#!/usr/bin/env python """ ========================================================== 2 - Multiple Sensor Management ========================================================== """ # %% # # This tutorial follows on from the Single Sensor Management tutorial and further explores how existing # Stone Soup features can be used to build simple sensor management algorithms for tracking and # state estimation. This second tutorial demonstrates the limitations of the brute force optimisation # method introduced in the previous tutorial by increasing the number of sensors used in the scenario. # # Introducing multiple sensors # ---------------------------- # The example in this tutorial considers the same sensor management methods as in Tutorial 1 and applies them to the # same set of ground truths in order to observe the difference in tracks. The scenario simulates 3 # targets moving on nearly constant velocity trajectories and in this case an adjustable number of sensors. # The sensors are # simple radar with a defined field of view which can be pointed in a particular direction in order # to make an observation. # # The first method, using the class :class:`~.RandomSensorManager` chooses a target for each sensor to # observe randomly with equal probability. # # The second method, uses the class :class:`~.BruteForceSensorManager` and aims to reduce the total # uncertainty of the track estimates at each # time step. To achieve this the sensor manager considers all possible configurations of directions for the sensors # to point in. The sensor manager chooses the configuration for which the sum of estimated # uncertainties (as represented by the Frobenius norm of the covariance matrix) can be reduced the most by observing # the targets within the chosen sensing configuration. # # The introduction of multiple sensors means an increase in the possible combinations of action choices # that the brute force sensor manager must consider. This brute force optimisation method of looking at every possible # combination of actions becomes very slow as more sensors are introduced, demonstrating the # limitations of using this method in more complex scenarios. # # As in the first tutorial the OSPA [#]_, SIAP [#]_ and uncertainty metrics are used to assess the performance of the # sensor managers. # %% # Sensor Management example # ------------------------- # # Setup # ^^^^^ # # First a simulation must be set up using components from Stone Soup. For this the following imports are required. import numpy as np import random from datetime import datetime, timedelta start_time = datetime.now() from stonesoup.models.transition.linear import CombinedLinearGaussianTransitionModel, ConstantVelocity from stonesoup.types.groundtruth import GroundTruthPath, GroundTruthState # %% # Generate ground truths # ^^^^^^^^^^^^^^^^^^^^^^ # # Generate transition model and ground truths as in Tutorial 1. # # The number of targets in this simulation is defined by `ntruths` - here there are 3 targets travelling # in different directions. The time the # simulation is observed for is defined by `time_max`. # # We can fix our random number generator in order to probe a particular example repeatedly. This can be undone by # commenting out the first two lines in the next cell. np.random.seed(1990) random.seed(1990) # Generate transition model transition_model = CombinedLinearGaussianTransitionModel([ConstantVelocity(0.005), ConstantVelocity(0.005)]) yps = range(0, 100, 10) # y value for prior state truths = [] ntruths = 3 # number of ground truths in simulation time_max = 50 # timestamps the simulation is observed over xdirection = 1 ydirection = 1 # Generate ground truths for j in range(0, ntruths): truth = GroundTruthPath([GroundTruthState([0, xdirection, yps[j], ydirection], timestamp=start_time)], id=f"id{j}") for k in range(1, time_max): truth.append( GroundTruthState(transition_model.function(truth[k - 1], noise=True, time_interval=timedelta(seconds=1)), timestamp=start_time + timedelta(seconds=k))) truths.append(truth) xdirection *= -1 if j % 2 == 0: ydirection *= -1 # %% # Plot the ground truths. This is done using the :class:`~.Plotterly` class from Stone Soup. from stonesoup.plotter import Plotterly # Stonesoup plotter requires sets not lists truths_set = set(truths) plotter = Plotterly() plotter.plot_ground_truths(truths_set, [0, 2]) plotter.fig # %% # Create sensors # ^^^^^^^^^^^^^^ # Create a set of sensors for each sensor management algorithm. As in Tutorial 1 this tutorial uses the # :class:`~.RadarRotatingBearingRange` sensor with the # number of sensors initially set as 2. Each sensor is positioned along the line :math:`x=10`, at distance # intervals of 50. # # Increasing the number of sensors above 2 significantly increases the run time of the sensor manager due to the # increase in combinations to be considered by the :class:`~.BruteForceSensorManager`. # Note that in Tutorial 1 we did not set the resolution for the dwell centre whereas here we are setting it to 30 # degrees. This is because for the brute force algorithm with multiple sensors, using the default resolution of 1 # degree is not practical. These limitations due to combinatorics are discussed further later. total_no_sensors = 2 from stonesoup.types.state import StateVector from stonesoup.sensor.radar.radar import RadarRotatingBearingRange from stonesoup.types.angle import Angle sensor_setA = set() for n in range(0, total_no_sensors): sensor = RadarRotatingBearingRange( position_mapping=(0, 2), noise_covar=np.array([[np.radians(0.5) ** 2, 0], [0, 1 ** 2]]), ndim_state=4, position=np.array([[10], [n * 50]]), rpm=60, fov_angle=np.radians(30), dwell_centre=StateVector([0.0]), max_range=np.inf, resolutions={'dwell_centre': Angle(np.radians(30))} ) sensor_setA.add(sensor) for sensor in sensor_setA: sensor.timestamp = start_time sensor_setB = set() for n in range(0, total_no_sensors): sensor = RadarRotatingBearingRange( position_mapping=(0, 2), noise_covar=np.array([[np.radians(0.5) ** 2, 0], [0, 1 ** 2]]), ndim_state=4, position=np.array([[10], [n * 50]]), rpm=60, fov_angle=np.radians(30), dwell_centre=StateVector([0.0]), max_range=np.inf, resolutions={'dwell_centre': Angle(np.radians(30))} ) sensor_setB.add(sensor) for sensor in sensor_setB: sensor.timestamp = start_time # %% # Create the Kalman predictor and updater # ^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^ # # Construct a predictor and updater using the :class:`~.KalmanPredictor` and :class:`~.ExtendedKalmanUpdater` # components from Stone Soup. The measurement model for the updater is `None` as it is an attribute of the sensor. from stonesoup.predictor.kalman import KalmanPredictor predictor = KalmanPredictor(transition_model) from stonesoup.updater.kalman import ExtendedKalmanUpdater updater = ExtendedKalmanUpdater(measurement_model=None) # measurement model is added to detections by the sensor # %% # Run the Kalman filters # ^^^^^^^^^^^^^^^^^^^^^^ # # Create priors which estimate the targets' initial states - these are the same as in the first # sensor management tutorial. from stonesoup.types.state import GaussianState priors = [] xdirection = 1.2 ydirection = 1.2 for j in range(0, ntruths): priors.append(GaussianState([[0], [xdirection], [yps[j]+0.1], [ydirection]], np.diag([0.5, 0.5, 0.5, 0.5]+np.random.normal(0,5e-4,4)), timestamp=start_time)) xdirection *= -1 if j % 2 == 0: ydirection *= -1 # %% # Initialise the tracks by creating an empty list and appending the priors generated. This needs to be done # separately for both sensor manager methods as they will generate different sets of tracks. from stonesoup.types.track import Track # Initialise tracks from the RandomSensorManager tracksA = [] for j, prior in enumerate(priors): tracksA.append(Track([prior])) # Initialise tracks from the BruteForceSensorManager tracksB = [] for j, prior in enumerate(priors): tracksB.append(Track([prior])) # %% # Create sensor managers # ^^^^^^^^^^^^^^^^^^^^^^ # # Next we create our sensor management classes. As in Tutorial 1, two sensor manager classes are used - # :class:`~.RandomSensorManager` and :class:`~.BruteForceSensorManager`. # # Random sensor manager # """"""""""""""""""""" # # The first method :class:`~.RandomSensorManager`, randomly chooses the action(s) for the sensors to # take to make an observation. To do this the # :meth:`choose_actions` function uses :meth:`random.choice()` to choose a direction for each # sensor to observe from the possible actions it can take. It returns the chosen configuration of sensors and # actions to be taken as a mapping. from stonesoup.sensormanager import RandomSensorManager # %% # Brute force sensor manager # """""""""""""""""""""""""" # # The second method :class:`~.BruteForceSensorManager` chooses the configuration of sensors and actions which results # in the greatest reward as calculated by the reward function. # # In this example this is the largest difference between the uncertainty covariances of the target # predictions and posteriors # assuming a predicted measurement corresponding