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Competition In An Internet Mall: A Strategic
Analysis of A New Marketing Venue
Chuan He∗
Washington University in St. Louis
Preliminary draft, comments welcome
September, 2001
∗I wish to thank Ambar Rao, Chakravarthi Narasimhan, Amit Pazgal, and Erik Durbinfor their many valuable comments.
Abstract
Retailers strive to differentiate themselves from competitors to avoid commoditizationand consequent price competition, using tools such as store location, store layout, andproduct assortment. However, such tools become ineffective on the Internet, wherecompetitors are a few clicks away, where web page design can be easily imitated, andwhere online shoppers can browse a variety of product categories at ease, making pricecomparisons using search engines. Thus, an integrated online shopping environmentsuch as that provided by an Internet mall would seem to be particularly unattractiveto retailers. Yet, Internet malls have emerged as an important electronic shoppingenvironment that, according to a recent Forrester Research report, may evolve into adominant force in Internet marketing. The purpose of this essay is to provide an expla-nation for this puzzle. We show that an Internet mall reduces price competition amongonline stores by leveraging two notable features: the search engine and the featuredstore. The search engine facilitates price comparisons but requires consumers to spendtime going through pages of search results. In contrast, consumers are directed to thefeatured store with a single click. Consumers trade off price reductions with reduc-tions in search time, leading to higher prices in the featured stores and a consequentsoftening of price competition.
We investigate a homogeneous product market with heterogeneous consumers. Weassume that consumers differ in their sensitivity to price and to the cost of time.Search costs are the product of a category specific search time and unit time cost. Tochoose between search engine driven comparison shopping and featured store shopping,consumers form price expectations that help them compare the reduction in priceobtained by searching with the cost of the search itself. We find that competitionis reduced. In addition, we find that as search costs increase, the price differentialbetween the featured stores and non-featured stores becomes larger, as is also the casewhen more shoppers purchase through the mall. We also find that a mall should featurestores for free when more shoppers purchase through it and when consumer search costsare substantial. Conversely, it should charge fees to featured stores when fewer peoplepurchase there and search costs are low. Finally, while a large mall should chargepercentage fees to participating stores, a small Internet mall may optimally offer freeparticipation to online stores. Preliminary empirical analysis supports our conclusions.
Keywords: E-Business, business models and strategies, changing customer expecta-tions, effective e-tailing approaches, game theory.
1 Introduction
Marketers usually strive to differentiate themselves from competitors to avoid commodi-
tization and consequent price competition. Retailers are no exception: store location,
store layout, and product assortment are some of the tools they use to create differen-
tiation. However, such tools become ineffective on the Internet. Competitors are just
a few clicks away, even the best web page design can be easily imitated, and online
shoppers can browse a variety of product categories at ease. And, customers can com-
parison shop using search engines. Thus, an integrated online shopping environment
such as that provided by an Internet mall would seem to be particularly unattractive
to retailers. Yet, Internet malls have emerged as an important electronic shopping
environment that may evolve into a dominant force in Internet marketing. According
to a Forrester Research report (March, 2001), Internet malls will drive almost half of
online retail sales by 2005.1 The purpose of this paper is to analyze this puzzle: we
investigate whether Internet malls can improve the profit potential of online stores and
how such profits (if any) can be achieved.
Internet malls are subsidiaries of major Internet portals, which attract millions of vis-
itors through news, games, and many other forms of entertainment. Yahoo! Shopping,
eShop at msn.com, or Shop@AOL at aol.com are some of the leaders. Similar to con-
ventional malls, Internet malls have numerous affiliated stores, thrive on their ability
to attract consumers, and derive their revenue streams by collecting fees from their
member stores. However, Internet malls differ from conventional malls in at least two
major ways. First, Internet malls have an open structure, i.e., even when an online
store is affiliated with an Internet mall, consumers can still access that store directly.
For example, the popular electronic store JandR is a member of Yahoo! Shopping. A
1It is predicted that US online retail sales will reach $104 billion in 2005.
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consumer who wants to shop at JandR can find it at the Electronics section of Yahoo!
Shopping. Alternatively, this consumer can simply go to www.jandr.com. If a brick and
mortar store is located in a conventional mall, then consumers have to go to the mall
to shop at that store. By contrast, online stores have virtual locations and thus can be
accessed directly, regardless of whether they are affiliated with an Internet mall or not.
Second, Internet malls distinguish themselves by the presence of search engines and
featured stores. The search engine allows a customer to compare prices for a product
across stores more easily than in a conventional mall, where a consumer needs to have
a sharp memory and endure several shopping trips in order to comparison shop. A
featured store has its logo embedded in a large icon that is placed in a prominent spot
on the Internet mall’s web page.2 With a single click, a consumer is directed to the
featured store. Note that when using the search engine, consumers take the initiative
in determining where they shop, whereas they are guided to the featured store by the
Internet mall. We contend that the search engine and featured stores lead to consumer
shopping behavior that is significantly different from that in conventional malls.
In this paper, we consider an Internet mall with on-line stores offering a homogeneous
product. The mall offers a menu of contracts to stores to join and to be featured.
If and when a store decides to join the mall, it decides whether to be featured or
not. It then formulates its pricing strategy based on the fee structure of the Internet
mall, on whether it is featured or not, and on consumer segmentation. Consumers are
heterogeneous, varying in their sensitivity to price and to search costs, which are the
product of a category specific search time and an individual’s unit time cost. Within
this environment, we study the following questions:
2An Internet mall’s web pages consist of shopping main page, which lists a number of productcategories, and a page for each category. The featured store icon is placed on the category specificpage the store is associated with.
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• How does the presence of search engines and featured stores affect price compe-
tition between online stores?
• If customers become sophisticated and their decision to shop at the featured
store or to use the search engine and comparison shop is endogenous, rather than
exogenously specified, what happens to the profitability of the stores and the fee
structure of Internet malls?
• When are online stores better off joining Internet malls? How does an owner of
an Internet mall determine the optimal fee structure?
We demonstrate that the presence of featured stores mitigates competition that might
otherwise be accentuated by the Internet mall environment. A featured store, because
it is easily reached, delivers extra convenience to shoppers and can therefore charge a
higher price on average. Customers can trade off this cost of convenience with the search
costs they would incur if they use the search engine to find the lowest price store. Those
who are more price sensitive and less sensitive to search costs engage in comparison
shopping, while those who are less price sensitive and more sensitive to search time opt
for the convenience of shopping at the featured store. We first examine the case where
customer segmentation is exogenously specified and it is known which customers shop
at the featured store and which ones comparison shop using the search engine. Next, we
endogenize the segmentation. We consider more sophisticated customers who make the
choice between shopping at the featured store and using the search engine to comparison
shop by forming price expectations that help them to compare the gain from search
with search costs. In both cases, we find that the featured store charges a higher price
on average than the non-featured store, thus mitigating competition. Thus Internet
malls, serving as an intermediary between online stores and consumers, improve the
profit potential of online stores. From the perspective of the mall, we find that while a
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large Internet mall charges fees that are a percentage of sales to participating stores, a
small Internet mall may optimally offer free participation. In terms of pricing, as more
shoppers purchase through an Internet mall, the price at the featured store becomes
higher, and both online stores and the Internet mall become more profitable. And, as
search costs increase, the price differential between the featured stores and non-featured
stores become larger. Preliminary empirical analysis supports these analytical results.
The rest of the paper is organized as follows: section 1.1 provides an overview of related
research, section 2 presents our model. Section 3 provides a summary and concludes.
1.1 Literature Review
Two streams of research are relevant to our study, one concerns why stores collocate,
and the other is the emerging literature on Internet institutions. Dudey (1990) argues
that firms collocate to attract more consumers by facilitating price comparisons, but
clustering increases the intensity of local competition. He shows that in the presence
of positive search costs, there exist conditions under which firms agglomerate in equi-
librium. Wernerfelt (1994) contends that when buyers incur evaluation costs for search
goods, they may refrain from incurring them for fear of later opportunism on the part
of sellers since these costs are sunk at the time of transaction. He demonstrates that
seller collocation can alleviate this problem. Messinger and Narasimhan (1997) observe
the proliferation of product assortments in grocery stores and supermarkets and at-
tribute the growth in one-stop shopping to consumer’s economizing on shopping time.
They offer theoretical and empirical evidence in support of this conjecture. Using a
Hotelling framework with vertical differentiation, Fischer and Harrington (1996) show
that firms selling similar products tend to collocate when 1. products exhibit suffi-
cient heterogeneity, 2. consumer search costs are positive, and 3. there is free entry.
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Under a similar framework, Iyer (2001) shows that when travel costs are low, even
firms selling homogeneous products (gas stations) may choose to cluster and that leads
to quality differentiation. In sum, the extant literature offers many insights on why
firms collocate. However, collocation on the Internet has distinct features due to its
open structure (Recall the JandR example). In the presence of general purpose search
engines, online stores compete with each other regardless of whether they are in or out-
side of Internet malls. Therefore, additional explanations are required to understand
why online stores join Internet malls.
