Introduction of a Product Family Penalty Function Using Physical Programming

2002 ◽  
Vol 124 (2) ◽  
pp. 164-172 ◽  
Author(s):  
Achille Messac ◽  
Michael P. Martinez ◽  
Timothy W. Simpson
Keyword(s):  
Penalty Function ◽  
Product Family ◽  
Product Variety ◽  
Product Platform ◽  
Product Families ◽  
Physical Programming ◽  
Product Platforms ◽  
Scaling Parameters ◽  
The Common ◽  
Selection Of

In an effort to increase customization for today’s highly competitive global markets, many companies are looking to product families to increase product variety and shorten product lead-times while reducing costs. The key to a successful product family is the common product platform around which the product family is derived. Building on our previous work in product family design, we introduce a product family penalty function (PFPF) in this paper to aid in the selection of common and scaling parameters for families of products derived from scalable product platforms. The implementation of the PFPF utilizes the powerful physical programming paradigm to formulate the problem in terms of physically meaningful parameters. To demonstrate the proposed approach, a family of electric motors is developed and compared against previous results. We find that the PFPF enables us to properly balance commonality and performance within the product family through the judicious selection of the common parameters that constitute the product platform and the scaling parameters used to instantiate the product family.

A Product Variety Tradeoff Evaluation Method for a Family of Cordless Drill Transmissions

1999 ◽  
Author(s):  
Carolyn G. Conner ◽  
Joseph P. De Kroon ◽  
Farrokh Mistree
Keyword(s):  
Evaluation Method ◽  
Product Family ◽  
Product Variety ◽  
Product Performance ◽  
Product Platform ◽  
Product Platforms ◽  
Individual Product ◽  
Alternative Product ◽  
Per Se

Abstract In this paper we present the Product Variety Tradeoff Evaluation Method for assessment of alternative product platforms in product family design. The Product Variety Tradeoff Evaluation Method is an attention-directing tool for evaluating tradeoffs between commonality and individual product performance for product platform alternatives with differing levels of commonality. We apply the Product Variety Tradeoff Evaluation Method to a case study in transmission redesign for a family of cordless drills. The emphasis in this paper is placed on the method rather than on the results, per se.

Two Methodologies for Identifying Product Platform Elements Within an Existing Set of Products

2006 ◽  
Author(s):  
Elizabeth D. Steva ◽  
Elizabeth N. Rice ◽  
Tucker J. Marion ◽  
Timothy W. Simpson ◽  
Robert B. Stone
Keyword(s):  
Product Family ◽  
Product Variety ◽  
Successful Implementation ◽  
Product Families ◽  
Product Platforms ◽  
Design Structure ◽  
Development Costs ◽  
Family Analysis ◽  
Depth Analysis ◽  
Single Use

As companies are pressured to decrease product development costs concurrently with increasing product variety, the need to develop products based upon common components and platforms is growing. Determining why a platform worked, or alternatively why it did not, is an important step in the successful implementation of product families and product platforms in any industry. Unfortunately, published literature on platform identification and product family analysis using product dissection and reverse engineering methods is surprisingly sparse. This paper introduces two platform identification methodologies that use different combinations of tools that can be readily applied based on information obtained directly from product dissection. The first methodology uses only the Bills-of-Materials and Design Structure Matrices while the second utilizes function diagrams, Function-Component Matrices, Product-Vector Matrices, and Design Structure Matrices to perform a more in-depth analysis of the set of products. Both methodologies are used to identify the platform elements in a set of five single-use cameras available in the market. The proposed methodologies identify the film advance and shutter actuation platform elements of the cameras, which include seven distinct components. The results are discussed in detail along with limitations of these two methodologies.

Comprehensive Product Platform Planning (CP3) Framework

2011 ◽  
Vol 133 (10) ◽  
Author(s):  
Souma Chowdhury ◽  
Achille Messac ◽  
Ritesh A Khire
Keyword(s):  
Planning Process ◽  
Continuous Optimization ◽  
Product Family ◽  
Mapping Function ◽  
Mixed Integer ◽  
Product Platform ◽  
Production Volume ◽  
Product Families ◽  
Product Platforms ◽  
Design Variables

