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Hardware Development Methods and Tools

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Hardware Development Methods and Tools Design Methodologies Component Variations Misuse Extended TRIZ * * * * * * * * * * * * * * * * * * * * * * * * * Graphic from ... – PowerPoint PPT presentation

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Title: Hardware Development Methods and Tools


1
Hardware Development Methods and Tools
  • Design Methodologies
  • Component Variations
  • Misuse
  • Extended TRIZ

2
Six Sigma
  • Six Sigma is a revolutionary business process
    geared toward dramatically reducing
    organizational inefficiencies that translate into
    bottom-line profitably. The steps are
  • Define
  • Measure
  • Analyze
  • Improve
  • Control.

3
The basis of Six Sigma is measuring and improving
processes re defects
  • Six Sigma 3.4 defects per million opportunities
  • Most current methodologies operate at 3 to 4
    sigma, allowing 25 loss of revenue because of
    failure rates due to defects
  • Result unhappy, non-returning customers!

4
Design for Six Sigma
  • Design for Six Sigma (DFSS) is an approach to
    designing or re-designing product and/or services
    to meet or exceed customer requirements and
    expectations (VOC). It begins by conducting a
    gap analysis of your entire product development
    system. This analysis finds the gaps in your
    processes that are negatively affecting new
    product performance

5
Methodology 1 DMADV
  • Define determine goals, VOC requirements
  • Measure assess customer needs specs.
  • Analyze- examine solution options
  • Design develop to meet requirements
  • Verify verify that you met requirements

6
Other Methods
  • DMADOV prior Optimize
  • IDEAS Identify/Design/Evaluate/Affirm/Scale up
  • IDOV Identify/Design/Optimize/Validate
  • DMEDI Define/Measure/Explore/Develop/Implement
  • DCCDI Define/Customer/Concepts/Design/Implement

7
In General, Design for Six Sigma
  • Is a structured approach to responding to the
    voice of the customer
  • Is augmented by standard tools such as QFD,
    Failure Modes and Effects Analysis, Pareto Charts
    analyses, Feather Diagrams, designsafe
    analyses, input from reliability groups, input
    from QA and customer complaint inputs, possible
    analyses from MAUDE data, etc.

8
Some Six Sigma Tools
  • Robust design Taguchi Method
  • Quality Function Deployment QFD (done)
  • Design Failure Modes and Effects Analysis
  • Axiomatic Design Nam Suh

9
Robust Design
  • By considering the noise factors (variation
    component deterioration) and the cost of failure
    this method helps ensure customer satisfaction.
    The focus is on improving the fundamental
    function of the product or process, facilitating
    flexible designs and concurrent engineering. It
    assists in reducing product cost, improving
    quality, while simultaneously reducing
    development interval.

10
Your Circuit Choice?
  • Compensate the customers for their losses.
  • Screen out circuits having large offset voltage
    at the end of the production line (discard).
  • Institute tighter tolerances through process
    control on the manufacturing line (inspect).
  • Change the nominal values of critical circuit
    parameters such that the circuit's function
    becomes insensitive to the cause, namely,
    manufacturing variation.

11
Parameter Diagram, aka P-Diagram
12
Robust Design Overview Step 1
  • Problem FormulationThis step consists of
    identifying the main function, developing the
    P-diagram, defining the ideal function and S/N
    ratio, and planning the experiments. The
    experiments involve changing the control, noise
    and signal factors systematically using
    orthogonal arrays.

13
Robust Design Overview Step 2
  • Data Collection/SimulationThe experiments may
    be conducted in hardware or through simulation.
    It is not necessary to have a full-scale model of
    the product for the purpose of experimentation.
    It is sufficient and more desirable to have an
    essential model of the product that adequately
    captures the design concept. Thus, the
    experiments can be done more economically.

14
Robust Design Overview Step 3
  • Factor Effects AnalysisThe effects of the
    control factors are calculated in this step and
    the results are analyzed to select optimum
    setting of the control factors.

15
Robust Design Overview Step 4
  • Prediction/ConfirmationIn order to validate
    the optimum conditions we predict the performance
    of the product design under baseline and optimum
    settings of the control factors. Then we perform
    confirmation experiments under these conditions
    and compare the results with the predictions. If
    the results of confirmation experiments agree
    with the predictions, then we implement else
    repeat.

