INTEGRATED OPTIMIZATION OF FUNCTIONAL

AND LAYOUT DESIGNS BASED ON GENETIC ALGORITHM

Consideration of Carbon Emission troughout Product’s Lifecycle

Masakazu Kobayashi and Masatake Higashi

Toyota Technological Institute, 2-12-1 Hisakata, Tempaku, Nagoya, Japan

Keywords: Design optimization, Conceptual design, Lifecycle assessment, Functional design, Layout design,

Hierarchical optimization, Genetic algorithm.

Abstract: In our previous research, the integrated optimization of functional / layout designs based on genetic

algorithm was developed for supporting conceptual design phase. This method can optimize a functional

structure and a parts layout simultaneously by evaluating performance, cost and size. In this paper, we now

focus on consideration of lifecycle characteristics in response to rise of environmental awareness in recent

years and combine our previous integrated method with lifecycle assessment (LCA) in order to enable

creation of product concepts that balance various characteristics including lifecycle ones at a higher level.

This paper also shows an application of the proposed method to a personal computer design and discusses

the effect of consideration of lifecycle characteristics during conceptual optimization.

1 INTRODUCTION

Due to rise of environmental awareness in recent

years, companies are required to assess and improve

various product lifecycle characteristics such as

carbon emission. To evaluate them, ISO14040

series, which describe the principles and framework

for LCA, were established and various commercial

LCA software such as GaBi, SimaPro and JEMAI

LCA pro was developed. However, since not only

lifecycle characteristics but also product’s primary

ones such as performance, cost and size need to be

simultaneously considered for creating an attractive

product, designers are forced to take a great deal of

time and effort to balance them at a higher level.

Based on the above background, this paper

proposes a new integrated optimization method for

creating product concepts that balance various

characteristics including lifecycle ones at a higher

level, based on our integrated optimization method

(Kobayashi, Suzuki and Higashi, 2009). Our

previous method is the integration of functional /

layout optimization based on genetic algorithm for

supporting a conceptual design phase. During a

conceptual design phase, since there are various

decision-makings, designers are asked to make

optimal decisions to create great product concepts by

considering various valuation characteristics such as

performance, cost and size. However, since

functional / layout designs, which are main two tasks

of a conceptual design phase, are very different tasks,

their design problems are highly hierarchized and

their solution spaces are vast, it is extremely difficult

for designers to build up great concepts only with

their own decision makings. To overcome such

difficulty, functional / layout optimization are

combined and executed cooperatively in our method.

Using this method, both a functional structure and a

parts layout that satisfy various characteristics at a

high level can be obtained. The method proposed in

this paper is based on our previous method and LCA,

which combination enables a design of a product

concept with consideration of various characteristics

including lifecycle ones.

2 INTEGRATED OPTIMIZATION

METHOD

2.1 Overview

This paper proposes an integrated method for

optimizing a functional structure and a parts layout

by considering various characteristics including

344

Kobayashi M. and Higashi M..

INTEGRATED OPTIMIZATION OF FUNCTIONAL AND LAYOUT DESIGNS BASED ON GENETIC ALGORITHM - Consideration of Carbon Emission

troughout Product’s Lifecycle.

DOI: 10.5220/0003077203440347

In Proceedings of the International Conference on Evolutionary Computation (ICEC-2010), pages 344-347

ISBN: 978-989-8425-31-7

 2010 SCITEPRESS (Science and Technology Publications, Lda.)

lifecycle ones, based on our previous method.

Improved point is to integrate lifecycle assessment

in order to consider its results as one of valuation

characteristics of the integrated optimization.

Figure 1 shows the overview of the proposed

integrated optimization method. As shown in this

figure, this method consists of functional / layout

optimization plus LCA. Functional optimization is

the main part of the proposed method and executed

just one time. Functional optimization is based on

the hierarchical genetic algorithm (HGA)

(Yoshimura and Izui, 2002) in order to consider

hierarchical nature of a functional structure. In the

proposed method, performance, cost, total area and

total carbon emission are considered as valuation

characteristics of the functional optimization. Any of

them can be configured as an objective function and

the rest of them are configured as constraint

conditions. The proposed method assumes that

performance and cost can be calculated by simply

summing up the values associated with each part,

whereas total area and total carbon emission can not

be calculated by simple summation. Therefore,

layout optimization and LCA are repeatedly invoked

from the functional optimization to obtain the layout

with minimum area and total carbon emissions

respectively for every design proposal and for every

generation of the functional optimization. Layout

optimization is based on the traditional genetic

algorithm and the sequence-pair representation

(Murata, Fujiyoshi, Nakatake, and Kajitani, 1996).

Generation of solutions

Evaluation of solutions

Layout optimization

using GA

Iteration

•Performance

•Carbon emission

•Cost

•Area

(Selection, crossover, mutation)

Functional optimization using HGA

Optimal solution

Functional structure including alternatives

•Optimal functional structure

•Optimal layout

Lifecycle assessment

Area

Figure 1: Overview of the integrated optimization.

