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1 function prob = quickscore(fpos, fneg, inhibit, prior, leak)
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2 % QUICKSCORE Heckerman's algorithm for BN2O networks.
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3 % prob = quickscore(fpos, fneg, inhibit, prior, leak)
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4 %
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5 % Consider a BN2O (Binary Node 2-layer Noisy-or) network such as QMR with
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6 % dieases on the top and findings on the bottom. (We assume all findings are observed,
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7 % since hidden leaves can be marginalized away.)
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8 % This algorithm takes O(2^|fpos|) time to compute the marginal on all the diseases.
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9 %
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10 % Inputs:
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11 % fpos = the positive findings (a vector of numbers in {1, ..., Nfindings})
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12 % fneg = the negative findings (a vector of numbers in {1, ..., Nfindings})
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13 % inhibit(i,j) = inhibition prob. for finding i, disease j, or 1.0 if j is not a parent.
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14 % prior(j) = prior prob. disease j is ON. We assume prior(off) = 1-prior(on).
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15 % leak(i) = inhibition prob. for the leak node for finding i
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16 %
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17 % Output:
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18 % prob(d) = Pr(disease d = on | ev)
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19 %
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20 % For details, see
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21 % - Heckerman, "A tractable inference algorithm for diagnosing multiple diseases", UAI89.
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22 % - Rish and Dechter, "On the impact of causal independence", UCI tech report, 1998.
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23 %
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24 % Note that this algorithm is numerically unstable, since it adds a large number of positive and
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25 % negative terms and hopes that some of them exactly cancel.
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26 %
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27 % For matlab experts, use 'mex' to compile C_quickscore, which has identical behavior to this function.
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28
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29 [nfindings ndiseases] = size(inhibit);
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30
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31 % make the first disease be always on, for the leak term
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32 Pon = [1 prior(:)'];
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33 Poff = 1-Pon;
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34 Uon = [leak(:) inhibit]; % U(f,d) = Pr(f=0|d=1)
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35 Uoff = [leak(:) ones(nfindings, ndiseases)]; % Uoff(f,d) = Pr(f=0|d=0)
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36 ndiseases = ndiseases + 1;
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37
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38 npos = length(fpos);
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39 post = zeros(ndiseases, 2);
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40 % post(d,1) = alpha Pr(d=off), post(d,2) = alpha Pr(d=m)
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41
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42 FP = length(fpos);
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43 %allbits = logical(dec2bitv(0:(2^FP - 1), FP));
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44 allbits = logical(ind2subv(2*ones(1,FP), 1:(2^FP))-1);
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45
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46 for si=1:2^FP
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47 bits = allbits(si,:);
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48 fprime = fpos(bits);
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49 fmask = zeros(1, nfindings);
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50 fmask(fneg)=1;
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51 fmask(fprime)=1;
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52 fmask = logical(fmask);
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53 p = 1;
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54 pterm = zeros(1, ndiseases);
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55 ptermOff = zeros(1, ndiseases);
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56 ptermOn = zeros(1, ndiseases);
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57 for d=1:ndiseases
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58 ptermOff(d) = prod(Uoff(fmask,d));
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59 ptermOn(d) = prod(Uon(fmask,d));
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60 pterm(d) = Poff(d)*ptermOff(d) + Pon(d)*ptermOn(d);
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61 end
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62 p = prod(pterm);
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63 sign = (-1)^(length(fprime));
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64 for d=1:ndiseases
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65 myp = p / pterm(d);
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66 post(d,1) = post(d,1) + sign*(myp * ptermOff(d));
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67 post(d,2) = post(d,2) + sign*(myp * ptermOn(d));
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68 end
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69 end
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70
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71 post(:,1) = post(:,1) .* Poff(:);
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72 post(:,2) = post(:,2) .* Pon(:);
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73 post = mk_stochastic(post);
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74 prob = post(2:end,2)'; % skip the leak term
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75
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76
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