_avg), adc_sample(ADC_0));
    }

    if (tick_is_expired(&(app.tlc5971_tick))) {
        app.tlc5971_tick = tick_from_ms(50);

        //for (i=0; i<12; i++) {
        //    app.bgr_buf[i] = adc_result;
        //}
        tlc5971_show(&(app.bgr_buf[0]), 4);
        //tlc5971_testpattern(&(app.bgr_buf[0]), 12);

        tlc5971_set_bgr(&(app.tlc), &(app.bgr_buf[0]));

        gpio_toggle(GPIO_LED_R);

        //max31855_read(&app.max31855);
    }

    if (tick_is_expired(&(app.servo_tick))) {
        app.servo_tick = tick_from_ms(30);

        /* Small deadband */
        /* TODO: Add deadband to PWM? */
        if ((adc_result > servo_last+16) || (adc_result < servo_last-16)) {
            pwm_set_freq(&(app.pwm_servo), 50000+(((190000-50000)/0xFFFF)*adc_result));
            servo_last = adc_result;
        }
    }

    if (tick_is_expired(&(app.lcd_tick))) {
        app.lcd_tick = tick_from_ms(500);
        serlcd_set_cursor(&(app.serlcd), SERLCD_ROW1_POS);
        serlcd_print_decimal(&(app.serlcd), adc_result);
    }
}
uint16_t hal_vdd_get_level(void)
{
  uint8_t i;
  uint16_t adc_value = 0;

  for (i = 0; i < 4; i++)
  {
    adc_value += adc_sample();
  }

  // Converting the sum of 4 10-bit samples to the number of mV
  // Which is: (adc_value * 3600) / (1024 * 4)
  // Reduced to: (adc_value * 225) / 256

  // adc_value * 225
  MD0 = (uint8_t)(adc_value & 0x00FF);
  MD4 = 225;
  MD1 = (uint8_t)(adc_value >> 8);
  MD5 = 0;

  // Wait for the calculation to complete
  for (i = 0; i < 11; i++)
  {
    _nop_();
  }

  // Charging the result for division
  MD0 = MD0;
  MD1 = MD1;
  MD2 = MD2;
  MD3 = MD3;

  // Divide by 256 (0x0100)
  MD4 = 0x00;
  MD5 = 0x01;

  // Wait for the calculation to complete
  for (i = 0; i < 17; i++)
  {
    _nop_();
  }

  return (uint16_t)((MD1<<8) | MD0);
}
示例#11
0
文件: launchpad_adc.c 项目: Ruhtu/emg
__interrupt void USCI0RX_ISR(void) {
  
  while(UCA0STAT & UCBUSY);
  
  if (UCA0RXBUF == TAKE_10_SAMPLES) {
    adc_sample(10);
    uart_send(output, 6);
  } else if (UCA0RXBUF == START_OPERATIONS) {
    RUNNING = 1;
    uart_send(">", 1);
  } else if (UCA0RXBUF == STOP_OPERATIONS) {
    RUNNING = 0;
    uart_send(".", 1);
  } else if (UCA0RXBUF == HELLO) {
    uart_send("h", 1);
  } else {
    uart_send("x", 1);
  }
  
}
示例#12
0
/*
 * main.c
 */
int main(void) {
    uart_init();
    adc_init();
    
    //Set serial as standard I/O
    stdout = stdin = &uart_stdout;

	printf("PowerLogger version 0.0.1 by deadbok.\r\n");

    //Run this code forever, but put the CPU to sleep
    while(1)
    {
        printf("\nVCC: %u\n", adc_get_vcc());
        printf("Temperature: %u\n", adc_get_temp());
        
        for(unsigned char i = 0; i < 4; i++)
        { 
            printf("Channel %u: %u\n", i, adc_sample(ADC_REF_AVCC, i));
        }
        _delay_ms(1000);
    }
}
void temperature_display(void)
{
    char buffer[LCD_CHARACTERS];

    int t_ref, t_tc1, t_tc2, t_tc3, t_tc4, t_tc5 = 0;
    float v_tc1, v_tc2, v_tc3, v_tc4, v_tc5 = 0;
    int v_ref = 0;

