Presentation is loading. Please wait.

Presentation is loading. Please wait.

1 Multi-dimensional Sequential Pattern Mining Helen Pinto, Jiawei Han, Jian Pei, Ke Wang, Qiming Chen, Umeshwar Dayal ~From: 10th ACM Intednational Conference.

Published byOscar Simmons Modified over 9 years ago

Similar presentations

Presentation on theme: "1 Multi-dimensional Sequential Pattern Mining Helen Pinto, Jiawei Han, Jian Pei, Ke Wang, Qiming Chen, Umeshwar Dayal ~From: 10th ACM Intednational Conference."— Presentation transcript:

1 1 Multi-dimensional Sequential Pattern Mining Helen Pinto, Jiawei Han, Jian Pei, Ke Wang, Qiming Chen, Umeshwar Dayal ~From: 10th ACM Intednational Conference on Information and Knowledge Management (CIKM 2001), Atlanta. 碩專二 69121507 阮士峰

2 2 Outline Why multidimensional sequential pattern mining? Problem definition UniSeq Algorithms Dim-Seq and Seq-Dim Experimental results Conclusions

3 3 Why Sequential Pattern Mining? Sequential pattern mining: Finding time-related frequent patterns (frequent subsequences) Many data and applications are time-related Customer shopping patterns, telephone calling patterns Natural disasters (e.g., earthquake, hurricane) Disease and treatment Stock market fluctuation Weblog click stream analysis DNA sequence analysis

4 4 Sequential Pattern: Basics 50 40 30 20 10 SequenceSeq. ID A sequence database A sequence : Elements is a subsequence of Given support threshold min_sup =2, is a sequential pattern

5 5 Multi-Dimenesion Sequence Database cidCust_grpCityAge_grpsequence 10BusinessBostonMiddle 20ProfessionalChicagoYoung 30BusinessChicagoMiddle 40EducationNew YorkRetired If support =2, P is a MD sequential pattern P=(*,Chicago,*, ) matches tuple 20 and 30

6 6 Problem definition Sequential patterns are useful “try a 100 hour free internet access package”  “subscribe to 15 hours/mouth package”  “ upgrade to 30 hours/mouth package”  “upgrade to unlimited package” Marketing, product design & development Problems: lack of focus Various groups of customers may have different patterns MD-sequential pattern mining: integrate multi- dimensional analysis and sequential pattern mining

7 7 UniSeq Embed MD information into sequences cidCust_grpCityAge_grpsequence 10BusinessBostonMiddle 20ProfessionalChicagoYoung 30BusinessChicagoMiddle 40EducationNew YorkRetired cidMD-extension of sequences 10 20 30 40 Mine the extended sequence database using sequential pattern mining methods Table1 SDB Table2 SDB MD

8 8 UniSeq(cont.) Sequence database SDB MD can be mined using PrefixSpan. First scan the database, PrefixSpan finds all the single-item frequent sequence. these are :2, :2, :2, :2, :4, :3, :2 and :2. The complete set of sequential patterns can then be partitioned into 8 subsets. cidMD-extension of sequences 10 20 30 40

9 9 UniSeq(cont.) Ex: the -projected database contains two postfix sequences: and. cidMD-extension of sequences 20 30 Then print out the sequential pattern, and find this projected database. They are : and, which form the sequential paterns “ :2” and “ :2” respectively. However, -projected database contains postfix sequences for: and with one frequent item between them find “” :2”  (*,Chicago,*, )

10 10 Mine Sequential Patterns by Prefix Projections Step 1: find length-1 sequential patterns,,,,, Step 2: divide search space. The complete set of seq. pat. can be partitioned into 6 subsets: The ones having prefix ; … The ones having prefix SIDsequence 10 20 30 40

11 11 Find Seq. Patterns with Prefix Only need to consider projections -projected database:,,, Find all the length-2 seq. pat. Having prefix :,,,,, Further partition into 6 subsets Having prefix ; … Having prefix SIDsequence 10 20 30 40

12 12 Completeness of PrefixSpan SIDsequence 10 20 30 40 SDB Length-1 sequential patterns,,,,, -projected database Length-2 sequential patterns,,,,, Having prefix -proj. db … Having prefix -projected database … Having prefix Having prefix, …, …

13 13 Efficiency of PrefixSpan No candidate sequence needs to be generated Projected databases keep shrinking Major cost of PrefixSpan: constructing projected databases

