mirror of https://github.com/davisking/dlib.git
355 lines
15 KiB
C++
355 lines
15 KiB
C++
// The contents of this file are in the public domain. See LICENSE_FOR_EXAMPLE_PROGRAMS.txt
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/*
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This example shows how you can use the dlib machine learning tools to make
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an object tracker. Depending on your tracking application there can be a
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lot of components to a tracker. However, a central element of many trackers
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is the "detection to track" association step and this is the part of the
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tracker we discuss in this example. Therefore, in the code below we define
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simple detection and track structures and then go through the steps needed
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to learn, using training data, how to best associate detections to tracks.
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It should be noted that these tools are implemented essentially as wrappers
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around the more general assignment learning tools present in dlib. So if
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you want to get an idea of how they work under the covers you should read
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the assignment_learning_ex.cpp example program and its supporting
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documentation. However, to just use the learning-to-track tools you won't
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need to understand these implementation details.
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*/
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#include <iostream>
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#include <dlib/svm_threaded.h>
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#include <dlib/rand.h>
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using namespace std;
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using namespace dlib;
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// ----------------------------------------------------------------------------------------
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struct detection
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{
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/*
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When you use these tools you need to define two structures. One represents a
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detection and another a track. In this example we call these structures detection
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and track but you can name them however you like. Moreover, You can put anything
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you want in your detection structure. The only requirement is that detection be
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copyable and contain a public typedef named track_type that tells us the track type
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meant for use with this detection object.
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*/
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typedef struct track track_type;
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// Again, note that this field is NOT REQUIRED by the dlib tools. You can put whatever
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// you want in your detection object. Here we are including a column vector of
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// measurements from the sensor that generated the detection. In this example we don't
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// have a real sensor so we will simulate a very basic one using a random number
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// generator. But the idea is that you should be able to use the contents of your
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// detection to somehow tell which track it goes with. So these numbers should contain
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// some identifying information about the real world object that caused this detection.
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matrix<double,0,1> measurements;
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};
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struct track
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{
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/*
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Here we define our corresponding track object. This object has more requirements
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than the detection. In particular, the dlib machine learning tools require it to
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have the following elements:
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- A typedef named feature_vector_type
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- It should be copyable and default constructable
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- The three functions: get_similarity_features(), update_track(), and propagate_track()
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Just like the detection object, you can also add any additional fields you like.
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In this example we keep it simple and say that a track maintains only a copy of the
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most recent sensor measurements it has seen and also a number telling us how long
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it has been since the track was updated with a detection.
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*/
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// This type should be a dlib::matrix capable of storing column vectors or an
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// unsorted sparse vector type such as std::vector<std::pair<unsigned long,double>>.
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typedef matrix<double,0,1> feature_vector_type;
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track()
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{
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time_since_last_association = 0;
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}
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void get_similarity_features(const detection& det, feature_vector_type& feats) const
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{
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/*
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The get_similarity_features() function takes a detection and outputs a feature
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vector that tells the machine learning tools how "similar" the detection is to
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the track. The idea here is to output a set of numbers (i.e. the contents of
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feats) that can be used to decide if det should be associated with this track.
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In this example we output the difference between the last sensor measurements
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for this track and the detection's measurements. This works since we expect
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the sensor measurements to be relatively constant for each track because that's
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how our simple sensor simulator in this example works. However, in a real
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world application it's likely to be much more complex. But here we keep things
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simple.
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It should also be noted that get_similarity_features() must always output
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feature vectors with the same number of dimensions. Finally, the machine
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learning tools are going to learn a linear function of feats and use that to
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predict if det should associate to this track. So try and define features that
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you think would work in a linear function. There are all kinds of ways to do
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this. If you want to get really clever about it you can even use kernel
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methods like the empirical_kernel_map (see empirical_kernel_map_ex.cpp). I
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would start out with something simple first though.
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*/
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feats = abs(last_measurements - det.measurements);
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}
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void update_track(const detection& det)
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{
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/*
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This function is called when the dlib tools have decided that det should be
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associated with this track. So the point of update_track() is to, as the name
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suggests, update the track with the given detection. In general, you can do
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whatever you want in this function. Here we simply record the last measurement
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state and reset the time since last association.