Internet and e-commerce have aroused considerable enthusiasm among marketing aca-
demics. Bakos (1997) recognizes the role of the Internet in reducing search costs. He
argues that the Internet provides consumers easier access to both price information
and product information. Assuming that consumers are homogeneous in their ability
to obtain information, he shows that electronic marketplaces will lead to greater al-
location efficiency at the expense of seller profits. Lynch and Ariely (2000) conduct
an experimental study to explore the implications of reduced search costs for Internet
marketing. They find that reduced search costs for price information increases price
sensitivity, whereas lowering the cost of search for quality information reduces price sen-
sitivity. Lal and Sarvary (1999) investigate the conditions under which Internet may
soften price competition. They categorize product attributes into digital attributes
and nondigital attributes. While digital attributes are amenable to the Internet and
can be evaluated easily online, nondigital attributes require physical inspection. This
classification is similar to the distinction between search goods and experience goods.
They demonstrate that given consumers’ favorable prior evaluation of nondigital at-
tributes, the low cost of evaluating digital attributes on the Internet enhances loyalty
and hence increases seller profits. In a conceptual paper, Alba et al. (1997) exam-
ine the impact of e-commerce on the entire marketing channel. They point out that
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online shopping reduces the importance of location and may replace or complement
traditional retail formats. Balasubramanian (1998) models competition in a multiple
channel environment where consumers may purchase from traditional retailers and di-
rect sellers, including catalog and Internet marketers. Assuming that consumers have
complete information about product and price information in all channels, he identifies
the conditions under which traditional stores may accommodate the entry of direct
sellers. Additionally, he shows that the level of information disseminated by direct sell-
ers have strategic implications. Specifically, high market coverage may depress profits.
Iyer and Pazgal (2001) explore the strategic implications of Internet shopping agents
(ISA), they show that when the reach of the institution is endogenous and when the
traffic at the ISA confers complementary side-benefits, there exists a unique number of
retailers who will join the institution. Furthermore, they find that the ISA will have
the incentive to share the side benefits with the inside retailers. Various other aspects
of Internet and e-commerce have been addressed in recent research. Novak, Hoffman
and Yung (2000) offer an approach to measure customer experience in an online en-
vironment, Hauble and Trifts (2000) study the effects of interactive decision aids in a
controlled experiment, Bradlow and Schmittlein (2000) model the performance of In-
ternet search engines, Bakos and Brynjolfsson (2000) provide insights to the bundling
of and competition among information goods.
This research adds to the extant literature in that it shows that an Internet institution
can generate a positive externality in a commodity market.3 In particular, an Internet
mall softens price competition between online stores and as the same time offers extra
convenience to consumers. These objectives are accomplished by leveraging two notable
features of Internet malls—the search engine and featured stores. Since consumers differ
3Although products are differentiated, online retailers’ product assortments have significant over-laps. In many cases, their product bundles can be considered roughly homogeneous.
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in their ability and willingness to search, the search engine facilitates price comparisons
for those who are price sensitive, while featured stores provide one-stop shopping to
those who are price insensitive.
2 The Model
Our model analyzes the strategic behavior of competing stores in an Internet mall,
henceforth referred to as the Emall. To capture the essential features while keeping the
analysis tractable, we investigate the interactions among the Emall and two competing
stores in a representative category. It is assumed that the Emall stores offer identical
products, with the only differentiating dimension being their pricing policies. We
assume that all consumers buy one unit of product in any given period and have a
common reservation price r. Without loss of generality, we normalize the costs of the
online stores, such as payment to wholesalers/manufacturers and selling costs, to be
zero.
Consumers are divided into two broad groups: those who shop at the Emall, and those
who don’t. The Emall shoppers have two options; they can either shop at the fea-
tured stores or shop using the Emall search engine. To make a shopping decision, an
Emall shopper compares the expected price difference between the featured and non-
featured stores with the expected time and cost he has to invest in searching. If he
finds that the benefit from search is greater than his search cost, he will shop using the
search engine, otherwise, he will shop at the featured store. The non-Emall shoppers
are either loyal customers or price shoppers. The loyal customers always shop at their
favorite stores. In contrast, the price shoppers are deal prone, they are either unaware
of the Emall or prefer to use shopping bots or general-purpose search engines. The
patterns of consumer behavior discussed above imply four distinct consumer segments:
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non-Emall price shoppers (A segment), Emall comparison shoppers (B segment), fea-
tured store shoppers (C segment), and loyal customers (D segment). Normalizing the
total consumers to a unit mass, we have A + B + C +∑
i αi = 1, where∑
i αi is the
size of the D segment, the subscript i is a store index, i = 1, 2.
Joining the Emall is not without cost, each store needs to pay a portion of its rev-
enues generated through the Emall as royalties. Consider the JandR example we used
earlier. If a consumer purchases a VCR from JandR by going to www.jandr.com, this
consumer is a non-Yahoo! shopper, and JandR does not pay anything to Yahoo! for
this consumer’s purchase. Alternatively, if the consumer goes to Yahoo! ’s Electronics
section and then buys from JandR using the links provided, JandR has to pay a portion
of such revenues to Yahoo!.
We assume that the Emall, the stores, and consumers are all utility maximizers with
rational expectations. The sequence of actions is as follows (see figure 1). First, the
Emall announces its fee structure for the featured and non-featured stores. Second,
the online stores simultaneously decide whether to join the Emall or not and whether
they want to be featured or not; they then simultaneously formulate their pricing
policies. Third, correctly anticipating the stores’ pricing strategies, consumers make
their purchase decision. In particular, Emall shoppers decide whether to use the search
engine or shop at the featured store.4 We adopt subgame perfect equilibrium as the
solution concept throughout the paper. To facilitate a smooth flow of our paper, we
have kept the mathematical details at a minimum. For technical notes and proofs,
readers are referred to Appendices A and B.
4A search engine facilitates price comparisons by looking up prices of the same item and similaritems from different stores but often requires a consumer to patiently go through pages of searchresults. By contrast, a consumer can make a purchase at a featured store with a few clicks.
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The Emall
Online Stores
EmallShoppers
fee structure(two-part tariff)
join or not, whether want to be featuredor not
price setting
in-inin-outout-out
featured store shopping
search
outcome
featured store
non-featured store
Figure 1: The decision process
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2.1 Base Model
The competition between the two stores is contingent upon their decisions in two stages.
In the first stage, the stores decide whether to join the Emall or not. In the second
stage, they determine their pricing policies. We begin our analysis from the second
stage.
2.1.1 The Setting
Assume that the two stores are symmetric with equal loyal segment of size α, con-
sumer segments are fixed and their sizes are public knowledge, and the Emall charges
a two-part tariff to its member stores.5 We begin our analysis assuming that the
Emall charges fixed fees. Later in this section we will consider percentage fees and
the implications of the two alternative fee structures. In formulating its pricing deci-
sion, each store faces three possible scenarios: 1. both stores are Emall stores (in-in),
2. one store joins the Emall, the other stays out (in-out), and 3. both stores are
non-Emall stores (out-out). We discuss each of these scenarios in turn.
2.1.2 Results
in-in Without loss of generality, we assume that store 1 is the featured store.6 The
fees that the stores pay to the Emall is sunk cost, therefore, it is not included in the
equilibrium analysis. Under this setting, it can be established that only mixed strategy
equilibrium exists.7 Let the price support of the two stores be [p, r], and Fi(p) the price
5Among a variety of linear and non-linear pricing schemes, we assume that the Emall chooses thesimplest schemes that guarantees full extraction of economic rents—two-part tariff.
6We will show later that featuring both stores is not optimal for the Emall. In equilibrium theEmall will charge a fee such that the featured store and the non-featured store expect the same levelof profits. Thus, the two stores are indifferent to being featured or not. If there is a tie, that is, bothstores want to be the featured store, the Emall randomly features one of the stores.
7Rigorous proofs are developed in Varian (1980) and Narasimhan (1988). More details are givenin Appendix A.
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distribution function for store i. In a mixed strategy equilibrium, store i is indifferent
to charging any price in its price support. If the featured store charges the reservation
price r, it will be patronized by its loyal customers and featured store shoppers, the
resulting profit is (α+C)r. If the featured store charges a lower price than that of its
competitor, it will get the business from comparison shoppers in addition to its loyal
customers and featured store shoppers, the resulting profit is (α+A+B +C)p. Since
the featured store can make at least (α + C)r by charging the reservation price r, the
lower bound of the price support is given by
p =(α + C)r
α + A+B + C(1)
Note that store 1 always gets the business from featured store shoppers (C segment),
whereas store 2 never gets their business. On the other hand, the store that charges
a lower price will be patronized by comparison shoppers (A and B segments). The
expected profits for store 1 and store 2 are π1 = (α + C)r and π2 = p(α + A + B),
respectively. Given the setup specified above, the two stores’ equilibrium strategies are
characterized by the following price distribution functions:
F1(p) =
0, p <(α+C)r
α+A+B+C,
(α+A+B)[(α+A+B+C)p−(α+C)r](α+A+B+C)(A+B)p
,(α+C)r
α+A+B+C≤ p < r,
1, p ≥ r.
(2)
and
F2(p) =
0, p <(α+C)r
α+A+B+C,
(α+A+B+C)p−(α+C)r(A+B)p
,(α+C)r
α+A+B+C≤ p ≤ r,
1, p ≥ r.
