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Return on Marketing / 109
Journal of Marketing
Vol. 68 (January 2004), 109–127
Roland T. Rust, Katherine N. Lemon, & Valarie A. Zeithaml
Return on Marketing:
Using Customer Equity to Focus
Marketing Strategy
The authors present a unified strategic framework that enables competing marketing strategy options to be traded
off on the basis of projected financial return, which is operationalized as the change in a firm’s customer equity rel-
ative to the incremental expenditure necessary to produce the change. The change in the firm’s customer equity is
the change in its current and future customers’ lifetime values, summed across all customers in the industry. Each
customer’s lifetime value results from the frequency of category purchases, average quantity of purchase, and
brand-switching patterns combined with the firm’s contribution margin. The brand-switching matrix can be esti-
mated from either longitudinal panel data or cross-sectional survey data, using a logit choice model. Firms can ana-
lyze drivers that have the greatest impact, compare the drivers’ performance with that of competitors’ drivers, and
project return on investment from improvements in the drivers. To demonstrate how the approach can be imple-
mented in a specific corporate setting and to show the methods used to test and validate the model, the authors
illustrate a detailed application of the approach by using data from the airline industry. Their framework enables
what-if evaluation of marketing return on investment, which can include such criteria as return on quality, return on
advertising, return on loyalty programs, and even return on corporate citizenship, given a particular shift in cus-
tomer perceptions. This enables the firm to focus marketing efforts on strategic initiatives that generate the great-
est return.
Roland T. Rust is David Bruce Smith Chair in Marketing, Director of the
Center for e-Service, and Chair of the Department of Marketing, Robert H.
Smith School of Business, University of Maryland (rrust@rhsmith.umd.
edu). Katherine N. Lemon is Associate Professor, Wallace E. Carroll
School of Management, Boston College (e-mail: lemonka@bc.edu).
Valarie A. Zeithaml is Roy and Alice H. Richards Bicentennial Professor
and Senior Associate Dean, Kenan-Flagler School of Business, University
of North Carolina, Chapel Hill (e-mail: zeithamv@bschool.unc.edu). This
research was supported by the Marketing Science Institute, University of
Maryland’s Center for e-Service, and the Center for Service Marketing at
Vanderbilt University. The authors thank Northscott Grounsell, Ricardo
Erasso, and Harini Gokul for their help with data analysis, and they thank
Nevena Koukova, Samir Pathak, and Srikrishnan Venkatachari for their
help with background research. The authors are grateful for comments and
suggestions provided by executives from IBM, Sears, DuPont, General
Motors, Unilever, Siemens, Eli Lilly, R-Cubed, and Copernicus. They also
thank Kevin Clancy, Don Lehmann, Sajeev Varki, Jonathan Lee, Dennis
Gensch, Wagner Kamakura, Eric Paquette, Annie Takeuchi, and seminar
participants at Harvard Business School, INSEAD, London Business
School, University of Maryland, Cornell University, Tulane University, Uni-
versity of Pittsburgh, Emory University, University of Stockholm, Norwe-
gian School of Management, University of California at Davis, and Mon-
terrey Tech; and they thank participants in the following: American
Marketing Association (AMA) Frontiers in Services Conference, MSI Cus-
tomer Relationship Management Workshop, MSI Marketing Metrics Work-
shop, INFORMS Marketing Science Conference, AMA A/R/T Forum, AMA
Advanced School of Marketing Research, AMA Customer Relationship
Management Leadership Program, CATSCE, and QUIS 7.
The Marketing Strategy Problem
T
op managers are constantly faced with the problem of
how to trade off competing strategic marketing initia-
tives. For example, should the firm increase advertis-
ing, invest in a loyalty program, improve service quality, or
none of the above? Such high-level decisions are typically
left to the judgment of the chief marketing or chief executive
officers, but these executives frequently have little to base
their decisions on other than their own experience and intu-
ition. A unified, data-driven basis for making broad, strate-
gic marketing trade-offs has not been available. In this arti-
cle, we propose that trade-offs be made on the basis of
projected financial impact, and we provide a framework that
top managers can use to do this.
Financial Accountability
Although techniques exist for evaluating the financial return
from particular marketing expenditures (e.g., advertising,
direct mailings, sales promotion) given a longitudinal his-
tory of expenditures (for a review, see Berger et al. 2002),
the approaches have not produced a practical, high-level
model that can be used to trade off marketing strategies in
general. Furthermore, the requirement of a lengthy history
of longitudinal data has made the application of return on
investment (ROI) models fairly rare in marketing. As a
result, top management has too often viewed marketing
expenditures as short-term costs rather than long-term
investments and as financially unaccountable (Schultz and
Gronstedt 1997). Leading marketing companies consider
this problem so important that the Marketing Science Insti-
tute has established its highest priority for 2002–2004 as
“Assessing Marketing Productivity (Return on Marketing)
and Marketing Metrics.” We propose that firms achieve this
financial accountability by considering the effect of strategic
marketing expenditures on their customer equity and by
relating the improvement in customer equity to the expendi-
ture required to achieve it.
110 / Journal of Marketing, January 2004
1
For expositional simplicity, we assume throughout much of the
article that the firm has one brand and one market, and therefore we
use the terms “firm” and “brand” interchangeably. In many firms,
the firm’s customer equity may result from sales of several brands
and/or several distinct goods or services.
Customer Equity
Although the marketing concept has reflected a customer-
centered viewpoint since the 1960s (e.g., Kotler 1967), mar-
keting theory and practice have become increasingly
customer-centered during the past 40 years (Vavra 1997, pp.
6–8). For example, marketing has decreased its emphasis on
short-term transactions and has increased its focus on long-
term customer relationships (e.g., Håkansson 1982; Stor-
backa 1994). The customer-centered viewpoint is reflected
in the concepts and metrics that drive marketing manage-
ment, including such metrics as customer satisfaction
(Oliver 1980), market orientation (Narver and Slater 1990),
and customer value (Bolton and Drew 1991). In recent
years, customer lifetime value (CLV) and its implications
have received increasing attention (Berger and Nasr 1998;
Mulhern 1999; Reinartz and Kumar 2000). For example,
brand equity, a fundamentally product-centered concept, has
been challenged by the customer-centered concept of cus-
tomer equity (Blattberg and Deighton 1996; Blattberg, Getz
and Thomas 2001; Rust, Zeithaml, and Lemon 2000). For
the purposes of this article, and largely consistent with Blat-
tberg and Deighton (1996) but also given the possibility of
new customers (Hogan, Lemon, and Libai 2002), we define
customer equity as the total of the discounted lifetime values
summed over all of the firm’s current and potential
customers.
1
Our definition suggests that customers and customer
equity are more central to many firms than brands and brand
equity are, though current management practices and met-
rics do not yet fully reflect this shift. The shift from product-
centered thinking to customer-centered thinking implies the
need for an accompanying shift from product-based strategy
to customer-based strategy (Gale 1994; Kordupleski, Rust,
and Zahorik 1993). In other words, a firm’s strategic oppor-
tunities might be best viewed in terms of the firm’s opportu-
nity to improve the drivers of its customer equity.
Contribution of the Article
Because our article incorporates elements from several liter-
ature streams within the marketing literature, it is useful to
point out the relative contribution of the article. Table 1
shows the contribution of this article with respect to several
streams of literature that influenced the return on marketing
conceptual framework. Table 1 shows related influential lit-
erature streams and exemplars of the stream, and it high-
lights key features that differentiate the current effort from
previous work. For example, strategic portfolio models, as
Larreché and Srinivasan (1982) exemplify, consider strate-
gic trade-offs of any potential marketing expenditures. How-
ever, the models do not project ROI from specific expendi-
tures, do not model competition, and do not model the
behavior of individual customers, their customer-level brand
switching, or their lifetime value. Our model adds to the
strategic portfolio literature by incorporating those
elements.
Three related streams of literature involve CLV models
(Berger and Nasr 1998), direct marketing–motivated models
of customer equity (e.g., Blattberg and Deighton 1996; Blat-
tberg, Getz, and Thomas 2001), and longitudinal database
marketing models (e.g., Bolton, Lemon, and Verhoef 2004;
Reinartz and Kumar 2000). Our CLV model builds on these
approaches. However, the preceding models are restricted to
companies in which a longitudinal customer database exists
that contains marketing efforts that target each customer and
the associated customer responses. Unless the longitudinal
database involves panel data across several competitors, no
competitive effects can be modeled. Our model is more gen-
eral in that it does not require the existence of a longitudinal
database, and it can consider any marketing expenditure, not
only expenditures that are targeted one-to-one. We also
model competition and incorporate purchases from com-
petitors (or brand switching), in contrast to most existing
models from the direct marketing tradition.
The financial-impact element of our model is foreshad-
owed by two related literature streams. The service profit
chain (e.g., Heskett et al. 1994; Kamakura et al. 2002) and
return on quality (Rust, Zahorik, and Keiningham 1994,
1995) models both involve impact chains that relate service
quality to customer retention and profitability. The return on
quality models go a step farther and explicitly project finan-
cial return from prospective service improvements. Follow-
ing both literature streams, we also incorporate a chain of
effects that leads to financial impact. As does the return on
quality model, our model projects ROI. Unlike other mod-
els, our model facilitates strategic trade-offs of any prospec-
tive marketing expenditures (not only service improve-
ments). We explicitly model the effect of competition—an
element that does not appear in the service profit chain or
return on quality models. Also different from prior research,
our approach models customer utility, brand switching, and
lifetime value.
