Sensors¶
The sensor subsystem exposes an API to uniformly access sensor devices. Common operations are: reading data and executing code when specific conditions are met.
Basic Operation¶
Channels¶
Fundamentally, a channel is a quantity that a sensor device can measure.
Sensors can have multiple channels, either to represent different axes of the same physical property (e.g. acceleration); or because they can measure different properties altogether (ambient temperature, pressure and humidity). Complex sensors cover both cases, so a single device can expose three acceleration channels and a temperature one.
It is imperative that all sensors that support a given channel express results in the same unit of measurement. Consult the API Reference for all supported channels, along with their description and units of measurement:
Values¶
Sensor devices return results as sensor_value
. This
representation avoids use of floating point values as they may not be
supported on certain setups.
Fetching Values¶
Getting a reading from a sensor requires two operations. First, an
application instructs the driver to fetch a sample of all its channels.
Then, individual channels may be read. In the case of channels with
multiple axes, they can be read in a single operation by supplying
the corresponding _XYZ
channel type and a buffer of 3
sensor_value
objects. This approach ensures consistency
of channels between reads and efficiency of communication by issuing a
single transaction on the underlying bus.
Below is an example illustrating the usage of the BME280 sensor, which
measures ambient temperature and atmospheric pressure. Note that
sensor_sample_fetch()
is only called once, as it reads and
compensates data for both channels.
1 2 3 4 5 6 7 8 9 10 11 12 13 14 15 16 17 18 19 20 21 22 23 24 25 26 27 28 29 30 31 32 33 34 35 36 37 38 39 40 41 42 43 44 45 46 47 48 49 | /* * Get a device structure from a devicetree node with compatible * "bosch,bme280". (If there are multiple, just pick one.) */ static const struct device *get_bme280_device(void) { const struct device *dev = DEVICE_DT_GET_ANY(bosch_bme280); if (dev == NULL) { /* No such node, or the node does not have status "okay". */ printk("\nError: no device found.\n"); return NULL; } if (!device_is_ready(dev)) { printk("\nError: Device \"%s\" is not ready; " "check the driver initialization logs for errors.\n", dev->name); return NULL; } printk("Found device \"%s\", getting sensor data\n", dev->name); return dev; } void main(void) { const struct device *dev = get_bme280_device(); if (dev == NULL) { return; } while (1) { struct sensor_value temp, press, humidity; sensor_sample_fetch(dev); sensor_channel_get(dev, SENSOR_CHAN_AMBIENT_TEMP, &temp); sensor_channel_get(dev, SENSOR_CHAN_PRESS, &press); sensor_channel_get(dev, SENSOR_CHAN_HUMIDITY, &humidity); printk("temp: %d.%06d; press: %d.%06d; humidity: %d.%06d\n", temp.val1, temp.val2, press.val1, press.val2, humidity.val1, humidity.val2); k_sleep(K_MSEC(1000)); } } |
The example assumes that the returned values have type sensor_value
,
which is the case for BME280. A real application
supporting multiple sensors should inspect the type
field of
the temp
and press
values and use the other fields
of the structure accordingly.
Configuration and Attributes¶
Setting the communication bus and address is considered the most basic configuration for sensor devices. This setting is done at compile time, via the configuration menu. If the sensor supports interrupts, the interrupt lines and triggering parameters described below are also configured at compile time.
Alongside these communication parameters, sensor chips typically expose multiple parameters that control the accuracy and frequency of measurement. In compliance with Zephyr’s design goals, most of these values are statically configured at compile time.
However, certain parameters could require runtime configuration, for example, threshold values for interrupts. These values are configured via attributes. The example in the following section showcases a sensor with an interrupt line that is triggered when the temperature crosses a threshold. The threshold is configured at runtime using an attribute.
Triggers¶
Triggers in Zephyr refer to the interrupt lines of the sensor chips. Many sensor chips support one or more triggers. Some examples of triggers include: new data is ready for reading, a channel value has crossed a threshold, or the device has sensed motion.
To configure a trigger, an application needs to supply a
sensor_trigger
and a handler function. The structure contains the
trigger type and the channel on which the trigger must be configured.
