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Logistics Systems Engineering

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Title: Logistics Systems Engineering


1
NTU SY-521-N
SMU SYS 7340
Logistics Systems Engineering System Cost
Analysis, Part II
James R. Brennan, Product Assurance Analysts
2
Agenda
  • Cost Analysis Principles
  • Life-Cycle Cost (LCC) Analysis
  • System Considerations
  • LCC Management
  • Design to Cost (DTC)
  • Cost as an Independent Variable (CAIV)

3
Agenda
  • LCC Organization
  • Warranties/ Guarantees
  • Wrap-Up

4
Cost Analysis Principles
  • Cost Analysis Essentials
  • Precise definition of what is being cost
  • Documentation of assumptions and constraints
  • Model tailored to needs of problem and consistent
    with existing level of system definition
  • Risk/Uncertainty analysis to identify any
    conditions which could affect a conclusion
  • Key limitations

5
Cost Analysis Principles
State Objectives
Define Assumptions
Select Cost Element
Develop CERS
Collect Data
Estimate Element Cost
Perform Sensitivity Analysis
Perform Uncertainty Analysis
Present Results
6
Cost Analysis Principles
  • Six Desired Characteristics of Cost Models
  • Consistency Conforms to current cost estimating
    practices. This allows the Proposed System to be
    compared to an Analogous System.
  • Flexibility Constructed so that it is useful in
    the early phases and can evolve to accommodate
    more detailed information as the program
    continues through its life cycle.

7
Cost Analysis Principles
  • Six Desired Characteristics of Cost Models
  • Simplicity Requires only the minimum data
    necessary to estimate the cost. More complex
    models can be used as more data becomes
    available.
  • Usefulness Provides useful information to the
    decision makers in their evaluation of support
    and design tradeoffs.
  • Completeness Models should include all
    applicable costs for a systems life.

8
Cost Analysis Principles
  • Six Desired Characteristics of Cost Models
  • Validity Capable of providing logical,
    reproducible results.

9
Cost Analysis Principles
  • Payback Analysis

Existing System
Cost ()
Crossover Point
Modified System
Payback Period
Time - Years
10
Life-Cycle Cost (LCC) Analysis
  • Introduction
  • LCC a well-traveled concept for over 30 years
  • Numerous papers, policies, and decisions issued
    relative to LCC over these years
  • Despite its longevity, a universal understanding
    of LCC has not been established
  • A common definition of LCC terms, processes and
    applications is required
  • LCC or a derivative will exist as long as
    controlling program costs is a critical
    consideration

11
Life-Cycle Cost (LCC) Analysis
  • Definitions
  • Life-Cycle Cost (LCC) Total cost to the
    customer of acquisition and ownership of a system
    over its full life. It includes the cost of
    development, production, operation and support
    and disposal.
  • Cost Effectiveness (CE) Consideration of
    mission capability, mission reliability and
    operational availability along with LCC to
    evaluate competing design, production or support
    alternatives

12
Life-Cycle Cost (LCC) Analysis
  • Definitions
  • Design To Cost (DTC) Cost is a design parameter
    receiving consideration along with performance,
    schedule, etc. In program decisions. DTC is a
    management process to integrate cost into design,
    production and support decisions.

13
Life-Cycle Cost (LCC) Analysis
  • Scope of LCC
  • LCC analysis can be applied on commercial as well
    as government programs
  • Existing programs require LCCA - increasing
    frequency is expected
  • LCC analysis is applicable across all program
    phases - development, production and use
  • LCC analysis is applicable to software as well as
    hardware
  • LCC analysis can be performed in constant,
    inflated or discounted dollars

14
Life-Cycle Cost (LCC) Analysis
  • LCC Limitations
  • LCC outputs are estimates and are only as
    accurate as the inputs
  • Interval estimates (Cost-Risk Analysis) are
    appropriate for LCC predicting or gudgeting
    purposes
  • Accuracy of LCC estimates is difficult to
    determine
  • Limited data exists on new programs particularly
    with respect to operation and support costs