to that prediction. This means the sensor manager chooses # to point the sensors in directions such that the uncertainty will be reduced the most by # making observations in those directions. from stonesoup.sensormanager import BruteForceSensorManager # %% # Reward function # """"""""""""""" # The :class:`UncertaintyRewardFunction` calculates the uncertainty reduction by computing the difference between the # covariance matrix norms of the # prediction and the posterior assuming a predicted measurement corresponding to that prediction. The sum # of these differences is returned as a metric for that configuration. from stonesoup.sensormanager.reward import UncertaintyRewardFunction # %% # Initiate sensor managers # ^^^^^^^^^^^^^^^^^^^^^^^^ # # Create an instance of each sensor manager class. Both sensor managers take in a `sensor_set`. # The :class:`~.BruteForceSensorManager` also requires a callable reward function which is initiated here # from the :class:`UncertaintyRewardFunction`. randomsensormanager = RandomSensorManager(sensor_setA) # initiate reward function reward_function = UncertaintyRewardFunction(predictor, updater) bruteforcesensormanager = BruteForceSensorManager(sensor_setB, reward_function=reward_function) # %% # Run the sensor managers # ^^^^^^^^^^^^^^^^^^^^^^^ # # Both sensor management methods require a timestamp and a list of tracks at each time step when calling # the function :meth:`choose_actions`. This returns a mapping of sensors and actions to be taken by each # sensor, decided by the sensor managers. # # For both sensor management methods, at each time step the chosen action is given to the sensors and then # measurements taken. The tracks are updated based on these measurements with predictions made for tracks # which have not been observed. # # First a hypothesiser and data associator are required for use in both trackers. from stonesoup.hypothesiser.distance import DistanceHypothesiser from stonesoup.measures import Mahalanobis hypothesiser = DistanceHypothesiser(predictor, updater, measure=Mahalanobis(), missed_distance=5) from stonesoup.dataassociator.neighbour import GNNWith2DAssignment data_associator = GNNWith2DAssignment(hypothesiser) # %% # Run random sensor manager # """"""""""""""""""""""""" # # Here the chosen target for observation is selected randomly using the method :meth:`choose_actions()` from the class # :class:`~.RandomSensorManager`. This returns a mapping of sensors to actions where actions are a # :class:`~.ChangeDwellAction`, selected at random. from ordered_set import OrderedSet # Generate list of timesteps from ground truth timestamps timesteps = [] for state in truths[0]: timesteps.append(state.timestamp) for timestep in timesteps[1:]: # Generate chosen configuration chosen_actions = randomsensormanager.choose_actions(tracksA, timestep) # Create empty dictionary for measurements measurementsA = [] for chosen_action in chosen_actions: for sensor, actions in chosen_action.items(): sensor.add_actions(actions) for sensor in sensor_setA: sensor.act(timestep) # Observe this ground truth measurements = sensor.measure(OrderedSet(truth[timestep] for truth in truths), noise=True) measurementsA.extend(measurements) hypotheses = data_associator.associate(tracksA, measurementsA, timestep) for track in tracksA: hypothesis = hypotheses[track] if hypothesis.measurement: post = updater.update(hypothesis) track.append(post) else: # When data associator says no detections are good enough, we'll keep the prediction track.append(hypothesis.prediction) # %% # Plot ground truths, tracks and uncertainty ellipses for each target. The positions of the sensors are indicated # by black x markers. plotterA = Plotterly() plotterA.plot_sensors(sensor_setA) plotterA.plot_ground_truths(truths_set, [0, 2]) plotterA.plot_tracks(set(tracksA), [0, 2], uncertainty=True) plotterA.fig # %% # In comparison to Tutorial 1 the performance of the :class:`~.RandomSensorManager` has improved. This is # because a greater number of sensors means each target is more likely to be observed. This means the uncertainty # of the track does not increase as much because the targets are observed more often. # %% # Run brute force sensor manager # """""""""""""""""""""""""""""" # # Here the direction for observation is selected based on the difference between the covariance matrices of the # prediction and posterior, for targets which could be observed by the sensor # pointing in the given direction. # # Within the sensor manager a dictionary is created of