Development of a family of products that satisfies different market niches introduces significant challenges to today’s manufacturing industries—from development time to aftermarket services. A product family with a common platform paradigm offers a powerful solution to these daunting challenges. This paper presents a new approach, the Comprehensive Product Platform Planning (CP3) framework, to design optimal product platforms. The CP3 framework formulates a generalized mathematical model for the complex platform planning process. This model (i) is independent of the solution strategy, (ii) allows the formation of sub-families of products, (iii) allows the simultaneous identification of platform design variables and the determination of the corresponding variable values, and (iv) seeks to avoid traditional distinctions between modular and scalable product families from the optimization standpoint. The CP3 model yields a mixed integer nonlinear programming problem, which is carefully reformulated to allow for the application of continuous optimization using a novel Platform Segregating Mapping Function (PSMF). The PSMF can be employed using any standard global optimization methodology (hence not restrictive); particle swarm optimization has been used in this paper. A preliminary cost function is developed to represent the cost of a product family as a function of the number of products manufactured and the commonality among these products. The proposed CP3 framework is successfully implemented on a family of universal electric motors. Key observations are made regarding the sensitivity of the optimized product platform to the intended production volume.

Effective Product Family Design Using Physical Programming and the Product Platform Concept Exploration Method

2000 ◽  
Author(s):  
Achille Messac ◽  
Michael P. Martinez ◽  
Timothy W. Simpson
Keyword(s):  
Product Family ◽  
Product Platform ◽  
The Novel ◽  
Customer Requirements ◽  
Product Family Design ◽  
Physical Programming ◽  
Product Platforms ◽  
Concept Exploration ◽  
Effective Product ◽  
Performance Gains

Abstract In an effort to produce more variety for today’s highly competitive market, companies are designing and developing families of products — groups of related products derived from common product platforms — to simultaneously satisfy multiple customer requirements. After reviewing the state of the art in product family and product platform design, we describe the Product Platform Concept Exploration Method (PPCEM) for designing common product platforms that can be scaled or “stretched” into a suitable family of products. This paper extends previous work by the authors through the novel integration of physical programming within the PPCEM to enable the product family design problem to be formulated using physically meaningful terms and preferences. The design of a family of universal electric motors is presented to demonstrate the effectiveness of the proposed approach. Performance gains are achieved in the motor family by utilizing physical programming within the PPCEM when compared to previous results.

Identification of Platform Variables in Product Family Design Using Sensitivity Analysis

2012 ◽  
Author(s):  
Chad Hume ◽  
David W. Rosen
Keyword(s):  
Sensitivity Analysis ◽  
Effective Means ◽  
Product Family ◽  
Product Variety ◽  
Product Performance ◽  
Constructal Theory ◽  
Product Platform ◽  
Product Family Design ◽  
The Impact ◽  
Selection Of

Product family design strategies based on a common core platform have emerged as an efficient and effective means of providing product variety. The main goal in product platform design is to maximize internal commonality within the family while managing the inherent loss in product performance. Therefore, identification and selection of platform variables is a key aspect when designing a family of products. Based on previous research, the Product Platform Constructal Theory Method (PPCTM) provides a systematic approach for developing customizable products, while allowing for multiple levels of commonality, multiple product specifications, and balancing the tradeoffs between commonality and performance. However, selection of platform variables and the modes for managing product variety are not guided by a systematic process in this method. When developing a platform with more than a few variables, a quantitative method is needed for selecting the optimal platform variable hierarchy. In this paper we present an augmented PPCTM which includes sensitivity analysis of platform variables, such that hierarchical rank is conducted based on the impact of the variables on the product performance. This method is applied to the design of a line of customizable finger pumps.

scholarly journals Product platform design and customization: Status and promise

2004 ◽  
Vol 18 (1) ◽  
pp. 3-20 ◽  
Author(s):  
TIMOTHY W. SIMPSON
Keyword(s):  
Product Development ◽  
Product Family ◽  
Lead Times ◽  
Product Platform ◽  
Product Family Design ◽  
Research Activity ◽  
Global Marketplace ◽  
Product Families ◽  
Web Based ◽  
Product Platforms

In an effort to improve customization for today's highly competitive global marketplace, many companies are utilizing product families and platform-based product development to increase variety, shorten lead times, and reduce costs. The key to a successful product family is the product platform from which it is derived either by adding, removing, or substituting one or more modules to the platform or by scaling the platform in one or more dimensions to target specific market niches. This nascent field of engineering design has matured rapidly in the past decade, and this paper provides a comprehensive review of the flurry of research activity that has occurred during that time to facilitate product family design and platform-based product development for mass customization. Techniques for identifying platform leveraging strategies within a product family are reviewed along with metrics for assessing the effectiveness of product platforms and product families. Special emphasis is placed on optimization approaches and artificial intelligence techniques to assist in the process of product family design and platform-based product development. Web-based systems for product platform customization are also discussed. Examples from both industry and academia are presented throughout the paper to highlight the benefits of product families and product platforms. The paper concludes with a discussion of potential areas of research to help bridge the gap between planning and managing families of products and designing and manufacturing them.

