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embd/sensor/l3gd20/l3gd20.go

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// Package l3gd20 allows interacting with L3GD20 gyroscoping sensor.
package l3gd20
import (
"fmt"
"math"
"sync"
"time"
"github.com/golang/glog"
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"github.com/kidoman/embd"
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)
const (
address = 0x6B
id = 0xD4
dpsToRps = 0.017453293
whoAmI = 0x0F
ctrlReg1 = 0x20
ctrlReg2 = 0x21
ctrlReg3 = 0x22
ctrlReg4 = 0x23
ctrlReg5 = 0x24
tempData = 0x26
statusReg = 0x27
xlReg = 0x28
xhReg = 0x29
ylReg = 0x2A
yhReg = 0x2B
zlReg = 0x2C
zhReg = 0x2D
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dr95 = 0x00
dr190 = 0x40
dr380 = 0x80
dr760 = 0xC0
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xEnabled = 0x01
yEnabled = 0x02
zEnabled = 0x04
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powerOn = 0x08
powerOff = 0x00
ctrlReg1Default = powerOn | xEnabled | yEnabled | zEnabled
ctrlReg1Finished = powerOff | xEnabled | yEnabled | zEnabled
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zyxAvailable = 0x08
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odr = 95
mult = 1.0 / odr
pollDelay = mult * 1000 * 1000
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)
// Range represents a L3GD20 range setting.
type Range struct {
sensitivity float64
value byte
}
// The three range settings supported by L3GD20.
var (
R250DPS = &Range{sensitivity: 0.00875, value: 0x00}
R500DPS = &Range{sensitivity: 0.0175, value: 0x10}
R2000DPS = &Range{sensitivity: 0.070, value: 0x20}
)
type axis struct {
name string
lowReg, highReg byte
availableMask byte
}
func (a *axis) regs() (byte, byte) {
return a.lowReg, a.highReg
}
func (a axis) String() string {
return a.name
}
var (
ax = &axis{name: "X", lowReg: xlReg, highReg: xhReg, availableMask: 0x01}
ay = &axis{name: "Y", lowReg: ylReg, highReg: yhReg, availableMask: 0x02}
az = &axis{name: "Z", lowReg: zlReg, highReg: zhReg, availableMask: 0x04}
)
type axisCalibration struct {
min, max, mean float64
}
func (ac axisCalibration) adjust(value float64) float64 {
if value >= ac.min && value <= ac.max {
return 0
}
return value - ac.mean
}
func (ac axisCalibration) String() string {
return fmt.Sprintf("%v, %v, %v", ac.min, ac.max, ac.mean)
}
type Orientation struct {
X, Y, Z float64
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}
// L3GD20 represents a L3GD20 3-axis gyroscope.
type L3GD20 struct {
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Bus embd.I2CBus
Range *Range
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initialized bool
mu sync.RWMutex
xac, yac, zac axisCalibration
orientations chan Orientation
closing chan chan struct{}
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}
// New creates a new L3GD20 interface. The bus variable controls
// the I2C bus used to communicate with the device.
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func New(bus embd.I2CBus, Range *Range) *L3GD20 {
return &L3GD20{
Bus: bus,
Range: Range,
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}
}
type values []float64
func (vs values) min() float64 {
value := math.MaxFloat64
for _, v := range vs {
value = math.Min(value, v)
}
return value
}
func (vs values) max() float64 {
value := -math.MaxFloat64
for _, v := range vs {
value = math.Max(value, v)
}
return value
}
func (vs values) mean() float64 {
sum := 0.0
for _, v := range vs {
sum += v
}
return sum / float64(len(vs))
}
func (d *L3GD20) calibrate(a *axis) (axisCalibration, error) {
glog.V(1).Infof("l3gd20: calibrating %v axis", a)
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values := make(values, 0)
for i := 0; i < 20; i++ {
again:
available, err := d.axisStatus(a)
if err != nil {
return axisCalibration{}, err
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}
if !available {
time.Sleep(100 * time.Microsecond)
goto again
}
value, err := d.readOrientationDelta(a)
if err != nil {
return axisCalibration{}, err
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}
values = append(values, value)
}
ac := axisCalibration{min: values.min(), max: values.max(), mean: values.mean()}
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glog.V(1).Infof("l3gd20: %v axis calibration (%v)", a, ac)
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return ac, nil
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}
func (d *L3GD20) setup() error {
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d.mu.RLock()
if d.initialized {
d.mu.RUnlock()
return nil
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}
d.mu.RUnlock()
d.mu.Lock()
defer d.mu.Unlock()
d.orientations = make(chan Orientation)
if err := d.Bus.WriteByteToReg(address, ctrlReg1, ctrlReg1Default); err != nil {
return err
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}
if err := d.Bus.WriteByteToReg(address, ctrlReg4, d.Range.value); err != nil {
return err
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}
// Calibrate
var err error
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if d.xac, err = d.calibrate(ax); err != nil {
return err
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}