    // while OK or ESC are not pressed
    // show temperatures
    while (OK_SWITCH && ESC_SWITCH) {
        v_tc1 = adc_sample(0);
        v_tc2 = adc_sample(1);
        v_tc3 = adc_sample(2);
        v_tc4 = adc_sample(3);
        v_tc5 = adc_sample(4);
        v_ref = adc_sample(5);

        t_ref = reference_temperature(v_ref);
        t_tc1 = temperature(v_tc1, v_ref);
        t_tc2 = temperature(v_tc2, v_ref);
        t_tc3 = temperature(v_tc3, v_ref);
        t_tc4 = temperature(v_tc4, v_ref);
        t_tc5 = temperature(v_tc5, v_ref);

        lcd_goto(1, 1);
        sprintf(buffer, "T0: %3d\001C  T3: %3d\001C", t_ref, t_tc3);
        lcd_write(buffer);
        lcd_goto(2, 1);
        sprintf(buffer, "T1: %3d\001C  T4: %3d\001C", t_tc1, t_tc4);
        lcd_write(buffer);
        lcd_goto(3, 1);
        sprintf(buffer, "T2: %3d\001C  T5: %3d\001C", t_tc2, t_tc5);
        lcd_write(buffer);

        // delay between measurements
        Delay10KTCYx(255);
        Delay10KTCYx(255);
        Delay10KTCYx(255);
        Delay10KTCYx(255);
    }
}
示例#14
0
static void
lcd_panel_server(cyg_addrword_t p)
{
    int iX, iY, newX, newY, diffX, diffY, timeout, samples;
    cyg_uint32 event;
    diag_printf("LCD panel server here\n");
    while (TRUE) {
        cyg_semaphore_wait(&lcd_panel_sem);
        samples = 0;  iX = 0;  iY = 0;
        // Wait for press to go away (no drag support)
        timeout = 0;
        while (timeout < LCD_PANEL_TIMEOUT) {
            *(volatile cyg_uint8 *)TOUCH_CTL = 0x00;  // Disable drives
            while (*(volatile cyg_uint32 *)INTSR1 & INTSR1_EINT2) ;
            *(volatile cyg_uint8 *)TOUCH_CTL = 0x70;  // Idle state (so interrupt works)
            cyg_thread_delay(2);  // Wait 20 ms
            if (*(volatile cyg_uint32 *)INTSR1 & INTSR1_EINT2) {
                // Still pressed
                // Drive TSPY, ground TSMY, and disconnect TSPX and TSMX
                *(volatile cyg_uint8 *)TOUCH_CTL = 0x50;  
                panel_delay();
                newY = adc_sample(2);
                // Drive TSPX, ground TSMX, and disconnect TSPY and TSMY
                *(volatile cyg_uint8 *)TOUCH_CTL = 0xA0;  
                panel_delay();
                newX = adc_sample(7);
#if 0
                diag_printf("timeout: %d, ISR: %x, newX: %d, newY: %d\n", 
                            timeout, *(volatile cyg_uint32 *)INTSR1, newX, newY);
#endif
                // See if this sample makes any sense
                if (samples) {
                    diffX = abs(iX/samples - newX);
                    diffY = abs(iY/samples - newY);
                    if ((diffX <= ((iX/samples)/4)) &&
                        (diffY <= ((iY/samples)/4))) {
                        samples++;
                        iX += newX;
                        iY += newY;
                    } else {
#if 0
                        diag_printf("Discard - newX: %d, X: %d, newY: %d, Y: %d\n",
                                    newX, iX/samples, newY, iY/samples);
#endif
                        break;
                    }
                } else {
                    iX = newX;
                    iY = newY;
                    samples = 1;
                }
                timeout = 0;
            } else {
                timeout++;
            }
        }
        if (samples) {
            // Send event to user level
            event = (iX/samples)<<16 | (iY/samples);
            if (!cyg_mbox_tryput(lcd_panel_events_mbox_handle, (void *)event)) {
                diag_printf("LCD event lost: %x\n", event);
            }
        }
        *(volatile cyg_uint8 *)TOUCH_CTL = 0x00;  // Disable drives
        while (*(volatile cyg_uint32 *)INTSR1 & INTSR1_EINT2) ;
        *(volatile cyg_uint8 *)TOUCH_CTL = 0x70;  // Idle state (so interrupt works)
        cyg_thread_delay(10);
        cyg_drv_interrupt_unmask(CYGNUM_HAL_INTERRUPT_EINT2);
    }
}
示例#15
0
/*---------------------------------------------------------------*/
PROCESS_THREAD(null_app_process, ev, data)
{

	static struct etimer rxtimer;

	PROCESS_BEGIN();


	printf("Hello world Started.\n");

#ifdef SF_FEATURE_SHELL_OPT
	serial_shell_init();
	remote_shell_init();
	shell_reboot_init();
	shell_blink_init();
	shell_sky_init();
#endif

	app_conn_open(&nullApp_callback);