Finally, we compare the current article with a recent
book on customer equity (Rust, Zeithaml, and Lemon 2000)
that focuses on broad managerial issues related to customer
equity, such as building a managerial framework related to
value equity, brand equity, and relationship equity. The book
includes only one equation (which is inconsistent with the
models in this article). Our article is a necessary comple-
ment to the book, providing the statistical and implementa-
tion details necessary to implement the book’s customer
equity framework in practice. The current work extends the
book’s CLV conceptualization in two important ways: It
allows for heterogeneous interpurchase times, and it incor-
porates customer-specific brand-switching matrices. In sum-
mary, the current article has incorporated many influences,
but it makes a unique contribution to the literature.
Overview of the Article
In the next section, on the basis of a new model of CLV, we
describe how marketing actions link to customer equity and
financial return. The following section describes issues in
the implementation of our framework, including data
options, model input, and model estimation. We then present
Return on Marketing / 111
TABLE 1
Comparing the Return on Marketing Model with Existing Marketing Models
Strategic Brand
Trade- ROI Can Be Net Present Switching
offs of Any Modeled Explicitly Applied to Value of Modeled at
Type of Marketing and Models Calculation Most Revenues and Customer Statistical
Model Exemplars Expenditures Calculated? Competition? of CLV? Industries? Costs? Level? Details?
Strategic Larreché and Yes No No No Yes Yes No Yes
portfolio Srinivasan
(1982)
CLV Berger and No No No Yes No Yes No Yes
Nasr (1998)
Direct Blattberg and No Yes No Yes Yes Yes No Yes
marketing: Deighton
customer (1996);
equity Blattberg,
Getz, and
Thomas (2001)
Longitudinal Bolton, Lemon, and Yes Yes No, unless Yes No Yes No, unless Yes
database Verhoef (2004); panel data panel data
marketing Reinartz and
Kumar (2000)
Service profit Heskett et al. No No No No No No No Yes
chain (1994);
Kamakura et
al. (2002)
Return on Rust, Zahorik, No Yes No No Yes Yes No Yes
quality and
Keiningham
(1994,1995)
Customer Rust, Zeithaml, Yes Yes Yes Yes Yes Yes No No
equity book and Lemon
(2000)
Return on Current paper Yes Yes Yes Yes Yes Yes Yes Yes
marketing
112 / Journal of Marketing, January 2004
an example application to the airline industry, showing some
of the details that arise in application, in testing and validat-
ing our choice model, and in providing some substantive
observations. We end with discussion and conclusions.
Linking Marketing Actions to
Financial Return
Conceptual Model
Figure 1 shows a broad overview of the conceptual model
that we used to evaluate return on marketing. Marketing is
viewed as an investment (Srivastava, Shervani, and Fahey
1998) that produces an improvement in a driver of customer
equity (for simplicity of exposition, we refer to an improve-
ment in only one driver, but our model also accommodates
simultaneous improvement in multiple drivers). This leads
to improved customer perceptions (Simester et al. 2000),
which result in increased customer attraction and retention
(Danaher and Rust 1996). Better attraction and retention
lead to increased CLV (Berger and Nasr 1998) and customer
equity (Blattberg and Deighton 1996). The increase in cus-
tomer equity, when considered in relation to the cost of mar-
keting investment, results in a return on marketing invest-
ment. Central to our model is a new CLV model that incor-
porates brand switching.
Brand Switching and CLV
It has long been known that the consideration of competing
brands is a central element of brand choice (Guadagni and
Little 1983). Therefore, we begin with the assumption that
competition has an impact on each customer’s purchase
decisions, and we explicitly consider the relationship
between the focal brand and competitors’ brands. In con-
trast, most, if not all, CLV models address the effects of
marketing actions without considering competing brands.
This is because data that are typically available to direct
marketers rarely include information about the sales or pref-
erence for competing brands. Our approach incorporates
information about not only the focal brand but competing
brands as well, which enables us to create a model that con-
tains both customer attraction and retention in the context of
brand switching. The approach considers customer flows
from one competitor to another, which is analogous to
brand-switching models in consumer packaged goods (e.g.,
Massy, Montgomery, and Morrison 1970) and migration
models (Dwyer 1997). The advantage of the approach is that
competitive effects can be modeled, thereby yielding a fuller
and truer accounting of CLV and customer equity.
When are customers gone? Customer retention histori-
cally has been treated according to two assumptions (Jack-
son 1985). First, the “lost for good” assumption uses the
customer’s retention probability (often the retention rate in
the customer’s segment) as the probability that a firm’s cus-
tomer in one period is still the firm’s customer in the fol-
lowing period. Because the retention probability is typically
less than one, the probability that the customer is retained
declines over time. The implicit assumption is that cus-
tomers are “alive” until they “die,” after which they are lost
for good. Models for estimating the number of active cus-
tomers have been proposed for relationship marketing
(Schmittlein, Morrison, and Columbo 1987), customer
retention (Bolton 1998), and CLV (Reinartz 1999).
The second assumption is the “always a share” assump-
tion, in which customers may not give any firm all of their
business. Attempts have been made to model this by a
“migration model” (Berger and Nasr 1998; Dwyer 1997).
The migration model assigns a retention probability as pre-
viously, but if the customer has missed a period, a lower
probability is assigned to indicate the possibility that the
customer may return. Likewise, if the customer has been
gone for two periods, an even lower probability is assigned.
This is an incomplete model of switching because it
includes purchases from only one firm.
In one scenario (consistent with the lost-for-good
assumption) when the customer is gone, he or she is gone.
This approach systematically understates CLV to the extent
that it is possible for customers to return. In another scenario
(consistent with the migration model), the customer may
leave and return. In this scenario, customers may be either
serially monogamous or polygamous (Dowling and Uncles
FIGURE 1
Return on Marketing
Marketing investment
Driver improvement(s)
Improved
customer perceptions
Increased
customer
attraction
Increased
customer
retention
Increased CLV
Increased
customer equity
Cost of
marketing
investment
Return on marketing investment
Return on Marketing / 113
2
It is also possible to model the share-of-wallet scenario that is
common to business-to-business applications by using the concept
of fuzzy logic (e.g., Varki, Cooil, and Rust 2000; Wedel and
Steenkamp 1989, 1991).
3
The Pfeifer and Carraway (2000) Markov model considers only
one brand and does not capture brand switching. Its states pertain
to recency rather than brand.
1997), and their degrees of loyalty may vary or even change.
We can model the second (more realistic) scenario using a
Markov switching-matrix approach.
2
Acquisition and retention. Note that the brand-switching
matrix models both the acquisition and the retention of cus-
tomers. Acquisition is modeled by the flows from other
firms to the focal firm, and retention is modeled by the diag-
onal element associated with the focal firm. The retention
probability for a particular customer is the focal firm’s diag-
onal element, as a proportion of the sum of the probabilities
in the focal firm’s row of the switching matrix. Note that this
implies a different retention rate for each customer × firm
combination (we show the details of this in a subsequent
section). This describes the acquisition of customers who
are already in the market. In growing markets, it is also
important to model the acquisition of customers who are
new to the market.
The switching matrix and lifetime value. We propose a
general approach that uses a Markov switching matrix to
model customer retention, defection, and possible return.
Markov matrices have been widely used for many years to
model brand-switching behavior (e.g., Kalwani and Morri-
son 1977) and have recently been proposed for modeling
customer relationships (Pfeifer and Carraway 2000; Rust,
Zeithaml, and Lemon 2000). In such a model, the customer
has a probability of being retained by the brand in the sub-
sequent period or purchase occasion. This probability is the
retention probability, as is already widely used in CLV mod-
els. The Markov matrix includes retention probabilities for
all brands and models the customer’s probability of switch-
ing from any brand to any other brand.
3
This is the feature
that permits customers to leave and then return, perhaps
repeatedly. In general, this “returning” is confused with ini-
tial “acquisition” in other customer equity and CLV
approaches. The Markov matrix is a generalization of the
migration model and is expanded to include the perspective
of multiple brands.
To understand how the switching matrix relates to CLV,
consider a simplified example. Suppose that a particular
customer (whom we call “George”) buys once per month,
on average, and purchases an average of $20 per purchase in
the product category (with a contribution of $10). Suppose
that George most recently bought from Brand A. Suppose
that George’s switching matrix is such that 70% of the time
he will rebuy Brand A, given that he bought Brand A last
time, and 30% of the time he will buy Brand B. Suppose that
whenever George last bought Brand B he has a 50% chance
of buying Brand A the next time and a 50% chance of buy-
4
Actually, George’s CLV also depends on word-of-mouth effects
(Anderson 1998; Hogan, Lemon, and Libai 2000), because George
may make recommendations to others that increase George’s value
to the firm. To the extent that positive word of mouth occurs, our
CLV estimates will be too low. Similarly, negative word of mouth
will make our estimates too high. Although these two effects, being
of the opposite sign, tend to cancel out to some extent, there will
be some unknown degree of bias due to word of mouth. However,
word-of-mouth effects are notoriously difficult to measure on a
practical basis.
ing Brand B. This is enough information for us to calculate
George’s lifetime value to both Brand A and Brand B.
4
Consider George’s next purchase. We know that he most
recently bought Brand A; thus, the probability of him pur-
chasing Brand A in the next purchase is .7 and the probabil-
ity of him purchasing Brand B is .3. To obtain the probabil-
ities for George’s next purchase, we simply multiply the
vector that comprises the probabilities by the switching
matrix. The probability of purchasing Brand A becomes
(.7 × .7) + (.3 × .5) = .64, and the probability of purchasing
Brand B becomes (.7 × .3) + (.3 × .5) = .36. We can calcu-
late the probabilities of purchase for Brand A and Brand B
as many purchases out as we choose by successive multipli-
cation by the switching matrix. Multiplying this by the con-
tribution per purchase yields George’s expected contribution
to each brand for each future purchase. Because future pur-
chases are worth less than current ones, we apply a discount
factor to the expected contributions. The summation of these
across all purchase occasions (to infinity or, more likely, to
a finite time horizon) yields George’s CLV for each firm.
