Reworked instant wind speed calculation and extended the available wind speed return values

2016-01-17 14:56:12 +01:00 · 2016-01-17 14:56:12 +01:00 · 61f1516369
parent 0cb80b0605
commit 61f1516369
3 changed files with 111 additions and 46 deletions
--- a/examples/zolertia/zoul/test-weather-meter.c
+++ b/examples/zolertia/zoul/test-weather-meter.c
@ -56,8 +56,8 @@
 #include <stdint.h>
 /*---------------------------------------------------------------------------*/
 #define READ_SENSOR_PERIOD          CLOCK_SECOND
-#define ANEMOMETER_THRESHOLD_TICK   8
+#define ANEMOMETER_THRESHOLD_TICK   13  /**< 16 Km/h */
-#define RAIN_GAUGE_THRESHOLD_TICK   15
+#define RAIN_GAUGE_THRESHOLD_TICK   15  /**< each increment of 4.19 mm */
 /*---------------------------------------------------------------------------*/
 static struct etimer et;
 /*---------------------------------------------------------------------------*/
@ -67,6 +67,7 @@ AUTOSTART_PROCESSES(&test_weather_meter_sensors);
 static void
 rain_callback(uint16_t value)
 {
  /* To calculate ticks from mm of rain, divide by 0.2794 mm */
  printf("*** Rain gauge over threshold (%u ticks)\n", value);
  weather_meter.configure(WEATHER_METER_RAIN_GAUGE_INT_OVER,
                          (value + RAIN_GAUGE_THRESHOLD_TICK));
@ -75,6 +76,12 @@ rain_callback(uint16_t value)
 static void
 wind_speed_callback(uint16_t value)
 {
  /* This checks for instant wind speed values (over a second), the minimum
   * value is 1.2 Km/h (one tick), as the reference is 2.4KM/h per rotation, and
   * the anemometer makes 2 ticks per rotation.  Instant speed is calculated as
   * multiples of this, so if you want to check for 16Km/h, then it would be 13
   * ticks
   */
  printf("*** Wind speed over threshold (%u ticks)\n", value);
 }
 /*---------------------------------------------------------------------------*/
@ -85,6 +92,9 @@ PROCESS_THREAD(test_weather_meter_sensors, ev, data)
  static uint32_t rain;
  static uint16_t wind_speed;
  static uint16_t wind_dir;
  static uint16_t wind_speed_avg;
  static uint16_t wind_speed_avg_2m;
  static uint16_t wind_speed_max;
  /* Register the callback handler when thresholds are met */
  WEATHER_METER_REGISTER_ANEMOMETER_INT(wind_speed_callback);
@ -109,6 +119,9 @@ PROCESS_THREAD(test_weather_meter_sensors, ev, data)
    rain = weather_meter.value(WEATHER_METER_RAIN_GAUGE);
    wind_speed = weather_meter.value(WEATHER_METER_ANEMOMETER);
    wind_dir = weather_meter.value(WEATHER_METER_WIND_VANE);
    wind_speed_avg = weather_meter.value(WEATHER_METER_ANEMOMETER_AVG);
    wind_speed_avg_2m = weather_meter.value(WEATHER_METER_ANEMOMETER_AVG_2M);
    wind_speed_max = weather_meter.value(WEATHER_METER_ANEMOMETER_MAX);
    #if WEATHER_METER_RAIN_RETURN_TICKS
      rain *= WEATHER_METER_AUX_RAIN_MM;
@ -122,8 +135,12 @@ PROCESS_THREAD(test_weather_meter_sensors, ev, data)
      printf("Rain: 0.%lu mm, ", rain);
    }
-    printf("Wind (dir: %u deg, ", wind_dir); 
+    printf("Wind dir: %u deg,\n", wind_dir); 
-    printf("speed %u m/h)\n", wind_speed); 
+    printf("Wind speed: %u m/h ", wind_speed);
    printf("(%u m/h avg, %u m/h 2m avg, %u m/h max)\n\n", wind_speed_avg,
                                                          wind_speed_avg_2m,
                                                          wind_speed_max);
    etimer_reset(&et);
  }
--- a/platform/zoul/dev/weather-meter.c
+++ b/platform/zoul/dev/weather-meter.c
@ -53,7 +53,7 @@
 #include "dev/gpio.h"
 #include "dev/ioc.h"
 #include "sys/timer.h"
-#include "sys/etimer.h"
+#include "sys/rtimer.h"
 /*---------------------------------------------------------------------------*/
 #define DEBUG 0
 #if DEBUG
@ -62,7 +62,7 @@
 #define PRINTF(...)