#ifdef ADC_SENSOR
	static uint16_t samples[ADC_SAMPLES_PER_FRAME]={0};
	uint8_t i;
//	static uint8_t samples_sorted_bytes[2*ADC_SAMPLES_PER_FRAME];
	static uint8_t sample_num = 0; //increments from 0 to samples_per_frame-1


	if (node_id != 0){
		adc_on();
		//adc_configure(0); //to sample reference voltage (Vref/2), ~2048.
		etimer_set( &rxtimer, (unsigned long)(CLOCK_SECOND/(ADC_SAMPLING_FREQ)));
	}
	else
		etimer_set(&rxtimer,CLOCK_SECOND/20);

	if(node_id != 0)
	{

	  while(1)
	  {

	    PROCESS_WAIT_EVENT_UNTIL(etimer_expired(&rxtimer));
	    etimer_reset(&rxtimer);

	    samples[sample_num]=adc_sample();
	    sample_num++;
	    if(sample_num == ADC_SAMPLES_PER_FRAME){
	    	sample_num=0;
	    	/*
	    	 * Byte order needs to be reversed because of low-endian system.
	    	 * Can be done at AP level too, if needed.
	    	 */
	    	// for(i=0;i<ADC_SAMPLES_PER_FRAME;i++){
	    	// 	samples_sorted_bytes[2*i]=(samples[i]>>8);
	    	// 	samples_sorted_bytes[2*i+1]= (samples[i]& 0xff);
	    	// }


	    	//app_conn_send(samples_sorted_bytes,sizeof(uint8_t)*ADC_SAMPLES_PER_FRAME*2);
	    	 tdma_rdc_buf_ptr = 0;
	    	 tdma_rdc_buf_send_ptr = 0;
	    	 tdma_rdc_buf_full_flg = 0;
	    	 app_conn_send(samples,sizeof(uint16_t)*ADC_SAMPLES_PER_FRAME/sizeof(uint8_t));
	    }

	  }
	}
#endif


#ifdef I2C_SENSOR
	//static rtimer_clock_t rt, del;
	int i;
	static uint8_t MPU_status = 0;
	static uint8_t sample_count = 0;
/*
	static uint8_t samples_sorted_bytes[14*MPU_SAMPLES_PER_FRAME],comp_samples_sorted_bytes[14*MPU_SAMPLES_PER_FRAME];
	static uint8_t sample_num=0, uncomp_data_len=14*MPU_SAMPLES_PER_FRAME,comp_data_len;
	static uint8_t *st;
*/


	static mpu_data sampleArray[MPU_SAMPLES_PER_FRAME];

	if (node_id != 0){

		MPU_status = 0;
		for(i = 0; i < 100 & (~MPU_status);i++)
		{
			MPU_status = mpu_enable();
		}

		if (MPU_status == 0)
			printf("MPU could not be enabled.\n");


		MPU_status = 0;
		for(i = 0; i < 100 & (~MPU_status);i++)
		{
			MPU_status = mpu_wakeup();
		}

		if (MPU_status == 0)
			printf("MPU could not be awakened.\n");

		etimer_set(&rxtimer, (unsigned long)(CLOCK_SECOND/MPU_SAMPLING_FREQ));
		}
	else
		etimer_set(&rxtimer,CLOCK_SECOND/20);

	if(node_id != 0)
	{

		while(1){
			PROCESS_WAIT_EVENT_UNTIL(etimer_expired(&rxtimer));
			etimer_reset(&rxtimer);

			mpu_data_union samples;
			int m=mpu_sample_all(&samples);
			app_conn_send((uint8_t *)(&samples),MPU_DATA_SIZE);
/*
			sampleArray[sample_count] = samples.data;

			sample_count = sample_count + 1;

			if(sample_count == MPU_SAMPLES_PER_FRAME)
			{
				sample_count = 0;
				tdma_rdc_buf_clear();

				app_conn_send(sampleArray,MPU_DATA_SIZE*MPU_SAMPLES_PER_FRAME);

			}
*/
/*
			st = &samples;
			for(i=0;i<7;i++){
				samples_sorted_bytes[2*i+14*sample_num]=*(st+2*i+1);
				samples_sorted_bytes[2*i+1+14*sample_num]= *(st+2*i);
			}
			sample_num++;

			if(sample_num==MPU_SAMPLES_PER_FRAME){
				sample_num=0;

				app_conn_send(samples_sorted_bytes,sizeof(uint8_t)*14*MPU_SAMPLES_PER_FRAME);
			}