Due to space limitation, the following section

only describes the part of LCA. See the reference

(Kobayashi, Suzuki and Higashi, 2009) for the

details of functional / layout optimization and their

integration.

2.2 Lifecycle Assessment

In the practical LCA, there are various valuation

characteristics such as emissions of CO2, SOx and

NOx throughout entire product’s lifecycle, usage

rate of renewable material and reuse / recycle rate.

This paper adopts carbon emission as a valuation

characteristic of the propsoed method, because CO

reduction is one of most interested problems in order

to fight global warming in recent years. Total carbon

emission of each design proposal obtained during

functional optimization processes is calculated by

the following concepts.

(a) Value of carbon emissions is evaluated and

configurated for each part by executing LCA.

(b) All parts can be classified into two types. One

has the fixed value of carbon emissions and the other

has the value of carbon emissions per unit area.

Most parts belong to the former type, whereas an

electronic substrate, for example, belongs to the

latter type. Actual value of carbon emissions of the

latter type is calculated by multiplying unit carbon

emissions by the area calculated by layout

optimization.

GHG

total

is defined by the below equation.







itotal

uGHGAreaGHGGHG

(1)

Where GHG

is the fixed value of carbon emissions

of part i, whereas, uGHG

is the value of carbon

emissions per unit area of part j. Area

is the value of

area of part j.

3 CASE STUDY

3.1 Problem Description

In the case study, internal devices of a personal

computer are designed using the proposed method .

“Internal devices” means that input devices, a

display and an enclosure are not included.

A computer consists of the following 5

components: motherboard, HDD, cooling system,

power supply and auxiliary storage. Motherboard,

cooling system and power supply can be

decomposed into more than one part, whereas HDD

and auxiliary storage can not be decomposed any

more. Table 1 shows an example of their alternatives.

Prices and sizes are configured by surveying their

retail price and measuring their size. Performances

INTEGRATED OPTIMIZATION OF FUNCTIONAL AND LAYOUT DESIGNS BASED ON GENETIC ALGORITHM -

Consideration of Carbon Emission troughout Product's Lifecycle

345

Supply

Power

Read/Write

Outer information

Process

Information

Storage

Inter information

Battery

Optical drive

Memory card

reader

HDD

Process

Information

Personal ComputerPersonal Computer

DVD combo

Super multi A

Super multi B

DVD combo

Super multi A

Super multi B

SD memory reader

CF memory reader

SD memory reader

CF memory reader

Motherboard B

Power supply

Discard

Heat

Cooler

Control

Power

Controller

Convert Electric

power to Torque

Motor

Generate

Wind

Fan

80mm Fan

120mm Fan

Convert Electric

power to Torque

Motor

Generate

Wind

Fan

80mm Fan

120mm Fan

Process

Information

Store Data

Transfer

Data

Other

functions

Chipset

Atom Z530

Atom Z520

Atom Z540

Atom Z530

Atom Z520

Atom Z540

DDR2-533 1G

DDR2-533 2G A

DDR2-533 2G B

DDR2-533 1G

DDR2-533 2G A

DDR2-533 2G B

Support

communication

Motherboard A

WLAN module A

WLAN module B

Support Wireless

communication

WLAN module

TV tuner A

TV tuner B

Receive TV

TV tuner

Other

functions

Other

devices

WLAN module A

WLAN module B

Support Wireless

communication

WLAN module

TV tuner A

TV tuner B

Receive TV

TV tuner

Other

functions

Other

devices

Other

devices

Other

devices

Sub-boardDIMMCPU

MK8009GAH

WD1600BEVT

WD5000AAKB

MK8009GAH

WD1600BEVT

WD5000AAKB

MK1214GAH

WD3200BEVT

WD1002FBYS

MK1214GAH

WD3200BEVT

WD1002FBYS

Lithium polymer A,B

Lithium ion A,B

Discard

Heat

Cooling system

Remove

Heat

Convey

Heat

Cooler

Heat pipe

Radiation sheet

Generate

Wind

Motor

Fan

40mm Fan

60mm Fan

80mm Fan

Convert Electric

power to Torque

Generate

Wind

Motor

Motor FanFan

40mm Fan

60mm Fan

80mm Fan

Convert Electric

power to Torque

Sheet A

Sheet B

Figure 2: Functional structure designed in the case study.

are subjectively and intuitively configured.

Carbon emissions are configured by surveying the

reference (Japan Environmental Management

Association For Industry, 2007). Figure 2 shows the

functional structure of a personal computer used

here. Note that, due to space limitation, the lower

functional structure of Motherboard B is not

described here. Motherboard B is similar to

Motherboard A, but has powerful CPU, more

Memory and discrete graphic card.

In the case study, performance is handled as an

objective function, whereas cost, total area and total

carbon emission are handled as constraint conditions.