sensors and all the possible actions they can take. # When the :meth:`choose_actions` function is called (at each time step), for each track in the tracks list: # # * A prediction is made for each track and the covariance matrix norms stored # * For each possible action a sensor could take, a synthetic detection is made using this sensor configuration # * A hypothesis is generated based on the stored prediction and synthetic detection # * This hypothesis is used to do an update and the covariance matrix norms of the update are stored # * The difference between the covariance matrix norms of the update and the prediction is calculated # # The overall reward is calculated as the sum of the differences between these covariance matrix norms # for the tracks observed by the possible action configuration. The sensor manager identifies the # configuration which results in the largest value of this reward and therefore # largest reduction in uncertainty. It returns the optimum sensors/actions configuration as a dictionary. # # The actions are given to the sensors, measurements made and # the tracks updated based on these measurements. Predictions are made for tracks # which have not been observed by the sensors. for timestep in timesteps[1:]: # Generate chosen configuration chosen_actions = bruteforcesensormanager.choose_actions(tracksB, timestep) # Create empty dictionary for measurements measurementsB = [] for chosen_action in chosen_actions: for sensor, actions in chosen_action.items(): sensor.add_actions(actions) for sensor in sensor_setB: sensor.act(timestep) # Observe this ground truth measurements = sensor.measure(OrderedSet(truth[timestep] for truth in truths), noise=True) measurementsB.extend(measurements) hypotheses = data_associator.associate(tracksB, measurementsB, timestep) for track in tracksB: hypothesis = hypotheses[track] if hypothesis.measurement: post = updater.update(hypothesis) track.append(post) else: # When data associator says no detections are good enough, we'll keep the prediction track.append(hypothesis.prediction) # %% # Plot ground truths, tracks and uncertainty ellipses for each target. plotterB = Plotterly() plotterB.plot_sensors(sensor_setB) plotterB.plot_ground_truths(truths_set, [0, 2]) plotterB.plot_tracks(set(tracksB), [0, 2], uncertainty=True) plotterB.fig # %% # The smaller uncertainty ellipses in this plot suggest that the :class:`~.BruteForceSensorManager` provides a much # better track than the :class:`~.RandomSensorManager`. # The tracking is also improved from Tutorial 1 due to the increased number of sensors. # %% # Combinatorics # ------------- # # The following graph demonstrates how the number of possible sensor-action configurations increases with the number # of sensors and number of actions. The number of configurations which are considered by the sensor manager # for :math:`M` actions and :math:`N` sensors is :math:`M^N`. # # With a resolution of 1 degree there are 360 possible dwell centres for a sensor so the number of # possible configurations should be :math:`360^N` # where :math:`N` is the number of sensors. This exponential increase means that as the number of # sensors increase, the run time of the sensor manager slows down significantly because there are so many more # iterations to consider. # # In this scenario :math:`N=2` so with a resolution of 1 degree that would 129,600 # actions to consider. # Even with a resolution of 30 degrees, changing the number of sensors to :math:`N\geq 2` leads to a # much longer run time. # This highlights a practical limitation of using this brute force optimisation method for multiple # sensors. In this example we have dealt with this by introducing a run time limit to the brute force sensor manager. import matplotlib.pyplot as plt nsensors = np.arange(1, 10) nactions = np.arange(1, 360.0) nsensors, nactions = np.meshgrid(nsensors, nactions) ncombinations = nactions**nsensors fig = plt.figure() ax = fig.add_subplot(projection="3d") ax.plot_surface(nsensors, nactions, np.log10(ncombinations), cmap='coolwarm') ax.set_xlabel("No. sensors") ax.set_ylabel("No. actions") ax.set_zlabel("log of no. combinations") # %% # Metrics # ------- # # Metrics can be used to compare how well different sensor management techniques are working. # As in Tutorial 1 the metrics used here are the OSPA, SIAP and uncertainty metrics. from stonesoup.metricgenerator.ospametric import OSPAMetric ospa_generator = OSPAMetric(c=40, p=1) from stonesoup.metricgenerator.tracktotruthmetrics import SIAPMetrics