(3)
Proposition 1. F1(p) first order stochastically dominates F2(p), that is, the featured
store charges a higher price on average. The expected price at the featured store and
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Emall profit are increasing in the number of Emall shoppers.
Proof: All proofs are in Appendix B.
The competitive environment is moderated by the size of the loyal segment: the
larger the loyal segment, the less intense is the competition between the stores. In
addition, the degree of competitiveness is also affected by the segmentation among
Emall shoppers, which is driven by the features of the Emall—search engine and fea-
tured store. The stores compete more vigorously when more shoppers engage in search
and less so when more shoppers shop at the featured store.
in-out Assume without loss of generality that store 1 is an Emall store but store 2
is not. In this situation, store 1 is the featured store by default. The expected profits
before fees to the Emall for store 1 and store 2 are π1′ = (α+C)r and π2′ = p(α+A+B),
respectively, where p = (α+C)rα+A+B+C
. Note that when no switchers shop at the Emall,8
i.e., (B+C)→ 0, the in-out scenario converges to the situation analyzed in Narasimhan
(1988).
out-out When both stores are non-members, their expected profits are π = αr. Be-
side their loyal customers, the two stores vie for the business of comparison shoppers.9
The payoffs for the two stores in the three alternative scenarios are summarized in
table 1. Note that all payoffs are gross profits before payment of fees to the Emall , if
any.
8Of course, if that is the case, the Emall will face extinction.
9When both stores are outside of the Emall, Emall comparison shoppers (B segment) and featuredstore shoppers (C segment) are not defined. In that case, consumers in B segment use all means tolook for the lowest price, while consumers in C segment may drop out, search, or become loyal. Weassume that all consumers in C segment search or drop out in this case. The two stores’ customerbase consists of their loyal customers and comparison shoppers of size A+B+C. Comparative staticsshow that our results hold when some consumers in C segment become loyal. If all consumers in Csegment become loyal, then no online store should ever join the Emall, which contradicts reality.
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Table 1: Payoffs for in-in, in-out, and out-out under fixed fees
in out
in , ,
out , α r , α r
Store 2
Store 1
)()(
BACBA
rC +++++
+ αα
α
)()(
BACBA
rC +++++
+ αα
αrC )( +α )(
)(BA
CBArC +++++
+ αα
α
rC )( +α
rC )( +α
Featuring one store vs both stores We have assumed earlier that the Emall features
one store only, will the Emall be better off featuring both stores? To answer this ques-
tion we need to look at the Emall’s revenue base (the largest possible revenue upon
which the Emall may collect fees) R under the two scenarios. The revenue base for
the Emall when one store is featured is simply the sum of the equilibrium revenues of
the two stores, R1 = (α + C)r + p(α + A + B) = (α + C)r + (α+C)rα+A+B+C
(α + A + B).
Since the two stores are identical, featured store shoppers are equally likely to shop at
either store when both stores are featured. Thus, the revenue base for the Emall when
both stores are featured is R2 = 2[(α + C2)r]. Since R1 > R2, the Emall will feature
one store only.
Percentage fee Rather than charging fixed fees, the Emall may charge percentage
fees to its member stores. It is not intuitively clear which fee structure yields higher
profit to the Emall and we need to identify the conditions under which one fee struc-
ture dominates the other. Assume that the percentages of revenue the Emall collects
from the featured store (store 1) and the non-featured store (store 2) are d1 and d2,
respectively. It should be noted that the percentage fee only applies to the purchases
driven by Emall traffic. In the in-out scenario, the Emall can only impose a percentage
fee of d on the store that chooses to join. The payoffs for the two stores in the in-in,
in-out, and out-out scenarios are summarized in table 2.
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Table 2: Payoffs for in-in, in-out, and out-out under percentage fees
in out
in , ,
out , α r , α r
Store 2
Store 1
)()1) ((
) ]1([BA
dCBArdC ++−+++
−+ αα
α
)()1) ((
) ]1([BA
dCBArdC ++−+++
−+ αα
α rdC )]1([ −+α
rdC )]1([ 1−+α rdC )]1([ −+α)]1([)1)((
)]1([2
1
1dBA
dCBArdC −++−+++
−+ αα
α
Optimal fee structure of the Emall With the two stores’ pricing decisions in
mind, we now examine their decisions regarding whether to join the Emall or not in
the first stage. Although each store is better off joining the Emall individually, it is
not necessarily so when both stores join simultaneously. The intuition is as follows.
When at least one store joins the Emall, some consumers10 forego search in favor
of the featured store. The featured store shoppers are willing to pay more for the
convenience11 and as a result, the featured store is less inclined to attract comparison
shoppers by cutting price.12 Consequently, the featured store softens competition and
both stores enjoy higher profits. However, the non-featured store can stay out to avoid
the Emall’s fee and still reaps the benefit of the improved competitive environment.
This free-riding limits the Emall’s ability to collect fees because as long as the non-
featured store can make a higher profit by not joining the Emall, both stores will choose
to stay out in equilibrium. To see this point, consider the payoffs for in-in, in-out, and
out-out under fixed fees, as shown in table 1. In order to attract both stores, the
Emall has to charge a fixed fee such that each store makes at least the same level of
profit as that of the outside store in the in-out scenario, (α+C)rα+A+B+C
(α + A+ B), which
is larger than the profit a store will make without the Emall, αr.
10These are the consumers who are aware of the Emall and have no loyalty to either store.
11As we shall see in the next section, the convenience is measured by the reduction in search costs.
12Technically, the lower bound of the price support is higher when one store is featured by theEmall.
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Proposition 2. The optimal strategies of the Emall are characterized as follows:
(i) For all fee structures both stores join the Emall in equilibrium.
(ii) Under fixed fees, the Emall charges f1 = (α+C)rCα+A+B+C
to the featured store and f2 = 0
to the non-featured store and its profit is Rf = (α+C)rCα+A+B+C
.
(iii) Under percentage fees, the Emall charges d1 = Cα+CA−αB(α+A)C
to the featured store and
d2 = CA−αB(α+A)C
to the non-featured store and its profit is Rp = Crd1+[α+C(1−d1)]r
α+A+(B+C)(1−d1)Bd2.
(iv) Percentage fees dominate fixed fees when CB> α
A.
Proposition 2 says that given the number of loyal customers (α segment) and those
who are unaware of the Emall (A segment), percentage fees are more profitable to the
Emall when the size of the featured store shoppers segment (C segment) is sufficiently
large relative to the Emall comparison shoppers segment (B segment). The superiority
of percentage fees vs fixed fees crucially depends on their ability to control free-riding,
which occurs when one store joins the Emall and the other store competes from outside
the Emall. In that case, the outside store reaps the benefit of the better competitive
environment in the presence of the Emall but avoids paying fee. The comparison be-
tween fixed fees and percentage fees is similar to that between lump-sum tax and ad
valorem tax. While ad valorem tax is easy to implement, it introduces distortion and
results in welfare loss. Fixed fees have no impact on the stores’ pricing strategies.
Under percentage fees, however, an online store’s pricing strategy is affected by the
Emall whether it is inside the Emall or out. The larger the size of the featured store
shoppers segment, the more influential are the Emall’s percentage fees on both stores’
pricing strategies, thereby effectively deters free-riding and improves the Emall’s prof-
itability. The drawback of percentage fees is that the higher percentage charged to
the featured store depresses the average price level and thus hurts the profits of both
stores as well as the Emall. To take advantage of percentage fees’ ability to control free
riding and ameliorate their downward pressure on price and profits, the Emall can use
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a combination of fixed fee and percentage fees. Specifically, the Emall should charge
a uniform percentage fee d to both stores and a fixed fee to the featured store in the
amount of [α + C(1 − d)]r − [α+C(1−d)]rα+A+(B+C)(1−d)
[α + A + B(1 − d)]. Under this pricing
scheme, a pure fixed fee is simply a special case when the percentage fee is 0.
Lemma 1. A two-part tariff is superior to pure fixed fees and pure percentage fees.
2.1.3 Discussion of Base Model Results
In the base model we analyzed the impact of the Emall on the competitive strategies
of the online stores and the Emall’s optimal fee. We show that the featured store
plays a competition reducing role and that the Emall is not only profitable but also
beneficial to both online stores and consumers. Our analyses demonstrate that per-
centage fees are superior to fixed fees when the featured store shoppers segment is
relatively large. This implies that the Emall should adopt fixed fees in its embryonic
stage and percentage fees as it becomes well established. These insights conform to
reality. For example, Excite shopping, a minor Internet mall, offers free participation
to online stores and charges fixed fees for advertising (note that feature is one form of
advertising). By contrast, Yahoo! Shopping charges 2% revenue share on sales driven
by Yahoo! Shopping to participating stores. In addition, it is widely publicized that
Yahoo! reached agreements with many of its featured stores in the form of payment
contract or mutual advertising agreements, which are equivalent to fixed fee.13 We
predict that the featured store charges a higher price on average, and that the more
shoppers purchase through the Emall, the higher the price of the featured store. These
predictions are supported by the data we collected.
13The pricing information of Excite shopping and Yahoo! Shopping were collected from their websites in February 2001.
16
2.2 Segmentation among Emall shoppers endogenized
We have shown that Internet mall is a profitable business model that benefits online
stores as well as consumers when customer segmentation is determined exogenously.
