Belief Propagation: An Extremely Rudimentary Discussion - PowerPoint PPT Presentation

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Belief Propagation: An Extremely Rudimentary Discussion

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Belief Propagation: An Extremely Rudimentary Discussion McLean & Pavel The Problem When we have a tree structure describing dependencies between variable, we want to ... – PowerPoint PPT presentation

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Title: Belief Propagation: An Extremely Rudimentary Discussion


1
Belief PropagationAn Extremely Rudimentary
Discussion
  • McLean Pavel

2
The Problem
  • When we have a tree structure describing
    dependencies between variable, we want to update
    our probability distributions based on evidence
  • Trees are nice to work with, as the probability
    distribution can be expressed as the product of
    edge marginals divided by the product of
    separator node marginals
  • Simple case if risk of heart disease depends on
    your fathers risk of heart disease, what can you
    say about your own risk if you know your
    grandfathers risk?
  • Essentially, given a prior distribution on the
    tree, find the posterior distribution given some
    observed evidence

3
The Solution
  • Belief Propagation is an algorithm to incorporate
    evidence into a tree distribution
  • Non-iterative method it only requires two passes
    through the tree to get an updated distribution

4
The Algorithm
  • First, incorporate evidence for each observed
    variable, find one edge that it is a part of, and
    set all entries in the edge table that do not
    correspond to the observed value to zero
  • Next, choose some edge as a root
  • Collect evidence in from every direction to the
    root
  • Normalize the root edge table
  • Distribute evidence out in every direction from
    the root

5
Okay, but what do you mean by collect evidence?
  • Well, we want to propagate evidence through the
    system
  • This is fairly simple for singly-linked items
    just update marginal based on joint, then update
    the next joint based on that marginal, and so on
  • So if we observed x, Txy becomes Txy, then we
    get Ty by summing Txy over all x
  • Then, Tyz (Tyz)(Ty/Ty)

x
y
6
And if we have multiply linked items?
  • Then its slightly (but only slightly) more
    complicated
  • Now if we observe x1 and x2, we get Tx1y and
    Tx2y
  • We then calculate T1y and T2y (the equivalents of
    Ty from before, but each using only the
    information from one of the Xs)
  • Now, Tyz(Tyz)(T1y/Ty)(T2y/Ty)
  • See Pavels handout for a complete workthrough
    using this graph, and a justification of the
    calculation of Tyz

x1
y
z
x2
7
But youve got two different marginals for Y!
That cant be right!
  • Patience. All will work out in time.
  • After we have finished collecting evidence, we
    normalize our root table in this case, the root
    would be Tyz
  • Now we distribute evidence this is the same
    process as collecting evidence, but in the
    opposite direction
  • Note that now we are only ever having a single
    input edge going to any given node, so we can
    come up with proper marginals
  • When weve finished distributing evidence, we
    will have a probability distribution over the
    tree that reflects the incorporated evidence.
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