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Title: University of Bologna (UOB)


1
University of Bologna (UOB)
  • DEIS (Department of Electronics, Computer Science
    and Automatics)
  • Faculty of Engineering
  • Operations Research Unit

2
University of Bologna
  • The University of Bologna (founded in 1088) is
    recognised as the oldest university in the
    western world.
  • It has about 110000 students, and is divided in
    23 faculties, 68 departments and 5 University
    Campus Branches (Bologna, Cesena, Forli, Ravenna
    and Rimini)
  • www.unibo.it

3
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4
DEIS
  • DEIS (Department of Electronics, Computer Science
    and Automatics) is composed by
  • 44 Full Professors
  • 33 Associate Professors
  • 35 Assistant Professors
  • 90 PhD students
  • 40 Post Doc researchers.
  • It has sites in Bologna and Cesena.
  • www.deis.unibo.it

5
DEIS
  • The research and educational activities involve
    the following main fields
  • Automatics
  • Biomedical Engineering
  • Computer Science
  • Electromagnetic Fields
  • Electronics
  • Operations Research
  • Telecommunications

6
DEIS
  • Undergraduate and Graduate Degrees
  • Automation Engineering
  • Biomedical Engineering
  • Computer Engineering
  • Electronic Engineering
  • Industrial Engineering
  • Telecommunications Engineering
  • PhD Degrees
  • Automatics and Operations Research
  • Electronics, Computer Science, Telecommunications
  • Biomedical Engineering

7
DEIS- Operations Research Unit
  • Research themes currently considered
  • Mathematical Programming methodologies (survey
    works on research areas and analysis of basic
    techniques)
  • Specific subjects in Combinatorial Optimization
    and Graph Theory (design and implementation of
    effective exact, heuristic and metaheuristic
    algorithms for the solution of NP-hard problems
    and study of polyhedral structures in the
    solution space)
  • Real-world applications (Crew Planning, Train
    Timetabling, Locomotive Scheduling, Train
    Platforming, Electric Power Dispatching, Staff
    Scheduling, Hydraulic Network Design, Vehicle
    Routing, Genome Comparison)

8
DEIS- Operations Research Unit
  • Current International Collaborations
  • Universite Libre de Bruxelles, Belgium
  • CRT, Montreal, Canada
  • Carnegie Mellon University, Pittsburgh, USA
  • University of Lancaster, UK
  • Technical University of Graz, Austria
  • University of Copenhagen, Denmark
  • University of Colorado, Boulder, USA
  • Universidad de La Laguna, Spain
  • University of New Brunswick, Saint John, Canada
  • Instituto Tecnologico de Aeronautica, Sao Jose
    dos Campos, SP Brazil

9
DEIS- Operations Research Unit
  • Staff members involved in the Project
  • Alberto Caprara
  • Associate Professor of Operations Research
  • Associate Editor of the journals INFORMS Journal
    on Computing, Operations Research Letters
  • Co-Editor of Optima (the newsletter of the
    Mathematical Programming Society)
  • Conferred the G.B. Dantzig Dissertation Award
    (for the best applied O.R. PhD Thesis) from
    INFORMS (1996)

10
DEIS- Operations Research Unit
  • Staff members involved in the Project
  • Andrea Lodi
  • Associate Professor of Operations Research
  • Associate Editor of the journals Mathematical
    Programming, Algorithmic Operations Research
  • Conferred the 2004-2005 IBM Herman Goldstine
    Postdoctoral Fellowship in Mathematical Sciences
    (currently at the IBM T.S. Watson Research
    Centre, Yorktown Heights, NY, USA)

11
DEIS- Operations Research Unit
  • Staff members involved in the Project
  • Silvano Martello
  • Professor of Operations Research
  • Co-Editor of the journal 4OR (Journal of the O.R.
    Societies of Belgium, France, Italy)
  • Associate Editor of the journals INFOR, Journal
    of Heuristics, Discrete Optimization, SIAM
    Monographs in Discrete Mathematics and
    Applications
  • Co-Editor of the Software Section of the
    journal Discrete Applied Mathematics
  • Coordinator of ECCO (European Chapter in
    Combinatorial Optimization)