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*/
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last_measurements = det.measurements;
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time_since_last_association = 0;
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}
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void propagate_track()
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{
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/*
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This function is called when the dlib tools have decided, for the current time
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step, that none of the available detections associate with this track. So the
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point of this function is to perform a track update without a detection. To
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say that another way. Every time you ask the dlib tools to perform detection
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to track association they will update each track by calling either
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update_track() or propagate_track(). Which function they call depends on
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whether or not a detection was associated to the track.
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*/
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++time_since_last_association;
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}
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matrix<double,0,1> last_measurements;
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unsigned long time_since_last_association;
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};
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// ----------------------------------------------------------------------------------------
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/*
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Now that we have defined our detection and track structures we are going to define our
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sensor simulator. In it we will imagine that there are num_objects things in the world
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and those things generate detections from our sensor. Moreover, each detection from
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the sensor comes with a measurement vector with num_properties elements.
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So the first function, initialize_object_properties(), just randomly generates
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num_objects and saves them in a global variable. Then when we are generating
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detections we will output copies of these objects that have been corrupted by a little
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bit of random noise.
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*/
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dlib::rand rnd;
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const long num_objects = 4;
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const long num_properties = 6;
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std::vector<matrix<double,0,1> > object_properties(num_objects);
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void initialize_object_properties()
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{
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for (unsigned long i = 0; i < object_properties.size(); ++i)
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object_properties[i] = randm(num_properties,1,rnd);
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}
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// So here is our function that samples a detection from our simulated sensor. You tell it
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// what object you want to sample a detection from and it returns a detection from that
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// object.
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detection sample_detection_from_sensor(long object_id)
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{
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DLIB_CASSERT(object_id < num_objects,
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"You can't ask to sample a detection from an object that doesn't exist.");
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detection temp;
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// Set the measurements equal to the object's true property values plus a little bit of
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// noise.
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temp.measurements = object_properties[object_id] + randm(num_properties,1,rnd)*0.1;
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return temp;
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}
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// ----------------------------------------------------------------------------------------
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typedef std::vector<labeled_detection<detection> > detections_at_single_time_step;
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typedef std::vector<detections_at_single_time_step> track_history;
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track_history make_random_tracking_data_for_training()
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{
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/*
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Since we are using machine learning we need some training data. This function
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samples data from our sensor and creates labeled track histories. In these track
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histories, each detection is labeled with its true track ID. The goal of the
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machine learning tools will then be to learn to associate all the detections with
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the same ID to the same track object.
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*/
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track_history data;
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// At each time step we get a set of detections from the objects in the world.
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// Simulate 100 time steps worth of data where there are 3 objects present.
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const int num_time_steps = 100;
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for (int i = 0; i < num_time_steps; ++i)
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{
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detections_at_single_time_step dets(3);
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// sample a detection from object 0
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dets[0].det = sample_detection_from_sensor(0);
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dets[0].label = 0;
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// sample a detection from object 1
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dets[1].det = sample_detection_from_sensor(1);
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dets[1].label = 1;
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// sample a detection from object 2
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dets[2].det = sample_detection_from_sensor(2);
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dets[2].label = 2;
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data.push_back(dets);
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}
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// Now let's imagine object 1 and 2 are gone but a new object, object 3 has arrived.
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for (int i = 0; i < num_time_steps; ++i)
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{
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detections_at_single_time_step dets(2);
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// sample a detection from object 0
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dets[0].det = sample_detection_from_sensor(0);
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dets[0].label = 0;
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// sample a detection from object 3
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dets[1].det = sample_detection_from_sensor(3);
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dets[1].label = 3;
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data.push_back(dets);
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}
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return data;
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}
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// ----------------------------------------------------------------------------------------
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std::vector<detection> make_random_detections(long num_dets)
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{
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/*
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Finally, when we test the tracker we learned we will need to sample regular old
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unlabeled detections. This function helps us do that.