			PRINTF("%d,%d,%d,%d,%d,%d,%d\n",samples.data.accel_x,samples.data.accel_y,samples.data.accel_z,samples.data.gyro_x,samples.data.gyro_y,
				samples.data.gyro_z,samples.data.temperature);
*/
//			app_conn_send(&samples,sizeof(mpu_data)/sizeof(uint8_t));
		}
	}

#endif

	PROCESS_END();

}
示例#16
0
文件: main.c 项目: jmesmon/reefdemon
int main(void)
{
	uint8_t last_min = 0;
	cli();

	DDRC = _BV(C_SCL);

	DDRD = _BV(D_LCD_BL) | _BV(D_LCD_SEL) | _BV(D_LCD_SCK) |
		_BV(D_LCD_MOSI) | _BV(D_LCD_RESET) | _BV(D_ALERT);

#if (FOSC == 18432000UL)
	/*
	 * Fosc = 18432000
	 * Fping = 100 Hz
	 *
	 * Fosc / Fping / 1024 = 180;
	 */
	set_timer2(_BV(CS22) | _BV(CS21) | _BV(CS20), 180);
#elif (FOSC == 7372800UL)
	/*
	 * Fosc = 7372800
	 * Fping = 100 Hz
	 *
	 * Fosc / Fping / 1024 = 72;
	 */
	set_timer2(_BV(CS22) | _BV(CS21) | _BV(CS20), 72);
#elif (FOSC == 16000000UL)
	/*
	 * Fosc = 16000000
	 * Fping = 100 Hz
	 *
	 * Fosc / Fping / 1024 = 156;
	 */
	set_timer2(_BV(CS22) | _BV(CS21) | _BV(CS20), 156);
#else
#error "unsupported FOSC freq"
#endif

	twi_master_init();
	twi_add_device(rtc_begin, rtc_end);
	twi_add_device(relay_begin, relay_end);
	sei();

	lcd_init();
	lcd_fill(0, 0, 131, 131, 0x000);

	ow_init();
	ds18b20_init();
	adc_sample();

	set_point = 25 << 8;

	while (1) {
		ds18b20_ping();

		if (last_min != time[1]) {
			temp_history[temp_history_idx] = ds18b20_temps[1];
			temp_history_idx++;
			if (temp_history_idx == ARRAY_SIZE(temp_history))
				temp_history_idx = 0;
			last_min = time[1];
		}

		if (ph == 0) {
			ph = (uint32_t)adc_data[2] << PH_IIR_SHIFT;
		} else {
			ph -= ph >> PH_IIR_SHIFT;
			ph += adc_data[2];
		}

		ui();

		if (alert)
			PORTD |= _BV(D_ALERT);
		else
			PORTD &= ~_BV(D_ALERT);

		cli();
		if (ds18b20_temps[1] < set_point)
			relays &= ~0x1;
		else if(ds18b20_temps[1] > (set_point + (1 << 4)))
			relays |= 0x1;
		sei();
	}

}
示例#17
0
文件: lab6.c 项目: ahnmelis/ee109
int main(void)
{
    unsigned char adc_result;


    // Initialize the LCD
    lcd_init();

    // Initialize the ADC
    adc_init(3);

    // Use the ADC to find a seed for rand();
    adc_result = adc_sample();
    srand(adc_result << 8 | adc_result);  // Make a 16-bit number for srand()

    // Write splash screen
	lcd_writecommand(1);
	lcd_stringout("Melissa Ahn");
		
    // Use lcd_moveto to start at an appropriate column 
    //in the bottom row to appear centered 
    lcd_moveto(1, 4);
    lcd_stringout("ee109 Lab6");
    // Delay 1 second
    _delay_ms(1000); 


    // Find a random initial position of the 'X'
	// n = 16; returns a value 0 - 15
	int pos_x = rand() % 16;


    // Display the 'X' on the screen
	lcd_writecommand(1);
    lcd_moveto(0, pos_x);
	lcd_writedata('X');

	//initializes carrot's position
	int pos_carrot = adc_sample() / 16;//rounds down
	int second_counter = 0;
	lcd_moveto(1, pos_carrot);
	lcd_writedata('^');

    while (1)               // Loop forever
	{
        
		// Do a conversion
        int new_pos_carrot = adc_sample() / 16;