12
DEIS- Operations Research Unit
  • Staff members involved in the Project
  • Paolo Toth
  • Professor of Combinatorial Optimization
  • Associate Editor of the journals Transportation
    Science, Journal of Heuristics, Networks,
    European Journal of Operational Research, Journal
    of the Operational Research Society, Discrete
    Optimization, Algorithmic Operations Research,
    International Transactions in Operational
    Research
  • Co-Editor of the Software Section of the
    journal Discrete Applied Mathematics
  • President of IFORS (International Federation of
    the OR Societies) in the period 2001-2003

13
DEIS- Operations Research Unit
  • Staff members involved in the Project
  • Daniele Vigo
  • Professor of Operations Research (Second Faculty
    of Engineering in Cesena)
  • Associate Editor of the journals Operations
    Research Letters, Operations Research (period
    2000-2003)
  • Chairman of the Organizing Committee of ROUTE
    2005 (International Workshop on Vehicle Routing
    Problems, Bertinoro, June 23-26, 2005)

14
DEIS- Operations Research Unit
  • Post-Doc Researchers
  • Manuel Iori
  • PhD Students
  • Alessandro Carrotta (grant from ILOG, Paris)
  • Matteo Fortini
  • Valentina Cacchiani
  • Enrico Malaguti

15
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16
OR-DEIS Papers in the last 3 years
  • Mathematical Programming 7
  • Operations Research 2
  • INFORMS J. on Computing 7
  • Journal of Heuristics 3
  • SIAM J. on Optimization 1
  • Mathematics of Operat. Research 1

    Networks
    2
  • EJOR
    6
  • Discrete Applied Mathematics 5
  • OR Letters
    2


17
OR-DEIS Current Research Topics
  • Exact and Heuristic Algorithms for Combinatorial
    Optimization Problems
  • Design and implementation of effective
    enumerative, heuristic and metaheuristic
    algorithms for the following basic problems

18
OR-DEIS Current Research Topics
  • Knapsack Problems
  • - 0 - 1 Knapsack Problem
  • - Subset-Sum Problem
  • - 2 - Constraint Knapsack Problem
  • - 2 - Dimensional Knapsack Problem

19
OR-DEIS Current Research Topics
  • Bin Packing Problems
  • - Bin Packing Problem
  • - 2 - Constraint Bin Packing Problem
  • - 2 - Dimensional Bin Packing Problem
  • - 3 - Dimensional Bin Packing Problem

20
OR-DEIS Current Research Topics
  • Graph Theory Problems
  • - Asymmetric Travelling Salesman Problem
  • - Travelling Salesman Problem with Time
    Windows
  • - Generalized Travelling Salesman Problem
  • - Orienteering Problem
  • - Graph Decomposition
  • - Bandwith-2 Graphs

21
OR-DEIS Current Research Topics
  • Vertex Coloring Problem
  • Edge Coloring Problem
  • Vehicle Routing Problem
  • Valid Inequalities for Integer Linear Programming
    Models
  • Set Covering and Partitioning Problems
  • Scheduling Problems
  • Integration of Constraint Programming and
    Mathematical Programming Techniques

22
OR-DEIS Current Research Topics
  • Crew Planning in Railway Applications
  • Design of bounds and heuristic algorithms,
    based on Lagrangian relaxations, for the solution
    of the Crew Planning Problem.
  • The problem requires to determine a minimum
    cost set of crew rosters for covering a given
    timetabled set of trips.

23
OR-DEIS Current Research Topics
  • Train Timetabling Problem
  • Design of exact and heuristic algorithms, based
    on Linear and Lagrangian relaxations, for the
    solution of real-world versions of the Train
    Timetabling Problem.
  • Given a set of timetabled trains to be run
    along a track, find a feasible timetable so as
    to satisfy all the operational constraints with
    the minimum variations with respect to the given
    timetable.

