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Product Design Selection Under Uncertainty

. OUTLINE. OVERVIEW OF THE PROJECT DESIGN VARIABLES AND ATTRIBUTES DESIGN ALTERNATIVE GENERATION THE UNCERTAINTY MODELING DESIGNER'S PREFERENCES DESIGN SELECTION APPROACH CONCLUSION. . THE PROJECT OVERVIEW. Objective: Select the product design that accounts for both customer's requi

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Product Design Selection Under Uncertainty

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    1. We present an approach for ranking design alternatives that is customer-based and considers designer’s preferences. We present an approach for ranking design alternatives that is customer-based and considers designer’s preferences.

    2. OUTLINE OVERVIEW OF THE PROJECT DESIGN VARIABLES AND ATTRIBUTES DESIGN ALTERNATIVE GENERATION THE UNCERTAINTY MODELING DESIGNER’S PREFERENCES DESIGN SELECTION APPROACH CONCLUSION

    3. THE PROJECT OVERVIEW A product design decision maker is often faced with selection of the “most preferred” design from a set of design alternatives. These alternatives, as shown in the center of this figure, might be non-dominated. That is from attributes point of view, none of these designs is dominant. So, any approach or metric has to: account for designer’s (which carries company’s) preferences account for customer wants…which means customer buy-no buy decision is based on the range of attributes. 3. account for uncertainties. Note that these uncertainties manifest themselves as follows: 1) while capturing designer’s preferences, as risk taking behavior of the designer, and 2) while calculating attribute level of design alternatives, as uncertainties in attribute levels. The objective of this research is to define a metric that accounts for both designer’s preferences and customers’ requirements to select the best possible design considering the associated uncertainties.A product design decision maker is often faced with selection of the “most preferred” design from a set of design alternatives. These alternatives, as shown in the center of this figure, might be non-dominated. That is from attributes point of view, none of these designs is dominant. So, any approach or metric has to: account for designer’s (which carries company’s) preferences account for customer wants…which means customer buy-no buy decision is based on the range of attributes. 3. account for uncertainties. Note that these uncertainties manifest themselves as follows: 1) while capturing designer’s preferences, as risk taking behavior of the designer, and 2) while calculating attribute level of design alternatives, as uncertainties in attribute levels. The objective of this research is to define a metric that accounts for both designer’s preferences and customers’ requirements to select the best possible design considering the associated uncertainties.

    4. DESIGN VARIABLES & ATTRIBUTES Design Variables Set of input variables (parameters) to the design simulation software (e.g. Motor type, Gear type, Gear ratio, DC voltage, Ambient temperature) Performance Attributes Set of attributes that is the output of the simulation software,and identifies a product design (e.g. Manufacturing cost, Weight, Time per operation per battery charge)

    5. DESIGN ALTERNATIVE GENERATION Two methods for generating design alternatives: Multiobjective Optimization Formulate a multiobjective optimization problem, solve for the alternatives that satisfy the objectives (performance attributes) the most. There is no closed form representation of the objective functions The design input parameters consist of both continuous and discrete variables Multiobjective Genetic Algorithm is a good choice to handle this type of problems The solution points constitute a non-dominated set w.r.t. all objective functions.

    6. DESIGN ALTERNATIVE GENERATION Multiobjective Optimization Contd. Example: min Cost (Motor type, Gear type, Batter type, Skin material, Labor) min Weight (Motor type, Gear type, Skin material) s.t. Motor type integer between [1,20] Gear type integer between [1,14] Battery type integer between [1,5] Gear ratio real between [10,20] Skin Material integer [1,3]

    7. DESIGN ALTERNATIVE GENERATION Permutation Over Attributes Generating design alternatives by permuting the attributes over all (or certain) levels Mapping between the attributes and the design variables is simple(i.e. we can easily obtain the corresponding design variables, once we get the attribute levels) Very easy to implement but less likely to be able to handle real applications. Example: Motor type [1,5] Gear type [1,3] 5x3x2 = 30 design alternatives Battery type [1,2]

    8. THE UNCERTAINTY The uncertainty exists in the input design variables Sources of Uncertainty The market price of the parts The fluctuations in input voltage/current The measurement error in the manufacturing of the parts The quality of the material/parts The Uncertainty Modeling Using presumed distributions for certain events (i.e. normal distribution for measurement error) Collecting the historical/field data and fit the best distribution using BestFit® (Distribution of input design variables)

    9. DISTRIBUTION OF ATTRIBUTES Monte Carlo Simulation Sample a random variable Construct the appropriate distribution for each design variable (i.e. Using @Risk or program that in Excel) Feed the design variables to the simulation software Obtain the distribution for the performance attributes

    10. MODELING DESIGNER’S PREFERENCES Utility Function Measure of the worth of a design alternative Accounts for the risk attitude of the designer Expected utility is a more realistic measure than expected value Example:

    11. UTILITY ASSESSMENT Certainty equivalent method Decision maker is asked to provide a certain value that he believes, is equivalent to the lottery. (x0 , p ; x*) ~ x† Or U(x†) = pU(x0) + (1-p)U(x*) Probability equivalent method Decision maker is asked to provide the probability in the lottery that makes him/her indifferent between the lottery and certain value.