	    // Move '^' to new position
        if (pos_carrot != new_pos_carrot)
	    {
		    lcd_moveto(1, pos_carrot);
		    lcd_writedata(' ');
		    lcd_moveto(1, new_pos_carrot);
		    lcd_writedata('^');
		    pos_carrot = new_pos_carrot;
	    }
	

	    // Delay
        _delay_ms(10);
	
	
        // Check if '^' is aligned with 'X'
        if (pos_carrot == pos_x)
	    {
		    second_counter++; //increase 10ms counter

        }
	
	    else
	    {
		    second_counter = 0; //reset to 0
	    }
	
	    if (second_counter != 0 && second_counter % 200 == 0)
	    {
		    lcd_moveto(1, 0);
		    lcd_stringout("You won!!!");
		    
			while(1){} //infinite loop; game ends
	    }
	
	}
	
	

    return 0;   /* never reached */
}
示例#18
0
float adc_sampleFloat(uint8_t pin) {
    return adc_sample(pin)/4096.0f;
}
示例#19
0
文件: imucode.c 项目: bobsomers/capax
int main()
{
	uint16_t adc_value[6];
	uint8_t digit[6][4];
	uint8_t i;
	uint8_t leds[9] = {0, 0, 0, 0, 0, 0, 0, 0, 0};
	uint8_t imu_comm_ctr = 0;
	uint8_t uart_buffer[3] = {0, 0, 0};
	uint8_t byte;

	// get the subsystems up and running
	uart_init();
	adc_init();
	leds_init();
	timer_init();

	timer_reset();
	while (1)
	{
		// is it time to do a sample (has 1/10th of a second passed?)
		if (timer_get() >= 11520)
		{
			// yes! do the adc sample and send it off down the uart
			
			// sample all 6 channels		
			for (i = 0; i < 6; i++)
			{
				adc_value[i] = adc_sample(i);
			}

			// convert to digits
			for (i = 0; i < 6; i++)
			{
				digit[i][3] = adc_value[i] / 1000;
				adc_value[i] = adc_value[i] % 1000;
				digit[i][2] = adc_value[i] / 100;
				adc_value[i] = adc_value[i] % 100;
				digit[i][1] = adc_value[i] / 10;
				adc_value[i] = adc_value[i] % 10;
				digit[i][0] = adc_value[i];
			}
	
			// output to the uart
			uart_send('$'); // start of line character
			for (i = 0; i < 6; i++)
			{
				uart_send(digit[i][3] + 48);
				uart_send(digit[i][2] + 48);
				uart_send(digit[i][1] + 48);
				uart_send(digit[i][0] + 48);
				uart_send('\t');
			}
			uart_send('\r');
			uart_send('\n');
			
			// increment the imu comm counter
			imu_comm_ctr++;

			// restart the timer
			timer_reset();
		}

		// update imu comm led status
		if (imu_comm_ctr > 0)
		{
			leds[IMU_COMM] = !leds[IMU_COMM];
			led_set(IMU_COMM, leds[IMU_COMM]);
			imu_comm_ctr = 0;
		}

		// try to get a byte from the uart
		if (uart_receive(&byte))
		{
			// shift the buffer
			uart_buffer[0] = uart_buffer[1];
			uart_buffer[1] = uart_buffer[2];
			uart_buffer[2] = byte;

			// middle byte MUST be a '=' for any of these to be true
			if (uart_buffer[1] == '=')
			{
				switch (uart_buffer[0])
				{
					case 'x':
						led_set(XBEE_COMM, uart_buffer[2] - 48);
						break;

					case 'g':
						led_set(GPS_LOCK, uart_buffer[2] - 48);
						break;

					case 'h':
						led_set(HEAD_LTS, uart_buffer[2] - 48);
						break;

					case 'b':
						led_set(BRAKE_LTS, uart_buffer[2] - 48);
						break;

					case 'l':
						led_set(LTURN_LTS, uart_buffer[2] - 48);
						break;

					case 'r':
						led_set(RTURN_LTS, uart_buffer[2] - 48);
						break;

					case 's':
						led_set(STARTER, uart_buffer[2] - 48);
						break;

					case 'n':
						led_set(HORN, uart_buffer[2] - 48);
						break;

					default:
						break;
				}
			}
		}
	}

	return 0;
}
示例#20
0
float adc_sampleBattery() {
    return adc_sample(ADC_BATTERY)*0.003;
}
示例#21
0
文件: adcpoll.c 项目: fjrti/remix
/* start sampling on all channels at the same time */
void start_sampling(void) {
    for (i = 0; i < 4; i++)
        adc_sample(adcchannels[i], 128);
}
PROCESS_THREAD(debug_process, ev, data) {
  char line[MAX_LINE_LENGTH];
  uint16_t read;
  uint8_t b;
  uint32_t flashAddress = 0;
  uint32_t flashCount = 0;
  uint32_t t = 0;

