handbook of multisensor data fusion phần 4 pot

The measurements at two different sampling instants are conditionally independent, i.e., 8.49 where p[·]is the probability density function.. Due to the presence of false measurements,

(8.47) The cumulative set of measurements during the entire period is

(8.48)

The following additional assumptions about the statistical characteristics of the measurements are also made:11

1 The measurements at two different sampling instants are conditionally independent, i.e.,

(8.49)

where p[·]is the probability density function.

2 A measurement that originated from the target at a particular sampling instant is received by the

sensor only once during the corresponding scan with probability P D and is corrupted by zero-mean Gaussian noise of known variance That is

(8.50) where is the bearing measurement noise Due to the presence of false measurements, the index of the true measurement is not known

3 The false bearing measurements are distributed uniformly in the surveillance region, i.e.,

(8.51)

4 The number of false measurements at a sampling instant is generated according to a Poisson law with a known expected number of false measurements in the surveillance region This is deter-mined by the detection threshold at the sensor (exact equations are given in Section 8.3.5) For narrowband sonar (with frequency measurements) the target motion model is defined by the five-dimensional vector

(8.52)

where γ is the unknown emitted frequency assumed constant Due to the relative motion between the

target and platform at t i, this frequency will be Doppler shifted at the platform The (noise-free) shifted frequency, denoted by γi (x), is given by

(8.53)

where c is the velocity of sound in the medium If the bandwidth of the signal processor in the sonar is

[Ω1, Ω2], the measurements can lie anywhere within this range As in the case of bearing measurements,

z i j( )=∆[ ]ij a ij ′

β

Z n Z i

i

n

={ } ( ) =

∆

1

p Z i Z i x[ ( ) ( )1 , 2 ]=p Z i x p Z i x[ ] ( )1 [ ] ( )2 ∀ ≠i1 i2

βij=θi( )x + ∈ij

∈ij~
0[ ],σθ2

βij~[ ]θ θ1, 2

x=∆[ ( ) ( )t t ]

ξ 1 , η 1 , ˙ , ˙ , ξ η γ

i

c

( )=  − ( ) ( )+ ( ) ( )















An Introduction to the

Combinatorics of

Optimal and Approximate Data

Association

9.1 Introduction

9.2 Background

9.3 Most Probable Assignments

9.4 Optimal Approach

9.5 Computational Considerations

9.6 Efficient Computation of the JAM

9.7 Crude Permanent Approximations

9.8 Approximations Based on Permanent Inequalities

9.9 Comparisons of Different Approaches

9.10 Large-Scale Data Association

9.11 Generalizations

9.12 Conclusions

Acknowledgments

Appendix 9.A Algorithm for Data Association Experiment

References

9.1 Introduction

Applying filtering algorithms to track the states of multiple targets first requires the correlation of the tracked objects with their corresponding sensor observations A variety of probabilistic measures can be applied to each track estimate to determine independently how likely it is to have produced the current observation; however, such measures are useful only in practice for eliminating obviously infeasible candidates Chapter 3 uses these measures to construct gates for efficiently reducing the number of feasible candidates to a number that can be accommodated within real-time computing constraints Subsequent elimination of candidates can then be effected by measures that consider the joint relationships among the remaining track and report pairs

After the gating step has been completed, a determination must be made concerning which feasible associations between observations and tracks are most likely to be correct In a dense environment, however, resolving the ambiguities among various possible assignments of sensor reports to tracks may Jeffrey K Uhlmann

University of Missouri

A Bayesian Approach

to Multiple-Target Tracking*

10.1 Introduction

Filtering

10.2 Bayesian Formulation of the Single-Target Tracking Problem

10.3 Multiple-Target Tracking without Contacts or Association (Unified Tracking)

Recursion

10.4 Multiple-Hypothesis Tracking (MHT)

Tracking

10.5 Relationship of Unified Tracking to MHT and Other Tracking Approaches

Relationship of Unified Tracking to Other Multiple-Target

10.6 Likelihood Ratio Detection and Tracking

Basic Definitions and Relations • Likelihood Ratio Recursion •

Track-Before-Detect

References

10.1 Introduction

This chapter views the multiple-target tracking problem as a Bayesian inference problem and highlights the benefits this approach The goal of this chapter is to provide the reader with some insights and perhaps a new view of multiple-target tracking It is not designed to provide the reader with a set of algorithms for multiple-target tracking

*This chapter is based on Bayesian Multiple Target Tracking, by Stone, L D., Barlow, C A., and Corwin, T L.,

1999 Artech House, Inc., Norwood, MA www.artechhouse.com

Lawrence D Stone

Metron Inc.