Will this result hold in a setting where consumer behavior is endogenous? In this
section we relax the assumption that the Emall comparison shoppers segment and
featured store shoppers segment are fixed and allow Emall shoppers to choose their
segment membership endogenously. Assume that the total search costs are the product
of search time and unit time cost, i.e., t = γs, where the time cost (s) is uniformly
distributed, s ∈ U [0, 1], and search time (γ) is a category specific constant. This
assumption embodies the idea that total search costs are stable for each individual but
are heterogeneous across consumers within each category, and that total search costs
for each individual differ across categories. We may interpret unit time cost (s) as
consumer type. Search time (γ) is determined by category characteristics such as the
complexity of product attributes and usage frequency. In inexpensive categories with
simple and salient attributes, such as CDs and books, search time is shorter. Such
categories are likely to be associated with small γ. The opposite is true for categories
which are more expensive and contain products with sophisticated and ambiguous
attributes, such as apparel and computers.
The choice between shopping at the featured store and using the search engine to find
the least expensive product depends on the pricing policies of the stores as well as
search costs. If customers believe that the difference in price between the featured and
non-featured stores is relatively small, consumers who have moderate search costs will
shop at featured store and thus become a member of the C segment. Conversely, if
the price differential is expected to be substantial, even consumers with high search
costs may use the search engine and become a member of the B segment. In order to
17
determine the size of the Emall comparison shoppers (B) and featured store shoppers
(C) segments, we need to consider consumers’ expectations. Recall that consumers
correctly anticipate the pricing policies of the stores. In the base model, we have shown
that the featured store charges a higher price on average. Therefore, featured store
shoppers expect to pay a higher price, but the price differential should be no greater
than the savings in search costs they would incur if they used the search engine. By
contrast, Emall comparison shoppers purchase from the low price store, which can be
either the non-featured store (more frequently) or the featured store (less frequently).
2.2.1 The Setting
As in the base model, we assume that store 1 is the featured store. Comparison shoppers
(B segment) expect to pay the average minimum price. By contrast, featured store
shoppers (C segment) expect to pay the average price (p) of store 1. The probability
distribution functions for pmin and p are as follows:
Prob{min(p1, p2) < p} = (1−Q)[1− (1− F c1 (p))(1− F2(p))] +QF2(p) (4)
and
Prob{pf = p} = Qr + (1−Q)F c1 (p) (5)
whereQ denotes the mass point of store 1’s price distribution function at the reservation
price r, Q = C(1−d)α+A+(B+C)(1−d)
, and F c1 (p) denotes store 1’s conditional price distribution
function for p ∈ [p, r).14
14Store 1’s price distribution function F1(p) as shown in the base model is not a proper distributionfunction because F1(r) < 1. To calculate the average price of the featured store, we derive F c
1 (p)conditional on p1 < r. More details are given in Appendix A.
18
Define disutility as any loss in utility. Emall shoppers incur different magnitudes of
disutility in comparison shopping versus featured store shopping. In both cases, con-
sumers suffer a utility loss for the price they pay. However, comparison shoppers
sustain a further utility loss by incurring higher search costs, which is measured by
the product of the time cost (s) and search time (γ). Without loss of generality, we
normalize the search costs for featured store shoppers to 0. The disutility for con-
sumers in comparison shopping (B segment) and featured store shopping (C segment)
are dui = pmin + γs and duf = p, respectively. In choosing their segment membership,
Emall shoppers will use the search engine when they expect dui < duf ; by contrast,
they will shop at the featured store when they expect duf < dui. In equilibrium, s∗
solves dui = duf , where s∗ = B
B+C. That is, consumers whose time cost is s ∈ [s∗, 1]
shop at the featured store, whereas consumers whose time cost is s ∈ [0, s∗] use the
search engine. Equilibria are obtained by backward induction and the derivation in-
volves the following steps: 1. The Emall decides on optimal fee structure, 2. Online
stores decide whether to join or not, 3. Knowing that prices affect segment sizes, online
stores formulate pricing strategies taking the Emalls fee structure as given, 4. Given
online stores pricing strategies, Emall shoppers form expectations and decide whether
to search or shop at the featured store. In equilibrium, the sizes of B and C segments
are such that all optimality conditions in steps 1, 2, and 3 are satisfied.
2.2.2 Equilibrium
As shown in Figures 2 and 3, two types of equilibria emerge. Each figure contains three
graphs. The graph on the top illustrates how the sizes of Emall comparison shopper
segment (B) and featured store shopper segment (C) change as search time (γ) varies;
the graph in the middle demonstrates how the average price at the featured store (pf )
and the average minimum price (pmin) change as search time (γ) varies; the graph at
19
Figure 2: A portrayal of the stable equilibrium
0
0.1
0.2
0.3
0.4
0.5
0.6
0.7
0.8
0 0.2 0.4 0.6 0.8 1 1.2γγγγ
Seg
men
t Siz
e
B
C
00.20.40.60.8
11.21.41.61.8
2
0 0.2 0.4 0.6 0.8 1 1.2γγγγ
p
Pf
Pmin
0
0.1
0.2
0.3
0.4
0.5
0.6
0.2 0.4 0.6 0.8 1 1.2
γγγγ
π πππ π1
π2
20
Figure 3: A portrayal of the unstable equilibrium
0
0.1
0.2
0.3
0.4
0.5
0.6
0 0.2 0.4 0.6 0.8 1 1.2γγγγ
Seg
men
t Siz
e
B
C
2.35
2.4
2.45
2.5
2.55
2.6
2.65
2.7
0 0.2 0.4 0.6 0.8 1 1.2γγγγ
p
Pf
Pmin
0
0.5
1
1.5
2
2.5
0 0.2 0.4 0.6 0.8 1 1.2
γγγγ
π πππ
π1
π2
21
the bottom shows how profits of the featured store (π1) and the non-featured store (π2)
change as search time (γ) varies.15 In one type of equilibrium (the stable equilibrium),
as search time (γ) increases, the number of featured store shoppers (C segment) in-
creases,16 the average price at the featured store (pf ) and the average minimum price
(pmin) both increase, and the profits of the featured store (π1) and the non-featured
store (π2) both increase. By contrast, in the other type of equilibrium (the unstable
equilibrium), as γ increases, the number of featured store shoppers (C segment) de-
creases, the movement of pf and pmin diverges with pf monotonically increasing and
pmin monotonically decreasing, π1 declines and π2 roughly stays put. The first type of
equilibrium is intuitively appealing because everything else being equal, more shoppers
shop at the featured store and the featured store enjoys higher profit as search costs17
increases. However, the other type of equilibrium is indeed subgame perfect. The
Emall’s profitability and whether the profitability is invariant to the degree of con-
sumer sophistication critically depend on which type of equilibria prevails. We show
that the first type of equilibria (the stable equilibrium) dominates the other using an
intuitive refinement.
Proposition 3. There is a unique subgame perfect Nash equilibrium that survives the
refinement. In that equilibrium, the price differential between the featured and non-
featured stores widens as the size of the featured store shopper segment (C) increases.
In Figure 4, the difference between p and pmin (diffp) is drawn against C. The stable
equilibrium is located in the increasing segment of the graph, whereas the unstable
15The following parameter values are used to calculate equilibria for each given value of γ: r=3,αi = 0.1, A = 0.08, B + C = 0.72.
16Note that the sum of B and C segments is fixed, so increasing number of featured store shoppers(C segment) implies declining number of Emall comparison shoppers (B segment).
17Recall that search costs are the product of time cost (s) and search time γ.
22
−2
−1.5
−1
−0.5
0
0.5
1
1.5
0.0 0.1 0.2 0.3 0.4 0.5 0.6 0.7 0.8
C
diff
p
a stable equilibrium
an unstable equilibrium
Figure 4: An intuitive refinement
equilibrium is located in the decreasing segment of the graph. Suppose that the two
stores’ strategy sets are fixed, as γ increases, more shoppers will shop at the featured
store (C increases). Now, since the stable equilibrium is in the increasing segment
of the graph, as C increases, the gap between p and pmin (diffp) widens—the gain
from using the search engine becomes larger, which counterbalances the increase in
C. Thus, the stable equilibrium is a fixed point. By contrast, since the unstable
equilibrium is in the decreasing segment of the graph, as C increases, the gap between
p and pmin (diffp) becomes narrower, which leads to further increase in C. Thus, an
irrelevant disturbance causes the collapse of the unstable equilibrium, in other words,
the unstable equilibrium does not constitute a fixed point.
2.3 Empirical support
In this section we test the following model predictions:
23
1. Featured stores charge higher prices on average.
2. A featured store at a large Internet mall charges a higher price than that of a
featured store at a small Internet mall.
2.3.1 Featured stores charge higher prices on average
We track the prices at a number of Yahoo! Shopping featured stores and non-featured
stores for the following product categories: PDAs, printers, digital cameras, phones,
camcorders, DVD players, small appliances, DVDs. Within each category, we check
the price of an item at a featured store and then search the same item using Yahoo!
Shopping search engine. For every product, there are a few featured stores but nu-
merous non-featured stores. We record the prices of a product at all stores. Yahoo!