Because most sensors are connected via SPI or I2C busses, it is not possible to communicate with them from the interrupt execution context. The execution of the trigger handler is deferred to a thread, so that data fetching operations are possible. A driver can spawn its own thread to fetch data, thus ensuring minimum latency. Alternatively, multiple sensor drivers can share a system-wide thread. The shared thread approach increases the latency of handling interrupts but uses less memory. You can configure which approach to follow for each driver. Most drivers can entirely disable triggers resulting in a smaller footprint.
The following example contains a trigger fired whenever temperature crosses the 26 degree Celsius threshold. It also samples the temperature every second. A real application would ideally disable periodic sampling in the interest of saving power. Since the application has direct access to the kernel config symbols, no trigger is registered when triggering was disabled by the driver’s configuration.
1 2 3 4 5 6 7 8 9 10 11 12 13 14 15 16 17 18 19 20 21 22 23 24 25 26 27 28 29 30 31 32 33 34 35 36 37 38 39 40 41 42 43 44 45 46 47 48 49 50 51 52 53 54 55 56 57 58 59 60 61 62 63 64 65 66 67 68 69 70 71 72 73 74 75 76 77 78 79 80 81 82 83 84 85 86 87 88 89 90 91 92 93 94 95 96 97 98 99 100 101 102 103 104 105 106 107 108 109 110 111 112 113 114 115 116 117 118 119 120 121 122 123 124 125 126 127 128 129 130 131 132 133 134 135 136 137 138 139 140 141 142 143 144 145 | #define UCEL_PER_CEL 1000000 #define UCEL_PER_MCEL 1000 #define TEMP_INITIAL_CEL 25 #define TEMP_WINDOW_HALF_UCEL 500000 static const char *now_str(void) { static char buf[16]; /* ...HH:MM:SS.MMM */ uint32_t now = k_uptime_get_32(); unsigned int ms = now % MSEC_PER_SEC; unsigned int s; unsigned int min; unsigned int h; now /= MSEC_PER_SEC; s = now % 60U; now /= 60U; min = now % 60U; now /= 60U; h = now; snprintf(buf, sizeof(buf), "%u:%02u:%02u.%03u", h, min, s, ms); return buf; } #ifdef CONFIG_MCP9808_TRIGGER static struct sensor_trigger trig; static int set_window(const struct device *dev, const struct sensor_value *temp) { const int temp_ucel = temp->val1 * UCEL_PER_CEL + temp->val2; const int low_ucel = temp_ucel - TEMP_WINDOW_HALF_UCEL; const int high_ucel = temp_ucel + TEMP_WINDOW_HALF_UCEL; struct sensor_value val = { .val1 = low_ucel / UCEL_PER_CEL, .val2 = low_ucel % UCEL_PER_CEL, }; int rc = sensor_attr_set(dev, SENSOR_CHAN_AMBIENT_TEMP, SENSOR_ATTR_LOWER_THRESH, &val); if (rc == 0) { val.val1 = high_ucel / UCEL_PER_CEL, val.val2 = high_ucel % UCEL_PER_CEL, rc = sensor_attr_set(dev, SENSOR_CHAN_AMBIENT_TEMP, SENSOR_ATTR_UPPER_THRESH, &val); } if (rc == 0) { printf("Alert on temp outside [%d, %d] milli-Celsius\n", low_ucel / UCEL_PER_MCEL, high_ucel / UCEL_PER_MCEL); } return rc; } static inline int set_window_ucel(const struct device *dev, int temp_ucel) { struct sensor_value val = { .val1 = temp_ucel / UCEL_PER_CEL, .val2 = temp_ucel % UCEL_PER_CEL, }; return set_window(dev, &val); } static void trigger_handler(const struct device *dev, struct sensor_trigger *trig) { struct sensor_value temp; static size_t cnt; int rc; ++cnt; rc = sensor_sample_fetch(dev); if (rc != 0) { printf("sensor_sample_fetch error: %d\n", rc); return; } rc = sensor_channel_get(dev, SENSOR_CHAN_AMBIENT_TEMP, &temp); if (rc != 0) { printf("sensor_channel_get error: %d\n", rc); return; } printf("trigger fired %u, temp %g deg C\n", cnt, sensor_value_to_double(&temp)); set_window(dev, &temp); } #endif void main(void) { const struct device *dev = DEVICE_DT_GET_ANY(microchip_mcp9808); int rc; if (dev == NULL) { printf("Device not found.