15
LCC Analysis Phased LCC Funding Trends
100
Funds Committed
Percentage
50
Funds Expended
0
Production
OS
Definition
RDTE
Life Cycle Phase
16
Life-Cycle Cost (LCC) Analysis
  • Cardinal Principles
  • Not an exact science - highly estimate
  • No right or wrong - reasonable or unreasonable
  • Most effective as a Trade-Off tool
  • Should employ cost-risk analysis for LCC
    estimation
  • Requires project team approach - need specialized
    expertise from the project disciplines

17
Life-Cycle Cost (LCC) Analysis
  • Cardinal Principles
  • Should be an integral part of the design,
    production and support processes - DTLCC

18
Life-Cycle Cost (LCC) Analysis
  • Cost Analysis Estimates
  • As system definition matures, system-comparable
    data replaced by system-specific data
  • Systems Engineer should be LCC team leader and
    coordinate input data from team members
  • Reliability
  • Maintainability
  • Logistics
  • Design
  • Production
  • Cost

19
Life-Cycle Cost (LCC) Analysis
  • Cost Analysis Estimates
  • Estimated data is followed by test and evaluation
    data which is in turn followed by field data

20
Life-Cycle Cost (LCC) Analysis
  • Basic LCC Models
  • LCC CA CS
  • CA Acquisition Cost
  • CS Sustaining Cost
  • CA CD CI
  • CD Development Cost
  • CI Investing Cost
  • CS COS CR
  • COS Operating and Support Cost
  • CR Retirement Cost

21
Life-Cycle Cost (LCC) Analysis
  • LCC Objectives
  • Estimate Costs
  • Compare Costs
  • Balance Cost

Acquisition Cost
Sustaining Cost
22
Insert Typical LCC Model Structure, p 18
23
Life-Cycle Cost (LCC) Analysis Flow
  • Doctrines
  • Procurement
  • Operational
  • Maint./Support

System Characteristics
Input Data Estimates
Cost Model
Estimate of LCC
Best Estimate of LCC
Sensitivity Analysis
Standard Factors
24
Life-Cycle Cost (LCC) Analysis
  • LCC Estimating Techniques
  • Analogy/Scaling
  • Parametrics-LCC as a function of weight for
    example
  • Engineering (Bottom-Up) Analysis
  • Vendor Data
  • Field Data

25
Life-Cycle Cost (LCC) Analysis
  • LCC Input Data
  • System Characteristics
  • Quantity of item under study in larger system
  • Item unit cost
  • Item MTBF/MTBM
  • Item Weight

26
Life-Cycle Cost (LCC) Analysis
  • LCC Input Data
  • System Characteristics
  • Item Volume
  • Item MTTR
  • Quantity of stock number introduced and managed
    support equipment (if applicable) unit cost

27
Life-Cycle Cost (LCC) Analysis
  • LCC Input Data
  • Standard Factors
  • Maintenance labor rates at each maintenance level
  • Shipping rates
  • Cost per stock number for introduction
  • Cost per stock number for management
  • Cost per page for technical data
    creation/management

28
Life-Cycle Cost (LCC) Analysis
  • LCC Input Data
  • Standard Factors
  • Attrition rates for recurring training
  • Facility space cost factors
  • Support equipment maintenance cost factor

29
LCC Analysis Data Paradox
Large Value
Large Amount
Cost Decision Value
Value of Cost Decision
Amount of Available Data
Data Availability
Small Value
Small Amount
30
Life-Cycle Cost (LCC) Analysis
  • Types of LCC Analysis
  • Baseline Evaluates LCC for particular system
    configuration for given operational and
    maintenance policies
  • Sensitivity Evaluates the impact on LCC of
    changes to the input data to identify cost
    drivers requiring special attention during the
    program
  • Tradeoff Evaluates alternative approaches to
    aid in the selection of the preferred option
    based on LCC, mission capability, availability
    and mission reliability

31
Life-Cycle Cost (LCC) Analysis
  • Types of LCC Analysis
  • Tracking Monitors LCC of System over time to
    identify variances from baseline and aid in
    definition of trade-offs to control total program
    cost

32
Life-Cycle Cost (LCC) Analysis
  • LCC Sensitivity Analysis
  • Types of LCC Drivers
  • Hardware - LRU/WRA, SRU/SRA, etc.
  • Cost Element - Initial spares, maintenance, etc.
  • Design Parameter - MTBF, UPC, weight, LOC, etc.