14 14 Dim-Seq First find MD-patterns E.g. (*,Chicago,*) Form projected sequence database and for (*,Chicago,*) Find seq. pat in projected database E.g. (*,Chicago,*, ) cidCust_grpCityAge_grpsequence 10BusinessBostonMiddle 20ProfessionalChicagoYoung 30BusinessChicagoMiddle 40EducationNew YorkRetired

15 15 Seq-Dim Find sequential patterns E.g. Form projected MD-database E.g. (Professional,Chicago,Young) and (Business,Chicago,Middle) for Mine MD-patterns E.g. (*,Chicago,*, ) cidCust_grpCityAge_grpsequence 10BusinessBostonMiddle 20ProfessionalChicagoYoung 30BusinessChicagoMiddle 40EducationNew YorkRetired

16 16 Dim-Seq and Seq-Dim The problem of multi-dimensional sequential pattern mining problem can reduced to two sub-problem: sequential pattern mining and MD-pattern mining As introduced before, sequential pattern mining can be done efficiently by PrefixSpan. For MD-pattern mining, we adopt a BUC-like algorithm.

17 17 BUC algorithm Kevin Beyer, Raghu Ramakrishnan, Bottom-up computation of sparse and Iceberg CUBE, Proceedings of the 1999 ACM SIGMOD international conference on Management of data, p.359-370, May 31-June 03, 1999, Philadelphia, Pennsylvania, United States

18 18 Mining MD-Patterns(BUC-like) All (cust-grp,*,*) (*,city,*)(*,*,age-grp) (cust-grp,city)Cust-grp,*,age-grp) (cust-grp,city,age-grp) cidCust_grpCityAge_grpsequence 10BusinessBostonMiddle 20ProfessionalChicagoYoung 30BusinessChicagoMiddle 40EducationNew YorkRetired BUC processing

19 19 Experimental results Run on Pentium III pc with 1G main memory. Using Microsoft Visual C++ 6.0 In this dataset, the number of items is set to 10,000, while the number of sequence is 10,000. The average number of items within each element is 2.5. The average number of elements in one sequence is 8.

20 20 Scalability Over Dimensionality

21 21 Scalability Over Cardinality

22 22 Scalability Over Support Threshold

23 23 Scalability Over Database Size

24 24 Pros & Cons of Algorithms Seq-Dim is efficient and scalable Fastest in most cases UniSeq is also efficient and scalable Fastest with low dimensionality Dim-Seq has poor scalability

25 25 Conclusions MD seq. pat. mining are interesting and useful Mining MD seq. pat. efficiently Uniseq, Dim-Seq, and Seq-Dim Future work Applications of sequential pattern mining

26 報告結束

27 27 References (1) R. Agrawal and R. Srikant. Fast algorithms for mining association rules. VLDB'94, pages 487-499. R. Agrawal and R. Srikant. Mining sequential patterns. ICDE'95, pages 3-14. Kevin Beyer, Raghu Ramakrishnan, Bottom-up computation of sparse and Iceberg CUBE, Proceedings of the 1999 ACM SIGMOD international conference on Management of data, p.359-370, May 31- June 03, 1999, Philadelphia, Pennsylvania, United States C. Bettini, X. S. Wang, and S. Jajodia. Mining temporal relationships with multiple granularities in time sequences. Data Engineering Bulletin, 21:32-38, 1998. M. Garofalakis, R. Rastogi, and K. Shim. Spirit: Sequential pattern mining with regular expression constraints. VLDB'99, pages 223-234. J. Han, G. Dong, and Y. Yin. Efficient mining of partial periodic patterns in time series database. ICDE'99, pages 106-115. J. Han, J. Pei, B. Mortazavi-Asl, Q. Chen, U. Dayal, and M.-C. Hsu. FreeSpan: Frequent pattern-projected sequential pattern mining. KDD'00, pages 355-359.

28 28 References (2) J. Han, J. Pei, and Y. Yin. Mining frequent patterns without candidate generation. SIGMOD'00, pages 1-12. H. Lu, J. Han, and L. Feng. Stock movement and n-dimensional intertransaction association rules. DMKD'98, pages 12:1-12:7. H. Mannila, H. Toivonen, and A. I. Verkamo. Discovery of frequent episodes in event sequences. Data Mining and Knowledge Discovery, 1:259-289, 1997. B. "Ozden, S. Ramaswamy, and A. Silberschatz. Cyclic association rules. ICDE'98, pages 412-421. J. Pei, J. Han, B. Mortazavi-Asl, H. Pinto, Q. Chen, U. Dayal, and M.-C. Hsu. PrefixSpan: Mining sequential patterns efficiently by prefix- projected pattern growth. ICDE'01, pages 215-224. R. Srikant and R. Agrawal. Mining sequential patterns: Generalizations and performance improvements. EDBT'96, pages 3-17.