 #endif
 /*---------------------------------------------------------------------------*/
-#define DEBOUNCE_DURATION  (CLOCK_SECOND >> 4)
+#define DEBOUNCE_DURATION  (CLOCK_SECOND >> 6)
 /*---------------------------------------------------------------------------*/
 #define ANEMOMETER_SENSOR_PORT_BASE  GPIO_PORT_TO_BASE(ANEMOMETER_SENSOR_PORT)
 #define ANEMOMETER_SENSOR_PIN_MASK   GPIO_PIN_MASK(ANEMOMETER_SENSOR_PIN)
@ -77,7 +77,7 @@ static uint8_t enabled;
 process_event_t anemometer_int_event;
 process_event_t rain_gauge_int_event;
 /*---------------------------------------------------------------------------*/
-static struct etimer et;
+static struct rtimer rt;
 static struct timer debouncetimer;
 /*---------------------------------------------------------------------------*/
 typedef struct {
@ -87,12 +87,65 @@ typedef struct {
  uint16_t int_thres;
 } weather_meter_sensors_t;
 typedef struct {
  uint16_t value_max;
  uint64_t ticks_avg;
  uint64_t value_avg;
  uint32_t value_buf_2m;
  uint16_t value_avg_2m;
 } weather_meter_ext_t;
 typedef struct {
  uint16_t wind_vane;
  weather_meter_sensors_t rain_gauge;
  weather_meter_sensors_t anemometer;
 } weather_meter_sensors;
 static weather_meter_sensors weather_sensors;
 static weather_meter_ext_t anemometer;
 /*---------------------------------------------------------------------------*/
 void
 rt_callback(struct rtimer *t, void *ptr)
 {
  uint32_t wind_speed;
  /* Disable to make the calculations in an interrupt-safe context */
  GPIO_DISABLE_INTERRUPT(ANEMOMETER_SENSOR_PORT_BASE,
                         ANEMOMETER_SENSOR_PIN_MASK);
  wind_speed = weather_sensors.anemometer.ticks;
  wind_speed *= WEATHER_METER_ANEMOMETER_SPEED_1S;
  weather_sensors.anemometer.value = (uint16_t)wind_speed;
  anemometer.ticks_avg++;
  anemometer.value_avg += weather_sensors.anemometer.value;
  anemometer.value_buf_2m += weather_sensors.anemometer.value;
  /* Take maximum value */
  if(weather_sensors.anemometer.value > anemometer.value_max) {
    anemometer.value_max = weather_sensors.anemometer.value;
  }
  /* Average every 2 minutes */
  if(!(anemometer.ticks_avg % 120)) {
    if(anemometer.value_buf_2m) {
      anemometer.value_avg_2m = anemometer.value_buf_2m / 120;
      anemometer.value_buf_2m = 0;
    } else {
      anemometer.value_avg_2m = 0;
    }
  }
  /* Check for roll-over */
  if(!anemometer.ticks_avg) {
    anemometer.value_avg = 0;
  }
  weather_sensors.anemometer.ticks = 0;
  /* Enable the interrupt again */
  GPIO_ENABLE_INTERRUPT(ANEMOMETER_SENSOR_PORT_BASE,
                        ANEMOMETER_SENSOR_PIN_MASK);
  rtimer_set(&rt, RTIMER_NOW() + RTIMER_SECOND, 1, rt_callback, NULL);
 }
 /*---------------------------------------------------------------------------*/
 PROCESS(weather_meter_int_process, "Weather meter interrupt process handler");
 /*---------------------------------------------------------------------------*/
@ -100,10 +153,6 @@ PROCESS_THREAD(weather_meter_int_process, ev, data)
 {
  PROCESS_EXITHANDLER();
  PROCESS_BEGIN();
  static uint32_t mph;
  static uint16_t rpm;
  etimer_set(&et, CLOCK_SECOND);
  while(1) {
    PROCESS_YIELD();
@ -121,33 +170,6 @@ PROCESS_THREAD(weather_meter_int_process, ev, data)
        rain_gauge_int_callback(weather_sensors.rain_gauge.ticks);
      }
    }
    if(ev == PROCESS_EVENT_TIMER) {
      if(weather_sensors.anemometer.ticks) {
        /* Disable to make the calculations in an interrupt-safe context */
        GPIO_DISABLE_INTERRUPT(ANEMOMETER_SENSOR_PORT_BASE,
                               ANEMOMETER_SENSOR_PIN_MASK);
        /* The anemometer ticks twice per rotation, and a wind speed of 2.4 km/h
         * makes the switch close every second, convert RPM to linear velocity
         */
        rpm = weather_sensors.anemometer.ticks * 30;
        mph = rpm * WEATHER_METER_AUX_ANGULAR;
