/* ************************************************************************* */
int main (int argc, char* argv[]) {
// Find default file, but if an argument is given, try loading a file
string filename = findExampleDataFile("dubrovnik-3-7-pre");
if (argc>1) filename = string(argv[1]);
// Load the SfM data from file
SfM_data mydata;
assert(readBAL(filename, mydata));
cout << boost::format("read %1% tracks on %2% cameras\n") % mydata.number_tracks() % mydata.number_cameras();
// Create a factor graph
NonlinearFactorGraph graph;
// We share *one* noiseModel between all projection factors
noiseModel::Isotropic::shared_ptr noise =
noiseModel::Isotropic::Sigma(2, 1.0); // one pixel in u and v
// Add measurements to the factor graph
size_t j = 0;
BOOST_FOREACH(const SfM_Track& track, mydata.tracks) {
BOOST_FOREACH(const SfM_Measurement& m, track.measurements) {
size_t i = m.first;
Point2 uv = m.second;
graph.push_back(MyFactor(uv, noise, C(i), P(j))); // note use of shorthand symbols C and P
}
j += 1;
}
// Add a prior on pose x1. This indirectly specifies where the origin is.
// and a prior on the position of the first landmark to fix the scale
graph.push_back(PriorFactor<SfM_Camera>(C(0), mydata.cameras[0], noiseModel::Isotropic::Sigma(9, 0.1)));
graph.push_back(PriorFactor<Point3> (P(0), mydata.tracks[0].p, noiseModel::Isotropic::Sigma(3, 0.1)));
// Create initial estimate
Values initial;
size_t i = 0; j = 0;
BOOST_FOREACH(const SfM_Camera& camera, mydata.cameras) initial.insert(C(i++), camera);
BOOST_FOREACH(const SfM_Track& track, mydata.tracks) initial.insert(P(j++), track.p);
/* Optimize the graph and print results */
Values result;
try {
LevenbergMarquardtParams params;
params.setVerbosity("ERROR");
LevenbergMarquardtOptimizer lm(graph, initial, params);
result = lm.optimize();
} catch (exception& e) {
cout << e.what();
}
cout << "final error: " << graph.error(result) << endl;
return 0;
}
/* ************************************************************************* */
TEST(PinholeCamera, BAL) {
string filename = findExampleDataFile("dubrovnik-3-7-pre");
SfM_data db;
bool success = readBAL(filename, db);
if (!success) throw runtime_error("Could not access file!");
SharedNoiseModel unit2 = noiseModel::Unit::Create(2);
NonlinearFactorGraph graph;
for (size_t j = 0; j < db.number_tracks(); j++) {
for (const SfM_Measurement& m: db.tracks[j].measurements)
graph.push_back(sfmFactor(m.second, unit2, m.first, P(j)));
}
Values initial = initialCamerasAndPointsEstimate(db);
LevenbergMarquardtOptimizer lm(graph, initial);
Values actual = lm.optimize();
double actualError = graph.error(actual);
EXPECT_DOUBLES_EQUAL(0.0199833, actualError, 1e-5);
}
/* ************************************************************************* */
int main (int argc, char* argv[]) {
// Find default file, but if an argument is given, try loading a file
string filename = findExampleDataFile("dubrovnik-3-7-pre");
if (argc>1) filename = string(argv[1]);
// Load the SfM data from file
SfM_data mydata;
readBAL(filename, mydata);
cout << boost::format("read %1% tracks on %2% cameras\n") % mydata.number_tracks() % mydata.number_cameras();
// Create a factor graph
NonlinearFactorGraph graph;
// We share *one* noiseModel between all projection factors
noiseModel::Isotropic::shared_ptr noise =
noiseModel::Isotropic::Sigma(2, 1.0); // one pixel in u and v
// Add measurements to the factor graph
size_t j = 0;
BOOST_FOREACH(const SfM_Track& track, mydata.tracks) {
BOOST_FOREACH(const SfM_Measurement& m, track.measurements) {
size_t i = m.first;
Point2 uv = m.second;
graph.push_back(MyFactor(uv, noise, C(i), P(j))); // note use of shorthand symbols C and P
}
j += 1;
}
// Add a prior on pose x1. This indirectly specifies where the origin is.
// and a prior on the position of the first landmark to fix the scale
graph.push_back(PriorFactor<SfM_Camera>(C(0), mydata.cameras[0], noiseModel::Isotropic::Sigma(9, 0.1)));
graph.push_back(PriorFactor<Point3> (P(0), mydata.tracks[0].p, noiseModel::Isotropic::Sigma(3, 0.1)));
// Create initial estimate
Values initial;
size_t i = 0; j = 0;
BOOST_FOREACH(const SfM_Camera& camera, mydata.cameras) initial.insert(C(i++), camera);
BOOST_FOREACH(const SfM_Track& track, mydata.tracks) initial.insert(P(j++), track.p);
/** --------------- COMPARISON -----------------------**/
/** ----------------------------------------------------**/
LevenbergMarquardtParams params_using_COLAMD, params_using_METIS;
try {
params_using_METIS.setVerbosity("ERROR");
gttic_(METIS_ORDERING);
params_using_METIS.ordering = Ordering::Create(Ordering::METIS, graph);
gttoc_(METIS_ORDERING);
params_using_COLAMD.setVerbosity("ERROR");
gttic_(COLAMD_ORDERING);
params_using_COLAMD.ordering = Ordering::Create(Ordering::COLAMD, graph);
gttoc_(COLAMD_ORDERING);
} catch (exception& e) {
cout << e.what();
}
// expect they have different ordering results
if(params_using_COLAMD.ordering == params_using_METIS.ordering) {
cout << "COLAMD and METIS produce the same ordering. "
<< "Problem here!!!" << endl;
}
/* Optimize the graph with METIS and COLAMD and time the results */
Values result_METIS, result_COLAMD;
try {
gttic_(OPTIMIZE_WITH_METIS);
LevenbergMarquardtOptimizer lm_METIS(graph, initial, params_using_METIS);
result_METIS = lm_METIS.optimize();
gttoc_(OPTIMIZE_WITH_METIS);
gttic_(OPTIMIZE_WITH_COLAMD);
LevenbergMarquardtOptimizer lm_COLAMD(graph, initial, params_using_COLAMD);
result_COLAMD = lm_COLAMD.optimize();
gttoc_(OPTIMIZE_WITH_COLAMD);
} catch (exception& e) {
cout << e.what();
}
{ // printing the result
cout << "COLAMD final error: " << graph.error(result_COLAMD) << endl;
cout << "METIS final error: " << graph.error(result_METIS) << endl;
cout << endl << endl;
cout << "Time comparison by solving " << filename << " results:" << endl;
cout << boost::format("%1% point tracks and %2% cameras\n") \
% mydata.number_tracks() % mydata.number_cameras() \
<< endl;
tictoc_print_();
}
return 0;
}
