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Python example and necessary wrapper gymnastics

release/4.3a0
Frank Dellaert 2020-03-18 17:28:40 -04:00
parent 2e75ffd01d
commit cd318b2295
4 changed files with 164 additions and 0 deletions
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128
cython/gtsam_unstable/examples/TimeOfArrivalExample.py Normal file
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@ -0,0 +1,128 @@
"""
GTSAM Copyright 2010-2018, Georgia Tech Research Corporation,
Atlanta, Georgia 30332-0415
All Rights Reserved
Authors: Frank Dellaert, et al. (see THANKS for the full author list)
See LICENSE for the license information
Track a moving object "Time of Arrival" measurements at 4 microphones.
Author: Frank Dellaert
"""
# pylint: disable=invalid-name, no-name-in-module
from gtsam import (LevenbergMarquardtOptimizer, LevenbergMarquardtParams,
NonlinearFactorGraph, Point3, Values, noiseModel_Isotropic)
from gtsam_unstable import Event, TimeOfArrival, TOAFactor
# units
MS = 1e-3
CM = 1e-2
# Instantiate functor with speed of sound value
TIME_OF_ARRIVAL = TimeOfArrival(330)
def defineMicrophones():
"""Create microphones."""
height = 0.5
microphones = []
microphones.append(Point3(0, 0, height))
microphones.append(Point3(403 * CM, 0, height))
microphones.append(Point3(403 * CM, 403 * CM, height))
microphones.append(Point3(0, 403 * CM, 2 * height))
return microphones
def createTrajectory(n):
"""Create ground truth trajectory."""
trajectory = []
timeOfEvent = 10
# simulate emitting a sound every second while moving on straight line
for key in range(n):
trajectory.append(
Event(timeOfEvent, 245 * CM + key * 1.0, 201.5 * CM, (212 - 45) * CM))
timeOfEvent += 1
return trajectory
def simulateOneTOA(microphones, event):
"""Simulate time-of-arrival measurements for a single event."""
return [TIME_OF_ARRIVAL.measure(event, microphones[i])
for i in range(len(microphones))]
def simulateTOA(microphones, trajectory):
"""Simulate time-of-arrival measurements for an entire trajectory."""
return [simulateOneTOA(microphones, event)
for event in trajectory]
def createGraph(microphones, simulatedTOA):
"""Create factor graph."""
graph = NonlinearFactorGraph()
# Create a noise model for the TOA error
model = noiseModel_Isotropic.Sigma(1, 0.5 * MS)
K = len(microphones)
key = 0
for toa in simulatedTOA:
for i in range(K):
factor = TOAFactor(key, microphones[i], toa[i], model)
graph.push_back(factor)
key += 1
return graph
def createInitialEstimate(n):
"""Create initial estimate for n events."""
initial = Values()
zero = Event()
for key in range(n):
TOAFactor.InsertEvent(key, zero, initial)
return initial
def TimeOfArrivalExample():
"""Run example with 4 microphones and 5 events in a straight line."""
# Create microphones
microphones = defineMicrophones()
K = len(microphones)
for i in range(K):
print("mic {} = {}".format(i, microphones[i]))
# Create a ground truth trajectory
n = 5
groundTruth = createTrajectory(n)
for event in groundTruth:
print(event)
# Simulate time-of-arrival measurements
simulatedTOA = simulateTOA(microphones, groundTruth)
for key in range(n):
for i in range(K):
print("z_{}{} = {} ms".format(key, i, simulatedTOA[key][i] / MS))
# create factor graph
graph = createGraph(microphones, simulatedTOA)
print(graph.at(0))
# Create initial estimate
initial_estimate = createInitialEstimate(n)
print(initial_estimate)
# Optimize using Levenberg-Marquardt optimization.
params = LevenbergMarquardtParams()
params.setAbsoluteErrorTol(1e-10)
params.setVerbosityLM("SUMMARY")
optimizer = LevenbergMarquardtOptimizer(graph, initial_estimate, params)
result = optimizer.optimize()
print("Final Result:\n", result)
if __name__ == '__main__':
TimeOfArrivalExample()
print("Example complete")

7
gtsam_unstable/geometry/Event.h
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@ -86,6 +86,7 @@ struct traits<Event> : internal::Manifold<Event> {};
/// Time of arrival to given sensor
class TimeOfArrival {
const double speed_; ///< signal speed
public:
typedef double result_type;
@ -93,6 +94,12 @@ class TimeOfArrival {
explicit TimeOfArrival(double speed = 330) : speed_(speed) {}
/// Calculate time of arrival
double measure(const Event& event, const Point3& sensor) const {
double distance = gtsam::distance3(event.location(), sensor);
return event.time() + distance / speed_;
}
/// Calculate time of arrival, with derivatives
double operator()(const Event& event, const Point3& sensor, //
OptionalJacobian<1, 4> H1 = boost::none, //
OptionalJacobian<1, 3> H2 = boost::none) const {

24
gtsam_unstable/gtsam_unstable.h
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@ -377,6 +377,30 @@ virtual class RangeFactor : gtsam::NoiseModelFactor {
typedef gtsam::RangeFactor<gtsam::PoseRTV, gtsam::PoseRTV> RangeFactorRTV;
#include <gtsam_unstable/geometry/Event.h>
class Event {
Event();
Event(double t, const gtsam::Point3& p);
Event(double t, double x, double y, double z);
double time() const;
gtsam::Point3 location() const;
double height() const;
void print(string s) const;
};
class TimeOfArrival {
TimeOfArrival();
TimeOfArrival(double speed);
double measure(const gtsam::Event& event, const gtsam::Point3& sensor) const;
};
#include <gtsam_unstable/slam/TOAFactor.h>
virtual class TOAFactor : gtsam::NonlinearFactor {
// For now, because of overload issues, we only expose constructor with known sensor coordinates:
TOAFactor(size_t key1, gtsam::Point3 sensor, double measured,
const gtsam::noiseModel::Base* noiseModel);
static void InsertEvent(size_t key, const gtsam::Event& event, gtsam::Values* values);
};
#include <gtsam/nonlinear/NonlinearEquality.h>
template<T = {gtsam::PoseRTV}>

5
gtsam_unstable/slam/TOAFactor.h
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@ -57,6 +57,11 @@ class TOAFactor : public ExpressionFactor<double> {
double speed = 330)
: TOAFactor(eventExpression, Expression<Point3>(sensor), toaMeasurement,
model, speed) {}
static void InsertEvent(Key key, const Event& event,
boost::shared_ptr<Values> values) {
values->insert(key, event);
}
};
} // namespace gtsam