\n"); return; } if (!device_is_ready(dev)) { printf("Device %s is not ready.\n", dev->name); return; } #ifdef CONFIG_MCP9808_TRIGGER rc = set_window_ucel(dev, TEMP_INITIAL_CEL * UCEL_PER_CEL); if (rc == 0) { trig.type = SENSOR_TRIG_THRESHOLD; trig.chan = SENSOR_CHAN_AMBIENT_TEMP; rc = sensor_trigger_set(dev, &trig, trigger_handler); } if (rc != 0) { printf("Trigger set failed: %d\n", rc); return; } printk("Trigger set got %d\n", rc); #endif while (1) { struct sensor_value temp; rc = sensor_sample_fetch(dev); if (rc != 0) { printf("sensor_sample_fetch error: %d\n", rc); break; } rc = sensor_channel_get(dev, SENSOR_CHAN_AMBIENT_TEMP, &temp); if (rc != 0) { printf("sensor_channel_get error: %d\n", rc); break; } printf("%s: %g C\n", now_str(), sensor_value_to_double(&temp)); k_sleep(K_SECONDS(2)); } } |
API Reference¶
-
group
sensor_interface
Sensor Interface.
Defines
-
SENSOR_G
¶ The value of gravitational constant in micro m/s^2.
-
SENSOR_PI
¶ The value of constant PI in micros.
Typedefs
-
typedef void (*
sensor_trigger_handler_t
)(const struct device *dev, struct sensor_trigger *trigger)¶ Callback API upon firing of a trigger.
- Parameters
dev – Pointer to the sensor device
trigger – The trigger
-
typedef int (*
sensor_attr_set_t
)(const struct device *dev, enum sensor_channel chan, enum sensor_attribute attr, const struct sensor_value *val)¶ Callback API upon setting a sensor’s attributes.
See sensor_attr_set() for argument description
-
typedef int (*
sensor_attr_get_t
)(const struct device *dev, enum sensor_channel chan, enum sensor_attribute attr, struct sensor_value *val)¶ Callback API upon getting a sensor’s attributes.
See sensor_attr_get() for argument description
-
typedef int (*
sensor_trigger_set_t
)(const struct device *dev, const struct sensor_trigger *trig, sensor_trigger_handler_t handler)¶ Callback API for setting a sensor’s trigger and handler.
See sensor_trigger_set() for argument description
-
typedef int (*
sensor_sample_fetch_t
)(const struct device *dev, enum sensor_channel chan)¶ Callback API for fetching data from a sensor.
See sensor_sample_fetch() for argument description
-
typedef int (*
sensor_channel_get_t
)(const struct device *dev, enum sensor_channel chan, struct sensor_value *val)¶ Callback API for getting a reading from a sensor.
See sensor_channel_get() for argument description
Enums
-
enum
sensor_channel
¶ Sensor channels.
Values:
-
enumerator
SENSOR_CHAN_ACCEL_X
¶ Acceleration on the X axis, in m/s^2.
-
enumerator
SENSOR_CHAN_ACCEL_Y
¶ Acceleration on the Y axis, in m/s^2.
-
enumerator
SENSOR_CHAN_ACCEL_Z
¶ Acceleration on the Z axis, in m/s^2.
-
enumerator
SENSOR_CHAN_ACCEL_XYZ
¶ Acceleration on the X, Y and Z axes.
-
enumerator
SENSOR_CHAN_GYRO_X
¶ Angular velocity around the X axis, in radians/s.
-
enumerator
SENSOR_CHAN_GYRO_Y
¶ Angular velocity around the Y axis, in radians/s.
-
enumerator
SENSOR_CHAN_GYRO_Z
¶ Angular velocity around the Z axis, in radians/s.