24
OR-DEIS Current Research Topics
  • Train Platforming Problem
  • Design of exact and heuristic algorithms for
    the solution of real-world versions of the Train
    Platforming Problem, in which one is required to
    assign an itinerary and a platform to each
    timetabled train visiting a station within a
    given time period.

25
OR-DEIS Current Research Topics
  • Optimization of the Electric Power Dispatching
  • Study of models and design of heuristic
    algorithms for the optimization of the electric
    power dispatching in a competitive environment.

26
OR-DEIS Current Research Topics
  • Combinatorial Optimization Methods for Genome
    Comparison
  • Two main objectives
  • - study of the most used model to compare two
    genomes, namely the computation of the minimum
    number of inversions (reversals) of gene
    subsequences that leads from one genome to the
    other.
  • - study of models to compare three or more
    genomes, recently proposed by computational
    biologists.

27
OR-DEIS Current Research Topics
  • Design of Hydraulic Networks
  • Design of exact and heuristic algorithms for the
    minimum cost design of hydraulic urban networks.

28
OR-DEIS
  • Cooperation with Industry
  • Railway Crew Planning with Trenitalia SpA
  • Locomotive Assignment with Trenitalia SpA
  • Train Timetabling with Rete Ferroviaria Italiana
    SpA
  • Train Platforming with Rete Ferroviaria Italiana
    SpA
  • Train Traction Unit Assignment with MAIOR Srl and
    Ferrovie Nord Milano Esercizio SpA
  • Staff Scheduling with Beghelli SpA and the
    Municipality of Bologna
  • Vehicle Routing with ILOG (Paris)
  • Strategic Planning of Solid Waste Flows with HERA
    (Metropolitan area of Bologna)
  • Bus Scheduling in Low Demand Areas with ATC Bo

29
OR-DEIS
  • European Union Projects
  • Human Capital and Mobility (1992-2000)
  • TRIO (railway crew management, 1998-2000)
  • TRIS (train timetabling, 2000-2002)
  • PARTNER (train timetabling, 2003-2005)
  • REORIENT (freight rail corridors, 2005-2007)

30
RAILWAY CREW PLANNING
  • We are given a planned timetable for the train
    services (actual journeys with passengers or
    freight, and the transfers of empty trains or
    equipment between different stations) to be
    performed every day of a certain time period.
  • Each train service is split into a sequence of
    trips (segments of train journeys which must be
    serviced by the same crew without interruption).
  • Each trip is characterized by
  • departure time, departure station,
  • arrival time, arrival station,
  • additional attributes.
  • Each daily occurrence of a trip has to be
    performed by a crew.

31
RAILWAY CREW PLANNING (2)
  • Each crew performs a roster
  • sequence of trips whose operational cost and
    feasibility depend on several rules laid down by
    union contracts and company regulations (cyclic
    for long time periods).
  • The problem consists of finding a set of
    rosters, covering every daily occurrence of each
    trip in the given time period, so as to satisfy
    all the operational constraints with minimum cost
    (minimum number of crews).
  • Very complex and challenging problem due to both
    the size of the instances and the type and number
    of operational constraints.
  • In the Italian Railway Company (Trenitalia -
    Ferrovie dello Stato FS) about 8000 trains and
    25000 drivers (largest problem involves about
    5000 trips).

32
EXAMPLE
  • 11 TRIPS TO BE COVERED EVERY DAY

T1
T2
T3
T4
T5
T6
T7
T8
T9
T10
T11
000 600 1200
1800 2400
33

EXAMPLE (2)
  • ROSTER OF A CREW COVERING THE 11 TRIPS

Day 1 Day 2 Day 3 Day 4
Day 5 Day 6
T3 T9 T2 T5 T7 T10
week 1
day day
1 2 3
4 5 6
T1 T4 T8 T11
T6
week 2
7 8 9
10 11 12
Crew weekly rest
  • CYCLIC TRIP SEQUENCE SPANNING 12 DAYS
  • (REQUIRING 12 CREWS)

