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Summary of Activities

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K Sudhakar Amitay Isaacs SK Sane. J Jayaraman PM Mujumdar ... Coordinates a Special Interest Group on MDO (SIG-MDO) Systems Engineering Process ... – PowerPoint PPT presentation

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Title: Summary of Activities


1
System Analysis towards System Optimization
Multi-disciplinary Design Optimization K
Sudhakar Amitay Isaacs SK
Sane J Jayaraman
PM Mujumdar ARDB Centre for Systems Design
Engineering Department of Aerospace
Engineering Indian Institute of Technology
Bombay October 13, 2003
2
Multi Disciplinary Analysis (MDA) towards System
Optimization Multi-disciplinary Design
Optimization K Sudhakar Amitay Isaacs
SK Sane J Jayaraman
PM Mujumdar ARDB Centre for
Systems Design Engineering Department of
Aerospace Engineering Indian Institute of
Technology Bombay October 13, 2003
3
CASDE - Activities
  • MTech in Systems Design Engineering
  • Courses of study
  • System Modeling Simulation
  • Optimization for Engineering Design
  • Multi-disciplinary Design Optimization (MDO)
  • Applied Mechatronics (hands on course)
  • Statistical Methods for Analysis Design
  • Systems Engineering Principles  
  • Also available as short courses
  • Coordinates a Special Interest Group on MDO
    (SIG-MDO)

4
Systems Engineering Process
  • System represents system under design
    development
  • Super-system represents operational scenario
    for the systems
  • under design development.

5
Systems Engineering Process
Context
Super System
Requirements to lower level
System
Solution from lower level
Sub System
  • System represents system under design
    development
  • Super-system represents operational scenario
    for the systems
  • under design development.

6
Systems Engineering Process
Context
Super System
Requirements to lower level
System
Solution from lower level
Sub System
  • Level 1 Good understanding of system
    knowledge base, heuristic
  • Computationally less
    expensive
  • Usually not available for
    new systems.
  • Level 3 Physics based modeling
    computationally intensive,
  • applicable to new systems
    (VV?)

7
Systems Engineering Process
Context
Super System
Requirements to lower level
System
Solution from lower level
Sub System
8
CASDE Activities
  • Research activity
  • High fidelity models in design loop ( CFD, . .)
  • Multi-Disciplinary Analysis (MDA) leading to
  • Multi-disciplinary Design Optimization (MDO)
  • MDO Studies
  • Hypersonic Vehicle (DRDL)
  • Combat Aircraft (ADA)
  • Launch Vehicle (VSSC)

9
System Optimization / Design
  • Design Problem Statement
  • Not always readily available
  • Not easy to reconstruct
  • Need for capturing problem as we go along
  • Optimization
  • System parameterization, x
  • Objectives Optimize f1(x), f2(x), . .
    . .
  • Constraints Equality h1(x), h2(x), . .
    . . 0
  • Inequality g1(x),
    g2(x), . . . . ? 0
  • Multi Disciplinary Analysis ? f1(x), . , h1(x),
    . , g1(x), .

10
System Optimization / Design
  • Multi Disciplinary Analysis Capability
  • Strengths exist in disciplinary analysis
  • Focus on Analysis for Design
  • Capture knowledge with traceability
  • Focus on verification / validation

11
System Optimisation / Design
  • Need for a group to
  • Capture design problems
  • Define needs for Analysis for Design
  • Extract / Establish traceability
  • Perform Verification / Validation
  • Explore design methodologies

SIG-MDO is doing this informally MSO-DMES
gives hopes of formalizing this
12
System Optimisation / Design (Contd.)
  • IT Enabled Design Environment
  • Stress on digital models
  • Need for distributed environment
  • Support to system designer for abstracting
  • Enabling disciplinary authority / control
  • MDO Frameworks!
  • Optimization Technology
  • Goes beyond theory
  • Goes beyond S/W packages
  • Guided search to improve than hunt for optima

13
System Level Analysis
14
System Level Analysis
15
System Level Analysis
16
System Level Analysis
17
Design Problem
  • Design an Air-Breathing Hypersonic Vehicle
  • Cruise M6.5 at H 30-35 km
  • Constraints
  • Dimensional constraints on overall length, height
    and width
  • Take-off gross weight
  • Intake entry conditions
  • Control deflection within allowable values
  • Vehicle drag to be less than thrust deliverable

18
Parameterization of HSTDV Body
Design variables XD ?1, ?2, ?3 , ?n_plan , ?wc
, wfac_pl, tfac_pl,, Hcruise
19
Hypersonic Vehicle Discipline
Interactions
Analysis Model
Output
Input variable
Ext. Compression Model AM1
?1
Y1 l1, l2, l3, h1, h2, h3 Y2 ma , MI, ?, pst
Y1
?2
Ext. Configuration Model AM2
Y3 (X,Y,Z) Y4 TOGW , C.G., Vol, Fuel mass
?3
Aero Model AM3
Y5 CN, Cm, CA
?n_pl
Trim Model AM4
Y6 TOGW_up, ?T , ?T , D
?w_c
SW
Thrust Model AM5
Y7 Th_deliv, Lp, Mp
ST
Hcr
Performance Model AM6
Y8 Cruise Range
?n_pl, SW ?1, Hcr
Variables not shared
Y1 Response from AM1 required as
input in AM2
Shared variables
20
System Level Analysis
21
MDO Framework
  • MDO Framework is an important infrastructure for
    design
  • Do MDO Framework exist?
  • iSIGHT,
  • Phoenix integration,
  • etc
  • Most design offices are migrating to MDO Framework

22
  • System Engineering Processes
  • Mr J Jayaraman
  • MDO Framework for System Optimization
  • Mr. Amitay Isaacs
  • Contd. . . .
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