Shopping rates merchants on a five-star scale. One-star means poor, five-star means
excellent. Store rating is based on customer feedback on a number of attributes such as
customer service, fulfillment, etc. We record store rating along with price information.
Data are collected for multiple items within each category.
Recall proposition 1 says that the pricing strategy of the featured store first order
stochastically dominates the pricing strategy of the non-featured store. This claim has
two implications. First, it implies mean dominance, i.e., the featured store charges a
higher price on average. Second, it implies that one should observe that the featured
store charges a higher price more frequently. Both of these implications will be tested.
Let pf and pnf denote the prices of an item at the featured store and a non-featured
store, respectively. In a reasonably large sample set, we should observe pf > pnf
(confirmation) with a frequency significantly larger than 50%, where pf is the average
price at the featured stores and pnf is the average price at the non-featured stores. The
percentage of confirmation provides partial support for the two implications mentioned
24
earlier. To see whether the difference between the average prices at the featured stores
and the average prices of the non-featured stores is significant, we perform a t-test.
Category level likelihood ratio test is conducted to examine whether the prices at the
featured stores are larger than the prices at the non-featured stores at a frequency
significantly above 50%. The test procedure of the category level likelihood ratio test
is as follows. Within each category, we count the number of occasions where the price
of a featured store is larger than that of the non-featured stores. Assume the event
that a featured store charges a higher price is a random draw from a binomial process,
then the likelihood of observing that event is:
L = C(n, k)pk(1− p)n−k
where n is the total number of price comparisons between the featured and non-featured
stores, k is the number of occasions where the featured store charges a higher price.
The null hypothesis is that it is equally likely to observe a featured store to charge a
higher or lower price than the non-featured store (p = 0.5), the alternative hypothesis
is that this probability is larger than 0.5 (p = kn). The test statistic is:
r = −2 lnL0
L1
which has a χ2 distribution. Table 3 presents some summary statistics. A snapshot of
the actual data is given in Appendix C. The complete data set is available from the
author upon request.
The percentages of confirmation, t statistics, and category level likelihood ratio test
statistics across the eight product categories reported in Table 3 support our theoretical
prediction that featured store charges higher prices on average. To check whether
25
Table 3: Some descriptive statistics of the data: Price comparisons between the fea-tured and non-featured stores (p-value in parenthesis)
Category PDAs Camcorders Printers Digital�Cameras
DVD�players
Phones Small�Appliances
DVDs
#�of�Products 10 10 10 10 10 10 6 10%�of�Confirmation 80% 80% 80% 90% 90% 70% 100% 90%
t�Statistics4.18�
(0.002)2.98�����
(0.015)6.28�
(0.0002)2.84�
(0.01)2.83�
(0.01)2.82�
(0.013)3.88����
(0.006)4.42�
(0.001)Category�Level�Likelihood�Ratio�Test�Statistics�(χχχχ2)
24.66�(<0.005)
16.56�(<0.005)
7.62�(0.01)
31.99�(<0.005)
16.25�(<0.005)
7.62�(0.01)
26.39�(<0.005)
11.63�(<0.005)
Table 4: Price–Rating Correlations (p-value in parenthesis)
PDAs Camcorders PrintersDigital�
CamerasDVD�
playersPhones
Small�Appliances
DVDs
Correlation�between�Price�and�
Rating
0.1351����(0.20)
0.0089���(0.93)
0.0785�(0.46)
0.0536��(0.62)
-0.0079�(0.94)
-0.1151�(0.28)
-0.0583�����(0.68)
-0.0423�(0.69)
featured stores charge higher prices due to other factors such as store reputation and
customer service level, we calculate the correlation between price and store rating for
each of the eight product categories. The results are reported in Table 4. It is found
that price is uncorrelated with store rating for all categories.
The fact that price is uncorrelated with store rating does not fully justify that feature
leads to higher price. For example, if consumers who prefer convenience to price rate
stores on the basis of convenience, and consumers who prefer price to convenience rate
stores on the basis of price, then store rating is inconsistent. To cope with this problem,
we conduct a survey. All stores in a Yahoo! Shopping product category are listed in the
survey. The subjects are asked to indicate whether they are aware of these stores, and
rate the perceived reputation for those stores that they are aware of. We search the
prices for ten products in this category. There are seven featured stores and eighty-two
26
Table 5: Regression Results
Intercept ∆∆∆∆A ∆∆∆∆RCoefficients 0.181971 -0.120255 -0.024674
t Stat 4.444724 -0.831226 -1.506315
Coefficients 0.126167 − −t Stat 4.808218 − −
non-featured stores that carry these products. For the featured and non-featured stores
that carry the same product, we calculate the difference in prices (∆P ), the difference
in awareness (∆A), and the difference in perceived reputation (∆R). We then regress
∆P on ∆A and ∆R. The intercept measures the effect of being featured. The results
are reported in Table 5. The coefficients of ∆A and ∆R are insignificant. In contrast,
the intercept is positive and significant. Thus, feature is the driving force behind the
price premiums of the featured stores over the non-featured stores.
2.3.2 A featured store at a large Internet mall charges a higher price than
that of a featured store at a small Internet mall
To verify whether featured stores at a large Internet mall charge higher prices than
those at a small Internet mall, we track the prices at a number of Yahoo! Shopping
featured stores and Shopping.com featured stores. Yahoo! Shopping is a large Internet
mall, and Shopping.com is a minor Internet mall, measured by the traffic volume
of their underlying Internet portals. According to PC Data Online, the numbers of
unique visitors to Yahoo! and AltaVista.com (the underlying portal of Shopping.com)
in December 2000 are 65.9 million and 18.5 million, respectively. We choose five pairs
of featured stores at the two Internet malls from the following two product categories:
computer and electronics. Within each category, we check the price of a particular
item at a Yahoo! Shopping featured store and that of its counterpart at Shopping.com.
27
Let pLf and pSf denote the prices of an item at the featured store of a large Internet mall
and a small Internet mall, respectively. In a reasonably large sample set, we should
observe pLf > pSf (confirmation) with a high frequency. The following table presents
some summary statistics. A snapshot of the actual data is given in Appendix C. The
complete data set is available from the author upon request.
Table 6: Some descriptive statistics of the data: Price comparisons between the fea-tured stores at a large Internet mall and a small Internet mall
Category # of Items # of Confirmation % of ConfirmationComputer 39 38 97.4%Electronics 9 8 88.9%
2 48 46 95.8%
2.4 An alternative featured store selection mechanism
It is not a priori clear how the Emall should choose the featured store. The decision to
feature a store may be an ongoing one, i.e., after the Emall announces its fee structure
for joining, every week the featuring decision is made (just as in a supermarket!).
Rather than collecting a fixed fee or a higher percentage fee from one of the stores
and feature it (mechanism 1), the Emall may choose to feature the store that charges
a higher price (mechanism 2). Intuitively, such a featured store selection mechanism
induces the stores to raise their prices to capture featured store shoppers (by being
featured). Without this inducement, the stores’ natural tendency is to compete for the
comparison shoppers by charging a lower price. Thus, mechanism 2 helps to reduce
price competition between online stores, thereby improves the Emall’s revenue. In this
section we investigate the relative merit of the two alternative featured store selection
mechanisms.
28
2.4.1 The Setting
Assume that both stores are members of the Emall and the Emall picks the high price
store to be the featured store. When store i charges the reservation price, it will be
selected as the featured store by the Emall and get the business from featured store
shoppers (C segment) and its loyal customers. On the other hand, if store i charges a
lower price than store j (i, j = 1, 2, i 6= j), it will get the business from switchers who
do comparison shopping (A and B segments) and its loyal customers.
2.4.2 Results
Under the alternative featured store selection mechanism, the two stores’ equilibrium
strategies are characterized by the following price distribution function:
F (p) =
0, p <[α+C(1−d)]rα+A+B(1−d)
,
[α+A+B(1−d)]p−[α+C(1−d)]r[A+(B−C)(1−d)]p
,[α+C(1−d)]rα+A+B(1−d)
≤ p ≤ r,
1, p ≥ r.
(6)
Lemma 2. The larger the featured store shopper segment (C), the more profitable are
the stores. On average, the featured store charges a higher price regardless of which
featured store selection mechanism is implemented.
Of the two alternative mechanisms to select the featured store, which one is more
advantageous to the Emall? It turns out that the relative merit of the two mechanisms
is closely related to the percentage of shoppers who shop at the Emall and search time
(γ). Define k as the percentage of shoppers who shop at the Emall, k = B+CA+B+C
. When
most shoppers shop at the Emall (k large), it is better off for the Emall to choose the
high price store to be the featured store (mechanism 2). On the other hand, when a
significant percentage of shoppers shop outside the Emall (k small), it is more desirable
29
0
0.1
0.2
0.3
0.4
0.5
0.6
0.7
0.8
0.9
1
0 0.2 0.4 0.6 0.8 1
k
Σπ ΣπΣπΣπ
Mechanism 1 dominates Mechanism 2 dominates
Figure 5: Comparing the two featured store selection mechanisms: a market coverageperspective
for the Emall to collect a fee from one of the stores and set that store as the featured
store (mechanism 1). This result can be visualized in Figure 5.