-
enumerator
SENSOR_CHAN_GYRO_XYZ
¶ Angular velocity around the X, Y and Z axes.
-
enumerator
SENSOR_CHAN_MAGN_X
¶ Magnetic field on the X axis, in Gauss.
-
enumerator
SENSOR_CHAN_MAGN_Y
¶ Magnetic field on the Y axis, in Gauss.
-
enumerator
SENSOR_CHAN_MAGN_Z
¶ Magnetic field on the Z axis, in Gauss.
-
enumerator
SENSOR_CHAN_MAGN_XYZ
¶ Magnetic field on the X, Y and Z axes.
-
enumerator
SENSOR_CHAN_DIE_TEMP
¶ Device die temperature in degrees Celsius.
-
enumerator
SENSOR_CHAN_AMBIENT_TEMP
¶ Ambient temperature in degrees Celsius.
-
enumerator
SENSOR_CHAN_PRESS
¶ Pressure in kilopascal.
-
enumerator
SENSOR_CHAN_PROX
¶ Proximity. Adimensional. A value of 1 indicates that an object is close.
-
enumerator
SENSOR_CHAN_HUMIDITY
¶ Humidity, in percent.
-
enumerator
SENSOR_CHAN_LIGHT
¶ Illuminance in visible spectrum, in lux.
-
enumerator
SENSOR_CHAN_IR
¶ Illuminance in infra-red spectrum, in lux.
-
enumerator
SENSOR_CHAN_RED
¶ Illuminance in red spectrum, in lux.
-
enumerator
SENSOR_CHAN_GREEN
¶ Illuminance in green spectrum, in lux.
-
enumerator
SENSOR_CHAN_BLUE
¶ Illuminance in blue spectrum, in lux.
-
enumerator
SENSOR_CHAN_ALTITUDE
¶ Altitude, in meters
-
enumerator
SENSOR_CHAN_PM_1_0
¶ 1.0 micro-meters Particulate Matter, in ug/m^3
-
enumerator
SENSOR_CHAN_PM_2_5
¶ 2.5 micro-meters Particulate Matter, in ug/m^3
-
enumerator
SENSOR_CHAN_PM_10
¶ 10 micro-meters Particulate Matter, in ug/m^3
-
enumerator
SENSOR_CHAN_DISTANCE
¶ Distance. From sensor to target, in meters
-
enumerator
SENSOR_CHAN_CO2
¶ CO2 level, in parts per million (ppm)
-
enumerator
SENSOR_CHAN_VOC
¶ VOC level, in parts per billion (ppb)
-
enumerator
SENSOR_CHAN_GAS_RES
¶ Gas sensor resistance in ohms.
-
enumerator
SENSOR_CHAN_VOLTAGE
¶ Voltage, in volts
-
enumerator
SENSOR_CHAN_CURRENT
¶ Current, in amps
-
enumerator
SENSOR_CHAN_POWER
¶ Power in watts
-
enumerator
SENSOR_CHAN_RESISTANCE
¶ Resistance , in Ohm
-
enumerator
SENSOR_CHAN_ROTATION
¶ Angular rotation, in degrees
-
enumerator
SENSOR_CHAN_POS_DX
¶ Position change on the X axis, in points.
-
enumerator
SENSOR_CHAN_POS_DY
¶ Position change on the Y axis, in points.
-
enumerator
SENSOR_CHAN_POS_DZ
¶ Position change on the Z axis, in points.
-
enumerator
SENSOR_CHAN_RPM
¶ Revolutions per minute, in RPM.