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*/
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DLIB_CASSERT(num_dets <= num_objects,
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"You can't ask for more detections than there are objects in our little simulation.");
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std::vector<detection> dets(num_dets);
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for (unsigned long i = 0; i < dets.size(); ++i)
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{
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dets[i] = sample_detection_from_sensor(i);
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}
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return dets;
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}
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// ----------------------------------------------------------------------------------------
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int main()
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{
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initialize_object_properties();
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// Get some training data. Here we sample 5 independent track histories. In a real
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// world problem you would get this kind of data by, for example, collecting data from
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// your sensor on 5 separate days where you did an independent collection each day.
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// You can train a model with just one track history but the more you have the better.
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std::vector<track_history> data;
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data.push_back(make_random_tracking_data_for_training());
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data.push_back(make_random_tracking_data_for_training());
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data.push_back(make_random_tracking_data_for_training());
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data.push_back(make_random_tracking_data_for_training());
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data.push_back(make_random_tracking_data_for_training());
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structural_track_association_trainer trainer;
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// Note that the machine learning tools have a parameter. This is the usual SVM C
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// parameter that controls the trade-off between trying to fit the training data or
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// producing a "simpler" solution. You need to try a few different values of this
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// parameter to find out what setting works best for your problem (try values in the
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// range 0.001 to 1000000).
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trainer.set_c(100);
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// Now do the training.
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track_association_function<detection> assoc = trainer.train(data);
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// We can test the accuracy of the learned association function on some track history
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// data. Here we test it on the data we trained on. It outputs a single number that
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// measures the fraction of detections which were correctly associated to their tracks.
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// So a value of 1 indicates perfect tracking and a value of 0 indicates totally wrong
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// tracking.
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cout << "Association accuracy on training data: "<< test_track_association_function(assoc, data) << endl;
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// It's very important to test the output of a machine learning method on data it
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// wasn't trained on. You can do that by calling test_track_association_function() on
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// held out data. You can also use cross-validation like so:
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cout << "Association accuracy from 5-fold CV: "<< cross_validate_track_association_trainer(trainer, data, 5) << endl;
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// Unsurprisingly, the testing functions show that the assoc function we learned
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// perfectly associates all detections to tracks in this easy data.
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// OK. So how do you use this assoc thing? Let's use it to do some tracking!
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// tracks contains all our current tracks. Initially it is empty.
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std::vector<track> tracks;
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cout << "number of tracks: "<< tracks.size() << endl;
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// Sample detections from 3 objects.
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std::vector<detection> dets = make_random_detections(3);
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// Calling assoc(), the function we just learned, performs the detection to track
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// association. It will also call each track's update_track() function with the
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// associated detection. For tracks that don't get a detection, it calls
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// propagate_track().
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assoc(tracks, dets);
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// Now there are 3 things in tracks.
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cout << "number of tracks: "<< tracks.size() << endl;
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// Run the tracker for a few more time steps...
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dets = make_random_detections(3);
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assoc(tracks, dets);
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cout << "number of tracks: "<< tracks.size() << endl;
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dets = make_random_detections(3);
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assoc(tracks, dets);
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cout << "number of tracks: "<< tracks.size() << endl;
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// Now another object has appeared! There are 4 objects now.
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dets = make_random_detections(4);
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assoc(tracks, dets);
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// Now there are 4 tracks instead of 3!
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cout << "number of tracks: "<< tracks.size() << endl;
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// That 4th object just vanished. Let's look at the time_since_last_association values
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// for each track. We will see that one of the tracks isn't getting updated with
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// detections anymore since the object it corresponds to is no longer present.
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dets = make_random_detections(3);
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assoc(tracks, dets);
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cout << "number of tracks: "<< tracks.size() << endl;
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for (unsigned long i = 0; i < tracks.size(); ++i)
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cout << " time since last association: "<< tracks[i].time_since_last_association << endl;
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dets = make_random_detections(3);
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assoc(tracks, dets);
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cout << "number of tracks: "<< tracks.size() << endl;
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for (unsigned long i = 0; i < tracks.size(); ++i)
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cout << " time since last association: "<< tracks[i].time_since_last_association << endl;
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// Finally, you can save your track_association_function to disk like so:
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serialize("track_assoc.svm") << assoc;
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// And recall it from disk later like so:
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deserialize("track_assoc.svm") >> assoc;
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}
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// ----------------------------------------------------------------------------------------
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