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Evaluating Queries over Route Collections

This PhD defense outline discusses the challenges and techniques for evaluating path queries over route collections, including examples such as sightseeing activities, pickup and delivery services, and driving data. It explores graph-based solutions, dynamic pickup and delivery with transfers, and the concept of the most trusted near shortest path. Conclusions and future work are also presented.

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Evaluating Queries over Route Collections

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  1. Evaluating Queries over Route Collections Panagiotis Bouros, PhD defense

  2. Outline • Introduction • Route collections examples • Query evaluation challenges • Evaluating path queries • Dynamic Pickup and Delivery with Transfers • Most Trusted Near Shortest Path • Conclusions • Future work PhD defense

  3. Routes as data • Several applications involve storing and querying large volumes of sequential data • Route, a sequence of spatial locations • POIs, waypoints etc. • Route collection • Routes as first-class citizens • Frequently updated • New routes added • Existing routes deleted or modified PhD defense

  4. Example 1: Sightseeing and activities • People visit Athens • GPS devices • Track sightseeing • Touristic routes • Route collections online • www.ShareMyRoutes.com • www.TravelByGPS.com • Updates • Add new interesting routes • Remove existing routes, not interesting any more PhD defense

  5. Example 1: Sightseeing and activities • Traditional graph queries • REACH: Is there a sequence of POIs from Academy to Zappeion? • PATH: Find a sequence of POIs from Academy to Zappeion • PATH more general • Graph-based solution • Searching • Low maintenance cost • Slow • Compressing TC • Fast • High maintenance cost • This thesis • Combine pros and cons • Reachability within routes PhD defense

  6. Example 1: Sightseeing and activities • Traditional graph queries • REACH: Is there a sequence of POIs from Academy to Zappeion? • PATH: Find a sequence of POIs from Academy to Zappeion • PATH more general • Graph-based solution • Searching • Low maintenance cost • Slow • Compressing TC • Fast • High maintenance cost • This thesis • Combine advantages • Reachability within routes PhD defense

  7. Example 2: Pickup and delivery • A courier company offering pickup and delivery services • Static plan • Set of requests • Transfers between vehicles • Collection of vehicles routes • Pickup and Delivery with Transfers • Create static plan • Updates • Ad-hoc requests • Modify vehicle routes to satisfy new requests PhD defense

  8. Example 2: Pickup and delivery • Query • Pickup object from ns and delivery at nt • Minimize company’s expenses • dynamic Pickup and Delivery with Transfers • Non-graph solution • Two-phase local search • This thesis • First work target dPDPT • Cost metrics • Company’s viewpoint, extra traveling or waiting time • Customer’s viewpoint, delivery time • Dynamic two-criterion shortest path problem PhD defense

  9. Example 2: Pickup and delivery • Query • Pickup object from ns and delivery at nt • Minimize company’s expenses • dynamic Pickup and Delivery with Transfers • Non-graph solution • Two-phase local search • This thesis • First work for dPDPT • Cost metrics • Company’s viewpoint, extra traveling or waiting time • Customer’s viewpoint, delivery time • Dynamic two-criterion shortest path problem PhD defense

  10. Example 3: Driving data • Group of people driving through the city • Track their driving • Vehicle routes • Sequence of road network intersections • Collection of vehicle routes • A trusted and familiar way of driving • People consult collection • Updates • New routes added - driving to unknown locations • Existing routes modified – new ways to reach known locations PhD defense

  11. Example 3: Driving data • Query • Driving directions from ns to nt • Graph-based solution • Shortest path • Time-dependent shortest path • This thesis • Capture how people actually drive • Tend to reuse roads • Consult friends • Prefer a trusted over the fastest way • New graph query • Most Trusted Near Shortest Path • Cost metrics • Unknown time, time outside routes • Length, total time • Path with lowest unknown time and length at most a times larger than SP PhD defense

  12. Example 3: Driving data • Query • Driving directions from ns to nt • Graph-based solution • Shortest path • Time-dependent shortest path • This thesis • Capture how people actually drive • Tend to reuse roads • Consult friends • Prefer a trusted over the fastest way • Cost metrics • Unknown time, time outside routes • Length, total time • New graph query • Most Trusted Near Shortest Path • Path with lowest unknown time and length at most a times larger than SP PhD defense