Optimal Kinematics Design of an Industrial Robot Family

2008 ◽  
Author(s):  
Johan O¨lvander ◽  
Xiaolong Feng ◽  
Bo Holmgren
Keyword(s):  
Mass Customization ◽  
Industrial Robot ◽  
Product Family ◽  
Industrial Robots ◽  
Mathematical Framework ◽  
Product Family Design ◽  
Product Families ◽  
The Common ◽  
Object Of Study ◽  
Common Platform

Product family design is a well recognized method to address the demands of mass customization. A potential drawback of product families is that the performance of individual members are reduced due to the constraints added by the common platform, i.e. parts and components need to be shared by other family members. This paper presents a formal mathematical framework where the product family design problem is stated as an optimization problem and where optimization is used to find an optimal product family. The object of study is kinematics design of a family of industrial robots. The robot is a serial manipulator where different robots share arms from a common platform. The objective is to show the trade-off between the size of the common platform and the kinematics performance of the robot.

A Tool to Integrate Design for Assembly During Product Platform Design

2008 ◽  
Author(s):  
Amar Pandit ◽  
Zahed Siddique
Keyword(s):  
Product Family ◽  
Product Platform ◽  
Design For Assembly ◽  
Design And Development ◽  
Single Product ◽  
Entire Family ◽  
Platform Design ◽  
Product Families ◽  
Integrate Design

To survive in the current market, many companies are moving toward design and development of product families using a platform approach. To effectively develop a family of products, companies have to consider both component and assembly perspectives. The assembly perspective has many issues associated with it for developing common platforms, which includes assemblability evaluation for the entire family. Application of Design for Assembly techniques to evaluate product family will require modifications to the current single product DFA method. In this paper a product family DFA tool and guidelines are presented. The application of this product family DFA tool is illustrated using Walkman® and Coffeemaker product family.

Knowledge Model for Managing Product Variety and Its Reflective Design Process

2006 ◽  
Author(s):  
Yutaka Nomaguchi ◽  
Tomohiro Taguchi ◽  
Kikuo Fujita
Keyword(s):  
Design Process ◽  
Product Family ◽  
Product Variety ◽  
Product Architecture ◽  
Air Conditioner ◽  
Knowledge Model ◽  
Product Families ◽  
Reflective Process ◽  
Reflective Design ◽  
Computer Based

Recent manufacturers have been utilizing product families to diversify and enhance the product performance by simultaneously designing multiple products under commonalization and standardization. Design information of product architecture and family is inevitably more complicated and numerous than that of a single product. Thus, more sophisticated computer-based support system is required for product architecture and family design. This paper proposes a knowledge model for a computer-based system to support reflective process of designing product architecture and product family. This research focuses on three problems which should be overcome when product family are modeled in the computer system; design repository without data redundancy and incorrectness, knowledge acquisition without forcing the additional effort on the designer, and integration of prescriptive models to support early stages of the design process. An ontology that is a foundation of a knowledge model is defined to resolve these problems. An example of designing an air conditioner product family is shown to demonstrate the capability of the system.

Advancements in a Web-Based Framework in Product Family Optimization and Visualization

2004 ◽  
Author(s):  
Jessica L. Mulberger ◽  
Timothy W. Simpson
Keyword(s):  
Design Process ◽  
Product Family ◽  
Aircraft Design ◽  
Product Variety ◽  
General Aviation ◽  
Design Parameters ◽  
Web Based ◽  
Ongoing Research ◽  
Product Platforms ◽  
Number Of Customers

Today’s market is becoming increasingly more competitive as companies strive to achieve success by reaching a large number of customers in a mass market while simultaneously treating them as individuals in a customized market. Many companies have begun to appreciate the benefits of using product platforms as they increase the customizability of their offered products, while reducing development costs and time to market. However, product variety is not customization; it is simply an attempt on the part of a company to meet the individual needs of their customers by flooding the market with many variations of the same product. With recent innovations in the field of information technology, web-based product development methodologies provide the capability for advanced customer involvement during the design process, which is a crucial aspect of differentiating customization from variety. Current approaches have provided web-based frameworks where users are offered a limited amount of control in the design process by assembling different configurations of given modules or by choosing a product already available in the company database. The focus in this paper is on advancements to a web-based framework where design parameters are collected from the user by means of a web-based browser interface, optimization is completed using the specified parameters, and a 3D visual representation is dynamically provided based on the results from the optimization. This proposed framework is illustrated using an example from ongoing research involving General Aviation Aircraft design.

Sign in / Sign up

Export Citation Format

Share Document