Multivariate Quality Loss Model and its Coefficient Determination

doi:10.4236/jssm.2010.31013

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J. Service Science & Management, 2010, 3: 106-109

doi:10.4236/jssm.2010.31013 Published Online March 2010 (http://www.SciRP.org/journal/jssm)

Multivariate Quality Loss Model and its

Coefficient Determination

Shuhai Fan, Xia Cao

Department of Industrial Engineering, Nanjing University of Technology, Nanjing, China.

Email: fanshuhai@tsinghua.org.cn

Received August 28th, 2009; revised October 10th, 2009; accepted November 27th, 2009.

ABSTRACT

In the ea rly 1970s, based on single ind ex deducted from absolut e quality deviants, Genichi Taguchi proposed th e qual-

ity loss module. This module builds the foundation of his three-stage design theory, e.g. system design, parameter de-

sign and tolerance design. In actual production process, nevertheless, it is multiple quality indices that influence the

total quality. Consequently, the interaction of the quality indices should be imported into the module as a key factor.

Accordingly, based on several indices of relative quality deviation, introduce a 2-order multivariate quality module at

first. Next, extend the module to 3 or even higher orders. Then, improve the previous quality module by simplifying the

2-order module as a multivariate quality loss module. Finally, bring forward a significant solution to determinate all

the coefficients in th e multivariate quality loss module and describe its work flow as well.

Keywords: Quality Loss, Multiple Variables, Model Building

1. Introduction

In the early 1970s, Dr. Genichi Taguchi, the famous

quality management expert of Japan, carried on an inno-

vation research into the theories and methods of quality

management [1]. He established the famous “Taguchi

Three-stage Design Methods”, the system design, the

parameter design and the tolerance design. The core of

his theory was his quality loss model [2,3]. And the qual-

ity loss model was based on the absolute quality deviant,

which suited for the single quality index. However, in the

actual production process, many partial quality indices

often affected the total quality in a coactions mode. After

these interactions being considered, a multivariate quality

loss mode can be brought forward [4].

To this many partial quality indices, Chan and Ibrahim

studied a quality evaluation model using loss function for

multiple S-type quality characteristics [5]. To determi-

nate the coefficients of the multivariate quality loss mode,

AHP method or tolerance method can be used [6,7].

2. Model Building

The total quality is a synthetic quality, which is often a

coaction of some machining qualities and some assem-

bling qualities of every part [1]. And it can be regarded

as a function of every partial quality (including the ma-

chining qualities and the assembling qualities):

product1 2

( ,,... ...,)

QfQQQQ

Assuming that f has continuous partial derivatives till

3-order in a neighborhood D of the origin, P0(0,0…0).

There are H partial quality indices altogether, q1, q2, …

qH. These partial quality indices are all continuous types;

their values are very small and stand for relative quality

deviants. When the values of q1, q2,…qH equal 0, it

stands for no quality deviant (Here we use the relative

quality deviants to get dimensionless. Thus a minor error

can be avoided in the derivation process of Taguchi’s

model.) [8]. Then the product quality can be expressed as

follows:

( ,...,...,)(0,0...,0)(0,0...,0)

(0,0...,0)

hHQ h

QQh h

fqq qqffq

qq R













while, R2 is the 2-order remainder term.

123

12 3

,, 1

1( ......)

3! hhh

QQQhHh hh

hh h

Rfqqqqqq









(0 1)





A brief proof is as follows:

considering a single variant function ()Qt

( )(,...,...,)

Qt fqtqtqtqt



, (1 1)t

Multivariate Quality Loss Model and Its Coefficient Determination

107

()Qt has continuous partial derivatives till 3-order for

(1 1)t .

Obeying the 2-order single variant Talylor’s formula

with Lagrange remainder term, we get:

( )(0)(0)(0)()

2! 3!

Qt QQtQtQ tt



 

 ,(0 1)





Let t=1, we get

(1)(0)(0)(0)( )

2! 3!

QQQ QQ





  (1)

Follow the definition of ()Qt and the differential

method of composite function. We get

( )(,...,...,)

QhHh

Qtfqt qtqtq







( )(,...,...,)

QQhHh h

Qtfqt qtqtqq



 



12 3

123

,, 1

( )(,...,...,)

hhh

QQQhHh hh

hhh

Qtfqt qtqtqqq



 



Then, when t =0,

(0) (0,...0,...,0)

Qf q







(0) (0,...0,...,0)

QQh h

Qf qq



 



123

,, 1

(0) (0,...0,...,0)

hh h

QQQh hh

hhh

Qf qqq



 



while

(1)( ,...,...,)

Qfqqqq,

(0) (0,...,0...,0)Qf

Substitute the results into (1)

The expansion equation can get proved.

To estimate the error term, we have:

f has continuous partial derivatives till 3-order; in the

neighborhood of (0,…,0,…0); the 3-order partial deriva-

tive has a bound M.

denote

22 22

...

qq qq









, (0)





then

123

212

,, 1

(... )

3! 3!

hhh H

hhh

Rqqqqqq







=(...)

3! 3!

Hhh

qq qqq





 









222

1()

3! 2

(...)

Mqq

MHq qq























 

=3! 3!