Note that if there are regular relationship maintenance
expenditures, they need to be discounted separately and sub-
tracted from the CLV.
The bridge of actionability. We assume that the firm can
identify expenditure categories, or drivers (e.g., advertising
awareness, service quality, price, loyalty program) that
influence consumer decision making and that compete for
marketing resources in the firm. We also assume that man-
agement wants to trade off the drivers to make decisions
about which strategic investments yield the greatest return
(Johnson and Gustafsson 2000). The drivers that are pro-
jected to yield the highest return receive higher levels of
investment. Connecting the drivers to customer perceptions
is essential to quantify the effects of marketing actions at the
individual customer level. Therefore, it is necessary to have
customer ratings (analogous to customer satisfaction rat-
ings) on the brand’s perceived performance on each driver.
For example, Likert-scale items can be used to measure each
competing brand’s perceived performance on each driver;
perceptions may vary across customers.
The firm may also want to assemble its drivers into
broader expenditure categories that reflect higher-level
resource allocation. We refer to these as “strategic invest-
ment categories.” For example, a firm may combine all its
brand-equity expenditures into a brand-equity strategic
investment category, with the idea that the brand manager is
responsible for drivers such as brand image and brand
awareness.
114 / Journal of Marketing, January 2004
5
To the extent that heterogeneity in the regression coefficients
exists, the state dependence effect will likely be overestimated
(Degeratu 1999; Frank 1962). This would result in underestimation
of the effects of the customer equity drivers, which means that the
effect of violation of this assumption would be to make the projec-
tions of the model more conservative. However, it has been shown
that our approach to estimating the inertia effect performs better
than other methods that have been proposed (Degeratu 2001).
Modeling the Switching Matrix
Thus, the modeling of CLV requires modeling of the switch-
ing matrix for each individual customer. Using individual-
level data from a cross-sectional sample of customers, com-
bined with purchase (or purchase intention) data, we model
each customer’s switching matrix and estimate model para-
meters that enable the modeling of CLV at the individual
customer level.
The utility model. In addition to the individual-specific
customer-equity driver ratings, we also include the effect of
brand inertia, which has been shown to be a useful predic-
tive factor in multinomial logit choice models (Guadagni
and Little 1983). The utility formulation can be conceptual-
ized as
(1) Utility = inertia + impact of drivers.
To make this more explicit, U
ijk
is the utility of brand k
to individual i, who most recently purchased brand j. The
dummy variable LAST
ijk
is equal to one if j = k and is equal
to zero otherwise; X is a row vector of drivers. We then
model
(2) U
ijk
= β
0k
LAST
ijk
+ X
ik
β
1k
+ ε
ijk
,
where β
0k
is a logit regression coefficient corresponding to
inertia,
β
1k
is a column vector of logit regression coeffi-
cients corresponding to the drivers, and ε
ijk
is a random error
term that is assumed to have an extreme value (double expo-
nential) distribution, as is standard in logit models. The β
coefficients can be modeled as either homogeneous or het-
erogeneous.
5
For the current exposition, we present the
homogeneous coefficient version of the model. In a subse-
quent section, we build and test alternative versions of the
model that allow for heterogeneous coefficients. The model
can also be estimated separately for different market
segments.
The individual-level utilities result in individual-level
switching matrices. Essentially, each row of the switching
matrix makes a different assumption about the most recent
brand purchased, which results in different utilities for each
row. That is, the first row assumes that the first brand was
bought most recently, the second row assumes that the sec-
ond brand was bought most recently, and so on. The utilities
in the different rows are different because the effect of iner-
tia (and the effect of any variable that only manifests with
repeat purchase) is present only in repeat purchases.
Consistent with the multinomial logit model, the proba-
bility of choice for individual i is modeled as
6
To simplify the mathematics, we adopt the assumption that a
customer’s volume per purchase is exogenous. We leave the mod-
eling of volume per purchase as a function of marketing effort as a
topic for further research.
(3) P
ijk*
= Pr[individual i chooses brand k*, given that brand j
was most recently chosen] = exp(U
ijk*
)/
Thus, the individual-level utilities result in individual-level
switching matrices, which result in an individual-level CLV.
Brand switching and customer equity. To make the CLV
calculation more specific, each customer i has an associated
J × J switching matrix, where J is the number of brands, with
switching probabilities p
ijk
, indicating the probability that
customer i will choose brand k in the next purchase, condi-
tional on having purchased brand j in the most recent pur-
chase. The Markov switching matrix is denoted as M
i
, and
the 1 × J row vector A
i
has as its elements the probabilities
of purchase for customer i’s current transaction. (If longitu-
dinal data are used, the A
i
vector will include a one for the
brand next purchased and a zero for the other brands.)
For brand j, d
j
represents firm j’s discount rate, f
i
is cus-
tomer i’s average purchase rate per unit time (e.g., three pur-
chases per year), v
ijt
is customer i’s expected purchase vol-
ume in a purchase of brand j in purchase t,
6
π
ijt
is the
expected contribution margin per unit of firm j from cus-
tomer i in purchase t, and B
it
is a 1 × J row vector with ele-
ments B
ijt
as the probability that customer i buys brand j in
purchase t. The probability that customer i buys brand j in
purchase t is calculated by multiplying by the Markov
matrix t times:
(4) B
it
= A
i
M
i
t
.
The lifetime value, CLV
ij
, of customer i to brand j is
(5) CLV
ij
=
–t/f
i
v
ijt
π
ijt
B
ijt
,
where T
ij
is the number of purchases customer i is expected
to make before firm j’s time horizon, H
j
(e.g., a typical time
horizon ranges from three to five years), and B
ijt
is a firm-
specific element of B
it
. Therefore, T
i
= int[H
j
f
i
], where int[
.
]
refers to the integer part, and firm j’s customer equity, CE
j
,
can be estimated as
(6) CE
j
= mean
i
(CLV
ij
) × POP,
where mean
i
(CLV
ij
) is the average lifetime value for firm j’s
customers i across the sample, and POP is the total number
of customers in the market across all brands. Note that the
CLV of each individual customer in the sample is calculated
separately, before the average is taken.
It is worth pointing out the subtle difference between
Equation 5 and most lifetime value expressions, as in direct
marketing. Previous lifetime value equations have summed
over time period, and the exponent on the discounting factor
becomes –t. However, in our case, we are dealing with dis-
tinct individuals with distinct interpurchase times (or equiv-
alently, purchase frequencies f
i
). For this reason, we sum
()1
0
+
=
∑
d
j
t
T
ij
exp( ).U
ijk
k
∑
Return on Marketing / 115
7
If standard marketing costs (e.g., retention promotional costs)
are spent on a time basis (e.g., every three months), they may either
be discounted separately and subtracted from the net present value
or be assigned to particular purchases (e.g., if interpurchase time is
three months, and a standard mailing goes out every six months,
the mailing cost could be subtracted on every other purchase).
8
We should also note that the expression implies that the first
purchase occurs immediately. Other assumptions are also possible.
over purchase instead of time period.
7
The exponent –t/f
i
reflects that more discounting is appropriate for purchase t if
purchasing is infrequent, because purchase t will occur fur-
ther into the future. If f
i
= 1 (one purchase per period), it is
clear that Equation 5 is equivalent to the standard CLV
expression. If f
i
> 1, the discounting per purchase becomes
less than the discounting per period, to an extent that exactly
equals the correct discounting per period. For example, for
f
i
= 2, the square root of the period’s discounting occurs at
each purchase.
8
We can also use the customer equity framework to
derive an overall measure of the company’s competitive
standing. Market share, historically used as a measure of a
company’s overall competitive standing, can be misleading
because it considers only current sales. A company that has
built the foundation for strong future profits is in better com-
petitive position than a company that is sacrificing future
profits for current sales, even if the two companies’ current
market shares are identical. With this in mind, we define
customer equity share (CES, in Equation 7) as an alternative
to market share that takes CLV into account. We calculate
customer equity share for each brand j as
ROI
Effect of changes. Ultimately, a firm wants to know the
financial impact that will result from various marketing
actions. This knowledge is essential if competing marketing
initiatives are to be evaluated on an even footing. A firm may
attempt to improve its customer equity by making improve-
ments in the drivers, or it may drill down further to improve
subdrivers that influence the drivers (e.g., improving dimen-
sions of ad awareness). This requires the measurement of
customer perceptions of the subdrivers about which the firm
wanted to know more.
A shift in a driver (e.g., increased ad awareness) pro-
duces an estimated shift in utility, which in turn produces an
estimated shift in the conditional probabilities of choice
(conditional on last brand purchased) and results in a revised
Markov switching matrix. In turn, this results in an
improved CLV (Equations 4 and 5). Summed across all cus-
tomers, this results in improved customer equity (Equation
6). We assume an equal shift (e.g., .1 rating points) for all
customers, but this assumption can be relaxed if appropriate,
because our underlying modeling framework does not
require a constant shift across customers.
() / .7 CES CE CE
jj k
k
=
∑
Projecting financial impact. It is often possible to devote
a strategic expenditure to improve a driver, but is that invest-
ment likely to be profitable? Modern thinking in finance
suggests that improved expenditures should be treated as
capital investments and viewed as profitable only if the ROI
exceeds the cost of capital. Financial approaches based on
this idea are known by such names as “economic value-
added” (Ehrbar 1998) or “value-based management” (Cope-
land, Koller, and Murrin 1996). The increased interest in
economic value-added approaches has attracted more atten-
tion to ROI approaches in marketing (Fellman 1999).
The discounted expenditure stream is denoted as E, dis-
counted by the cost of capital, and ∆CE is the improvement
in customer equity that the expenditures produce. Then, ROI
is calculated as
(8) ROI = (∆CE – E)/E.