  13. Query evaluation • Frequent updated route collections available • Challenge for query evaluation • Path queries • Sequence of locations contained in routes • Evaluate queries directly on routes • Is it faster? • Route as a set of precomputed answers PhD defense

  14. Outline • Introduction • Route collections examples • Query evaluation challenges • Evaluating path queries • Dynamic Pickup and Delivery with Transfers • Most Trusted Near Shortest Path • Conclusions • Future work PhD defense

  15. Evaluating path queries PhD defense

  16. Evaluating PATH queries • Query • PATH(ns,nt) • Solution • Answer: a sequence of locations in routes from ns to nt • Indexing route collections • Route traversal paradigm • Link traversal paradigm • Methods for index maintenance PhD defense

  17. Indexing route collections • R-Index • Associates each location of the collection with the routes containing it • T-Index • Captures all possible transitions between routes via links • Links are shared nodes PhD defense

  18. Indexing route collections • R-Index • Associates each location of the collection with the routes containing it • T-Index • Captures all possible transitions between routes via links • Links are shared nodes PhD defense

  19. Traversal paradigms • Route traversal paradigm • Traverse collection similar to depth-first search • For each route, push all locations after current n in search stack • Access indices on routes to terminate search • RTS: current location and target on same route (R-Index) • RTST: current location on route connected to route of target (T-Index) • Link traversal paradigm • Traverse collection similar to depth-first search on links • R-Index+ • For each route, push first link after current n in search stack • Access indices to create target list T • LTS: routes containing target (R-Index+) • LTST: routes connected to routes containing target (T-Index) • LTS-k: routes connected to routes containing target via first k links before target (R-Index+) PhD defense

  20. Traversal paradigms • Route traversal paradigm • Traverse collection similar to depth-first search • For each route, push all locations after current n in search stack • Access indices on routes to terminate search • RTS: current location and target on same route (R-Index) • RTST: current location on route connected to route of target (T-Index) • Link traversal paradigm • Traverse collection similar to depth-first search on links • R-Index+ • For each route, push first link after current n in search stack • Access indices to create target list T • LTS: routes containing target (R-Index+) • LTST: routes connected to routes containing target (T-Index) • LTS-k: routes connected to routes containing target via first k links before target (R-Index+) PhD defense

  21. Traversal paradigms (cont’d) • Expand path (s) • Consider every location after a in routes r1 and r3 • Route trav.: PUSH w,a,g • Link trav.: PUSH a PhD defense

  22. Traversal paradigms (cont’d) • Expand path (s) • Consider every location after a in routes r1 and r3 • Route trav.: PUSH w,a,g • Link trav.: PUSH a PhD defense

  23. Traversal paradigms (cont’d) • RTS, 5th iteration • POP d, r1 contains d before t • RTST, 3rd iteration • POP a, r2 connected with r1 containing t via d • LTS, TLTS = {r1, r5}, 4th iteration • POP f, r1 contains f before t • LTST, TLTST = {r1,r2,r3,r4,r5}, 2nd iteration • POP a, r2 connected with r1 containing t via link d • LTS-1, TLTS-1 = {r1,r4,r5}, 3rd iteration • POP c, r2 connected with r1 containing t via link d PhD defense

  24. Traversal paradigms (cont’d) • RTS, 5th iteration • POP d, r1 contains d before t • RTST, 3rd iteration • POP a, r2 connected with r1 containing t via d • LTS, TLTS = {r1, r5}, 4th iteration • POP f, r1 contains f before t • LTST, TLTST = {r1,r2,r3,r4,r5}, 2nd iteration • POP a, r2 connected with r1 containing t via link d • LTS-1, TLTS-1 = {r1,r4,r5}, 3rd iteration • POP c, r2 connected with r1 containing t via link d PhD defense

  25. Traversal paradigms (cont’d) • RTS, 5th iteration • POP d, r1 contains d before t • RTST, 3rd iteration • POP a, r2 connected with r1 containing t via d • LTS, TLTS = {r1, r5}, 4th iteration • POP f, r1 contains f before t • LTST, TLTST = {r1,r2,r3,r4,r5}, 2nd iteration • POP a, r2 connected with r1 containing t via link d • LTS-1, TLTS-1 = {r1,r4,r5}, 3rd iteration • POP c, r2 connected with r1 containing t via link d PhD defense