Hq H















2()Ro



 , (0)





It is the general form that is used to describe the total

quality index in the above formula. If the quality loss

form index is adopted, the model can be much more sim-

plified. Imply that when all the partial quality indices

equal 0, the total quality index takes the minimum, 0. It

is easy to see that the 0-order and 1-order derivative can

be gotten rid of. Then a new product quality loss model

can be built as follows:

212 1 2

112

product

11,

hhhhh

hhhh

Qwq wqq







(2)

Compared it with Taguchi’s model, we can see that (2)

is actually the extended multivariate form of Taguchi’s

quality loss model.

Here, Qproduct is a target total quality index and de-

scribed as the quality loss. All the n partial quality indi-

ces influence Qproduct in a coaction mode, and qh is the

relative quality deviant. Every partial quality deviant can

be gotten by statistic. Here we use the relative partial

quality deviant, and it can be expressed by the relative

quality value of the deviant from the target value and

severalfold tolerances. If the value of quality characteris-

tic lies beyond the tolerance, it should be multiplied by a

punishment factor.

where, 2



, 1212

112

hhh h

hhh

wqq



 are separately the

self-action item and the inter-action item of the partial

quality deviants. 2

w is the self-action influence weight

of the quality deviant 2h

q; 12

w is the inter-action

weight of deviant 12

qq .

Compared with our expansion equation, it can be got-

ten

22 2

(0,...,0,...0)(0,...,0,...0)

2! 2

hQ Q

wf f

 



12 12

12 21

12 12

1(0,...,0,...0)

1(0,...,0,...0) (0,...,0,...0)

=(0,...,0,...0) ()

hh hh

hhQQ

QQ QQ







 





 

If necessary, we can also expand the product quality

model further more to U-order.

Multivariate Quality Loss Model and Its Coefficient Determination

108



()

product ...

2,,...1

10, 0..., 0...

!hh hu

uQQQhhhU

uhhh

QfqqqR





















()





When the quality model is expanded to 2-order, the

inter-actions of partial quality indices have been fully

considered. In fact, the impactions of items higher than

2-order are very little [10,11]. Thus for the simplification

of computation and the actual requirement, further higher

orders are never needed.

The above work suits the small-is-better and the nomi-

nal-is-best problems. The large-is-better problem can

also be reformed into a small-is-better problem.

3. Coefficient Determination

3.1 The Tolerance Limits Method

The quality loss model (2) can also be written as

product

11,





iiiij ij

iiij

Qwqwqq

(3)

the coefficients wij can be determined using the following

method all these wij (i≤j) can constitute a upper triangular

matrix like Figure 1.

1) Determine the elements in Diagonal for an arbitrary

i (i=1,2,..., H), when all the qk=0, (k≠i) i

 is the toler-

ance limit of defective for self quality and Ai is the self

quality loss when defective happens.

Then we have

product

11,

()

iiiiijijiii

iiij

QAwqwqqw



 



/( )

ii i i

wA

2) Determine other elements for an arbitrary i,j

(i,j=1,2,...,H, i≤j), when all the qk=0, (k≠i, k≠j), i



is the

tolerance limit of quality i for coaction quality i and j,



Figure 1. Upper triangular matrix of coefficients then, we

can determine these coefficients

is the tolerance limit of quality j for coaction quality i

and j and Aij is the coaction quality loss when coaction

defective happens.

Then we have

11,

0, 20,20,0,

()( )

productijiiiijij

iiij

ijij

iiijjjijij ijij

QAwqwqq

ww w



 

 



Thus we have

00,2 0,20,0,

()()/

ijij

ijijiiijjjijij ij

wAww









where

002

/( )

ii ii



, 002

/( )

wA

This coefficient determination process can be de-

scribed in Figure 2.

Remark:

In some particular circumstances,

0, 00,0

ij iijj





we have a simplified form

000 00

ijijijij

w AAA





 



3.2 Other Methods

To determinate the weight coefficients, the least square

method can also be adopt. However linear neural net-

works are more suitable [11–14]. The input weights of

the trained neural network are just the weight coefficients

of the model.

4. Conclusions

Based on the quality loss model of Taguchi, the total

quality model which is based on multivariate relative

quality deviants was studied. A 2-order product quality

model, which was based on several indices of relatively

quality deviation, was built. Then, the model was suc-

cessfully extended to 3 or even higher orders. To deduce

w11 w12w13w14 w15 w16w17

w22 w23w24w25 w26 w27

w33 w34w35w36 w37

w44 w45w46w47

w55 w56w57

w66 w67

w77

Figure 2. From the diagonal elements to other elements

Multivariate Quality Loss Model and Its Coefficient Determination

109

a simplified formula, a new simplified product quality

model (a multivariate quality loss model) was built and

the error of it was also analyzed. Finally, a useful

method of the coefficient determination was brought

forward to determinate all the coefficients in the mul-

tivariate quality loss model and the work flow of it was

also described.

However, in the complex product, the coupling factor,

structure layer and the number of parts may have a fur-

ther increase, and the quality loss model become more

and more complex. Then there are no enough data for the

determination of the coefficients and the calculation also

become more and more complex. To make full use of

historical data and similar data, a quick-response incre-

mental model of multivariate quality loss is needed. So it

should be in our further research.

5. Acknowledgment

This project was supported by National Natural Science

Foundation of China (70801036), Natural Science Foun-

dation of the Jiangsu Higher Education Institutions of

China (07KJB460045).

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