16
Design for Failure Modes Effect Analysis Form
Data Process
  • Number (No.)
  • Item/Function
  • Potential Failure Mode
  • Potential Effect(s) of Failure
  • Severity (S)
  • Potential Cause(s)/Mechanism(s) of Failure
  • Occurrence (O)

17
Design for Failure Modes Effect Analysis
Continued
  • Classification
  • Current Mitigations
  • Verification
  • Detection (D)
  • Recommended actions
  • Action Results

18
(No Transcript)
19
Axiomatic Design
  • CTS Critical To Satisfaction (or CR, customer
    requirements)
  • FR Functional Requirements
  • DP Design Parameters
  • PV Process Variable
  • Matrix based, aim is to develop FR vectors that
    are independent wrt DPs and result in minimal
    complexity.

20
Redundancy
  • Active redundancy MTBF 1/? gt 3/2?
  • Standby redundancy MTBF 1/? gt 2/?
  • Active units are in parallel always active
  • Standby units swap out when bad

21
Component Selection Considerations
  • Component reliability
  • Vendor assessment (Hx, failure, etc.)
  • Vendor audit (check facility)
  • Vendor evaluation (inspect incoming)
  • Vendor qualification (on-list?)
  • Component history
  • military reliability groups
  • government info bases
  • Safety (FMEA, etc.)

22
Hardware Software Techniques ctd.
  • Component Derating
  • Practice of limiting the stresses
  • Use 2 watt R in 1 watt situation, decrease
    failure rate gt30 (T, humidity, P, V, I,
    friction, vibration)
  • Usage ratio max stress/stress rating (.5-.9)
  • Goal is reliability!
  • Pacemaker example

23
Hardware Software Techniques ctd.
  • Safety Margin
  • (mean safety factor) - 1
  • (mean strength/mean stress) - 1
  • Elevator safety margin2
  • Medical devices Fries - .5 and up.
  • Load Protection
  • Environment
  • Product misuse
  • Design for variation (6 sigma)

24
Product misuse Plan for
  • excess application of cleaning solutions
  • physical abuse
  • spills
  • excess weight applied to certain parts
  • excess torque applied to controls or screws
  • improper voltages, frequencies or pressures
  • improper or interchangeable electrical or
    pneumatic connections.

25
The Clean-Room Approach To Reverse-Engineering
  • One person or group takes a device apart and
    describes what it does in as much detail as
    possible at a higher level of abstraction than
    the specific code. That description is then given
    to another group or person who has absolutely no
    knowledge of the specific device in question.
    This second party then builds a new device based
    on the description. The end result is a new
    device that works identically to the original but
    was created without any possibility of
    specifically copying the original.
  • -Mathew Schwartz

26
Extended TRIZ Design TechniquesExample Effect
of a grounding pad
27
Problem Statement
  • Grounding pad is needed in order to conduct
    current from scalpel to ground
  • Grounding pad must adhere to the body, otherwise
    there might be hot spots or burns
  • Removal of the grounding pad causes injury, as
    seen in the photo. Injuries may include tearing
    of the skin, not just what is seen here.

28
Concept Map for Skin Problem
29
Ideation Process Fill in the blanks -
  • Brief description of the problem
  • Problem Formulation build the diagram

30
Formulate
  • 1. Find an alternative way to obtain the
    (conducts electricity well) that does not require
    the (Adheres tightly to skin).
  • 2. Consider transitioning to the next
    generation of the system that will provide the
    (conducts electricity well) in a more effective
    way and/or will be free of existing problems.
  •  

31
Continued
  • 3. Find an alternative way to obtain the
    (Adheres tightly to skin) that offers the
    following provides or enhances the (conducts
    electricity well), does not cause the (Tears
    skin).
  • 4. Try to resolve the following contradiction
    The useful factor the (Adheres tightly to skin)
    should be in place in order to provide or enhance
    the (conducts electricity well), and should not
    exist in order to avoid the (Tears skin). 
  • 5. Find a way to eliminate, reduce, or prevent
    the (Tears skin) under the conditions of the
    (Adheres tightly to skin).

32
Continued -
  • Select likely suggestions,
  • Expand upon
  • Select solution

33
End of chapter -
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