33
Life-Cycle Cost (LCC) Analysis
  • LCC Sensitivity Analysis
  • Common LCC Drivers
  • System Usage - Hours, miles, cycles, etc.
  • Unit Production Cost (UPC)
  • Mean Time Between Failures (MTBF)
  • Mean Time to Repair (MTTR)
  • System Quantity
  • Expected Service Life of System

34
Life-Cycle Cost (LCC) Analysis
  • LCC Applications
  • Customer
  • Affordability studies - CAIV
  • Source Selection
  • Design Trade Studies - Establishing reliability
    and maintainability goals / requirements
  • Repair Level Analysis
  • Warranty should cost and cost effectivenss

35
Life-Cycle Cost (LCC) Analysis
  • LCC Applications
  • Supplier
  • Identification of cost drivers for emphasis
    during program - sensitivity analysis
  • Comparison of competing design, production and
    support alternatives - trade-off ranking
  • LCC Tracking during program - problem isolation
  • Marketing tool - new and modification programs
  • Warranty Pricing

36
Life-Cycle Cost (LCC) Analysis
  • Cost Analysis Considerations
  • Time Value of Money
  • Constant Dollars States all costs in terms of
    constant purchasing power measured at a given
    time - also known as real dollars
  • Inflated Dollars Cost stated in terms of
    estimated expenditures at the time the money is
    spent - also known as then-year future or actual
    dollars

37
Life-Cycle Cost (LCC) Analysis
  • Cost Analysis Considerations
  • Time Value of Money
  • Discounted Dollars All costs are referenced to
    a common point in time based upon the anticipated
    earning power of money - costs can be in constant
    or inflated dollars, but the anticipated earning
    power must be adjusted thusly

38
Insert Monte Carlo Process, p. 29
39
System Considerations
  • Driving System Concepts
  • Procurement Data
  • Number of Systems procured
  • Production Schedule
  • Installation Schedule
  • Design to unit production cost (DTUPC)
    requirements
  • First destination transportation requirements

40
System Considerations
  • Driving System Concepts
  • Operational Data
  • Number of operational sites
  • Quantity of systems per site
  • Mission schedule - number of missions per period
  • Mission Profile - mission length, mission type
  • Ground operation requirements
  • Mission readiness and reliability requirements

41
System Considerations
  • Driving System Concepts
  • Maintenance/Support Data
  • Number of levels of maintenance
  • Quantity of maintenance sites per level
  • Location of maintenance sites
  • Number of systems supported per site
  • Description of maintenance at each level
  • Scheduled/preventive maintenance requirements

42
System Considerations
  • Driving System Concepts
  • Maintenance/Support Data
  • Required MTTR at each maintenance level
  • Required spares assurance factors and TATS
  • Support equipment requirments

43
RMS as Key System Elements
  • Availability
  • Sortie Generation Rates
  • Basing

Product
  • Reliability
  • Maintainability
  • Supportability
  • Testability
  • Organization
  • Requirements
  • Schedule Maintenance
  • Unscheduled Maintenance
  • Spares
  • Technical Publications
  • Training
  • Support Equipment