In Figure 5, we have drawn the total profits of the two firms (∑
π) against the per-
centage of shoppers who shop at the Emall (k). When the Emall has high market
coverage (k > 0.78 in the graph), mechanism 2 yields higher total profits than that
from mechanism 1, which implies that the Emall will receive more revenue by choosing
the high price store as the featured store.
Similarly, when shoppers have strong preference toward the featured store due to high
search costs, the Emall is better off to choose the high price store as the featured store
(mechanism 2). By contrast, when featured store preference is relatively weak (search
costs are low), it is more advantageous for the Emall to let one of the stores pay a
fee and be featured (mechanism 1). Recall that search costs depend on search time
30
0
0.2
0.4
0.6
0.8
1
1.2
1.4
1.6
1.8
0.56 0.61 0.66 0.71 0.76 0.81 0.86 0.91 0.96
γγγγ
Σπ ΣπΣπΣπ
Mechanism 1dominates
Mechanism 2 dominates
Figure 6: Comparing the two featured store selection mechanisms: a search costsperspective
(γ). We illustrate this result in Figure 6. In Figure 6, the total profits of the two
firms (∑
π) are drawn against category specific search time (γ). When search time is
substantial (γ > 0.67 in the graph), mechanism 1 yields higher total profits than that
from scenario 2. Thus, mechanism 1 is more profitable to the Emall when γ is large.
Proposition 4. It is more profitable for the Emall to select the high price store to be
the featured store when the Emall is sufficiently attractive (k large), or shoppers incur
substantial search costs (γ large).
The intuition for proposition 4 is as follows. Under mechanism 2, online stores trade
off the benefit from charging a lower price with that of charging a higher price. While
a lower price attracts comparison shoppers, a higher price improves the store’s chance
of being featured, in which case the store captures featured store shoppers. The larger
the featured store shoppers segment, the larger the benefit of charging a higher price.
31
When the featured store shoppers segment is large enough (γ and k large enough), the
incentive of the stores to raise price is so high under mechanism 2 that the resulting
revenue is higher than that under mechanism 1.
3 Summary and Conclusions
This research takes the first step toward understanding Internet malls as a new form
of e-commerce. We begin our analysis by providing a specific type of consumer seg-
mentation and examining the incentives of online stores to join Internet malls. In the
base model, we analyze the pricing policies and profit implications for online stores
and Internet malls, taking the segmentation scheme as given. We then allow consumer
segmentation to interact with the pricing policies of online stores and explore how such
interactions moderate the competitive strategies of online stores and Internet malls.
This paper distinguishes itself from previous research in that it focuses on the unique
mode of interactivity18 afforded by search engines and featured stores in Internet malls.
We demonstrate that Internet mall is a profitable business model through the compe-
tition reducing role of the featured store. Next, we show that Internet malls continue
to be profitable when consumer segmentation is endogenous. This result is supported
by a unique mixed strategy equilibrium that survives an intuitive refinement. Finally,
we prescribe how Internet malls and their member stores may fine-tune their strategies
by responding to market characteristics such as consumer search costs and the reach of
an Internet mall. Specifically, an Internet mall should feature stores for free when its
reach is high and consumer search costs are substantial. Conversely, it should charge
fees to featured stores when both its reach and consumer search costs are low. Our
empirical tests provide support to the model predictions. We show that: 1. on average,
18Alba et al. (1997) define interactivity as a continuous construct capturing the quality of two-waycommunication between two parties.
32
featured stores charge higher prices than non-featured stores when other factors such
as store reputation and customer service are taken into account, 2. featured stores at
a large Internet mall charge higher prices than those at a small Internet mall, 3. as
search costs increase, the price differential between featured and non-featured stores
becomes larger. To managers, our research presents a positive analysis of Internet
malls as a business model. It serves as a preliminary guide to e-tailers and shows when
it is beneficial to join Internet malls and how they should adapt their strategies in
this particular online shopping environment. Our analysis also helps Internet portals
(owners of Internet malls) to evaluate their pricing schemes and shows what steps can
be taken to improve their profitability.
Our model can be extended in several ways. First, we have only analyzed Internet malls
in the context of homogeneous product market. An obvious extension is to consider
differentiated markets. Second, repeat buyers may form their expectations differently.
Specifically, they may incorporate their prior purchase experience into their future
expectations. To allow such expectations, we have to model consumers as Bayesians
who update their beliefs each period. Third, we have assumed that there is a single
featured store for mathematical tractability. An extension in which multiple featured
stores are allowed may be of interest. To model this situation, we may classify featured
stores and non-featured stores into two groups and analyze intra-group and inter-group
competition. We expect that most of the findings in this paper should carry through
in that case.
33
Appendix A
Technical note for the base model
As noted earlier, our base model is built upon the pioneering works by Varian (1980)
and Narasimhan (1988). We briefly recapitulate some key findings in Narasimhan
(1988) that are relevant to our model:
1. There is no Nash equilibrium in pure strategies.
2. The strategy sets of the two stores are convex.
3. Neither can have a mass point in the interior or at the lower bound of the other’s
price support, nor can either store have a mass point at the upper bound of the
other’s price support if that upper bound is a mass point for the other firm.
4. The two stores’ strategy sets are identical when neither store has a mass point.
If store j has a mass point at the upper bound of the price support, store i will
have zero density at that price in equilibrium.
In the base model we have shown that two-part tariff is superior to pure fixed fees
and pure percentage fees. All subsequent analyses are based on two-part tariff. Recall
that the expected profits for store 1 and store 2 are π1 = [α + C(1 − d)]r and π2 =
p[α+A+B(1−d)], respectively. The loyal customers and featured store shoppers will
buy from store 1 as long as its price is no greater than their reservation price, but the
competition for the comparison shoppers puts downward pressure on price. Clearly,
store 1 has more to lose when it moves away from reservation price. Thus, store 1 has
a mass point at the reservation price r. By contrast, store 2 does not. We can state
the equilibrium conditions for p ∈ [p, r) as follows:
p{α+ C(1− d) + (1− F2(p))[A+B(1− d)]} = [α + C(1− d)]r (A–1)
34
and
p{α+ (1− F1(p))[A+B(1− d)]} = p[α + A+B(1− d)] (A–2)
Solving for F1(p) and F2(p) from equations (A–1) and (A–2) we get
F1(p) =[α + A+B(1− d)]{[α + A+ (B + C)(1− d)]p− [α + C(1− d)]r}
[α + A+ (B + C)(1− d)][A+B(1− d)]p(A–3)
and
F2(p) =[α + A+ (B + C)(1− d)]p− [α + C(1− d)]r
[A+B(1− d)]p(A–4)
From (A–3) and (A–4) we see that F1(p) = F2(p) = 0, F2(r) = 1, and F2(r) = 1−Q,
where
Q =C(1− d)
α + A+ (B + C)(1− d)(A–5)
This indicates that F1(p) has a mass point at r equals to Q.
Technical note for extension 1: segmentation among switchers
endogenized
Before we can write down the probability distribution functions for pmin and p, we need
to resolve the issue of mass point. Recall that the equilibrium distribution function for
store 1 F1(p) as shown in the base model is not a proper distribution function since
F1(r) = 1−Q. Given the mass point Q, we can derive the conditional price distribution
function for store 1 F c1 (p) from the following equilibrium condition:
p{α + [(1−Q)(1− F c1 (p)) +Q][A+B(1− d)]} = p[α + A+B(1− d)] (A–6)
35
From (A–6) we get
F c1 (p) =
[α + A+ (B + C)(1− d)]p− [α + C(1− d)]r
[A+B(1− d)]p(A–7)
Note that F c1 (p) is a proper distribution function with F c
1 (p) = 0 and F c1 (r) = 1. We
can now express the probability distribution functions for pmin and p as follows:
Prob{min(p1, p2) < p} = (1−Q)[1− (1− F c1 (p))(1− F2(p))] +QF2(p) (A–8)
and
Prob{pf = p} = Qr + (1−Q)F c1 (p) (A–9)
Derivation of pmax and pmin in section 2.2
From (4) and (5) we can calculate pmin and p from the following expressions:
pmin =
∫ r
p
pd{(1−Q)[1− (1− F c1 (p))(1− F2(p))] +QF2(p)} (A–10)
and
p = Qr + (1−Q)
∫ r
p
pdF c1 (p) (A–11)
Substitute F c1 (p), F2(p), and Q into (A–10) and (A–11) we get
pmin = r(C − Cd+ α)[2B2 − 2Bα− 2Bdα+ 2Aα+ 2B2d2 − 4dB2 + 4BA−
2Cα ln(η) + 2Cαµ+ CBµ− CB ln(η)− 2Bα ln(η) + 2Bαµ+ 2A2−
dCAµ+ 2Cdα ln(η)− 2Cdαµ+ CAµ+ d2CBµ− 2α2 ln(η) + 2α2µ−
4dBA− d2CB ln(η) + 2dCB ln(η)− 2dCBµ+ dCA ln(η) + 2dBα ln(η)−
2dBαµ+ 2Aαµ− CA ln(η)− 2Aα ln(η)]/[(B −Bd+A)2η]
(A–12)
36
and
p = r[B2αµ+B2α ln(η)− C2d3B ln(η) + 2C2αdµ+ 2Bd2AC ln(η) +A2Cdµ−
A2Cd ln(η) + 3B2d2C ln(η)− 3B2d2Cµ+ 4BACdµ− 4BACd ln(η)− 3B2·
Cd ln(η) + 3B2Cdµ+ 2BAC ln(η)− 2BACµ−B2d2αµ+B2d2α ln(η)+
2BdAαµ− 2BAαµ+ 2BAα ln(η)−B2Cµ+B2C ln(η) +A2C ln(η)−
A2Cµ− 2BdAα ln(η)−A2αµ+A2α ln(η) +B2d3Cµ−B2d3C ln(η)−
2Bd2ACµ− 2B2dα ln(η) + 2B2dαµ+ 2rBd2CA− rB2d3C − rA2Cd+
2rBCA− 4rBdCA+ 3rB2d2C + rA2C − 3rB2Cd+ rB2C − 2Cdα2 ln(η)−
2Bdα2 ln(η) + 2Bα2 ln(η) +BC2 ln(η) + C2α ln(η)−BC2µ− 2Bα2µ−
C2αµ+ α3 ln(η)− α3µ+ C2d2A ln(η)−AC2µ+ 2Bdα2µ− 2AC2d ln(η)+
AC2 ln(η)− 6CBdα ln(η)− C2d2Aµ+ 2AC2dµ+ 2Cdα2µ+ 6CBdαµ+
2Cα2 ln(η)− 2Cα2µ− 3CdAα ln(η) + 3CdAαµ+ C2d3Bµ− 2C2αd ln(η)−
3BdC2 ln(η) + 3BdC2µ+ 3CAα ln(η)− 3CAαµ+ 3CBα ln(η)− 3CBαµ+
2Aα2 ln(η)− 2Aα2µ+ 3Bd2C2 ln(η)− 3Bd2C2µ+ 3Cd2Bα ln(η)− 3Cd2Bαµ+
C2d2α ln(η)− C2d2αµ]/[(B −Bd+A)η2]
(A–13)
where η = α + A+ (B + C)(1− d), µ = ln[α + C(1− d)].
