1 / 22

FT228/4 Knowledge Based Decision Support Systems

FT228/4 Knowledge Based Decision Support Systems . Uncertainty Management in Rule-Based Systems Certainty Factors. Ref: Artificial Intelligence A Guide to Intelligent Systems Michael Negnevitsky – Aungier St. Call No. 006.3. Uncertainty Approaches in AI. Quantitative Numerical Approaches

cconner
Télécharger la présentation

FT228/4 Knowledge Based Decision Support Systems

An Image/Link below is provided (as is) to download presentation Download Policy: Content on the Website is provided to you AS IS for your information and personal use and may not be sold / licensed / shared on other websites without getting consent from its author. Content is provided to you AS IS for your information and personal use only. Download presentation by click this link. While downloading, if for some reason you are not able to download a presentation, the publisher may have deleted the file from their server. During download, if you can't get a presentation, the file might be deleted by the publisher.

E N D

Presentation Transcript

  1. FT228/4 Knowledge Based Decision Support Systems Uncertainty Management in Rule-Based Systems Certainty Factors Ref: Artificial Intelligence A Guide to Intelligent Systems Michael Negnevitsky – Aungier St. Call No. 006.3

  2. Uncertainty Approaches in AI • Quantitative • Numerical Approaches • Probability Theory • Certainty Factors • Dempster-Shafer evidential theory • Fuzzy logic • Qualitative • Logical Approaches • Reasoning by cases • Non-monotonic reasoning • Hybrid approaches

  3. Arguments against probability • Requires massive amount of data • Requires enumeration of all possibilities • Hides details of character of uncertainty • People are bad probability estimators • Difficult to use

  4. Bayesian Inference • Describes the application domain as a set of possible outcomes termed hypotheses • Requires an initial probability for each hypothesis in the problem space • Prior probability • Bayesian inference then updates probabilities using evidence • Each piece of evidence may update the probability of a set of hypotheses • Represent revised beliefs in light of known evidence • Mathematically calculated from Bayes theorem

  5. Certainty Factors • Certainty factors express belief in an event • Fact or hypothesis • Based upon evidence • Experts assessment • Composite number that can be used to • Guide reasoning • Cause a current goal to be deemed unpromising and pruned from search space • Rank hypotheses after all evidence has been considered

  6. Certainty Factors • Certainty Factor cf(x) is a measure of how confident we are in x • Range from –1 to +1 • cf=-1 very uncertain • cf=+1 very certain • cf=0 neutral • Certainty factors are relative measures • Do not translate to measure of absolute belief

  7. Total Strength of Belief • Certainty factors combin belief and disbelief into a single number based on some evidence • MB(H,E) • MD(H,E) • Strength of belief or disbelief in H depends on the kind of evidence E observed cf= MB(H,E) – MD(H,E) 1 – min[MB(H,E), MD(H,E)]

  8. Belief • Positive CF implies evidence supports hypothesis since MB > MD • CF of 1 means evidence definitely supports the hypothesis • CF of 0 means either there is no evidence or that the belief is cancelled out by the disbelief • Negative CF implies that the evidence favours negation of hypothesis since MB < MD

  9. Certainty Factors • Consider a simple rule IF A is X THEN B is Y • Expert may not be absolutely certain rule holds • Suppose it has been observed that in some cases even when the antecedent is true, A takes value X, the consequent is false and B takes a different value Z IF A is X THEN B is Y {cf 0.7}; B is Z {cf 0.2}

  10. Certainty Factors • Factor assigned by the rule is propagated through the reasoning chain • Establishes the net certainty of the consequent when the evidence for the antecedent is uncertain

  11. Stanford Certainty Factor Algebra • There are rules to combine CFs of several facts • (cf(x1) AND cf(x2)) = min(cf(x1),cf(x2)) • (cf(x1) OR cf(x2)) = max(cf(x1),cf(x2)) • A rule may also have a certainty factor cf(rule) • cf(action) = cf(condition).cf(rule)