44
System Considerations
  • Cost-Effectiveness Analysis Outcomes
  • A is preferable IF E is
  • worth more than C

A
LCC
C
B
  • A is more effective
  • B cost less

E
Effectiveness
45
Insert Cost-Effectiveness Factor Interaction,
p. 36
46
Design to Cost (DTC)
  • Establishes LCC as a design parameter - not a
    consequence of design
  • Requires establishment of cost goals, monitoring
    of these goals and tread-off actions to keep the
    LCC within these goals (budgets)
  • Activity focuses on identifying system cost
    drivers, potential risk areas relative to the
    drivers and on-going cost/ scheduled/ performance
    tradeoffs
  • Should be early and continuos

47
Design to Cost (DTC) Terms
  • Design to unit production cost (DTUPC)
    Concerned with managing UPC goals- includes
    recurring and non-recurring production cost
  • Design to LCC (DTLCC) Concerned with managing
    the total LCC of a system, including development,
    investment, operation and support and retirement-
    focuses on drivers since out-year costs are
    difficult to manage

48
Design to Cost (DTC) Terms
  • Design to Cost Effectiveness (DTCE) Concerned
    with managing not only LCC but also other system
    parameters such as mission reliability, readiness
    and mission capability

49
Design to Cost (DTC)
  • DTLCC Implementation
  • Keys to Success
  • Useable LCC model
  • Reasonable input data
  • Extensive trade-off analyses- LCC not ony
    criterion
  • Relating of results to hardware/software design
  • Implementation of trade-off decisions into the
    hardware/software design

50
Design to Cost (DTC)
  • DTLCC Implementation
  • Keys to Success
  • Challenging the performance requirements
  • Adhering to hierarchy - equipment, cost category
    and design driver

51
Design to Cost (DTC)
  • DTLCC
  • Program trade-off issues
  • UPC vs. MTBF
  • Redundancy vs. no redundancy
  • Built-InTest (BIT) vs. no BIT
  • Two vs. Three-Level maintenance
  • Repair vs. discard
  • LCC vs. system performance
  • Different sparing assurances
  • Different levels of environmental stress
    screening (ESS)

52
Design to Cost (DTC)
  • Trade-Off Process

Insert Trade-Off process, p. 42
53
Design to Cost (DTC)
  • LCC Vs. MTBF

Total Life Cycle Cost
Cost ()
Operating and Support Cost
Development and Acquisition Cost
MTBF (Hours)
54
Scheduled Maintenance Trade Study
Scheduled Vs. Unscheduled Maintenance
1.85
Unsched
Sched 1000
1.80
Sched 800
B
1.75
1.70
LCC (Billions)
A
1.65
1.60
1.55
1.50
1.45
100
120
140
80
60
Percent of Predicted Baseline - MTBF
55
Repair Versus Discard Trade Study
Repair
LCC
Discard
600
Unit Production Cost (UPC)
Discard
LCC
Repair
12 Staff-hrs
Staff-hrs per repair
56
Cost as an Independent Variable
  • What is CAIV?
  • An acquisition strategy/methodology to acquire
    and manage affordable systems
  • Early, continual and consistent focus on
    balancing requirements to the program budget
  • Establishment and management of cost targets
    consistent with the program budget
  • Diligent use of trade-off analysis between
    requirements and cost to maintain performance and
    cost within targets

57
Cost as an Independent Variable
  • What is CAIV?
  • An extension of DTLCC where cost and requirements
    are independent variables not just requirements

58
Cost as an Independent Variable
CAIV Vision Team Effort
  • Define Operational
  • Requirement
  • Control
  • Make Trade Decisions

User
Acquirer
Industry
  • Mange Contract
  • Identify Trades
  • Define Capabilities
  • Make Trade Inputs
  • Build System

59
Cost as an Independent Variable
Insert Cost Vs. Capability, p. 49
60
Cost as an Independent Variable
Insert CAIV Process Flow, p. 50
61
LCC Organization
  • Team Organization

Program Manager
Systems Engineer
  • Design-Prime
  • and Support
  • Equip
  • Electrical
  • Mechanical
  • Systems
  • Software