Operationally, the calculation can be accomplished by using
a spreadsheet program or a dedicated software package.
Note, though, that even if ∆CE is negative, the ROI expres-
sion still holds.
Implementation Issues
Cross-Sectional Versus Longitudinal Data
Our approach requires the collection of cross-sectional sur-
vey data; the approach is similar in style and length to that
of a customer satisfaction survey. The survey collects cus-
tomer ratings of each competing brand on each driver. Other
necessary customer information can be obtained either from
the same survey or from longitudinal panel data, if it is
available. The additional information collected about each
customer includes the brand purchased most recently, aver-
age purchase frequency, and average volume per purchase.
The logit model can be calibrated in two ways: (1) by
observing the next purchase (from either the panel data or a
follow-up survey) or (2) by using purchase intent as a proxy
for the probability of each brand being chosen in the next
purchase.
Obtaining the Model Input
The implementation of our approach begins with manager
interviews and exploratory research to obtain information
about the market in which the firm competes and informa-
tion about the corporate environment in which strategic
decisions are made. From interviews with managers, we
identified competing firms and customer segments; chose
drivers that correspond to current or potential management
initiatives; and obtained the size of the market (total number
of customers across all brands) and internal financial infor-
mation, such as the discount rate and relevant time horizon.
In addition, we estimated contribution margins for all com-
petitors. If there was a predictable trend in gross margins for
any firm in the industry, we also elicited that trend. From
exploratory research, using both secondary sources and
focus group interviews, we identified additional drivers,
which we reviewed with management to ensure that they
were managerially actionable items. On the basis of the
combined judgment of management and the researchers, we
116 / Journal of Marketing, January 2004
reduced the set of drivers to a number that allows for a sur-
vey of reasonable length. The drivers employed typically
vary by industry.
Estimating Shifts in Customer Ratings
The calculation of ROI requires an estimate of the rating
shift that will be produced by a particular marketing expen-
diture. For example, a firm may estimate that an advertising
campaign will increase the ad awareness rating by .3 on a
five-point scale. These estimates can be obtained in several
ways. If historical experience with similar expenditures is
available, that experience can be used to approximate the
ratings shift. For example, many marketing consulting firms
have developed a knowledge base of the effects of market-
ing programs on measurable indexes. Another way, analo-
gous to the decision calculus approach (Blattberg and
Deighton 1996; Little 1970), is to have the manager supply
a judgment-based estimate. The manager may reflect uncer-
tainty by supplying an optimistic and a pessimistic estimate.
If the outcome was favorable for the optimistic estimate, but
unfavorable for the pessimistic estimate, the outcome would
be considered sensitive to the rating shift estimate, indicat-
ing the need for more information gathering. Another lim-
ited cost approach is to use simulated test markets (Clancy,
Shulman, and Wolf 1994; Urban et al. 1997) to obtain a pre-
liminary idea of market response. Finally, the marketing
expenditure can be implemented on a limited basis, using
actual test markets, and the observed rating shift can be
monitored (e.g., Rust et al. 1999; Simester et al. 2000).
Calibrating the Data
It is typical in many sampling plans to have respondents
with different sampling weights, w
i
, correcting for varia-
tions in the probability of selection. We can use the sampling
weights directly, in the usual way, to generate a sample-
based estimate of market share, which we denote as
MS
sample
. If the sample is truly representative, MS
sample
should be equal to the actual market share, MS
true
. To make
the sample more representative of actual purchase patterns,
we can assign a new weight, w
i,new
= (MS
true
/MS
sample
) × w
i
to each respondent, with market shares corresponding to that
respondent’s most recently chosen brand, which will correct
for any sampling bias with respect to any brand. The implied
market share from the sample will then equal the actual mar-
ket share.
If purchase intent rather than actual purchase data is
used, the application must be done with some care. Previous
researchers have long noted that purchase-intention subjec-
tive probabilities occasionally may be systematically biased
(Lee, Hu, and Toh 2000; Pessemier et al. 1971; Silk and
Urban 1978). We assume that the elicited purchase inten-
tions, p
ij
, of respondent i purchasing brand j in the next pur-
chase need to be calibrated. In general, we assume that there
is a calibrated probability, p*
ij
, that captures the true proba-
bility of the next purchase. These probabilities can be cali-
brated in two possible ways. First, if it is possible to follow
up with each respondent to check on the next purchase, we
can find a multiplier K
j
for each brand that best predicts
choice. (We set K
j
for the first brand arbitrarily to one, with-
out loss of generality, to allow for uniqueness.) The K’s can
be quickly found using a numerical search. If p*
ij
is the
stated probability of respondent i choosing brand j in the
next purchase, the calibrated choice probability is p*
ij
=
K
j
p
ij
/Σ
k
K
k
p
ik
. Second, if checking the next purchase is not
possible, it is still possible to calibrate the purchase inten-
tions by making an approximating assumption. Assuming
that the market share (as the percentage of customers who
prefer a brand) for each brand in the near future (including
each respondent’s next purchase) is roughly constant, we
employ a numerical search to find the K
j
’s (again setting
K
1
= 1) for which MS
true
= mean
i
(p*
ij
).
Model Estimation
Principal components regression. In this application, as
in customer satisfaction measurement, multicollinearity is
an issue that needs to be addressed (Peterson and Wilson
1992). For this reason, we adopt an estimation approach that
addresses the multicollinearity issue. Principal components
regression (Massy 1965) is an approach that combats multi-
collinearity reasonably well (Frank and Friedman 1993), yet
it can be implemented with standard statistical software.
Principal components regression is a two-stage procedure
that is widely known and applied in statistics, econometrics,
and marketing (e.g., Freund and Wilson 1998; Hocking
1996; Naik, Hagerty, and Tsai 2000; Press 1982). Principal
components multinomial logit regression has been used suc-
cessfully in the marketing literature, leading to greater
analysis interpretability and coefficient stability (e.g., Gess-
ner et al. 1988).
The idea is to reduce the dimensionality of the indepen-
dent variables by extracting fewer principal components that
explain a large percentage of the variation in the predictors.
The principal components are then used as independent vari-
ables in the regression analysis. Because the principal com-
ponents are orthogonal, there is no multicollinearity issue
with respect to their effects. In addition, eliminating the
smallest principal components, which may be essentially
random, may reduce the noise in the estimation. Because the
principal components can be expressed as a linear combina-
tion of the independent variables (and vice versa), the coef-
ficients of the independent variables can be estimated as a
function of the coefficients of the principal components, and
the coefficients (after the least important principal compo-
nents are discarded) may result in better estimates of the dri-
vers’ effects. Estimation details are provided in Appendix A.
Importance of customer equity drivers. The results from
the model estimation in Equation 2 provide insight into
which customer equity drivers are most critical in the indus-
try in which the firm competes. When examining a specific
industry, it is useful to know what the key success factors are
in that industry. Ordinarily, this might be explored by calcu-
lating market share elasticities for each driver. However, that
approach is not correct here, because the drivers are inter-
vally scaled rather than ratio scaled. This means that it is
incorrect to calculate percentages of the drivers, as is neces-
sary in the calculation of elasticities. Moreover, our focus is
customer equity rather than market share. To arrive at the
impact of a driver on customer equity, we need to determine
the partial derivative of choice probability, with respect to
the driver, for each customer in the sample. That is, if a dri-
Return on Marketing / 117
ver were improved by a particular amount, what would be
the impact on customer choice and, ultimately, on CLV and
customer equity? Appendix A provides details of these com-
putations and significance tests for the drivers.
An Example Application
Data and Sampling
Survey items. We illustrate our approach with data col-
lected from customers of five industries. We assume three
strategic investment categories: (1) perceived value (Para-
suraman 1997; Zeithaml 1988), (2) brand equity (Aaker and
Keller 1990), and (3) relationship management (Anderson
and Narus 1990; Gummeson 1999). The three categories
span all major marketing expenditures (Rust, Zeithaml, and
Lemon 2000). We drew heavily on the relevant academic
and managerial literature in these areas to build our list of
drivers and ensured that the drivers could be translated into
actionable expenditures. The resulting survey contained
questions pertaining to shopping behavior and customer rat-
ings of each driver for the four or five leading brands in the
markets we studied. In addition, several demographics ques-
tions were asked at the end of the survey. We selected indus-
tries (airlines, electronics stores, facial tissues, grocery, and
rental cars) that represented a broad set of consumer goods
and services. To save space, we present the details for the
airline industry analysis only; however, our approach was
similar across the other four industries. The complete list of
the survey items used in our analysis of the airline industry
appears in Appendix B.
Population. We obtained illustrative data from two com-
munities in the northeastern United States: an affluent small
town/suburb and a medium-sized city that adjoins a larger
city. Respondents were real consumers who had purchased
the product or service in the industry in question during the
previous year. Demographic statistics suggest that the sam-
ple is representative of similar standard metropolitan statis-
tical areas in the United States, with the exception of gener-
ally high levels of education and income. For example, in
the small town (with a population of approximately 20,000),
the average age of the respondent was 47, the average
household had two adults and one child, the average house-
hold income was $91,000, and the average years of educa-
tion was 17. In the larger city, the average age was somewhat
lower (39 years), the average household had two adults and
one child, the average household income was $70,000, and
the average years of education was similar to that of the
small town.
Sampling.We obtained respondents from three random
samples. The first sample, drawn from the city population,
answered questions about electronics stores and rental car
companies. The second sample, also drawn from the city
population, addressed groceries and facial tissues. The third
sample, drawn from the small town, focused on airlines.