  12. Example cf(shep is a dog)=0.7 cf(shep has wings)=-0.5 cf(Shep is a dog and has wings) = min(0.7, -0.5) = -0.5 Suppose there is a rule If x has wings then x is a bird Let the cf of this rule be 0.8 IF (Shep has wings) then (Shep is a bird) = -0.5 . 0.8 = -0.4

  13. Certainty Factors – Conjunctive Rules IF <evidence1> AND <evidence2> . . AND <evidencen> THEN <hypothesis H> {cf} cf(H, E1  E2  …  En) = min[cf(E1),cf(E2)…cf(En)] x cf

  14. Certainty Factors – Conjunctive Rules • For example IF sky is clear AND forecast is sunny THEN wear sunglasses cf{0.8} cf(sky is clear)=0.9 cf(forecast is sunny)=0.7 cf(action)=cf(condition).cf(rule) = min[0.9,0.7].0.8 =0.56

  15. Certainty Factors – Disjunctive Rules IF <evidence1> OR <evidence2> . . OR <evidencen> THEN <hypothesis H> {cf} cf(H, E1  E2  …  En) = max[cf(E1),cf(E2)…cf(En)] x cf

  16. Certainty Factors – Disjunctive Rules • For example IF sky is overcast AND forecast is rain THEN take umbrella cf{0.9} cf(sky is overcast)=0.6 cf(forecast is rain)=0.8 cf(action)=cf(condition).cf(rule) = max[0.6,0.8].0.8 =0.72

  17. Consequent from multiple rules Suppose we have the following : IF A is X THEN C is Z {cf 0.8} IF B is Y THEN C is Z {cf 0.6} What certainty should be attached to C having Z if both rules are fired ? cf(cf1,cf2)= cf1 + cf2 x (1- cf1) if cf1> 0 and cf2 > 0 = cf1 + cf2 if cf1 < 0 orcf2 < 0 1- min[|cf1|,|cf2|] = cf1+cf2 x (1+cf1) if cf1 < 0 and cf2 < 0 cf1=confidence in hypothesis established by Rule 1 cf2=confidence in hypothesis established by Rule 2 |cf1| and |cf2| are absolute magnitudes of cf1 and cf2

  18. Consequent from multiple rules • cf(E1)=cf(E2)=1.0 • cf1(H,E1)=cf(E1) x cf = 1.0 x 0.8 = 0.8 • cf2(H,E2)=cf(E2) x cf = 1.0 x 0.6 = 0.6 • Cf(cf1,cf2)= cf1(H,E1) + cf2(H,E2) x [1-cf1(H,E1)] = 0.8 + 0.6 x(1 –0.8)= 0.92

  19. Certainty Factors • Practical alternative to Bayesian reasoning • Heuristic manner of combining certainty factors differs from the way in which they would be combined if they were probabilities • Not mathematically pure • Does mimic thinking process of human expert

  20. Certainty Factors - Problems • Results may depend on order in which evidence considered in some cases • Reasoning often fairly insensitive to them • Don’t capture credibility in some cases • What do they mean exactly ? • In some cases can be interpreted probabilistically

  21. Comparison of Bayesian Reasoning & Certainty Factors • Probability Theory • Oldest & best-established technique • Works well in areas such as forecasting & planning • Areas where statistical data is available and probability statements made • Most expert system application areas do not have reliable statistical information • Assumption of conditional independence cannot be made • Leads to dissatisfaction with method

  22. Comparison of Bayesian Reasoning & Certainty Factors • Certainty Factors • Lack mathematical correctness of probability theory • Outperforms Bayesian reasoning in areas such as diagnostics and particularly medicine • Used in cases where probabilities are not known or too difficult or expensive to obtain • Evidential reasoning • Can manage incrementally acquired evidence • Conjunction and disjunction of hypotheses • Evidences with varying degree of belief • Provide better explanations of control flow

More Related