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Welcome to MS383 Simulation

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Title: Welcome to MS383 Simulation


1
Welcome to MS383 (Simulation)
2
Course Introduction
  • Welcome to the course!
  • Thanks for taking the course with me.
  • This is an OR minor course focused on modeling
    systems using simulation techniques.
  • We will meet thrice a week in the E slot here in
    HSB 334.
  • The course overview MS Word file.

3
Course Objectives
  • The course hopes to answer
  • How to build models of real systems using
    simulation techniques (as against analytical
    techniques)?
  • How to statistically analyze these models?
  • How to gain managerial insights about the real
    systems from the simulation models?
  • To achieve these objectives, we will spend
    considerable time on statistical tools and
    techniques relevant to simulation.
  • However, no pre-requisite knowledge of statistics
    is required for the course.

4
Course Introduction
  • Why is this not CS383?
  • True, we are going to mimic the real systems by a
    computer code (or software).
  • The focus is going to be more on analyses rather
    than the code itself.
  • We are more interested in finding the performance
    parameters of the system using simulation. So
    that we can take decisions based on the models.
  • Simulation software packages and tailor-made
    codes are going to be just tools to achieve our
    objective which is to draw conclusions about
    the real system.

5
Simulation
  • To imitate The operations of various kinds of
    real-life facilities or processes can be
    simulated using a computer code.
  • The facility of process of interest is the
    system. System is a collection of entities that
    act and interact together toward the
    accomplishment of some logical end.
  • To imitate the real-life processes, we may have
    to make some assumptions.
  • The logical or mathematical relationships amongst
    these assumptions is a model.

6
Simulation
  • If the inter-relationships are simple, we can
    represent them in the form of exact mathematical
    expressions. These are the analytical models. The
    results we get from these are exact called
    analytical solution.
  • When the inter-relationships are complex, we
    analyze them numerically using computers. These
    are simulation models. Here, we gather data in
    order to estimate the desired true
    characteristics of the model.

7
Systems
  • State of a system collection of variables that
    describe the system completely (with respect to
    the study) at a particular time instance.
  • Discrete systems is the one for which the state
    variables change instantaneously at separated
    points of time.
  • e.g. Bank with of customers as state variable.
  • Continuous systems is one for which the state
    variables change continuously with respect to
    time.
  • e.g. Fluid flow in pipe-lines.

8
Systems
Real System
Experiment with actual system
Experiment with a model
Physical model
Logical model
Analytical solution
Simulation
9
Systems
  • Static vs. dynamic models In static models,
    there is no time axis.
  • Deterministic vs. stochastic models No
    probabilistic components in the deterministic
    models.
  • Continuous time vs. Discrete time models Same
    as earlier definitions of continuous and
    discrete time systems.

10
Pros and Cons of Simulation
  • Advantages
  • Mathematical models (which can give analytical
    solutions) fail to describe many complex,
    real-life systems accurately.
  • Using simulation, performance of the existing
    system can be estimated for a range of operating
    conditions.
  • Alternatives to existing system could be tested
    with relative ease.
  • Control in simulation experiment is better than
    that in experiment with the system itself.
  • Time axis can be played around with relative ease.

11
Pros and Cons of Simulation
  • Disadvantages
  • Most often, the results of simulation are
    estimates. Several runs of the model could be
    required to study the system in details.
  • Often are time consuming and expensive.
  • Large volume of numerical data and animation
    (with the use of latest software) create at
    times, false impression of accuracy and hence,
    confidence.

12
Pitfalls of Simulation
  • Failure to have clearly defined objective at the
    beginning of the study.
  • Inappropriate level of modeling details.
  • Failure to communicate with the management on
    regular basis.
  • Treating it as if it is a complex exercise in
    computer programming.
  • Failure to have people with OR and Statistics
    background in modeling teams.
  • Using commercial simulation software without
    knowing its limitations.
  • Misuse of animation.

13
Pitfalls of Simulation
  • Failure to account for correct source of
    randomness.
  • Using arbitrary distributions as input.
  • Analyzing output data from one simulation run
    without any consideration of reality.
  • Making single replication of the model. And
    comparing alternate systems based on the same.
  • Using wrong measures of performance.

14
Steps in Simulation Study
  • Formulate the problem and plan the study Clear
    statement of purpose of the study, its overall
    objectives, and specific issues to be addressed
    is a must. The alternatives system designs to be
    studied should be delineated, and criteria for
    evaluating the efficacy of these alternatives
    should be given.
  • Collect data and define a model Information and
    data should be collected and used to specify
    operating procedures and probability
    distributions for the random variables used in
    the model. Data on performance of the system
    should be collected for validation.
  • Check for validity Though validation should be
    carried out through the study period, it is
    required at scoping stage.

15
Steps in Simulation Study
  • Write a computer program and verify Decision
    about either using a general purpose computer
    language (C, C etc) or a simulation package
    (ARENA etc) should be made. General purpose
    language might be preferred by the modeler but to
    include complex features to the model simulation
    package might be better.
  • Make a pilot run Pilot runs of the verified
    model are made for validation purpose in Step 6.

16
Steps in Simulation Study
  • Check for validity Pilot runs can be used to
    test the sensitivity of the models output to
    small changes in input parameters. This will
    emphasize the need for better estimates of input
    parameters. The data from system (if it exists)
    and model could be compared for closeness.
  • Design the experiments If testing more than one
    alternatives, decide about what system design to
    simulate. For each design to be tested, decide
    about the initial conditions for the run(s),
    warm-up periods of each run, the length of the
    simulation run(s), and number of independent
    replications.

17
Steps in Simulation Study
  • Make production runs Production runs are made to
    provide performance data on the system design of
    interest.
  • Analyze output data Statistical techniques are
    used to analyze the output data from production
    runs. Goal is to construct confidence interval
    for a measure of performance on one particular
    system or to decide which simulated system is the
    best choice.
  • Document, present, implement results Compilation
    of the entire study, assumptions, model
    description, results, and conclusions.
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