1 / 1

Structure Refinement in First Order Conditional Influence Language

t1.id. r1.id. t1.cd. t1.la. T2.id. r2.id. t2.la. s1.la. s1.f. t2.cd. s2.la. r1.id. t1.id. t2.id. s1.f. s2.f. s2.f. r2.id. t1.id. r1.id. t2.id. r2.id. C. W. W. B. I. C. C. B. I. C. <. l. d. b. 2. 1. t. e. a. r. n. e. e. s. s1.folder. s2.folder. d.f.

camden-britt
Télécharger la présentation

Structure Refinement in First Order Conditional Influence Language

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. t1.id r1.id t1.cd t1.la T2.id r2.id t2.la s1.la s1.f t2.cd s2.la r1.id t1.id t2.id s1.f s2.f s2.f r2.id t1.id r1.id t2.id r2.id C W W B I C C B I C < l d b 2 1 t e a r n e e s s1.folder s2.folder d.f d.f d.f d.f d.f d.f d.f d.f d.folder d.folder d.folder d.folder d.f d.f d.f d.f d.folder d.folder d.f d.f d.folder Structure Refinement in First Order Conditional Influence Language Sriraam Natarajan, Weng-Keen Wong, Prasad Tadepalli School of EECS, Oregon State University Synthetic Data Set Prior Program Irrelevant attributes First-order Conditional Influence Language (FOCIL) Relevant attributes Weighted Mean{ If {task(t), doc(d), role(d,r,t)} then t.id, r.id, t.creationDate, t.lastAccessed Qinf (Mean) d.folder If {doc(s), doc(d), source(s,d) } then s.folder, s.lastAccessed Qinf (Mean) d.folder } Weighted Mean{ If {task(t), doc(d), role(d,r,t)} then t.id, r.id Qinf (Mean) d.folder If {doc(s), doc(d), source(s,d) } then s.folder Qinf (Mean) d.folder } “Unrolled” Network for Folder Prediction Learned Program Weighted Mean{ If {task(t), doc(d), role(d,r,t)} then t.id, r.id Qinf (Mean) d.folder If {doc(s), doc(d), source(s,d) } then s.folder Qinf (Mean) d.folder } Conclusions • Data is expensive – Exploit prior knowledge in structure search • Derived the CBIC score for our setting • Learned the “true” network in the synthetic dataset • Folder dataset: Learned the best network with only relevant attributes • Folder dataset with irrelevant attributes: Scoring metric • Conditional BIC score = -2 *CLL + dmlogN • Different instantiations of the same rule share parameters • Conditional Likelihood: EM – Maximize the joint likelihood • CBIC score with penalty scaled down • Greedy Search with random restarts Prior Network Future work • Different scoring metrics • BDeu • Bias/Variance • Choose the best combining rule that fits the data • Structure refinement in large real-world domains Folder Prediction Learned Network Issues • What is the correct complexity penalty in the presence of multi-valued variables? • Counting the # of parameters may not be the right solution • What is the right scoring metric in relational setting for classification? • Can the search space be intelligently pruned?

More Related