Technical note for extension 2: an alternative featured store
selection mechanism
By a similar argument as in the base model, we can show that the price support is
p ∈ [p, r], where
p =[α + C(1− d)]r
α+ A+B(1− d)(A–14)
Note that if the numerator is larger than the denominator, i.e., more customers are
either loyal customers or featured store shoppers then p = r. The profits for store i at
37
a price p is given by
πi(p) = {α + Fj(p)C(1− d) + (1− Fj(p))[A+B(1− d)]}p (A–15)
where p ∈ [p, r], i 6= j, i, j = 1, 2. Each store chooses its pricing policy to maximize its
expected profit
maxFi
E(πi) =
∫
πi(p)dFi(p) (A–16)
such that
πi ≥ αr∫ r
p
dFi(p) = 1
By assumption, the two stores are symmetric, therefore, their equilibrium price dis-
tributions are identical, i.e., F1(p) = F2(p) = F (p). We can state the equilibrium
condition for p ∈ [p, r] as
[α + C(1− d)]r = {α + F (p)C(1− d) + (1− F (p))[A+B(1− d)]}p (A–17)
From (A–17),
F (p) =[α + A+B(1− d)]p− [α + C(1− d)]r
[A+ (B − C)(1− d)]p(A–18)
Consumer segmentation endogenized
In this case, the expectation of consumers in segment B remain unchanged (they expect
to pay the average minimum price), but consumers in C segment now expect to pay
the average maximum price. The probability distribution functions of pmax and pmin
38
are given by
Prob{max(p1, p2) < p} = [F (p)]2 (A–19)
and
Prob{min(p1, p2) < p} = [1− (1− F (p))2] (A–20)
From (A–19) and (A–20) we can calculate pmax and pmin as follows:
pmax =
∫ r
p
pd[F (p)]2 (A–21)
and
pmin =
∫ r
p
pd[1− (1− F (p))2] (A–22)
substitute (A–18) into (A–21) and (A–22) we get
pmax =2r[α+ C(1− d)]{α(χ− φ) + C(1− d) +B[(χ− φ− 1)(1− d)]−A(1 + φ− χ)}
[A+ (B − C)(1− d)]2
(A–23)
and
pmin =2r[α+ C(1− d)][α(φ− χ) +A+B(1− d) + C(1− d)(φ− χ− 1)]
[A+ (B − C)(1− d)]2(A–24)
where φ = ln[α + A+B(1− d)], χ = ln[α + C(1− d)].
The disutility for the B and C segments of consumers are dui = pmin + γs and duf =
pmax, respectively. In equilibrium, s∗ solves dui = duf , s∗ = B
B+C, which implies that
consumers whose time cost is s ∈ [s∗, 1] shop at featured store, whereas consumers of
type s ∈ [0, s∗] use the search engine. The optimal sizes of B and C can be derived
accordingly. As in section 2.2, two types of equilibria emerge. The properties of these
equilibria are illustrated in Figures 7, 8, and 9. By proposition 3, we can eliminate the
unstable equilibrium.
39
Figure 7: Mechanism 2: the stable equilibrium
00.20.40.60.8
11.21.41.61.8
2
0.5 0.55 0.6 0.65 0.7 0.75 0.8
γγγγ
p
Pmax
Pmin
0
0.1
0.2
0.3
0.4
0.5
0.6
0.7
0.8
0.5 0.55 0.6 0.65 0.7 0.75 0.8γγγγ
π πππ i iii
0
0.1
0.2
0.3
0.4
0.5
0.6
0.7
0.8
0.5 0.55 0.6 0.65 0.7 0.75 0.8
γγγγ
Seg
men
t Siz
e
B
C
40
Figure 8: Mechanism 2: the unstable equilibrium
0
0.1
0.2
0.3
0.4
0.5
0.6
0 0.1 0.2 0.3 0.4 0.5 0.6 0.7 0.8
γγγγ
Seg
men
t Siz
e
B
C
0
0.5
1
1.5
2
2.5
3
3.5
0 0.1 0.2 0.3 0.4 0.5 0.6 0.7 0.8
γγγγ
p
Pmax
Pmin
0
0.2
0.4
0.6
0.8
1
1.2
1.4
1.6
0 0.1 0.2 0.3 0.4 0.5 0.6 0.7 0.8γγγγ
π πππ i iii
41
0
0.1
0.2
0.3
0.4
0.5
0.6
0.7
0.00 0.05 0.10 0.15 0.20 0.25 0.30 0.35 0.40 0.45
C
diff
p
an unstable equilibrium
a stable equilibrium
Figure 9: An illustration of the two types of equilibria: Mechanism 2
We now proceed to present an illuminating example and some interesting comparative
statics. As in section 2.2, suppose that the reservation price is $3 (r = 3) for the
consumers, each store enjoys a loyal segment of size 0.1 (α = 0.1), 90% of the rest of
the shoppers go to the Emall (k = 0.9). We vary search time (γ) and compile a sample
output in Figures 7 and 8. Given the parameter values specified above, the most
profitable scheme is for the Emall to collect 7% of revenue from its member stores.
Under this scheme, the equilibrium segment sizes for B and C are 0.641 and 0.079,
respectively. Each store makes a profit of 0.52, the revenue to the Emall is 0.073.
42
Appendix B
Proof of Proposition 1
Proof. It is easy to verify that for every p ∈ (p, r), F1(p) < F2(p), which implies
that F1(p) first order stochastically dominates F2(p). When more switchers shop at
the Emall, that is, non-Emall shoppers (A segment) become Emall shoppers (B and
C segments), the number of comparison shoppers (B segment) and featured store
shoppers (C segment) increases proportionally. Define E(p) as the expected price, we
have
E(p) =
∫ r
p
pdF (p) (B–1)
= [pF (p)]rp −
∫ r
p
F (p)dp
= r −
∫ r
p
F (p)dp
Thus, E(p) increases (decreases) when F (p) decreases (increases). Recall that F1(p) =
[α+A+B(1−d)]{[α+A+(B+C)(1−d)]p−[α+C(1−d)]r}[α+A+(B+C)(1−d)][A+B(1−d)]p
, and p = [α+C(1−d)]rα+A+(B+C)(1−d)
.
Clearly, p is increasing in C, but the F1(p) is decreasing in C. Note that the profits for
store 1 and store 2 are (α+C)r and p(α+A+B), respectively. Therefore, the average
price as the featured store (E(p1)) and the Emall’s profits (proportional to the sum of
the two stores’ profits) increase as more shoppers purchase through the Emall.
Proof of Proposition 2
Proof. To prove that both stores join the Emall in equilibrium, we need to show that
out-out and in-out cannot occur in equilibrium. It’s easy to verify that out-out is not
an equilibrium (see tables 1 and 2). Suppose that store 1 joins the Emall and store
2 stays out, and in-out is an equilibrium. The expected profits of store 1 before and
43
after joining the Emall are αr and (α + C)r, respectively. The Emall will charge a
fixed fee in the amount of Cr to fully extract the additional benefits accrued to store
1, which leaves store 1 indifferent between joining the Emall or not. By contrast, store
2’s expected profits after store 1 joining the Emall are (α+C)rα+A+B+C
× (α+A+B), which
is strictly greater than αr. Therefore, both stores want to be the one that stays out,
this contradicts the assumption that in-out is an equilibrium.