  PROCESS_BEGIN();

  while (1) {
    PROCESS_YIELD();

    while (dma_ring_buffer_readline(&g_debugUsartDmaInputRingBuffer, line, MAX_LINE_LENGTH)) {
      if (strcmp(line, "!CONNECT\n") == 0) {
        debug_write_line("+OK");
        debug_write_line("!clear");
        debug_write_line("!set name,dc-electronic-load");
        debug_write_line("!set description,'DC Electonic Load'");
      }
      
      else if (strcmp(line, "!RESET\n") == 0) {
        debug_write_line("+OK");
        NVIC_SystemReset();
      }

#ifdef ADC_ENABLE
      else if (strcmp(line, "!ADCLAST\n") == 0) {
        debug_write("+OK ");
        debug_write_u16(lastAdcValue[0], 10);
        debug_write(",");
        debug_write_u16(lastAdcValue[1], 10);
        debug_write(",");
        debug_write_u16(lastAdcValue[2], 10);
        debug_write(",");
        debug_write_u16(lastAdcValue[3], 10);
        debug_write(",");
        debug_write_u16(setCurrentMilliamps, 10);
        debug_write_line("");
      } else if (strcmp(line, "!ADCRAW\n") == 0) {
        debug_write("+OK ");
        debug_write_u16(adc_sample(ADC_CH0_SINGLE), 10);
        debug_write(",");
        debug_write_u16(adc_sample(ADC_CH1_SINGLE), 10);
        debug_write(",");
        debug_write_u16(adc_sample(ADC_CH2_SINGLE), 10);
        debug_write(",");
        debug_write_u16(adc_sample(ADC_CH3_SINGLE), 10);
        debug_write_line("");
      }
#endif

#ifdef FAN_ENABLE
      else if (strncmp(line, "!FANSET ", 8) == 0) {
        uint8_t fanSetOverride = atoi(line + 8);
        fan_set(fanSetOverride);
        debug_write_line("+OK");
      } else if (strcmp(line, "!FANGET\n") == 0) {
        debug_write("+OK ");
        debug_write_u8(fan_get(), 10);
        debug_write_line("");
      }
#endif

#ifdef DISP6800_ENABLE
      else if (strcmp(line, "!DISPON\n") == 0) {
        disp6800_set_display_onoff(DISP6800_DISPLAY_ON);
        debug_write_line("+OK");
      } else if (strcmp(line, "!DISPOFF\n") == 0) {
        disp6800_set_display_onoff(DISP6800_DISPLAY_OFF);
        debug_write_line("+OK");
      }
#endif

#ifdef FLASH_ENABLE
      else if (strcmp(line, "!FLASHCLEAR\n") == 0) {
        flashsst25_erase_chip();
        debug_write_line("+OK");
      } else if (strncmp(line, "!FLASHWRITE ", 12) == 0) {
        flashAddress = atoi(line + 12);
        flashCount = FLASH_BLOCK_SIZE;

        debug_write_line("+READY");
        t = time_ms();
        while (1) {
          if (flashCount <= 0) {
            debug_write("+OK ");
            debug_write_u32(flashAddress, 10);
            debug_write_line("");
            break;
          }
          if ((time_ms() - t) > 5000) {
            debug_write_line("-FAIL");
            break;
          }
          if ((read = dma_ring_buffer_read(&g_debugUsartDmaInputRingBuffer, (uint8_t*)line, MIN(flashCount, sizeof(line)))) <= 0) {
            continue;
          }
          flashsst25_write(flashAddress, (uint8_t*)line, read);
          flashAddress += read;
          flashCount -= read;
          t = time_ms();
        }
      } else if (strncmp(line, "!FLASHREAD ", 11) == 0) {
        flashAddress = atoi(line + 11);
        flashCount = FLASH_BLOCK_SIZE;
        debug_write_line("+OK");
        flashsst25_read_begin(flashAddress);
        while (flashCount > 0) {
          b = flashsst25_read();
          debug_write_bytes(&b, 1);
          flashCount--;
        }
        flashsst25_read_end();
      }
#endif

      else {
        debug_write("?Unknown command: ");
        debug_write_line(line);
      }
    }
  }

  PROCESS_END();
}