34
  • The overall problem is approached in THREE
    PHASES
  • (C-F-T-V-G, Mathematical Programming 1997)
  • PAIRING GENERATION a very large number of
    feasible PAIRINGS (duties) is generated.
  • PAIRING
  • sequence of trips to be covered by a single crew
    in 1-2 days
  • starts and ends at the same depot
  • cost depending on its characteristics.
  • PAIRING OPTIMIZATION the best subset of the
    generated pairings is selected, so as to cover
    all the trips at minimum cost solution of a
  • SET COVERING SET PARTITIONING
    PROBLEM.
  • PHASES 1 2 CREW SCHEDULING PHASE

35
  • 3. ROSTERING OPTIMIZATION the selected
    pairings are sequenced to obtain the final
    rosters (separately for each depot), defining a
    periodic duty assignment to each crew which
    guarantees that all the pairings are covered for
    a given number of consecutive days (i.e. one
    month)

36
  • The SET COVERING PROBLEM (SCP)
  • Given
  • a BINARY MATRIX Aij (very sparse)
  • m number of rows (i 1,, m)
  • n number of columns (j 1,, n)
  • a COST VECTOR (cj ) cj cost of column j
    (j1,,n)
  • (w.l.o.g. cj gt 0 and integer)
  • Select a subset of the n columns of Aij
    such that
  • the sum of the costs of the selected columns is a
    minimum,
  • all the m rows are COVERED by the selected
    columns (i.e. for each row i at least one
    selected column j has an element of value 1 in
    row i Ai j 1).

37
Train Timetabling Problem
  • Defines the actual timetable for each train
  • Departure time from the first station
  • Arrival time at the last station
  • Arrival and departure times for the intermediate
    stations
  • Separate timetabling problems are solved for
    distinct corridors in the network
  • The trains are assumed to have different speeds

38
Train Timetabling Constraints
  • Basic Operational Constraints required in order
    to guarantee safety and regularity margin
  • Minimum distance between a train and the next one
    along the corridor
  • Minimum distance between two consecutive arrivals
    (departures) in a station
  • Overtaking between trains can occur only within a
    station

39
Train Timetabling Objectives
  • Quality of service
  • Minimum deviation of the actual timetable with
    respect to the ideal one
  • Robustness of the timetable with respect to
    random disturbances and failures

40
Optimization Methods
  • Heuristic algorithms possibly based on
    mathematical programming tools
  • Mixed Integer Linear Programming formulations
  • Enumerative algorithms
  • Linear and Lagrangian relaxations
  • Aimed at finding an optimal timetable starting
    from the ideal one
  • Applicable at both Planning and Operational levels

41
Basic Train Timetabling Problem
  • One single track is considered
  • We are given on input a so-called ideal timetable
    which is typically infeasible.
  • To obtain a feasible (actual)timetable two
    kinds of modifications of the ideal timetable are
    allowed
  • change the departure time of some trains from
    their first station (shift)
  • and/or
  • increase the minimum stopping time in some of the
    intermediate stations (stretch).

42

Ideal timetable
Actual timetable
ideal_departure_instant
Shift
Station 1
stop
Station 2
Stretch
stop
Station 3
Station 4
43
Objective of the problem
  • Each train j is assigned an ideal profit pj
    depending on the type of the train (intercity,
    local, freight, etc).
  • If the train is shifted and/or stretched the
    profit is decreased.
  • If the profit becomes null or negative the train
    is cancelled.
  • Actual profit of train j pj aj ( vj
    ) ßj (uj ) vj shift,
  • uj stretch (sum of the stretches in all
    stations)
  • The objective is to maximize the overall profit
    of the trains

44
Optimization Algorithm
  • Graph Theory Model
  • Integer Linear Programming Formulation
  • Lagrangian Relaxation
  • Constructive Heuristic Algorithms
  • Local Search Procedures

45
Additional Characteristics
  • Fixed block or Moving block signalling
  • Capacities of the stations
  • Full or Residual track capacity evaluation
  • Maintenance operations
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