Detection

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Detection

• Chia-Hsin Cheng

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Outlines

• Detection Theory
• Simple Binary Hypothesis Tests
• Bayes Criterion
• The MAP Criterion
• The ML Criterion
• Neyman-Pearson Criterion
• M Hypotheses
• Composite Hypothesis
• GLRT (Generalized LRT)
• The General Gaussian Problem
• Course Information

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Detection Theory

• Example Know Signal in Noise Problem

Decision rule
decision
We are faced with the problem of decision which
of two possible signals was transmitted. Detection
problem observes r(t) and guess whether s1(t)
or s2(t) was sent.
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Classical Detection Theory

• The source generates outputs of two choices
  (hypotheses), H0 and H1.We do not know which
  hypothesis is true.
• The transition mechanism can be viewed as a
  device that knows which hypothesis is true.(i.e.,
  channel model, likelihood function)
  
• Based on this knowledge, it generates a point in
  the observation space according to some
  probability law.

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Classical Detection Theory

• Example symbol rate sampling
• Example over the symbol rate sampling
• We confine our discussion to problems in which
  the observation space is finite-dimensional. The
  observations consist of a set of N numbers and
  can be represented as a point in a N-dimensional
  space.

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• After observing the outcome in the observation
  space, we shall guess which hypothesis is true,
  and to accomplish this, we develop a decision
  rule that assign each point in the observations
  space to one of the hypotheses.

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Simple Binary Hypothesis Tests

• We assume that the observation space corresponds
  to a set of N observations
  , or in a vector r ,
• The probabilistic transition mechanism generates
  points in accord with the two known conditional
  probability densities
• and
  . The objective is to use this
  information to develop a suitable decision rule.
• Example

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Decision Criteria

• In the binary hypothesis problem, we know that
  either H0 or H1 is true. Each time the experiment
  is conducted, one of things can happen

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Bayes Criterion

• Two assumptions
• 1. A Priori probabilities are known
• 2. Costs are assigned Cij
• We should like to design our decision rule so
  that on the average the cost will be as small as
  possible.
• Average cost risk

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Bayes Criterion (cont.)

• Because the decision rule must say either H1 or
  H0,we can view it as a rule for dividing the
  total observation space Z into two parts Z0 and
  Z1. When an observation falls in Z0, we say H0,
  and whenever and observation falls in Z1,we say
  H1.
• Optimal Bayes test design Z0 and Z1 to minimize

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Bayes Criterion (cont.)

• The risk function of (1) can be written in terms
  of the transition probabilities and the decision
  regions
• We shall assume throughout our work that the cost
  of a wrong decision is higher than the cost of a
  correct decision, i.e.,

(2)
(3)
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Bayes Criterion (cont.)

• To find the Bayes test, we must choose the
  decision regions Z0 and Z1 in such a manner that
  the risk will be minimized. Because we require
  that a decision be made, this means that we must
  assign each point R in the observation space Z to
  Z0 or Z1 .
• Thus
• Rewriting (2), we have
• Observing that
• Substituting into (5)

(6)
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Bayes Criterion (cont.)

• Then, we have
• The first two terms of (7) represent the fixed
  cost. The assumptions in (3) imply that the two
  terms inside the brackets are positive, the
  second term is larger than the first should be
  included in Z0 because they contribute a negative
  amount to the integral.
• The decision regions are defined by the
  statement

(7)
H1
(8)
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Bayes Criterion (cont.)
(9)
Likelihood ratio
(10)

• The quantity on the right of (9) is the threshold
  of the test and is
• denoted by

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Bayes Criterion (cont.)

• The Bayes criterion leads us to a likelihood
  ratio test (LRT)
• Because the natural logarithm is a monotonic
  function, and both sides of (11a) are positive,
  an equivalent test is (log LRT)

(11a)
(11b)
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The MAP Criterion

• A priori (before we observe R r) P0 and P1
• A posteriori (after we have observed R r)
• When C10C011, C00C110
• Form (9) and dividing by Pr(R)
• MAP(maximum a posteriori probability)
  Criterion

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The ML Criterion

• The possible likelihoods of r
  and
• When P0 P1 1/2, C10C011,and C00C110

Form (9)
ML(maximum likelihood) Criterion
MAP Criterion ML Criterion (when all Pi are
the same)
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Bayes Criterion Example

• Example We assume that under H1 the source
  output is a constant voltage m and that under
  H0 the source output is zero. Before observation
  that voltage is corrupted by an Gaussian noise.

because the noise samples are Gaussian.
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Bayes Criterion Example (cont.)
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Bayes Criterion Example (cont.)

• The likelihood ratio test is

Thus, the log LRT is

or , equivalently

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Bayes Criterion Example (cont.)

• If C00 C11 0 and C01 C10 1, the risk
  function of (5) reduces to the probability of
  error
• i.e., the Bayes test is minimizing the
  total probability of error.
• When the decision regions are chosen, the values
  of the integrals in (5) are determined. We denote
  the probabilities of false alarm, detection, and
  miss, respectively, as

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Bayes Criterion Example (cont.)

• For any choice of decision regions, the risk
  function can be written from (5) as
• Because
• Then

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Neyman-Pearson Criterion

• In many physical situations, it is difficult to
  assign realistic costs or a priori probabilities.
  A simple procedure to bypass this difficulty is
  to work with the conditional probabilities PF and
  PD.

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Neyman-Pearson Criterion (cont.)

• For any positive value of ? an LRT will minimize
  F. (A negative value of gives an LRT with the
  inequalities reversed)
• Thus F is minimized by the likelihood radio test
• To satisfy the constraint we choose ? so that
  , i.e.,
• Observe that decreasing ? is equivalent to
  increasing Z1 thus PD increase as ? decreases.

