photoprism/pkg/geo/movement.go
2021-11-24 16:56:57 +01:00

235 lines
5.2 KiB
Go

package geo
import (
"fmt"
"math"
"time"
)
// Movement represents a position change in degrees per second.
type Movement struct {
Start Position
End Position
}
// NewMovement returns the movement between two positions and points in time.
func NewMovement(pos1, pos2 Position) (m Movement) {
// Make sure start and end are in the right order.
if d := pos1.Time.Sub(pos2.Time); d > 0 {
return Movement{Start: pos2, End: pos1}
} else {
return Movement{Start: pos1, End: pos2}
}
}
// Duration calculates the movement duration.
func (m *Movement) Duration() time.Duration {
return m.End.Time.Sub(m.Start.Time)
}
// Deg calculates the position change in degrees.
func (m *Movement) Deg() (lat, lng float64) {
return m.DegLat(), m.DegLng()
}
// DegLng calculates the longitude change in degrees.
func (m *Movement) DegLng() float64 {
return m.End.Lng - m.Start.Lng
}
// DegLat calculates the latitude change in degrees.
func (m *Movement) DegLat() float64 {
return m.End.Lat - m.Start.Lat
}
// DegPerSecond returns the position change in degrees per second.
func (m *Movement) DegPerSecond() (latSec, lngSec float64) {
s := m.Seconds()
if s < 1 {
return 0, 0
}
latSec = m.DegLat() / s
lngSec = m.DegLng() / s
return latSec, lngSec
}
// Km calculates the movement distance in km.
func (m *Movement) Km() float64 {
return math.Abs(Km(m.Start, m.End))
}
// Meter calculates the movement distance in m.
func (m *Movement) Meter() float64 {
return m.Km() * 1000
}
// Speed calculates the average movement speed in km/h.
func (m *Movement) Speed() float64 {
km := m.Km()
if km == 0 {
return 0
}
h := m.Hours()
if h == 0 {
return 0
}
return km / h
}
// Midpoint returns the movement midpoint position.
func (m *Movement) Midpoint() Position {
return Position{
Name: "midpoint",
Lat: (m.Start.Lat + m.End.Lat) / 2,
Lng: (m.Start.Lng + m.End.Lng) / 2,
}
}
// Closest returns the position closest in time, either start or end.
func (m *Movement) Closest(t time.Time) Position {
delaStart := math.Abs(m.Start.Time.Sub(t).Seconds())
deltaEnd := math.Abs(m.End.Time.Sub(t).Seconds())
if delaStart > deltaEnd {
return m.End
} else {
return m.Start
}
}
// Seconds returns the movement duration in seconds.
func (m *Movement) Seconds() float64 {
return math.Abs(m.Duration().Seconds())
}
// Hours returns the movement duration in hours.
func (m *Movement) Hours() float64 {
return math.Abs(m.Duration().Hours())
}
// String returns the movement information as string for logging.
func (m *Movement) String() string {
lat, lng := m.Deg()
return fmt.Sprintf("movement from %s to %s in %f s, Δ lat %f, Δ lng %f, dist %f km, speed %f km/h",
m.Start.Time.Format("2006-01-02 15:04:05.999999999"),
m.End.Time.Format("2006-01-02 15:04:05.999999999"),
m.Seconds(), lat, lng, m.Km(), m.Speed())
}
// Realistic tests if the movement may have happened in the real world.
func (m *Movement) Realistic() bool {
speed := m.Speed()
switch {
case speed > 900:
return false
case speed > 200 && m.Seconds() < 60:
return false
default:
return true
}
}
// AverageAltitude returns the average altitude.
func (m *Movement) AverageAltitude() float64 {
if m.Start.Altitude != 0 && m.End.Altitude == 0 {
return m.Start.Altitude
} else if m.Start.Altitude == 0 && m.End.Altitude != 0 {
return m.End.Altitude
} else if m.Start.Altitude != 0 && m.End.Altitude != 0 {
return (m.Start.Altitude + m.End.Altitude) / 2
}
return 0
}
// EstimateAccuracy returns the position estimate accuracy in meter.
func (m *Movement) EstimateAccuracy(t time.Time) int {
var a float64
if !m.Realistic() {
a = m.Meter() / 2
} else if t.Before(m.Start.Time) {
d := m.Start.Time.Sub(t).Hours() * 1000
d = math.Copysign(math.Sqrt(math.Abs(d)), d)
a = m.Speed() * d
} else if t.After(m.End.Time) {
d := t.Sub(m.End.Time).Hours() * 1000
d = math.Copysign(math.Sqrt(math.Abs(d)), d)
a = m.Speed() * d
} else {
a = m.Meter() / 20
}
if meter := math.Round(math.Abs(a)); meter > 5 {
return int(meter)
}
return 5
}
// EstimateAltitude estimates the altitude at a given time.
func (m *Movement) EstimateAltitude(t time.Time) float64 {
if t.Before(m.Start.Time) {
return m.Start.Altitude
} else if t.After(m.End.Time) {
return m.End.Altitude
}
return m.AverageAltitude()
}
// EstimateAltitudeInt returns the estimated altitude as integer.
func (m *Movement) EstimateAltitudeInt(t time.Time) int {
return int(math.Round(m.EstimateAltitude(t)))
}
// EstimatePosition returns the estimated position at a given time.
func (m *Movement) EstimatePosition(t time.Time) Position {
t = t.UTC()
d := t.Sub(m.Start.Time)
s := d.Seconds()
estimate := Position{
Name: "estimate",
Time: t,
Altitude: m.EstimateAltitude(t),
Accuracy: m.EstimateAccuracy(t),
Estimate: true,
}
if m.Realistic() {
if t.Before(m.Start.Time) || t.After(m.End.Time) {
s = math.Copysign(math.Sqrt(math.Abs(s)), s)
}
latSec, lngSec := m.DegPerSecond()
estimate.Lat = m.Start.Lat + latSec*s
estimate.Lng = m.Start.Lng + lngSec*s
return estimate
} else if km := m.Km(); km < 1 {
p := m.Midpoint()
estimate.Lat = p.Lat
estimate.Lng = p.Lng
return estimate
} else {
p := m.Closest(t)
estimate.Lat = p.Lat
estimate.Lng = p.Lng
return estimate
}
}