Potential respondents were contacted at random by
recruiters from a professional market research organization
(by telephone solicitation or building intercept). The screen-
ing process consisted of two criteria: (1) the respondent had
purchased from the industry in the past 12 months, and (2)
9
Mean substitution can result in biased estimates, but in our
judgment, the additional effort of employing a more sophisticated
missing values procedure (e.g., data imputation) was not justified
in this case, given the relatively low percentage of missing values.
10
This decision was based solely on the researchers’ best judg-
ment. Our model does not require this.
the respondent had a household income of at least $20,000
per year. Respondents agreed to participate and received $20
compensation for completing the questionnaire. In the elec-
tronics stores and rental cars survey, 246 consumers were
approached: 153 were eligible, 144 cooperated, and 7 were
disqualified, resulting in a total of 137 total surveys com-
pleted. In the groceries and facial tissues survey, 177 con-
sumers were approached: 124 were eligible, 122 cooperated,
and 4 were disqualified, resulting in a total of 118 surveys
completed. In the airline survey, 229 consumers were
approached: 119 were eligible, 105 cooperated, and 5 were
disqualified, resulting in a total of 100 surveys completed.
Data collection and preliminary analysis. Data were
collected in December 1998 and January 1999 at the firm’s
offices in each location. The respondents came to the facil-
ity to complete the pencil-and-paper questionnaire, which
took about 30 minutes. They were then thanked for their par-
ticipation and compensated. In addition, we obtained aggre-
gate statistics on the small town and city (e.g., percentage of
population that uses rental cars, average spent at grocery
store) from secondary sources and used them in subsequent
analysis. For purposes of financial analysis, we used local
population and aggregate usage statistics for predominantly
local industries (electronics stores and groceries) and
national statistics for predominantly national industries (air-
lines, facial tissues, and rental cars). Although our random
samples may not be fully representative of U.S. users, we
extrapolated to the national market for national industries to
show the type of dollar magnitudes that can arise given a
large population. Because our examples are illustrative,
truly precise dollar estimates are unnecessary.
Data were cleaned to eliminate obvious bad cases and
extreme outliers. Because listwise deletion of cases would
have resulted in too many cases being removed (even though
only a relatively small percentage of responses were missing
for particular items), we employed mean substitution as our
missing data option for all subsequent analyses.
9
Because
we suspected that the relationship drivers would affect pri-
marily repeat purchasers, we collected relationship items
only for the brand most recently purchased.
10
We mean-
centered the relationship-related drivers for the cases in
which the brand considered was the previously purchased
brand, and we set them equal to zero for the cases in which
the brand considered was different from the previously pur-
chased brand. This enabled the “pure” inertia effect to be
separated from the relationship effect of the drivers.
Choice Model Results
Principal components analysis results. We reduced the
dimensionality of the predictor variables in each industry by
conducting a principal components analysis. We used an
eigenvalue cutoff of .5, which we judged to provide the best
118 / Journal of Marketing, January 2004
11
The 1.0 eigenvalue cutoff (Kaiser 1960) is typically employed
in marketing, but it is just one of many possible cutoff criteria (for
two alternatives, see Cattell 1966; Jolliffe 1972). As Kaiser (1960,
p. 143), who proposed the 1.0 cutoff, points out, “by far [the] most
important viewpoint for choosing the number of factors [is] … psy-
chological meaningfulness.” In other words, the cutoff should be
chosen such that the results are substantively meaningful, which is
our justification for using the particular cutoff level that we chose.
trade-off between parsimony and managerial usefulness.
11
The airline analysis began with 17 independent variables,
and we retained 11 orthogonal factors. Table 2 shows the
loadings on the rotated factors. The resulting factor structure
is rich. All the factors are easily interpretable. The few neg-
ative loadings are small and insignificant; they are zero for
all practical purposes. All drivers load on only one factor,
and many (e.g., inertia, quality, price, convenience, trust,
corporate citizenship) load on their own unique factor.
There is some degree of discrimination among the value,
brand, and relationship strategic investment categories in
that drivers in the three strategic action categories of differ-
ent drivers do not correlate highly on the same factors. As
we expected, the strategic investment categories, value,
brand, and relationship are not unidimensional. The drivers
that constitute the categories can be grouped for managerial
purposes as managers consider them, but drivers in a partic-
ular strategic investment category may be quite distinct in
the customer’s mind.
Logit regression results. Using the resulting factors as
independent variables, we conducted multinomial logit
analyses, using the analysis we described previously. Table
3 shows the coefficients that arise from the multinomial
logit regression analysis, highlighting the significant factors.
Using Equations A1–A9, we converted the factor-level
results to the individual drivers. The resulting coefficients,
standard errors, and test statistics are shown in Table 4. All
12
This nested chi-square was also insignificant in the other four
industries that we studied (electronics = 6.79, facial tissues = 1.00,
grocery = 5.82, and rental cars = .28).
the drivers are significant and have the correct sign, but
some drivers have a larger effect than others. The most
important drivers span all three strategic investment cate-
gories. In addition to the drivers, inertia has a large, signifi-
cant impact (.849, p < .01). Among the value-related drivers,
convenience has the largest coefficient (.609), followed by
quality (.441); for brand-related drivers, direct mail infor-
mation has the largest impact (.638), followed by ad aware-
ness (.421) and ethical standards (.421). The loyalty pro-
gram (.295) and preferential treatment (.280) are the most
important relationship-related drivers.
Model Testing and Validation
We tested and validated the core choice model in several dif-
ferent ways. We tested for brand-specific effects, hetero-
geneity of response, a more general covariance matrix, and
the reliability of the coefficient estimates.
Brand-specific effects. The model in Equation 2 assumes
that there are no brand-specific effects. We tested the valid-
ity of this assumption by including brand-specific constants
in the model of Equation 2. Testing the significance of the
more complicated model can be accomplished through the
use of a nested-likelihood-ratio chi-square test (in the airline
application, this involves three degrees of freedom, reflect-
ing a number of brand-specific constants that is equal to the
number of brands minus one). The resulting nested model
comparison was not significant (χ
2
3
= .977
), from which we
conclude that brand-specific constants are not required.
12
Heterogeneity of response. It is reasonable to suspect
that there may be unobserved heterogeneity of response
TABLE 2
Factor Loadings: Airline Industry
Driver F1 F2 F3 F4 F5 F6 F7 F8 F9 F10 F11
Inertia –.013 –.004 .033 .038 .015 .116 –.024 .984 .029 .043 .002
Quality .097 .058 .174 .076 .147 .212 .014 .049 .068 .904 .083
Price .044 –.007 .128 .054 .078 .023 .039 .030 .975 .059 .034
Convenience .078 .068 .219 .161 .043 .830 .066 .163 .018 .260 –.015
Ad awareness –.031 .130 .038 .938 –.010 .022 .048 –.011 .074 .101 .058
Information .216 –.077 .248 .656 .322 .299 –.207 .125 –.038 –.058 .016
Corporate citizenship .011 .122 .150 .093 .880 .001 .256 .021 .077 .137 .006
Community events .021 .100 .188 –.042 .226 .051 .921 –.026 .041 .011 .029
Ethical standards –.016 .044 .605 .105 .458 .266 .028 –.034 .104 .109 .218
Image fits my personality .098 .112 .878 .107 .069 .092 .203 .058 .110 .142 .081
Investment in loyalty program .921 .044 .090 .032 –.007 –.060 .018 .014 –.003 .137 –.103
Preferential treatment .898 .087 .082 –.002 .022 –.071 –.029 .032 –.007 .077 .104
Know airline’s procedures .708 .232 –.022 .116 .029 .166 .058 –.033 .010 –.069 .240
Airline knows me .681 .309 –.073 –.059 –.001 .356 –.012 –.061 .136 –.075 .219
Recognizes me as special .214 .851 .069 .077 –.036 .042 .138 –.004 –.044 .118 .092
Community .175 .876 .065 .031 .166 .035 –.015 .001 .036 –.042 .129
Trust .246 .227 .179 .069 .041 –.003 .031 .006 .038 .091 .889
Notes: Loadings greater than .5 are shown in bold.
Return on Marketing / 119
TABLE 3
Logit Regression Results: Airline Industry
Independent Variable Coefficient Standard Error b/s.e. p
F1 .325** .122 2.65 .008
F2 –.031 .118 –.26 .795
F3 .421* .210 2.00 .045
F4 .459 .285 1.61 .107
F5 .212 .228 .93 .352
F6 .331* .159 2.08 .037
F7 –.081 .279 –.29 .771
F8 .633** .100 6.36 .000
F9 .034 .164 .21 .835
F10 .184 .147 1.26 .209
F11 –.033 .115 –.29 .772
Log-likelihood = –98.46
Chi-square (11 degrees of freedom) = 69.246**
*p < .05.
**p < .01.
TABLE 4
Driver Coefficients: Airline Industry
Driver Coefficient Standard Error b/s.e.
Inertia .849 .075 11.341*
Quality .441 .041 10.871*
Price .199 .020 9.858*
Convenience .609 .093 6.553*
Ad awareness .421 .099 4.242*
Information .638 .082 7.819*
Corporate citizenship .340 .045 7.617*
Community events .170 .024 6.974*
Ethical standards .421 .053 7.901*
Image fits my personality .390 .050 7.874*
Investment in loyalty program .295 .027 10.956*
Preferential treatment .280 .026 10.857*
Know airline’s procedures .238 .027 8.779*
Airline knows me .249 .041 6.108*
Recognizes me as special .167 .017 9.771*
Community .151 .016 9.412*
Trust .203 .023 8.725*
*p < .01.
across the respondents. That is, expressed in terms of Equa-
tion 2, the βs may be different across respondents. To test
this, we employed a random coefficients logit model (Chin-
tagunta, Jain, and Vilcassim 1991) in which we permitted
the driver coefficients to be distributed as an independent
multivariate normal distribution. The log-likelihood
improved from –97.58 to –93.24, which is an insignificant
improvement (χ
2
11
= .8.68
). Therefore, we conclude that the
random coefficients logit formulation does not produce a
better model and that it is not worthwhile in this case to
model unobserved heterogeneity in the parameters.