if d.yac, err = d.calibrate(ay); err != nil {
return err
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}
if d.zac, err = d.calibrate(az); err != nil {
return err
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}
d.initialized = true
return nil
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}
func (d *L3GD20) axisStatus(a *axis) (bool, error) {
data, err := d.Bus.ReadByteFromReg(address, statusReg)
if err != nil {
return false, err
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}
if data&zyxAvailable == 0 {
return false, nil
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}
available := data&a.availableMask != 0
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return available, nil
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}
func (d *L3GD20) readOrientationDelta(a *axis) (float64, error) {
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rl, rh := a.regs()
l, err := d.Bus.ReadByteFromReg(address, rl)
if err != nil {
return 0, err
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}
h, err := d.Bus.ReadByteFromReg(address, rh)
if err != nil {
return 0, err
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}
value := float64(int16(h)<<8 | int16(l))
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value *= d.Range.sensitivity
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return value, nil
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}
func (d *L3GD20) calibratedOrientationDelta(a *axis) (float64, error) {
value, err := d.readOrientationDelta(a)
if err != nil {
return 0, err
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}
switch a {
case ax:
value = d.xac.adjust(value)
case ay:
value = d.yac.adjust(value)
case az:
value = d.zac.adjust(value)
}
return value, nil
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}
func (d *L3GD20) measureOrientationDelta() (float64, float64, float64, error) {
if err := d.setup(); err != nil {
return 0, 0, 0, err
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}
dx, err := d.calibratedOrientationDelta(ax)
if err != nil {
return 0, 0, 0, err
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}
dy, err := d.calibratedOrientationDelta(ay)
if err != nil {
return 0, 0, 0, err
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}
dz, err := d.calibratedOrientationDelta(az)
if err != nil {
return 0, 0, 0, err
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}
return dx, dy, dz, nil
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}
// Orientation returns the current orientation reading.
func (d *L3GD20) OrientationDelta() (float64, float64, float64, error) {
return d.measureOrientationDelta()
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}
// Temperature returns the current temperature reading.
func (d *L3GD20) Temperature() (int, error) {
if err := d.setup(); err != nil {
return 0, err
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}
data, err := d.Bus.ReadByteFromReg(address, tempData)
if err != nil {
return 0, err
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}
temp := int(int8(data))
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return temp, nil
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}
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// Orientations returns a channel which will have the current temperature reading.
func (d *L3GD20) Orientations() (<-chan Orientation, error) {
if err := d.setup(); err != nil {
return nil, err
}
return d.orientations, nil
}
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// Start starts the data acquisition loop.
func (d *L3GD20) Start() error {
if err := d.setup(); err != nil {
return err
}
d.closing = make(chan chan struct{})
go func() {
var x, y, z float64
var orientations chan Orientation
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timer := time.Tick(time.Duration(math.Floor(pollDelay)) * time.Microsecond)
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for {
select {
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case <-timer:
dx, dy, dz, err := d.measureOrientationDelta()
if err != nil {
glog.Errorf("l3gd20: %v", err)
} else {
x += dx * mult
y += dy * mult
z += dz * mult
orientations = d.orientations
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}
case orientations <- Orientation{x, y, z}:
orientations = nil
case waitc := <-d.closing:
waitc <- struct{}{}
close(d.orientations)
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return
}
}
}()
return nil
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}
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// Stop the data acquisition loop.
func (d *L3GD20) Stop() error {
if d.closing != nil {
waitc := make(chan struct{})
d.closing <- waitc
<-waitc
d.closing = nil
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}
if err := d.Bus.WriteByteToReg(address, ctrlReg1, ctrlReg1Finished); err != nil {
return err
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}
d.initialized = false
return nil
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}
// Close.
func (d *L3GD20) Close() error {
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return d.Stop()
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}