Download ppt "1 Multi-dimensional Sequential Pattern Mining Helen Pinto, Jiawei Han, Jian Pei, Ke Wang, Qiming Chen, Umeshwar Dayal ~From: 10th ACM Intednational Conference."

Similar presentations

Frequent Itemset Mining Methods. The Apriori algorithm Finding frequent itemsets using candidate generation Seminal algorithm proposed by R. Agrawal and.

Frequent Itemset Mining Methods. The Apriori algorithm Finding frequent itemsets using candidate generation Seminal algorithm proposed by R. Agrawal and.
Mining Frequent Patterns Using FP-Growth Method Ivan Tanasić Department of Computer Engineering and Computer Science, School of Electrical.

Mining Frequent Patterns Using FP-Growth Method Ivan Tanasić Department of Computer Engineering and Computer Science, School of Electrical.
PREFIXSPAN ALGORITHM Mining Sequential Patterns Efficiently by Prefix- Projected Pattern Growth al113301m@student.etf.rs.

PREFIXSPAN ALGORITHM Mining Sequential Patterns Efficiently by Prefix- Projected Pattern Growth
LOGO Association Rule Lecturer: Dr. Bo Yuan

LOGO Association Rule Lecturer: Dr. Bo Yuan
10 -1 Lecture 10 Association Rules Mining Topics –Basics –Mining Frequent Patterns –Mining Frequent Sequential Patterns –Applications.

10 -1 Lecture 10 Association Rules Mining Topics –Basics –Mining Frequent Patterns –Mining Frequent Sequential Patterns –Applications.
ICDM'06 Panel 1 Apriori Algorithm Rakesh Agrawal Ramakrishnan Srikant (description by C. Faloutsos)

ICDM'06 Panel 1 Apriori Algorithm Rakesh Agrawal Ramakrishnan Srikant (description by C. Faloutsos)
Rakesh Agrawal Ramakrishnan Srikant

Rakesh Agrawal Ramakrishnan Srikant
IncSpan: Incremental Mining of Sequential Patterns in Large Databases Hong Cheng,Xifeng Yan,Jiawei Han University of Illinois at Urbana-Champaign.

IncSpan: Incremental Mining of Sequential Patterns in Large Databases Hong Cheng,Xifeng Yan,Jiawei Han University of Illinois at Urbana-Champaign.
Cube Explorer: Online Exploration of Data Cubes Jiawei Han, Jianyong Wang, Guozhu Dong, Jian Pei, Ke Wang.

Cube Explorer: Online Exploration of Data Cubes Jiawei Han, Jianyong Wang, Guozhu Dong, Jian Pei, Ke Wang.
Our New Progress on Frequent/Sequential Pattern Mining We develop new frequent/sequential pattern mining methods Performance study on both synthetic and.

Our New Progress on Frequent/Sequential Pattern Mining We develop new frequent/sequential pattern mining methods Performance study on both synthetic and.
Multi-dimensional Sequential Pattern Mining

Multi-dimensional Sequential Pattern Mining
Data Mining Association Analysis: Basic Concepts and Algorithms

Data Mining Association Analysis: Basic Concepts and Algorithms
Sequential Pattern Mining

Sequential Pattern Mining
Data Mining Association Rules Yao Meng Hongli Li 91.574 Database II Fall 2002.

Data Mining Association Rules Yao Meng Hongli Li Database II Fall 2002.
Sequence Databases & Sequential Patterns

Sequence Databases & Sequential Patterns
Mining Sequential Patterns Dimitrios Gunopulos, UCR.

Mining Sequential Patterns Dimitrios Gunopulos, UCR.
Business Systems Intelligence: 4. Mining Association Rules Dr. Brian Mac Namee (www.comp.dit.ie/bmacnamee)www.comp.dit.ie/bmacnamee.

Business Systems Intelligence: 4. Mining Association Rules Dr. Brian Mac Namee (
Temporal Pattern Matching of Moving Objects for Location-Based Service GDM Ronald Treur14 October 2003.

Temporal Pattern Matching of Moving Objects for Location-Based Service GDM Ronald Treur14 October 2003.
1 Mining Association Rules in Large Databases Association rule mining Algorithms for scalable mining of (single-dimensional Boolean) association rules.

1 Mining Association Rules in Large Databases Association rule mining Algorithms for scalable mining of (single-dimensional Boolean) association rules.
Association Analysis: Basic Concepts and Algorithms.

Association Analysis: Basic Concepts and Algorithms.

Similar presentations

Ads by Google