    12. UTILITY FUNCTION DISTRIBUTION Multi Attribute Utility Function Measure for designer’s preferences over all attributes of the product Importance weights are required Obtain the MAU distribution by Monte Carlo simulation Estimate the Expected MAU and its variance for each design

    13. DESIGN SELECTION APPROACH This flowchart describes the overall selection approach. Here are the steps: 1) The uncertainty in the attribute levels will be modeled by Monte Carlo simulation. The cause of the uncertainty is the randomness and fluctuation in the values of the design parameters. For instance the ambient temperature or the diameter of the shaft,… are all representatives for random design parameters. The designer’s utility is a deterministic function which gets the attribute levels as input values and generates the utility of each value. Since the input value of this function is stochastic, the output will be stochastic as well. The customer provides the attributes’ range(s) that he/she is willing to purchase a product within those ranges. Then using the PDF of the attribute levels and the utility function and customer’s ranges, we’re able to calculate the CEU for the current design alternative. This process will be performed for all design alternatives, and finally the design with the highest value of CEU will be selected.This flowchart describes the overall selection approach. Here are the steps: 1) The uncertainty in the attribute levels will be modeled by Monte Carlo simulation. The cause of the uncertainty is the randomness and fluctuation in the values of the design parameters. For instance the ambient temperature or the diameter of the shaft,… are all representatives for random design parameters. The designer’s utility is a deterministic function which gets the attribute levels as input values and generates the utility of each value. Since the input value of this function is stochastic, the output will be stochastic as well. The customer provides the attributes’ range(s) that he/she is willing to purchase a product within those ranges. Then using the PDF of the attribute levels and the utility function and customer’s ranges, we’re able to calculate the CEU for the current design alternative. This process will be performed for all design alternatives, and finally the design with the highest value of CEU will be selected.

    14. CONCLUSIONS We used the following multiplicative utility model for the designer’s preferences. It is assumed that the designer prefers: cheaper product over a more efficient or faster one. we have calculated the CEU value for all design alternatives. The design #4 is the one which is most likely gain the highest demand as well as satisfying the designer.We used the following multiplicative utility model for the designer’s preferences. It is assumed that the designer prefers: cheaper product over a more efficient or faster one. we have calculated the CEU value for all design alternatives. The design #4 is the one which is most likely gain the highest demand as well as satisfying the designer.

    15. BACKUP SLIDES We used the following multiplicative utility model for the designer’s preferences. It is assumed that the designer prefers: cheaper product over a more efficient or faster one. we have calculated the CEU value for all design alternatives. The design #4 is the one which is most likely gain the highest demand as well as satisfying the designer.We used the following multiplicative utility model for the designer’s preferences. It is assumed that the designer prefers: cheaper product over a more efficient or faster one. we have calculated the CEU value for all design alternatives. The design #4 is the one which is most likely gain the highest demand as well as satisfying the designer.

    16. SET OF DESIGN ALTERNATIVES & DESIGNER’S MAU This example explore the design selection of a cordless power tool. Two attributes are considered, and there are five competing design alternatives as shown in the figure. The uncertainty in the attribute levels are assumed to be normal with the following parameters. The nominal value of each attribute level is assumed to be the most likely value. The attributes are assumed to be statistically independent from each other.This example explore the design selection of a cordless power tool. Two attributes are considered, and there are five competing design alternatives as shown in the figure. The uncertainty in the attribute levels are assumed to be normal with the following parameters. The nominal value of each attribute level is assumed to be the most likely value. The attributes are assumed to be statistically independent from each other.

    17. UTILITY ASSESSMENTS This example explore the design selection of a cordless power tool. Two attributes are considered, and there are five competing design alternatives as shown in the figure. The uncertainty in the attribute levels are assumed to be normal with the following parameters. The nominal value of each attribute level is assumed to be the most likely value. The attributes are assumed to be statistically independent from each other.This example explore the design selection of a cordless power tool. Two attributes are considered, and there are five competing design alternatives as shown in the figure. The uncertainty in the attribute levels are assumed to be normal with the following parameters. The nominal value of each attribute level is assumed to be the most likely value. The attributes are assumed to be statistically independent from each other.

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