Correlated errors. Another way the independence from
irrelevant alternatives property can be violated is if the error
terms in Equation 2 are correlated. For example, it is possi-
ble that people who prefer American Airlines more than the
model predicted will systematically dislike Southwest Air-
lines more than the model predicted. To address this issue,
we turned to a multinomial probit model (Chintagunta
1992). In this model, the error terms in Equation 2 are
assumed to be normally distributed rather than extreme
value, and they are permitted to have a general covariance
matrix.
120 / Journal of Marketing, January 2004
FIGURE 2
Distribution of CLV: American Airlines
0%
10%
20%
30%
40%
50%
60%
70%
Relative Frequency
0–99 100–199 200–299 300–399 400–499 500+
CLV ($)
Our original logit model is no longer a constrained ver-
sion of the more complicated model, so we cannot do the
nested likelihood-ratio chi-square test. However, by com-
paring the general multinomial probit model with a multin-
omial probit model in which the error terms are assumed to
be independent, we can address the issue of whether model-
ing the more general covariance matrix is useful. This
results in a nested test. We found that the uncorrelated errors
version of the model resulted in a log-likelihood of –98.46
(slightly worse than the multinomial logit log-likelihood)
and that the more general model produced a log-likelihood
of –97.57. The improvement is insignificant (χ
2
3
= .82
). We
also can compare the general multinomial probit model with
the original multinomial logit model by using the Akaike
information criterion. The improvement from –97.58 to
–97.57 does not compensate for the additional three esti-
mated parameters (we would need a log-likelihood
improvement of at least 3.0), suggesting that the general
multinomial probit model is not better than our multinomial
logit model. Thus, we conclude that the more general
covariance matrix is not warranted.
Coefficient reliability. Given our relatively small sample
size (96 usable data points after the data are cleaned), we
were unable to pursue split-half tests or complete holdout
samples. However, to further understand the reliability of
our model estimates, we randomly split our sample into
three parts (A, B, and C) and estimated our model on AB,
AC, and BC. The mean range (and median range) of the
coefficient estimates across the 11 factors was .14; that is, on
average, the swing between the largest and smallest coeffi-
cient estimate across the three samples was .14, which
comes out to about .6 standard errors, on average. Thus, the
model appears to produce reasonably stable coefficient
estimates.
CLV
Using Equation 5, we calculated CLV for American Airlines
for each respondent in our airline sample. To operationalize
the equation, we assumed a time horizon of three years, a
discount rate of 10%, and a contribution margin of 15%. The
15% figure was approximately equal to the average operat-
ing margin for the industry for the five years preceding the
survey, according to annual reports of the four firms we
studied (since our study, airline industry operating margins
have declined). We also based our contribution margin fig-
ures in the other four industries on financial data from
annual reports. To extend the CLV figures to the firm’s U.S.
customer equity, we used U.S. Census data to determine the
number of adults in the United States (187,747,000), and we
then combined this with the percentage of U.S. adults who
were active users of airline travel (23.3%), yielding a total
number of U.S. adult airline customers of 43,745,051. To
approximate the total customer equity, we multiplied this
number by the average CLV across our respondents. Note
that though we used average CLV to project customer
equity, we calculated CLV at the individual customer level
for each customer in the sample.
Customer loyalty and CLV. Some insights can be
obtained from examining American Airlines’ CLV distribu-
tion. For example, Figure 2 shows the distribution of CLV
across American Airlines’ customers. The $0–$99 category
includes more than 60% of American’s customers, and the
$500-plus category includes only 11.6% of customers, indi-
cating that the bulk of American’s customers have low CLV.
Figure 3 also indicates that American’s customers are fickle.
Almost half of American’s customers have a 20% or less
share-of-wallet (by CLV) allocated to American. Only
10.5% give more than 80% of their CLV to American. This
percentage shows dramatically that the vast majority of
American’s customers cannot be considered monogamously
loyal. Figure 4 shows a startling picture of the percentage of
American’s customer equity that is contributed by each CLV
category. The $0–$99 category, though by far the largest
(more than 60% of American’s customers), produces less
than 10% of American’s customer equity. In contrast, the
$500-plus CLV category, though only 11.6% of American’s
customers, produces approximately 50% of American’s cus-
tomer equity.
Comparison with the lost-for-good CLV model. Previ-
ously, we proposed that some models of CLV that do not
account for customers’ returning systematically underesti-
FIGURE 3
Distribution of CLV Share (Share of Wallet):
American Airlines
0%
10%
20%
30%
40%
50%
Relative Frequency
0%–20% 21%–40% 41%–60% 61%–80% 81%–100%
CLV
Return on Marketing / 121
0
10
20
30
40
50
Percentage (%) of Customer Equity
0–99 100–199 200–299 300–399 400–499 500+
CLV
(
$
)
FIGURE 4
Percentage Customer Equity by CLV Category:
American Airlines
mate CLV and customer equity (for an exception, see Dwyer
1997). Using the airline sample, we explored the degree to
which this was true. The lost-for-good model is simply a
constrained version of our switching model, such that all
probabilities of switching from another brand to the focal
brand are zero. In other words, to calculate the results, we
considered only the customers who were retained from the
first purchase. When the customer chose another brand, we
gave a probability of zero to any further purchase from the
focal brand. For American Airlines, our brand-switching
model gives a customer equity of $7.303 billion. Without
accounting for switching back, the estimated customer
equity declines to $3.849 billion. Thus, the lost-for-good
model provides a systematic underestimation of customer
equity that, in this case, is an underestimation of 47.3%.
Customer equity and the value of the firm. It has been
suggested (Gupta, Lehmann, and Stuart 2001) that customer
equity is a reasonable proxy for the value of the firm. Our
analysis of American Airlines provides some support for this
idea. Multiplication of American’s average CLV ($166.94)
by the number of U.S. airline passengers (43,745,051)
yields a total customer equity for American of $7.3 billion.
Given American’s opening share price for 1999 ($60) and its
number of shares outstanding at that time (161,300,000)
(AMR Corporation 1999), we calculate a market capitaliza-
tion of $9.7 billion. Because our projection ignores profits
from international customers and nonflight sources of
income, our customer equity calculation is largely compati-
ble with American’s market capitalization at the time of the
survey.
Projected Financial Return
Our framework enables the financial impact of improvement
efforts to be analyzed for any of the usual marketing expen-
ditures. For example, American Airlines recently spent a
reported $70 million to upgrade the quality of its passenger
compartments in coach class by adding more leg room. Is
such an investment justified? To perform an analysis such as
this, we estimated the amount of ratings shift and the costs
incurred in effecting the ratings shift. We then used the rat-
ings shift to alter (for each respondent) the focal brand’s
utility, switching matrix, and CLV (see Equations 2–5),
which, when averaged across respondents and projected to
the size of the population (see Equation 6), resulted in a
revised estimate for the firm’s customer equity. In this way,
and using the discount rate and contribution margin we dis-
cussed previously, we analyzed the recent American Airlines
seating improvement. We used the $70 million cost figure
reported by the company.
If we assume that the average for the item that measures
quality of the passenger compartment (a subdriver of qual-
ity) increases by .2 rating points on the five-point scale, our
analysis (see Table 5) indicates that customer equity will
improve by 1.39%, resulting in an improvement in customer
equity of $101.3 million nationally, or an ROI of 44.7%,
which indicates that the program has the potential to be a
large success. Table 5 shows the results of similar analyses
from the other four industries. For example, a $45 million
expenditure by Puffs facial tissues to improve ad awareness
TABLE 5
Projected ROI from Marketing Expenditures
Percentage Dollar
Improvement Improvement
Company Area of Geographic Amount in Customer in Customer Projected
(Industry) Expenditure Region Investment Improved Equity Equity ROI
American Passenger United States $70 million .2 rating point 1.39% $101.3 million 44.7%
(airlines) compartment
Puffs Advertising United States $45 million .3 rating point 7.04% $58.1 million 29.1%
(facial tissues)
Delta (airlines) Corporate United States $50 million .1 rating point 1.68% $85.5 million 71.0%
ethics
Bread & Circus Loyalty Local market $100,000 .5 rating point 7.04% $87,540 –12.5%
(groceries) programs in two measures
122 / Journal of Marketing, January 2004
13
To conserve space, we show the details only for the airline
example, but the details of the other industry examples are similar.
by .3 rating points would result in a $58.1 million improve-
ment in customer equity and an ROI of 29.1%.
13
It is even possible to measure the financial impact of cor-
porate ethical standards or corporate citizenship. For exam-
ple, if Delta spent $50 million to improve customers’ per-
ceptions of Delta’s ethical standards by .1 rating points, this
would project to a customer equity improvement of $85.5
million (a 1.68% increase). Such findings may cause some
airlines to reconsider practices such as canceling flights that
are not full in order to be profitable.
Not all investments will project to be profitable. For
example, suppose that the grocery store Bread & Circus
decides to spend $100,000 in the local retail area to improve
its loyalty program ratings across two measures by .5 points.
The projected benefit is not enough to justify the expendi-
ture, and the ROI is –12.5%.
The preceding examples illustrate only some of the mar-
keting expenditures that can be evaluated by means of the
customer equity framework. Any marketing expenditure can
be related to the drivers of customer equity, measured, and
evaluated financially. This capability enables a firm to
screen improvement ideas either before application or after
a test market has nailed down the expected degree of
improvement.
Model Sensitivity
The preceding analyses are based on point estimates, but
how sensitive is the ROI model to errors of estimation or
measurement? Sensitivity to errors of estimation can be ana-
lyzed by considering the sampling distribution of β
x
.