-
enumerator
SENSOR_CHAN_GAUGE_VOLTAGE
¶ Voltage, in volts
-
enumerator
SENSOR_CHAN_GAUGE_AVG_CURRENT
¶ Average current, in amps
-
enumerator
SENSOR_CHAN_GAUGE_STDBY_CURRENT
¶ Standy current, in amps
-
enumerator
SENSOR_CHAN_GAUGE_MAX_LOAD_CURRENT
¶ Max load current, in amps
-
enumerator
SENSOR_CHAN_GAUGE_TEMP
¶ Gauge temperature
-
enumerator
SENSOR_CHAN_GAUGE_STATE_OF_CHARGE
¶ State of charge measurement in %
-
enumerator
SENSOR_CHAN_GAUGE_FULL_CHARGE_CAPACITY
¶ Full Charge Capacity in mAh
-
enumerator
SENSOR_CHAN_GAUGE_REMAINING_CHARGE_CAPACITY
¶ Remaining Charge Capacity in mAh
-
enumerator
SENSOR_CHAN_GAUGE_NOM_AVAIL_CAPACITY
¶ Nominal Available Capacity in mAh
-
enumerator
SENSOR_CHAN_GAUGE_FULL_AVAIL_CAPACITY
¶ Full Available Capacity in mAh
-
enumerator
SENSOR_CHAN_GAUGE_AVG_POWER
¶ Average power in mW
-
enumerator
SENSOR_CHAN_GAUGE_STATE_OF_HEALTH
¶ State of health measurement in %
-
enumerator
SENSOR_CHAN_GAUGE_TIME_TO_EMPTY
¶ Time to empty in minutes
-
enumerator
SENSOR_CHAN_GAUGE_TIME_TO_FULL
¶ Time to full in minutes
-
enumerator
SENSOR_CHAN_GAUGE_CYCLE_COUNT
¶ Cycle count (total number of charge/discharge cycles)
-
enumerator
SENSOR_CHAN_GAUGE_DESIGN_VOLTAGE
¶ Design voltage of cell in V (max voltage)
-
enumerator
SENSOR_CHAN_GAUGE_DESIRED_VOLTAGE
¶ Desired voltage of cell in V (nominal voltage)
-
enumerator
SENSOR_CHAN_GAUGE_DESIRED_CHARGING_CURRENT
¶ Desired charging current in mA
-
enumerator
SENSOR_CHAN_ALL
¶ All channels.
-
enumerator
SENSOR_CHAN_COMMON_COUNT
¶ Number of all common sensor channels.
-
enumerator
SENSOR_CHAN_PRIV_START
= SENSOR_CHAN_COMMON_COUNT¶ This and higher values are sensor specific. Refer to the sensor header file.
-
enumerator
SENSOR_CHAN_MAX
= INT16_MAX¶ Maximum value describing a sensor channel type.
-
enumerator
-
enum
sensor_trigger_type
¶ Sensor trigger types.
Values:
-
enumerator
SENSOR_TRIG_TIMER
¶ Timer-based trigger, useful when the sensor does not have an interrupt line.
-
enumerator
SENSOR_TRIG_DATA_READY
¶ Trigger fires whenever new data is ready.
-
enumerator
SENSOR_TRIG_DELTA
¶ Trigger fires when the selected channel varies significantly. This includes any-motion detection when the channel is acceleration or gyro. If detection is based on slope between successive channel readings, the slope threshold is configured via the SENSOR_ATTR_SLOPE_TH and SENSOR_ATTR_SLOPE_DUR attributes.
-
enumerator
SENSOR_TRIG_NEAR_FAR
¶ Trigger fires when a near/far event is detected.
-
enumerator
SENSOR_TRIG_THRESHOLD
¶ Trigger fires when channel reading transitions configured thresholds. The thresholds are configured via the SENSOR_ATTR_LOWER_THRESH, SENSOR_ATTR_UPPER_THRESH, and SENSOR_ATTR_HYSTERESIS attributes.
-
enumerator
SENSOR_TRIG_TAP
¶ Trigger fires when a single tap is detected.
-
enumerator
SENSOR_TRIG_DOUBLE_TAP
¶ Trigger fires when a double tap is detected.
-
enumerator
SENSOR_TRIG_FREEFALL
¶ Trigger fires when a free fall is detected.
-
enumerator
SENSOR_TRIG_COMMON_COUNT
¶ Number of all common sensor triggers.
-
enumerator
SENSOR_TRIG_PRIV_START
= SENSOR_TRIG_COMMON_COUNT¶ This and higher values are sensor specific. Refer to the sensor header file.