from stonesoup.measures import Euclidean siap_generator = SIAPMetrics(position_measure=Euclidean((0, 2)), velocity_measure=Euclidean((1, 3))) from stonesoup.dataassociator.tracktotrack import TrackToTruth associator = TrackToTruth(association_threshold=30) from stonesoup.metricgenerator.uncertaintymetric import SumofCovarianceNormsMetric uncertainty_generator = SumofCovarianceNormsMetric() # %% # Generate a metrics manager for each sensor management method. from stonesoup.metricgenerator.manager import SimpleManager metric_managerA = SimpleManager([ospa_generator, siap_generator, uncertainty_generator], associator=associator) metric_managerB = SimpleManager([ospa_generator, siap_generator, uncertainty_generator], associator=associator) # %% # For each time step, data is added to the metric manager on truths and tracks. # The metrics themselves can then be generated from the metric manager. metric_managerA.add_data(truths, tracksA) metric_managerB.add_data(truths, tracksB) metricsA = metric_managerA.generate_metrics() metricsB = metric_managerB.generate_metrics() # %% # OSPA metric # ^^^^^^^^^^^ # # First we look at the OSPA metric. This is plotted over time for each sensor manager method. ospa_metricA = metricsA['OSPA distances'] ospa_metricB = metricsB['OSPA distances'] fig = plt.figure() ax = fig.add_subplot(1, 1, 1) ax.plot([i.timestamp for i in ospa_metricA.value], [i.value for i in ospa_metricA.value], label='RandomSensorManager') ax.plot([i.timestamp for i in ospa_metricB.value], [i.value for i in ospa_metricB.value], label='BruteForceSensorManager') ax.set_ylabel("OSPA distance") ax.set_xlabel("Time") ax.legend() # %% # The OSPA distance for the :class:`~.BruteForceSensorManager` is generally smaller than for the random # observations of the :class:`~.RandomSensorManager`. # # SIAP metrics # ^^^^^^^^^^^^ # # Next we look at SIAP metrics. We are only interested in the positional accuracy (PA) and # velocity accuracy (VA). These metrics can be plotted to show how they change over time. fig, axes = plt.subplots(2) times = metric_managerA.list_timestamps() pa_metricA = metricsA['SIAP Position Accuracy at times'] va_metricA = metricsA['SIAP Velocity Accuracy at times'] pa_metricB = metricsB['SIAP Position Accuracy at times'] va_metricB = metricsB['SIAP Velocity Accuracy at times'] axes[0].set(title='Positional Accuracy', xlabel='Time', ylabel='PA') axes[0].plot(times, [metric.value for metric in pa_metricA.value], label='RandomSensorManager') axes[0].plot(times, [metric.value for metric in pa_metricB.value], label='BruteForceSensorManager') axes[0].legend() axes[1].set(title='Velocity Accuracy', xlabel='Time', ylabel='VA') axes[1].plot(times, [metric.value for metric in va_metricA.value], label='RandomSensorManager') axes[1].plot(times, [metric.value for metric in va_metricB.value], label='BruteForceSensorManager') axes[1].legend() # %% # Similar to the OSPA distance the :class:`~.BruteForceSensorManager` generally results in both a better # positional accuracy and velocity accuracy than the random observations of the :class:`~.RandomSensorManager`. # # Uncertainty metric # ^^^^^^^^^^^^^^^^^^ # # Finally we look at the uncertainty metric which computes the sum of covariance matrix norms of each state at each # time step. This is plotted over time for each sensor manager method. uncertainty_metricA = metricsA['Sum of Covariance Norms Metric'] uncertainty_metricB = metricsB['Sum of Covariance Norms Metric'] fig = plt.figure() ax = fig.add_subplot(1, 1, 1) ax.plot([i.timestamp for i in uncertainty_metricA.value], [i.value for i in uncertainty_metricA.value], label='RandomSensorManager') ax.plot([i.timestamp for i in uncertainty_metricB.value], [i.value for i in uncertainty_metricB.value], label='BruteForceSensorManager') ax.set_ylabel("Sum of covariance matrix norms") ax.set_xlabel("Time") ax.legend() # sphinx_gallery_thumbnail_number = 7 # %% # This metric shows that the uncertainty in the tracks generated by the :class:`~.RandomSensorManager` is # generally greater than for those generated by the :class:`~.BruteForceSensorManager`. # This is also reflected by the uncertainty ellipses # in the initial plots of tracks and truths. # %% # References # ---------- # # .. [#] *D. Schuhmacher, B. Vo and B. Vo*, **A Consistent Metric for Performance Evaluation of # Multi-Object Filters**, IEEE Trans. Signal Processing 2008 # .. [#] *Votruba, Paul & Nisley, Rich & Rothrock, Ron and Zombro, Brett.*, **Single Integrated Air # Picture (SIAP) Metrics Implementation**, 2001