Appendix A shows how to construct confidence intervals for
β
x
. Then, by applying the end points of the confidence inter-
val to the ROI model, it is possible to analyze the sensitivity
of ROI to estimation error. In general, this error is of more
concern on the low side, because overoptimism may result
in inappropriate expenditures. With this in mind, we suggest
calculation of a coefficient, β
x
, which will be greater than
the true value only 5% of the time. Assuming that there is a
large n, this is calculated as
(9) β
x
= β
x
– 1.645(standard error of β
x
).
Then, β
x
can be used to produce “conservative” projections
of the customer equity change and the ROI. This can be
done by inserting β
x
directly into the customer equity calcu-
lations. For example, if we calculate a conservative estimate
of customer equity impact for the American Airlines exam-
ple in Table 5, we obtain a $93.9 million increase in cus-
tomer equity, or a 1.29% increase. This would result in a
34.2% ROI, indicating that even a conservative estimate
shows a quite favorable return.
Sensitivity to errors of measurement can be addressed by
considering the sampling distribution of the sample mean. In
Equation A5 in Appendix A, unlike the case in regression
analysis, the level of a variable affects the extent to which a
change in the variable affects choice and thus utility, CLV,
and customer equity. By evaluating the end points of the
confidence interval for the sample mean of a variable to be
improved, we can thus obtain a confidence interval for the
ROI that will result from a shift in that variable. We per-
formed this analysis for the Delta Airlines corporate ethics
example in Table 5. A 95% confidence interval for the mean
on the corporate ethics variable was 3.346 .188, which
results in a 95% confidence interval for corporate ethics
improvement of $83.1 million/$87.8 million and a 95% con-
fidence interval for ROI of 66%/76%.
If the projected rating shift results from a test market, the
sampling distribution of the rating shift can also be
employed to generate a confidence interval. Under the
assumption that the sources of error are independent, which
is not unreasonable, it would then be straightforward to sim-
ulate an all-inclusive confidence interval for ROI, incorpo-
rating errors in the model coefficient estimate, estimated
sample mean, and estimated shift that are based on an
assumption of a multivariate normal distribution with
orthogonal components.
Discussion and Conclusions
Contributions to Theory and Practice
We make several contributions to marketing theory and
practice. First, we identify the important problem of making
all of marketing financially accountable, and we build the
first broad framework that attempts to address the problem.
We provide a unified framework for analyzing the impact of
competing marketing expenditures and for projecting the
ROI that will result from the expenditures. This big-picture
contribution extends the scope of ROI models in marketing,
which to date have focused on the financial impact of par-
ticular classes of expenditure and have not addressed the
general problem of comparing the impact of any set of com-
peting marketing expenditures. Our work is the first serious
attempt to address this issue in its broadest form: the trading
off of any strategic marketing alternatives on the basis of
customer equity. Marketing Science Institute member com-
panies have identified this research area as the most impor-
tant problem they face today.
Second, we provide a new model of CLV, incorporating
the impact of competitors’ offerings and brand switching;
previous CLV models have ignored competition. We also
discount according to purchase rather than time period. Pre-
vious CLV models have been limited to the consideration of
purchases made in prespecified time units, which is realistic
for some businesses (e.g., subscription services, sports sea-
son tickets) but not for others (e.g., consumer packaged
goods). By discounting according to purchase, at the indi-
vidual level, our model is more widely applicable. The
approach set out previously considers customer equity for
the entire relevant competitive set, which has two advan-
tages over existing approaches. First, this approach consid-
ers the expected lifetime value of both existing customers
and prospective customers, thereby incorporating acquisi-
tion and retention (for the focal firm and competitors) in the
same model. Second, by explicitly considering competitive
effects in the choice decision, it is possible to use the model
Return on Marketing / 123
to consider the impact of competitive responses on the
firm’s customer equity.
Third, we provide a method for estimating the effects of
individual customer equity drivers, testing their statistical
significance, and projecting the ROI that will occur from
expenditures on those drivers. We present a principal com-
ponents multinomial logit regression model for estimating
the Markov brand-switching matrix, and we separate the dri-
ver effects from the inertia effect. The identification and
measurement of key drivers has been a process widely and
successfully employed in the fields of customer satisfaction
measurement and customer value management (e.g., Gale
1994; Kordupleski, Rust, and Zahorik 1993). We extend this
idea to customer equity. By doing so, companies can answer
questions such as, “Should we spend more on advertising, or
should we improve service quality”? and “Which will have
a bigger effect”?
Fourth, customer equity provides a theoretical frame-
work for making the firm truly customer centered, and it is
applicable to a wide variety of market contexts and indus-
tries. Basing strategic investment on the drivers of customer
equity is an outside-in approach that directly operationalizes
these fundamental marketing concepts. In other words, the
customer equity approach provides a means of making
strategic marketing decisions inherently information driven,
which is consistent with the long-term trends of decreasing
costs for information gathering and information processing.
Fifth, application of the customer equity framework is
consistent with practical management needs. The results
provide insight into competitive strengths and weaknesses
and an understanding of what is important to the customer.
By contrasting the firm’s customer equity, customer equity
share, and driver performance with those of its competitors,
the firm can quickly determine where it is gaining or losing
competitive ground with respect to the value of its customer
base. In addition, the model results include the distribution
of CLV across the firm’s customers, the distribution of CLV
share (discounted share-of-wallet) across the firm’s cus-
tomers, and the percentage of the firm’s customer equity
provided by the firm’s top X% of customers. Collectively,
the information gives useful information about how to seg-
ment the firm’s customers on the basis of importance.
Finally, the mathematical infrastructure of our framework
can be implemented by means of widely available statistical
packages and spreadsheet programs, and we have conducted
all the analyses by using only standard, commercially avail-
able software packages.
Limitations and Directions for Further Research
In this article, we have developed and illustrated a practical
framework for basing marketing strategy on CLV and cus-
tomer equity. As with any new endeavor, there is much work
yet to be done. Specifically, we have determined seven key
areas for further research. First, the effects of market
dynamics on customer equity should be examined. For
example, if the market is rapidly expanding or rapidly
shrinking, an assumption of stable market size is inappro-
priate. In such markets, it would be necessary to model the
changing size of the market and relate that to customer
equity. This also implies the explicit modeling of a birth and
death process for customers in the market. New-to-the-
world products and services and markets in which firms are
expanding globally are examples of contexts in which we
believe this will be particularly important.
Second, our model assumes that there is one brand or
product in the firm and does not consider cross-selling
between a firm’s brands or products. We believe that the
model we have described provides a solid foundation for
firms to understand what drives customer equity in a given
brand or product category. However, because many firms
have multiple offerings and hope to encourage customer
cross-buying of these products, it will be important to under-
stand the influence of the drivers of customer equity on cus-
tomer cross-buying behavior and to incorporate the impact
of cross-selling on customer equity. This is particularly
important for firms that rely on customer cross-buying
behavior for long-term customer profitability (e.g., financial
service firms).
Third, we adopt the assumption that a customer’s vol-
ume per purchase is exogenous. An extension of this
research would permit volume per purchase to vary as a
function of marketing effort. For example, it will be impor-
tant to understand whether marketing efforts that may result
in forward buying (e.g., short-term price discounts) have a
long-term effect on customer equity.
Fourth, there is a need to develop dynamic models of
CLV and customer equity. Traditional models of CLV have
been adopted from the net-present-value approach in the
finance literature. Understanding how the value of the firm’s
customers (and overall customer equity) changes over time
will enable managers to make even better marketing invest-
ments. There is also an opportunity to develop richer mod-
els of CLV that incorporate a deeper understanding of con-
sumer behavior.
Fifth, there is an opportunity to relate customer equity to
corporate valuation (Gupta, Lehmann, and Stuart 2001).
This should involve the evaluation of corporate assets, lia-
bilities, and risk, as well as the estimated customer equity.
Sixth, applications of this framework and further empirical
validation of its elements would be useful, especially across
different cultures. For example, in what kinds of cultures are
various drivers more important or less important, and why?
Seventh, although our model incorporates competition, it
makes no provision for competitive reactions. An extension
of this work might involve a game theoretic competitive
structure in order to understand the effects of potential com-
petitive reactions to the firm’s intended improvements in key
drivers of customer equity.
Summary
We have provided the first broad framework for evaluating
return on marketing. This enables us to make marketing
financially accountable and to trade off competing strategic
marketing investments on the basis of financial return. We
build our customer equity projections from a new model of
CLV, one that permits the modeling of competitive effects
and brand-switching patterns. Customer equity provides an
information-based, customer-driven, competitor-cognizant,
124 / Journal of Marketing, January 2004
and financially accountable strategic approach to maximiz-
ing the firm’s long-term profitability.
Appendix A
Estimation Details
Principal Components Regression
The independent variables for the principal components
analysis are all the drivers and the LAST variable. The vec-
tor X
ijk
denotes the original independent variables for each
customer i by previously purchased firm j by next-purchase
firm k combination. Treating the customer by firm combi-
nations as replications, we extract the largest principal com-
ponents of X
ijk
and rotate them using varimax rotation to
maximize the extent to which the factors load uniquely on
the original independent variables, thereby aiding manager-
ial interpretability. The vector F
ijk
denotes the rotated factor.
These form the independent variables for our logit regres-
sion, which we describe subsequently.
Expressing Equation 2 in terms of the underlying factors
leads to the following:
(A1) U
ijk
= F
ijk
γ
+ ε
i
,
where
γ
is a vector of coefficients.
From factor analysis theory, it is known that the factors
are linear combinations of the underlying variables X
ijk
. In
other words, there exists a matrix A for which F
ijk
= X
ijk
A.