-
enumerator
SENSOR_TRIG_MAX
= INT16_MAX¶ Maximum value describing a sensor trigger type.
-
enumerator
-
enum
sensor_attribute
¶ Sensor attribute types.
Values:
-
enumerator
SENSOR_ATTR_SAMPLING_FREQUENCY
¶ Sensor sampling frequency, i.e. how many times a second the sensor takes a measurement.
-
enumerator
SENSOR_ATTR_LOWER_THRESH
¶ Lower threshold for trigger.
-
enumerator
SENSOR_ATTR_UPPER_THRESH
¶ Upper threshold for trigger.
-
enumerator
SENSOR_ATTR_SLOPE_TH
¶ Threshold for any-motion (slope) trigger.
-
enumerator
SENSOR_ATTR_SLOPE_DUR
¶ Duration for which the slope values needs to be outside the threshold for the trigger to fire.
-
enumerator
SENSOR_ATTR_HYSTERESIS
¶
-
enumerator
SENSOR_ATTR_OVERSAMPLING
¶ Oversampling factor
-
enumerator
SENSOR_ATTR_FULL_SCALE
¶ Sensor range, in SI units.
-
enumerator
SENSOR_ATTR_OFFSET
¶ The sensor value returned will be altered by the amount indicated by offset: final_value = sensor_value + offset.
-
enumerator
SENSOR_ATTR_CALIB_TARGET
¶ Calibration target. This will be used by the internal chip’s algorithms to calibrate itself on a certain axis, or all of them.
-
enumerator
SENSOR_ATTR_CONFIGURATION
¶ Configure the operating modes of a sensor.
-
enumerator
SENSOR_ATTR_CALIBRATION
¶ Set a calibration value needed by a sensor.
-
enumerator
SENSOR_ATTR_FEATURE_MASK
¶ Enable/disable sensor features
-
enumerator
SENSOR_ATTR_ALERT
¶ Alert threshold or alert enable/disable
-
enumerator
SENSOR_ATTR_COMMON_COUNT
¶ Number of all common sensor attributes.
-
enumerator
SENSOR_ATTR_PRIV_START
= SENSOR_ATTR_COMMON_COUNT¶ This and higher values are sensor specific. Refer to the sensor header file.
-
enumerator
SENSOR_ATTR_MAX
= INT16_MAX¶ Maximum value describing a sensor attribute type.
-
enumerator
Functions
-
int
sensor_attr_set
(const struct device *dev, enum sensor_channel chan, enum sensor_attribute attr, const struct sensor_value *val)¶ Set an attribute for a sensor.
- Parameters
dev – Pointer to the sensor device
chan – The channel the attribute belongs to, if any. Some attributes may only be set for all channels of a device, depending on device capabilities.
attr – The attribute to set
val – The value to set the attribute to
- Returns
0 if successful, negative errno code if failure.
-
int
sensor_attr_get
(const struct device *dev, enum sensor_channel chan, enum sensor_attribute attr, struct sensor_value *val)¶ Get an attribute for a sensor.
- Parameters
dev – Pointer to the sensor device
chan – The channel the attribute belongs to, if any. Some attributes may only be set for all channels of a device, depending on device capabilities.
attr – The attribute to get
val – Pointer to where to store the attribute
- Returns
0 if successful, negative errno code if failure.
-
static inline int
sensor_trigger_set
(const struct device *dev, struct sensor_trigger *trig, sensor_trigger_handler_t handler)¶ Activate a sensor’s trigger and set the trigger handler.
The handler will be called from a thread, so I2C or SPI operations are safe. However, the thread’s stack is limited and defined by the driver. It is currently up to the caller to ensure that the handler does not overflow the stack.
- Function properties (list may not be complete)
- Parameters
dev – Pointer to the sensor device
trig – The trigger to activate
handler – The function that should be called when the trigger fires
- Returns
0 if successful, negative errno code if failure.
-
int
sensor_sample_fetch
(const struct device *dev)¶ Fetch a sample from the sensor and store it in an internal driver buffer.