Table 1: Examples of parts specifications.

Cost

(USD)

Dimension

(cm)

Perfor

mance

(kg)

SD memory reade

25 2.4*3.2 3 0.13

CF memory reader 130 4.3*3.6 2 0.27

CD-R/RW/DVD combo 80 12.8*13.0 7 2.87

Super multi drive A

130 12.8*13.0 8 2.87

Super multi drive B

260 12.8*13.0 10 2.87

3.2 Results

Figure 3 shows the results from the use of our

previous method that does not consider carbon

emission. In this case, optimizations ars executed 12

times under 12 various cost constraints from 550

USD to 2550 USD and constant area constraint

(Area < 1200 cm

). Parameters of HGA and GA are

shown in Tabel 2. The optimal layouts of the design

solutions denoted by two stars in Figure 3 are shown

in Figure 4. Whereas, Figure 5 shows the result from

the use of the proposed method that considers

carbon emission. In this case, optimizations are also

executed 12 times under 12 various constraints of

carbon emission from 5 kg to 50 kg and constant

constraints (Cost < 3000 USD and Area < 1500 cm

Parameters of HGA and GA shown in Table 2 are

also used in this case.

Table 2: Parameters of HGA and GA.

HGA GA

Population 100 60

Crossover rate 1 1

Mutation rate 0.05 0.01

Generation gap 0.9 0.5

Terminal generation 200 50

100

120

500 1000 1500 2000 2500 3000

Cost

Performance

Figure 3: Relationships between performance and cost of

obtained solutions.

ICEC 2010 - International Conference on Evolutionary Computation

346

Battery

Cooling

system

HDD

Card reader

Motherboard

240mm

174mm

Motherboard

HDD

Cooling

system

Power supply

Optical

drive

240mm

Figure 4: Optimal layouts (Left: Star 1, Right: Star 2).

100

120

0 102030405060

Carbon emission

Performance

Figure 5: Relationships between performance and carbon

emission of obtained solutions.

A Comparison between two results shows that a

constraint of carbon emission makes it difficult to

design a high performance PC even if constraints of

cost and area are sufficiently relaxed. This is

because high performance parts used in the case

study have a tendency to emit a lot of CO

throughout their lifecycle. These results show that

the proposed method can obtain a optimal product

concept with consideration of various characteristics

including carbon emission.

4 CONCLUSIONS

To create optimum product concepts that balance

product primary characteristics such as performance

and cost and product lifecycle ones such as carbon

emissions at a higher level in response to rise of

environmental awareness in recent years, this paper

combines LCA with our previous method that

integrates functional / layout optimization. Using the

proposed method, optimal functional structure and

parts layout can be obtained by considering various

characteristics including lifecycle ones. Although

consideration of lifecycle characteristics are

indispensable in recent product development, not

only lifecycle characteristics but also product’s

primary ones such as performance and cost need to

be simultaneously considered and balanced at a

higher level for creating an attractive product. This

is why the proposed method is quite useful.

In the case study, the proposed method is applied

to a design of a personal computer and the results

show the effect of consideration of lifecycle

characteristics during conceptual design phase.

As for future works, we are planning to improve

the following points.

(1) For practical products, since connections

between components or parts have crucial roles such

as force transmission and object transport, their

consideration is the first issue to be settled.

(2) For practical products, since parts have many

different appearances and are placed in 3D space,

consideration of a three-dimensional layout with

arbitrary part shape is required to extend the range of

application of the proposed method.

(3) In the proposed method, only carbon emission is

considered. Consideration of lifecycle characteristics

in addition to carbon emission will improve the

effectiveness of the proposed method.

ACKNOWLEDGEMENTS

This study was supported in part by a grant of

Strategic Research Foundation Grant-aided Project

for Private Universities from Ministry of Education,

Culture, Sport, Science, and Technology, Japan

(MEXT), 2008-2012 (S0801058).

REFERENCES

Yoshimura, M. and Izui, K. (2002). Smart Optimization of

Machine Systems Using Hierarchical Genotype

Representations. Transaction of ASME, Journal of

Mechanical Design, 124, 375-384.

Kobayashi, M., Suzuki, Y. and Higashi, M. (2009).

Integrated Optimization for Supporting Functional and

Layout Designs during Conceptual Design Phase.

Proceedings from IDETC/CIE 2009: ASME 2009

International Design Engineering Technical

Conferences & Computers and Information in

Engineering Conference, San Diego, CA.

Murata, H., Fujiyoshi, K., Nakatake, S. and Kajitani, Y.

(1996). VLSI Module Placement Based on Rectangle-

Packing by the Sequence-Pair. IEEE Transactions on

Computer-Aided Design of Integrated Circuits and

Systems, 15(12), 1518-1524.

Japan Environmental Management Association for

Industry (2007). Implementation manual of product

LCA.

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Consideration of Carbon Emission troughout Product's Lifecycle

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