However, the idea of the principal components analysis was
to discard the potentially muddling effects of the least
important components. Denoting A* as the subvector of A
that corresponds to the reduced factor space (discarding the
principal components that do not meet the eigenvalue cutoff)
and
γ
* as the estimated
γ
that corresponds to the reduced
space, Equation A1 can be expressed as
(A2) Û
ijk
= (X
ijk
A*)
γ
* = X
ijk
(A*
γ
*),
where Û
ijk
is the estimated utility, which means that
β
* =
A*
γ
* can be the estimated coefficient vector. In other
words, the coefficients of X
ijk
are obtained by multiplying
the regression coefficients obtained from the logit regression
on the factors by the factor coefficients that relate the drivers
to the factors.
Logit Estimation
Usually in multinomial logit regression, the observed depen-
dent variable values are ones and zeroes, corresponding to
the purchased brand (1 = “brand was purchased,” 0 = “brand
was not purchased”). This will be the case if the next pur-
chase is observed from a longitudinal panel or follow-up
survey. However, if purchase intent is used as a proxy for
next purchase, the dependent variable values will be propor-
tions that correspond to the stated (or calibrated) purchase
intention probabilities. This does not create any difficulties.
From Equation 9, we have U
ijk
= F
ijk
γ
* + ε
i
, after discard-
ing the principal components that did not meet the cutoff.
Using the laws of conditional probability, we can express
the likelihood of a particular parameter vector
γ
* given
respondent i’s observed next purchase (or purchase inten-
tion) vector p*
i
as
14
Actually, convergence is faster, because the probabilities of
next purchase are given directly, so the law of large numbers does
not need to be evoked with respect to the dependent variable.
15
For convenience, we suppress the j subscript for D, P, and U,
because for any customer i in the sample, j is fixed.
where Y
ij
equals one if customer i chooses brand j and
equals zero otherwise, the likelihoods on the right side are
the usual 0–1 logit likelihood expressions obtained as in
Equation 3, and p*
ij
is the element of p*
i
that corresponds to
firm j. The resulting likelihood for the sample is then the
product of the individual likelihoods across the respondents.
It is easily shown that with this adjustment in the likelihood,
the standard logit regression maximum likelihood algo-
rithms can be employed (Greene 1997, p. 916, 1998, pp.
520, 524). The same adjustment of the likelihood does not
affect the derivation of the asymptotic distribution of the
regression coefficients
14
(as is evident in McFadden’s [1974,
pp. 135–38] work), which means that the usual chi-square
statistics, as given in standard logit software such as
LIMDEP, can still be employed, even if the p*
ij
vector is not
all zeroes and ones.
From Equation 3, it is easily shown that the partial deriv-
ative of probability of choice with respect to utility, for
respondent i and firm k, is
15
Then, from Equation A2 we have
(A5) ∂P
ik
/∂X
ijk
= ∂P
ik
/∂U
ik
× ∂U
ik
/∂X
ijk
= (A*
γ
*)D
ik
= (A*
γ
*) p*
ik
(1 – p*
ik
).
This equation shows how each customer’s brand-
switching matrix will change given a change in any driver
(or changes in more than one driver). This result is nonlin-
(
A4) D = P / U
=
exp(U )
exp(U )
exp(U )
exp(U )
exp(U )
exp(U )
exp(U ) exp(U )
=p*
exp(U ) – exp(U )
ik ik ik
ik*
k*
ik
ik
ik*
k*
ik
ik*
k*
ik ik*
k*j k
ik
ij ik
j
∂∂
[]
−
[]
}
=
[]
×
∑
∑
∑
∑∑
∑
≠
2
2
∑
exp(U )
=p* (1–p* ).
ik*
k*
ik ik
(
A3) L( | ) = L( |Y = 1)P(Y = 1)
=L(|Y=1)p*
ij ij
ij ij
γγγγ
γγ
**
*
p*
i
j
J
j
J
=
=
∑
∑
1
1
,
Return on Marketing / 125
ear and implies diminishing returns for any driver improve-
ment. By applying the altered switching matrix in Equation
4, reestimating CLV by using Equation 5, and aggregating
across customers by using Equation 6, we find the impact on
customer equity.
The relative importance of each driver, measured as the
impact of a marginal improvement in the driver on utility,
can also be addressed as a proportion of the total marginal
impact summed across all drivers. In other words, the
importance of driver x is the per-unit amount that it con-
tributes to utility, and the relative importance is that amount
expressed as a percentage.
where C is the set of retained principal components, A
cx
is
the factor coefficient relating driver x to factor c, and γ
c
is
the logit coefficient corresponding to factor c.
In addition, we address the statistical significance of the
drivers. The coefficients, γ
c
, as estimated by the logit model,
are distributed asymptotically normally, and mean and vari-
ance are estimated and reported by standard logit regression
software. If the estimated logit coefficient and variance of
the estimate for factor c are g
c
and σ
2
c
, respectively, and
β
x
= Σ
c
A
cx
γ
c
is the coefficient estimator for driver x, then, if
we assume that the g
c
’s are distributed independently, β
x
is
a linear combination of independent normal distributions
and thus is also normally distributed. Specifically:
which results asymptotically in the following z-test for β
x
:
which is easily calculated from the results of the principal
components analysis (for A
2
cx
) and logit analysis (for β
x
and
σ
2
c
).
Computational Issues in Estimating CLV
If the time horizon is long or the customer’s frequency of
purchase is high, there may be many purchases expected
before the time horizon, which increases computation con-
siderably. Therefore, it is useful to make a simplifying
approximation that can speed up the computation. In prac-
tice, the expected purchase probabilities, B
ijt
, approach
equilibrium and change little after about 15 purchases. This
enables us to employ the approximation that the purchase
probabilities do not change after 15 purchases. If T
i
≤ 15, we
can estimate CLV
ij
as in Equation 5. However, if T
i
> 15, we
(A9) z = ,
x
1
2
β
σA
cx
c
c
22
∑
(
A8) Standard error of =
x
β
σA
cx
c
c
22
1
2
∑
,
(
)),
(
)
)()
,
*
*
A
A
A
c
c
C
c
c
C
cx
c
C
c
xS
d
6
7
100
1
11
Importance = (A and
Relative importance
(A
cx
cx
γ
γγ
=
==∈
∑
∑∑∑
=
×
16
We could also use the equilibrium probabilities. In practice,
there is little difference between the two.
can simplify the calculations. Let CLV
ij
(15) denote the life-
time value of customer i to firm j in 15 purchases, as calcu-
lated by Equation 5, and let CLV
ij
*(T
i
) and CLV
ij
*(15)
denote the lifetime values that would occur (through T
i
pur-
chases and 15 purchases, respectively) if the purchase prob-
abilities were constant and equal to B
ij,15
.
16
The expected
lifetime value of the purchases beyond purchase 15 can be
approximated as CLV
ij
*(T
i
) – CLV
ij
*(15). This is helpful
because CLV* can be viewed as a net present value of an
annuity, and it can be calculated in closed form because the
probabilities B
ij,15
are constant. Expressing the individual-
specific discount rate per purchase as d
i
* = d
i
–1/f
i
, we have
the standard expression for the net present value of an
annuity:
(A10) CLV
ij
*(t) = v
ijt
π
ijt
B
ij,15
(1/d
i
*)[1 – (1 + d
i
*)
–t
],
from which we obtain the estimated lifetime value of
(A11) Estimated CLV
ij
= CLV
ij
(15) + CLV
ij
*(T
i
) – CLV
ij
*(15).
Appendix B
Example Survey Items
(Airline Survey)
Here are some examples of survey items that might be used
to measure customer equity and its drivers. These items are
from the survey that we used to analyze the airline market.
(The headings in this Appendix are for explanatory purposes
and would not be read to the respondent.)
Market Share and Transition Probabilities
1. Which of the following airlines did you most recently fly?
(please check one)
2. The next time you fly a commercial airline, what is the
probability that you will fly each of these airlines?
Probability (please provide a percentage for each airline,
and have the percentages add up to 100%)
Size and Frequency of Purchase
3. When you fly, how much on average does the airline ticket
cost?
_____less than $300
_____between $300 and $599
_____between $600 and $899
_____between $900 and $1199
_____between $1200 and $1499
_____between $1500 and $1799
_____between $1800 and $2099
_____$2100 or more
4. On average, how often do you fly on a commercial airline?
_____once a week or more
_____once every two weeks
_____once a month
_____3–4 times per year
126 / Journal of Marketing, January 2004
_____once a year
_____once every two years, or less
Value-Related Drivers
5. How would you rate the overall quality of the following air-
lines? (5 = “very high quality,” 1 = “very low quality”)
6. How would you rate the competitiveness of the prices of
each of these airlines? (5 = “very competitive,” 1 = “not at
all competitive”)
7. The airline flies when and where I need to go. (5 = “strongly
agree,” 1 = “strongly disagree”)
Brand-Related Drivers (5 = “Strongly Agree,” 1 =
“Strongly Disagree”)
8. I often notice and pay attention to the airline’s media
advertising.
9. I often notice and pay attention to information the airline
sends to me.
10. The airline is well known as a good corporate citizen.
11. The airline is an active sponsor of community events.
12. The airline has high ethical standards with respect to its
customers and employees.
13. The image of this airline fits my personality well.
Relationship-Related Drivers (5 = “Strongly Agree,”
1 = “Strongly Disagree”)
14. I have a big investment in the airline’s loyalty (frequent
flyer) program.
15. The preferential treatment I get from this airline’s loyalty
program is important to me.
16. I know this airline’s procedures well.
17. The airline knows a lot of information about me.
18. This airline recognizes me as being special.
19. I feel a sense of community with other passengers of this
airline.
20. I have a high level of trust in this airline.
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