Read all of a sensor’s active channels and, if necessary, perform any additional operations necessary to make the values useful. The user may then get individual channel values by calling sensor_channel_get.
Since the function communicates with the sensor device, it is unsafe to call it in an ISR if the device is connected via I2C or SPI.
- Parameters
dev – Pointer to the sensor device
- Returns
0 if successful, negative errno code if failure.
-
int
sensor_sample_fetch_chan
(const struct device *dev, enum sensor_channel type)¶ Fetch a sample from the sensor and store it in an internal driver buffer.
Read and compute compensation for one type of sensor data (magnetometer, accelerometer, etc). The user may then get individual channel values by calling sensor_channel_get.
This is mostly implemented by multi function devices enabling reading at different sampling rates.
Since the function communicates with the sensor device, it is unsafe to call it in an ISR if the device is connected via I2C or SPI.
- Parameters
dev – Pointer to the sensor device
type – The channel that needs updated
- Returns
0 if successful, negative errno code if failure.
-
int
sensor_channel_get
(const struct device *dev, enum sensor_channel chan, struct sensor_value *val)¶ Get a reading from a sensor device.
Return a useful value for a particular channel, from the driver’s internal data. Before calling this function, a sample must be obtained by calling sensor_sample_fetch or sensor_sample_fetch_chan. It is guaranteed that two subsequent calls of this function for the same channels will yield the same value, if sensor_sample_fetch or sensor_sample_fetch_chan has not been called in the meantime.
For vectorial data samples you can request all axes in just one call by passing the specific channel with _XYZ suffix. The sample will be returned at val[0], val[1] and val[2] (X, Y and Z in that order).
- Parameters
dev – Pointer to the sensor device
chan – The channel to read
val – Where to store the value
- Returns
0 if successful, negative errno code if failure.
-
static inline int32_t
sensor_ms2_to_g
(const struct sensor_value *ms2)¶ Helper function to convert acceleration from m/s^2 to Gs.
- Parameters
ms2 – A pointer to a sensor_value struct holding the acceleration, in m/s^2.
- Returns
The converted value, in Gs.
-
static inline void
sensor_g_to_ms2
(int32_t g, struct sensor_value *ms2)¶ Helper function to convert acceleration from Gs to m/s^2.
- Parameters
g – The G value to be converted.
ms2 – A pointer to a sensor_value struct, where the result is stored.
-
static inline int32_t
sensor_rad_to_degrees
(const struct sensor_value *rad)¶ Helper function for converting radians to degrees.
- Parameters
rad – A pointer to a sensor_value struct, holding the value in radians.
- Returns
The converted value, in degrees.
-
static inline void
sensor_degrees_to_rad
(int32_t d, struct sensor_value *rad)¶ Helper function for converting degrees to radians.
- Parameters
d – The value (in degrees) to be converted.
rad – A pointer to a sensor_value struct, where the result is stored.
-
static inline double
sensor_value_to_double
(const struct sensor_value *val)¶ Helper function for converting struct sensor_value to double.
- Parameters
val – A pointer to a sensor_value struct.
- Returns
The converted value.
-
static inline void
sensor_value_from_double
(struct sensor_value *val, double inp)¶ Helper function for converting double to struct sensor_value.
- Parameters
val – A pointer to a sensor_value struct.
inp – The converted value.
-
struct
sensor_value
¶ - #include <sensor.h>
Representation of a sensor readout value.
The value is represented as having an integer and a fractional part, and can be obtained using the formula val1 + val2 * 10^(-6). Negative values also adhere to the above formula, but may need special attention. Here are some examples of the value representation:
0.5: val1 = 0, val2 = 500000 -0.5: val1 = 0, val2 = -500000 -1.0: val1 = -1, val2 = 0 -1.5: val1 = -1, val2 = -500000
-
struct
sensor_trigger
¶ - #include <sensor.h>
Sensor trigger spec.
Public Members
-
enum sensor_trigger_type
type
¶ Trigger type.
-
enum sensor_channel
chan
¶ Channel the trigger is set on.
-
enum sensor_trigger_type
-
struct
sensor_driver_api
¶ - #include <sensor.h>
-