  26. Traversal paradigms (cont’d) • RTS, 5th iteration • POP d, r1 contains d before t • RTST, 3rd iteration • POP a, r2 connected with r1 containing t via d • LTS, TLTS = {r1, r5}, 4th iteration • POP f, r1 contains f before t • LTST, TLTST = {r1,r2,r3,r4,r5}, 2nd iteration • POP a, r2 connected with r1 containing t via link d • LTS-1, TLTS-1 = {r1,r4,r5}, 3rd iteration • POP c, r2 connected with r1 containing t via link d PhD defense

  27. Traversal paradigms (cont’d) • RTS, 5th iteration • POP d, r1 contains d before t • RTST, 3rd iteration • POP a, r2 connected with r1 containing t via d • LTS, TLTS = {r1, r5}, 4th iteration • POP f, r1 contains f before t • LTST, TLTST = {r1,r2,r3,r4,r5}, 2nd iteration • POP a, r2 connected with r1 containing t via link d • LTS-1, TLTS-1 = {r1,r4,r5}, 3rd iteration • POP c, r2 connected with r1 containing t via link d PhD defense

  28. Index maintenance • Indices as inverted files on disk • Lazy updates • Buffering phase • Update main memory indices • Flushing phase • Propagate changes to disk • Insertions • Buffering: mark new entries or changed entries in lists • Flushing: merge main memory information with disk-based indices • Deletions • No buffering: a list of deleted routes since last flushing • Flushing: rebuilding affected lists PhD defense

  29. Experimental analysis • Rival: DFS, depth-first search over links • Datasets • Synthetic route collections • Vary |R| = {20K, 50K, 100K, 200K, 500K} • Vary |Lr| = {3, 5, 10, 30, 50} • Vary |N| = {20K, 50K, 100K, 200K, 500K} • Vary α = {0.2, 0.4, 0.6, 0.8, 1} • Experiments • Index construction • Query evaluation (queries with/without answer) • RTS, RTST Vs LTS • DFS Vs LTS, LTS-k, LTST • Index maintenance PhD defense

  30. RTS, RTST Vs LTS Execution time Execution time PhD defense

  31. DFS Vs LTS, LTS-k, LTST Execution time Execution time PhD defense

  32. Dynamic Pickup and Delivery with Transfers PhD defense

  33. Solving dPDPT • Query • dPDPT(ns,nt) • Solution • Modify static plan • 4 modifications, called actions, allowed with/without detours • Pickup, delivery, transfer, transport • A sequence of actions, path p • Operational cost Op • Customer cost Cp • Dynamic plan graph • All possible actions • Answer: path p that primarily minimizes Op, secondarily Cp • Algorithms SP and SPM PhD defense

  34. Solving dPDPT (cont’d) PhD defense

  35. Solving dPDPT (cont’d) PhD defense

  36. Solving dPDPT (cont’d) PhD defense

  37. Solving dPDPT (cont’d) PhD defense

  38. Solving dPDPT (cont’d) PhD defense

  39. The SP and SPM algorithms • The SP algorithm • Dynamic plan graph violates subpath optimality => path enumeration • Label <Via,p,Op,Cp> for each path to Via • At each iteration select label with lowest combined cost • Compute candidate answer – upper bound • Prune search space • Terminate search • The SPM algorithm • Modified dynamic plan graph • Break Op into Op* and OpR • Subpath optimality • Extends SP • Label <Via,p,Op*,OpR> for each path to Via • Most “promising” paths to every vertex PhD defense

  40. The SP and SPM algorithms • The SP algorithm • Dynamic plan graph violates subpath optimality => path enumeration • Label <Via,p,Op,Cp> for each path to Via • At each iteration select label with lowest combined cost • Compute candidate answer – upper bound • Prune search space • Terminate search • The SPM algorithm • Modified dynamic plan graph • Break Op into Op* and OpR • Subpath optimality • Extends SP • Label <Via,p,Op*,OpR> for each path to Via • Most “promising” paths to every vertex PhD defense

  41. The SP and SPM algorithms (cont’d) • INITIALIZATION • Pickup Es1a and Es3b • SP: Q = {<V1a, (Vs,V1a),6,16>, <V3b,(Vs,V3b),6,36>} • SPM: Q = {<V1a, (Vs,V1a),6,0>, <V3b,(Vs,V3b),6,0>} • pcand = null T = 6 PhD defense