(12)
Solving (12) for ? gives the threshold.
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Neyman-Pearson Criterion (cont.)
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???
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Q-function

• Gaussian (normal) distribution
• erfc-function
• Q-function

The pdf of a Gaussian or normal distribution
The cumulative distribution function (CDF) of a
N(0,1)
The complementary CDF of a N(0,1)
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Q-function (cont.)
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Q-function (cont.)
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Neyman-Pearson Criterion (cont.)
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Receiver operating characteristic(ROC)
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Summary

• Using either a Bayes criterion or a
  Neyman-Pearson criterion, we find that the
  optimum test is a likelihood ratio test. Thus,
  regardless of the dimensionality of the
  observation space, the test consists of comparing
  a scalar variable with a threshold.
• In many cases, construction of the LRT can be
  simplified if we can identifies a sufficient
  statistic.
• A complete description of the LRT performance was
  obtained by plotting the conditional
  probabilities PD and PF as the threshold was
  varied.

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M Hypotheses

• In the simple M-ary test, there are M source
  outputs, each of which corresponds to one of M
  hypotheses. As before, we are forced to make a
  decision.
• The Bayes criterion assigns a cost to each of the
  alternatives, assumes a set of a priori
  probabilities , and
  minimizes the risk.
• The cost Cij denotes that the i-th hypothesis is
  chosen and the j-th hypothesis is true.

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M Hypotheses (cont.)

• The risk function for the M-ary hypothesis
  problem is
• To find the optimum test, we vary the Zi to
  minimize R. We
• consider the case of M3 below.

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Noting that Z0Z-Z1-Z2, because the regions are
disjoint, we obtain
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Bayes criterion
The optimum Bayes test becomes
(I)
(II)
(III)

• We see that the decision rules correspond to
  three lines in the ?1, ?2 plane.
• It is easy to verify that these three lines
  intersect at a common point.

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(III)
(II)
(I)
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1
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When , MAP? ML
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Some Points of M-ary Detection

• The minimum dimension of the decision space is no
  more than M-1. The boundaries of the decision
  regions are hyperplanes in the(?1, , ?M-1).
• A particular test of importance is the minimum
  total probability of error test. Here we compute
  the a posteriori probability of each hypothesis
  Pr(HiR) and choose the largest.

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Composite Hypothesis

• Example

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Composite Hypothesis (cont.)

• If ? is a random variable with a know pdf and
  the probability density of ? on the two
  hypotheses as
• the likelihood ratio is

Above ex Let ? M
(14)
Reduce the problem to a simple hypothesis-testing
problem ( knowing a pdf of ? )
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Composite Hypothesis (cont.)

• Example (continued) We assume that the
  probability density governing m on H1 is
• Then,
• Integrating and taking the logarithm of both
  sides, we obtain

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GLRT (Generalized LRT)

• Using ML (maximum likelihood) estimate the value
  of ? under the two hypotheses (H0, H1), the
  result is called a generalized likelihood ratio
  test

where ? 1, ranges over all ? in H1 and ? 0,
ranges over all ? in H0. In other words, we make
a ML estimate of ? 1 , assuming that H1 is true.
We then evaluate for
and use this value in the numerator. A similar
procedure gives the denominator.
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The General Gaussian Problem

• Definition A set of random variables
  are defined as jointly Gaussian if
  all their linear combinations are Gaussian random
  variables.
• Definition A vector r is a Gaussian random
  vector when its components
  are jointly Gaussian random variables.
• Definition A Gaussian random vector r is
  characterized by its mean m and covariance matrix
  , i.e.,

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• Consider the following binary hypothesis problem

(15)
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? Equal covariance matrices
(17)
(17)
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we defined d as the distance between the means on
the two hypothesis when the variance was
normalized to equal one.
(18)
The performance of this binary detection problem
depends on d
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PD
d
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• Case1. Independent Components with Equal
  Variance.
• Substituting to (18)

We see that d corresponds to the distance between
the two mean-value vectors divided by the
standard deviation of Ri.
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• Case 2. Independent Components with Unequal
  Variance.
• Case 3. A general case.
• PLS refer to textbook pp.101-107.

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Course Information

• Instructor Chia-Hsin Cheng
• Room 525
• Tel05-2720411 ext23240
• E-mail vincent_at_wireless.ee.ccu.edu.tw
• Text book
• H.L. Van Trees, Detection, Estimation and
  Modulation Theory, Wiley, 2001, pt. I, Chap1
  chap2.
• Reference books
• S.M. Kay, Fundamentals of Statistical Signal
  Processing Detection Theory, Prentice Hall,
  1998, pt. II.
• H.V. Poor, An Introduction to Signal Detection
  and Estimation, 2nd ed., Springer-Verlag, 1994.

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Ultra wideband

• UWB First Reading
• 1Moe Z. Win Robert A. Scholtz, Impulse
  Radio How it works, IEEE Communication
  Letters,February 1998.
• 2 R. A. Scholtz, Multiple access with
  time-hopping impulse modulation,in Proc. MILCOM,
  Oct. 1993.
• 3 Durisi, G. Romano, On the validity of
  Gaussian Approximation to Characterize the
  Multiuser Capacity of UWB TH PPM, IEEE
  Conference on Ultra Wideband Systems and
  Technologies. Digest of Papers , Baltimore,
  USA,pp.157 - 161, 2002.
• 4PlusON Technology Overview,
  http//www.timedomain.com ,July 2000.
• 5 K. Mandke et al., The Evolution of Ultra
  Wide Band Radio for Wireless Personal Area
  Networks, High Frequency Electronics, September
  2003, pp. 22-32.