        mph /= 1000;
        /* This will return values in metres per hour */
        weather_sensors.anemometer.value = (uint16_t)mph;
        /* Restart the counter */
        weather_sensors.anemometer.ticks = 0;
        /* Enable the interrupt again */
        GPIO_ENABLE_INTERRUPT(ANEMOMETER_SENSOR_PORT_BASE,
                              ANEMOMETER_SENSOR_PIN_MASK);      
        etimer_restart(&et);
      }
    }
  }
  PROCESS_END();
 }
@ -184,8 +206,14 @@ weather_meter_interrupt_handler(uint8_t port, uint8_t pin)
 static int
 value(int type)
 {
-  if((type != WEATHER_METER_ANEMOMETER) && (type != WEATHER_METER_RAIN_GAUGE) &&
+  uint64_t aux;
-    (type != WEATHER_METER_WIND_VANE)) {
+
  if((type != WEATHER_METER_ANEMOMETER) &&
    (type != WEATHER_METER_RAIN_GAUGE) &&
    (type != WEATHER_METER_WIND_VANE) &&
    (type != WEATHER_METER_ANEMOMETER_AVG) &&
    (type != WEATHER_METER_ANEMOMETER_AVG_2M) &&
    (type != WEATHER_METER_ANEMOMETER_MAX)) {
    PRINTF("Weather: requested an invalid sensor value\n");
    return WEATHER_METER_ERROR;
  }
@ -204,6 +232,19 @@ value(int type)
  case WEATHER_METER_ANEMOMETER:
    return weather_sensors.anemometer.value;
  case WEATHER_METER_ANEMOMETER_AVG:
    if(anemometer.value_avg <= 0) {
      return (uint16_t)anemometer.value_avg;
    }
    aux = anemometer.value_avg / anemometer.ticks_avg;
    return (uint16_t)aux;
  case WEATHER_METER_ANEMOMETER_AVG_2M:
    return anemometer.value_avg_2m;
  case WEATHER_METER_ANEMOMETER_MAX:
    return anemometer.value_max;
  /* as the default return type is int, we have a lower resolution if returning
   * the calculated value as it is truncated, an alternative is returning the
   * ticks and calculating on your own with WEATHER_METER_AUX_RAIN_MM
@ -234,6 +275,9 @@ configure(int type, int value)
  if(type == WEATHER_METER_ACTIVE) {
    anemometer.value_avg = 0;
    anemometer.ticks_avg = 0;
    weather_sensors.anemometer.int_en = 0;
    weather_sensors.rain_gauge.int_en = 0;
    weather_sensors.anemometer.ticks = 0;
@ -278,6 +322,7 @@ configure(int type, int value)
                           RAIN_GAUGE_SENSOR_PIN);
    process_start(&weather_meter_int_process, NULL);
    rtimer_set(&rt, RTIMER_NOW() + RTIMER_SECOND, 1, rt_callback, NULL);
    GPIO_ENABLE_INTERRUPT(ANEMOMETER_SENSOR_PORT_BASE, ANEMOMETER_SENSOR_PIN_MASK);
    GPIO_ENABLE_INTERRUPT(RAIN_GAUGE_SENSOR_PORT_BASE, RAIN_GAUGE_SENSOR_PIN_MASK);
--- a/platform/zoul/dev/weather-meter.h
+++ b/platform/zoul/dev/weather-meter.h
@ -53,9 +53,12 @@
 * \name Weather meter sensor return and operation values
 * @{
 */
 #define WEATHER_METER_ANEMOMETER          0x00
 #define WEATHER_METER_RAIN_GAUGE          0x01
 #define WEATHER_METER_WIND_VANE           0x02
 #define WEATHER_METER_ANEMOMETER          0x03
 #define WEATHER_METER_ANEMOMETER_AVG      0x04
 #define WEATHER_METER_ANEMOMETER_AVG_2M   0x05
 #define WEATHER_METER_ANEMOMETER_MAX      0x06
 #define WEATHER_METER_ACTIVE              SENSORS_ACTIVE
 #define WEATHER_METER_ANEMOMETER_INT_OVER HW_INT_OVER_THRS
@ -66,11 +69,11 @@
 #define WEATHER_METER_SUCCESS              0
 #define WEATHER_METER_ERROR                (-1)
-#define WEATHER_METER_ANEMOMETER_RADIUS    65  /**< 65.2 mm pin to cup centre */
+/* 2.4Km/h per tick, 2 per rotation */
-#define WEATHER_METER_AUX_CAL              377 /**< 2*pi*60 (376.992 rounded) */
+#define WEATHER_METER_ANEMOMETER_SPEED_1S  (1200)
-#define WEATHER_METER_AUX_ANGULAR          (WEATHER_METER_ANEMOMETER_RADIUS * \
+
-                                           WEATHER_METER_AUX_CAL)
+/* 0.2794mm per tick */
-#define WEATHER_METER_AUX_RAIN_MM          2794 /**< 0.2794mm per tick */
+#define WEATHER_METER_AUX_RAIN_MM          2794
 #ifdef WEATHER_METER_RAIN_CONF_RETURN
 #define WEATHER_METER_RAIN_RETURN_TICKS    WEATHER_METER_RAIN_CONF_RETURN