Integrated Logistics Support (Support- ability)
Manufac- turing
Relia- bility
Maintain- ability
LCC
62
LCC Organization
  • Management of LCC
  • Engineering Team Member Responsibilities
  • Manage assigned cost targets for their cost
    drivers
  • Define tradeoffs in their respective disciplines
  • Estimate input data to LCC model for trade-off
    analyses
  • Assist in discussion of trade-off results leading
    to decisions

63
LCC Organization
  • Management of LCC
  • Engineering Team Member Responsibilities
  • Implement trade-off decisions into
    hardware/software design
  • Document trade-off analysis decisions

64
LCC Organization
  • Management of LCC
  • Cost Analyst Team Responsibilities
  • Understand, modify or develop LCC and trade-off
    models for use on program
  • Clearly define input data requirements for team
    member data estimation
  • Perform all LCC-related analyses
  • Interpret LCC analysis results to team members to
    aid decision making and implementation of
    decisions

65
LCC Organization
  • Management of LCC
  • Cost Analyst Team Responsibilities
  • Assume role of catalyst for team by performing
    baseline analysis and establishing drivers
    through sensitivity analysis

66
Warranties / Guarantees
  • Introduction Scope of Warranties

Marketing (Getting the Business)
WARRANTIES
Customer Satisfaction (Keeping the Business)
67
Warranties / Guarantees
  • Warranties and Quality
  • The best warranty is one you never have to use
  • A warranty you never have to use means a quality
    product
  • A quality product means a satisfied customer
  • Satisfied customers mean increased sales
  • Increased sales mean more opportunities to
    satisfy customers

68
Warranties / Guarantees
  • Warranty Principles
  • Benefits
  • Good marketing tool for suppliers
  • Insurance for customers
  • Good measure of customer satisfaction
  • Criteria of Good Warranty
  • Motivates supplier to impv. Rel. of product
  • Profit opportunity of supplier
  • Insurance for customer
  • Win/win

69
Warranties / Guarantees
  • Warranty Principles
  • Warranty Objectives
  • Insurance
  • Assurance
  • Incentives
  • Warranty Types
  • Repair-Threshold or failure-free
  • Systemic
  • Performance

70
Warranties / Guarantees
  • Warranty Principles
  • Coverage
  • Material and Workmanship (Failures)
  • Design Manufacturing (Defects)
  • Performance (compliance/non-compliance)
  • Remedies
  • Repair/replace-eliminate failure under MW
    coverage
  • Redesign/retrofit-eliminate defect under DM
    coverage
  • Penalties/Incentives under perf. coverage

71
Warranties / Guarantees
  • Warranty Principles
  • Realities of Warranties
  • Items under warranty may fail
  • Warranties are not free
  • Warranties are not iron-clad assurance that all
    the warranted parameters will be met- no magic
  • Warranties indicate the level of liability for
    which the supplier accepts responsibility
  • RMS are driving issues in the conception,
    costing, negotiating and implementation of a
    warrant

72
Warranties / Guarantees
  • Warranty Principles
  • Warranty Process
  • Requirements
  • Costing/pricing
  • Negotiating
  • Cost Benefit
  • Implementation/administration

73
Warranties / Guarantees
  • Warranty Principles
  • Warranty Keys
  • Customer satisfaction involves the product
    quality/reliability and quality service
  • Warranty is a process not a discipline - it is
    the amalgamation of several disciplines
  • We should always strive to design
    quality/reliability into the product-warranties
    motivate suppliers to that end
  • Good reliability wins the bets from both supplier
    and customer standpoints

74
Wrap-Up
  • LCC can be controlled on commercial and
    government programs through the diligent
    application of CAIV
  • CAIV is a management tool to establish
    affordability and integrate LCC into the design
    process
  • Tradeoffs are the cornerstone of CAIV
  • CAIV should be applied as early in the program
    design process as possible

75
Wrap-Up
  • Team concept is vehicle for a successful CAIV
    program
  • Cost must be a design parameter not a consequence
    of design
  • CAIV is here to stay- the well is drying up
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