  42. The SP and SPM algorithms (cont’d) • POP <V1a, (Vs,V1a),…,…> • Transport E12a • SP: Q = {<V2a, (Vs,V1a,V2a),6,26>, <V3b,(Vs,V3b),6,36>} • SPM: Q = {<V2a, (Vs,V1a,V2a),6,0>, <V3b,(Vs,V3b),6,0>} • pcand = null T = 6 PhD defense

  43. The SP and SPM algorithms (cont’d) • POP <V2a, (Vs, V1a,V2a),…,…> • Transfer E25ac • Arr5c = 10 < 26 < Dep5c = 40 • SP: Q = {<V3b,(Vs,V3b),6,36>, <V5c, (Vs,V1a,V2a,V5c),18,36>} • SPM: Q = {<V3b,(Vs,V3b),6,0>, <V5c, (Vs,V1a,V2a,V5c),6,12>} • pcand = null T = 6 PhD defense

  44. The SP and SPM algorithms (cont’d) • POP <V3b, (Vs,V3b),6,36> and <V4b, (Vs,V3b,V4b),6,46> • Transport E34b and transfer E46bc • 46 > Dep6c = 40 • SP: Q = {<V5c,(Vs,V1a,V2a,V5c),18,36>, <V6c,(Vs,V3b,V4b,V6c),24,52>} • SPM: Q = {<V5c,(Vs,V1a,V2a,V5c),6,12>, <V6c,(Vs,V3b,V4b,V6c),12,12>} • pcand = null T = 6 PhD defense

  45. The SP and SPM algorithms (cont’d) • POP <V5c,(Vs,V1a,V2a,V5c),…,…> • Transport E56c • SP: Q = {<V6c,(Vs,V1a,V2a,V5c,V6c),18, 46>, <V6c,(Vs,V3b,V4b,V6c),24,52>} • SPM: Q = {<V6c,(Vs,V1a,V2a,V5c,V6c),6, 12>, <V6c,(Vs,V3b,V4b,V6c),12,12>} • pcand = null T = 6 PhD defense

  46. The SP and SPM algorithms (cont’d) • POP <V5c,(Vs,V1a,V2a,V5c),…,…> • Transport E56c • SP: Q = {<V6c,(Vs,V1a,V2a,V5c,V6c),18, 46>, <V6c,(Vs,V3b,V4b,V6c),24,52>} • SPM: Q = {<V6c,(Vs,V1a,V2a,V5c,V6c),6, 12>, <V6c,(Vs,V3b,V4b,V6c),12,12>} • pcand = null T = 6 PhD defense

  47. The SP and SPM algorithms (cont’d) • POP <V5c,(Vs,V1a,V2a,V5c),…,…> • Transport E56c • SP: Q = {<V6c,(Vs,V1a,V2a,V5c,V6c),18, 46>, <V6c,(Vs,V3b,V4b,V6c),24,52>} • SPM: Q = {<V6c,(Vs,V1a,V2a,V5c,V6c),6, 12>} • pcand = null T = 6 PhD defense

  48. The SP and SPM algorithms (cont’d) • POP <V6c,(Vs,V1a,V2a,V5c,V6c),…,…> • Transport E67c • SP: Q = {<V7c,(Vs,V1a,V2a,V5c,V6c,V7c), 18, 56>, <V6c,(Vs,V3b,V4b,V6c),24,52>} • SPM: Q = {<V7c,(Vs,V1a,V2a,V5c,V6c,V7c), 6,12>} • pcand = null T = 6 PhD defense

  49. The SP and SPM algorithms (cont’d) • POP <V7c,(Vs,V1a,V2a,V5c,V6c,V7c), …,…> • Delivery E7ec • FOUND pcand • SP: Q = {<V6c,(Vs,V3b,V4b,V6c),24,52>} • SPM: Q = {} END • pcand = (Vs,V1a,V2a,V5c,V6c,V7c) • Opcand = 24 • Cpcand = 59 T = 6 PhD defense

  50. The SP and SPM algorithms (cont’d) • POP <V6c,(Vs,V3b,V4b,V6c),24,52> • Opcand = 24 • SP: END T = 6 PhD defense

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