Under fixed fees, the outside option for both stores when both stores join the Emall is
(α+C)rα+A+B+C
(α + A + B). As shown in table 1, the payoffs to the featured store and
non-featured store are (α + C)r and (α+C)rα+A+B+C
(α + A + B), respectively. Therefore,
the optimal fixed fees to the featured store and non-featured stores are f1 = (α+C)rCα+A+B+C
and f2 = 0. If the non-featured store chooses not to join, the outside option for the
featured store becomes αr, and the Emall will charge a fixed fee of f = Cr in this
situation. Given the Emall’s strategy, the best response for each store is to join the
Emall. Thus, both stores join the Emall under f1 and f2.
Under percentage fees, the outside option for both stores when both stores join the
Emall is αrα+A
(α + A + B). As shown in table 2, the payoffs to the featured store
and non-featured store are [α + C(1 − d1)]r and [α+C(1−d1)]rα+A+(B+C)(1−d1)
[α + A + B(1 − d2)],
respectively. Therefore, the optimal percentage fees to the featured store and non-
featured stores are d1 = Cα+CA−αB(α+A)C
and d2 = CA−αB(α+A)C
. If the non-featured store chooses
not to join, the outside option for the featured store becomes αr, and the Emall will
charge a percentage fee of d = 100% in this situation. Given the Emall’s strategy, the
best response for each store is to join the Emall. Thus, both stores join the Emall under
d1 and d2.
The Emall’s profits under fixed fees and percentage fees are Rf = (α+C)rCα+A+B+C
and Rp =
Crd1r +[α+C(1−d1)]r
α+A+(B+C)(1−d1)Bd2, respectively. The difference between Rp and Rf is given
44
by
Rp −Rf =r(α+A+B)(2αB2 + α2B +AαB + 2CαB + Cα2 + 2CαA+ CA2)(CA− αB)
(Cα2 + 2CαA+ CA2 + αB2 + CαB)(α+A)(α+A+B + C)(B–2)
Hence, percentage fees dominate fixed fees when CA > αB. ¤
Proof of Lemma 1
Proof. From proposition 2, we know that fixed fees are superior to percentage fees
when CA ≤ αB. In this parameter range, two-part tariff is equivalent to fixed fees
(by setting percentage fees to 0). When CA > αB, it suffices to show that two-
part tariff yields higher revenue to the Emall than percentage fees. Under two-part
tariff, the Emall charges a uniform percentage fee d to both stores and a fixed fee
to the featured store. The outside option for both stores when both stores join the
Emall is αrα+A
(α + A + B). The payoffs to the featured store and non-featured store
are [α + C(1 − d)]r and p[α + A + B(1 − d)], respectively, where p = [α+C(1−d)]rα+A+(B+C)(1−d)
.
Comparing the optimal two-part tariff percentage fee d to the optimal percentage fees
d1 and d2 under pure percentage fees, it is easy to verify that d2 < d < d1. The Emall’s
revenue from the non-featured store can be written as R2 = pBd. Under percentage
fees, Rper2 = [α+C(1−d1)]r
α+A+(B+C)(1−d1)[α + A+ B(1− d2)]. It can be shown that p is decreasing
in d when CA > αB. Since d2 < d < d1, R2 is larger under two-part tariff. The
Emall’s revenue from the featured store (the sum of fixed fee and percentage fee) can
be written as R1 = [α+C(1− d)]r− αrα+A
(α+A+B). Since d < d1, R1 is larger under
two-part tariff. This completes the proof for the lemma.
Proof of Proposition 3
Proof. In Figure 4, the difference between p and pmin (diffp) is drawn against C. The
stable equilibrium is located in the increasing segment of the graph, whereas the un-
stable equilibrium is located in the decreasing segment of the graph. Suppose that
45
the two stores’ strategy sets are fixed, as γ increases, more shoppers will shop at the
featured store (C increases). Now, since the stable equilibrium is in the increasing
segment of the graph, as C increases, the gap between p and pmin (diffp) widens—the
gain from using the search engine becomes larger, which counterbalances the increase
in C. Thus, the stable equilibrium is a fixed point. By contrast, since the unstable
equilibrium is in the decreasing segment of the graph, as C increases, the gap between
p and pmin (diffp) becomes narrower, which leads to further increase in C. Thus, an
irrelevant disturbance causes the collapse of the unstable equilibrium, in other words,
the unstable equilibrium does not constitute a fixed point.
Proof of Lemma 2
Proof. The first half of the lemma can be proved by observing that in mechanism 1,
the two stores equilibrium profits are π1 = [α+C(1−d)]r and π2 = [α+C(1−d)]rα+A+(B+C)(1−d)
[α+
A + B(1 − d)], respectively. Both are increasing in C. In mechanism 2, each store’s
equilibrium profit is π = [α+ C(1− d)]r, which is increasing in C. The second half of
the proposition is true for mechanism 2 by definition. For mechanism 1, note that F1(p)
stochastically dominates F2(p) in the first order, which implies E(p1) > E(p2).
Proof of Proposition 4
Proof. This proposition is derived from numerical simulations. Details are available
from the author upon request.
Appendix C
46
Table 7: Featured stores charge higher prices on average: A snapshot of the data
Category Item
Palm Vx 299.98 281.72 √Palm m505 449.99 421.06 √
Palm IIIc 299.99 283.09 √Casio Cassiopeia E-
125638 555.69 √
Casio PC-Unite BZX-20
114 90.73 √Compaq iPAQ
H3650525 529.05 ×
HP Jornada 548 449.99 471.1 ×HP Jornada 547 449 419.44 √HP Jornada 720 899.99 876.87 √Sony Clie PEG-
S300329.99 302.2 √
% of Confirmation
80%
4.18 (0.002)
24.66 (0.0001)
PDAs
t Statistic ( ), p-value in parenthesis
Category Level Likelihood Ratio Test Statistic (χχχχ2222), p-value in parenthesis
nfp f nfp p>
f nfp p>
fp
47
Table 8: Featured stores at a large Internet mall charge higher prices than their counterparts in a small Internet mall: A snapshot of the data
Category
Mall Shopping.com price Yahoo! price
Featured Store ABT Electronics circuit city √Item JVC VCR
HRS4800U226 JVC VCR
HRS4800U249.99 √
Item JVC VCR HRS3800U
181 JVC VCR HRS3800U
199.99 √
Item Sony VCR SLVN80 198 Sony VCR SLVN80 199.99 √
Item Panasonic VCR PVV4620
148 Panasonic VCR PVV4620
149.99 √
Item Sony CD Player CDPCX235
189 Sony CD Player CDPCX235
199.99 √
Item Sony CD Player CDPCX53
169 Sony CD Player CDPCX53
149.99 ×Featured Store BeachCamera RitzCamera
ItemCanon ELURA 2
DIGITAL CAMCORDER
1249Canon ELURA 2
DIGITAL CAMCORDER
1599.95 √
Item Canon ES55 8MM CAMCORDER
285 Canon ES55 8MM CAMCORDER
349.95 √
ItemCanon OPTURA PI
DIGITAL CAMCORDER
1149Canon OPTURA PI
DIGITAL CAMCORDER
1499.95 √
ItemPanasonic - PV-
D100 Digital Camcorder
579Panasonic - PV-
D100 Digital Camcorder
799.95 √
ItemPanasonic - PV-
DV400 Digital Camcorder
704Panasonic - PV-
DV400 Digital Camcorder
999.95 √
Item
Panasonic - PV-DV600 Mini-DV Palmcorder with
Niteshot
839
Panasonic - PV-DV600 Mini-DV Palmcorder with
Niteshot
1199.95 √
ItemPanasonic - PV-L550 Palmcorder
Camcorder 327
Panasonic - PV-L550 Palmcorder
Camcorder 399.95 √
ItemPanasonic - PV-L650 Palmcorder
Camcorder 415
Panasonic - PV-L650 Palmcorder
Camcorder 499.95 √
ItemPanasonic - PV-L750 Palmcorder
Camcorder 449
Panasonic - PV-L750 Palmcorder
Camcorder 599.99 √
ItemCanon - Powershot G1 3.3MP Digital
Camera 848
Canon - Powershot G1 3.3MP Digital
Camera 899.99 √
Item Canon - S20 Digital Camera
554 Canon - S20 Digital Camera
699.99 √
Item FUJI FINEPIX 1400 DIGITAL CAMERA
234 FUJI FINEPIX 1400 DIGITAL CAMERA
299.99 √
Item FUJI FINEPIX 2400 DIGITAL CAMERA
338 FUJI FINEPIX 2400 DIGITAL CAMERA
374.99 √
Item FUJI FINEPIX 4700 DIGITAL CAMERA
599 FUJI FINEPIX 4700 DIGITAL CAMERA
799.99 √
Item Kodak DC-215 DIGITAL CAMERA
279 Kodak DC-215 DIGITAL CAMERA
299.99 √
Item Kodak DC-3400 DIGITAL CAMERA
394 Kodak DC-3400 DIGITAL CAMERA
499.99 √# of
Confirmation38 out of
39% of
Comfirmation97.4%
ElectronicsSf
Lf pp >
48
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