How TV Ads Influence Online Shopping
Jura Liaukonyte,1 Thales Teixeira,
2 Kenneth C. Wilbur
3
April 7, 2014
Media multitasking distracts consumers’ attention from television advertising, but it also enables
immediate and measurable response to advertisements. This paper explores how the content of
television advertising influences online shopping. We construct a massive dataset spanning $4
billion in advertising expenditures by 20 brands, online shopping behavior at those brands’
websites, and content measures for 1,269 distinct television commercials. We use a quasi-
experimental research design to estimate how advertising content influences changes in online
shopping data within two-minute pre/post windows of time. We also measure the effects within
two-hour windows of time using a difference-in-differences approach. The findings show that
direct-response tactics increase both web traffic and purchase probability. Information-based
arguments and emotional content actually reduce traffic but increase sales among those who visit
the brand’s website. Imagery content reduces direct traffic but does not affect purchase
probability. These results imply that brands seeking to attract multitaskers’ attention and dollars
must select their advertising copy carefully according to their objectives.
Keywords: Advertising content, difference-in-differences, internet, media multitasking, online
purchases, simultaneous equations model, quasi-experimental design, television.
1 Dake Family Assistant Professor, Cornell University, Dyson School of Applied Economics and
Management, https://faculty.cit.cornell.edu/jl2545. 2
Assistant Professor of Business Administration, Harvard Business School, http://www.hbs.edu/
faculty/Pages/profile.aspx?facId=522373. 3 Assistant Professor, University of California, San Diego, Rady School of Management,
http://kennethcwilbur.com.
The authors thank comScore, the Cornell University Dyson School Faculty Research Program,
Dake Family Endowment, and the Division of Research and Faculty Development of the
Harvard Business School for providing the funds to acquire and build the dataset in this research.
Teixeira thanks Elizabeth Watkins for research assistantship. Wilbur thanks Duke University for
employing him during part of the time this research was conducted. We are grateful to Donald
Lichtenstein, Chris Oveis, Catherine Tucker, the editor, area editor, two anonymous referees and
numerous seminar audiences for their helpful suggestions. Authors contributed equally.
1
1. Introduction
As computers have grown smaller and more convenient, simultaneous television and internet
consumption (“media multitasking”) has increased rapidly (Lin, Venkataraman and Jap 2013).
Numerous studies have reported large increases in media multitasking; among them, Nielsen
(2010) claimed that 34% of all internet usage time occurred simultaneously with television
consumption. Meanwhile, television usage has not fallen, with Americans still watching about
five hours per day. In fact, time spent with television and time spent with internet are positively
correlated at the household level (Nielsen 2011).
One might therefore suspect that television can effectively engage online shoppers. But
do multitaskers engage with television ads or does simultaneous media consumption steal
consumer attention away from commercials? Numerous studies suggest that engagement is
possible. Among them, Nielsen (2012) found that 27% of US viewers had looked up product
information for a TV advertisement, and 22% had looked up advertised coupons or deals
advertised on TV. Ofcom (2013) reported that 16% of UK consumers had searched for product
information or posted to a social network about a television advertisement.
The current paper studies how the content of television advertising influences online
shopping. It aims to contribute to the literature on cross-media effects by answering the
following questions: can TV advertising trigger online shopping? If so, how does it work and
what type of content is most effective?
Recent research (Zigmond and Stipp 2010, Lewis and Reiley 2013, Joo et al. 2014) has
used online search data to show that search engine queries to Google and Yahoo respond almost
instantaneously to television commercials. However, to our knowledge, no past research has
looked at the effects of television advertising on direct website traffic or online purchase data.
2
This paper not only establishes that online shopping responds to television advertising, it also
investigates how those effects depend on advertising content.
To uncover these issues, we merged two large databases of television advertising and
internet usage, and then created a third database of advertising content. The ad data represent
$4.1 billion spent by 20 brands in 5 product categories to air 1,269 distinct advertisements
365,017 times in 2010. The contents of these advertisements were coded to assess the extent to
which each one incorporated direct response tactics, arguments, emotional content and imagery.
Finally, the advertising data were supplemented with comprehensive, passively measured brand-
level website traffic and sales data from a daily sample of 100,000 consumers.
Advertising response studies are notoriously plagued by endogeneity. To address this, we
employ a quasi-experimental research design in conjunction with narrow two-minute event
windows (Chaney et al. 1991). For each ad insertion, online shopping variables are measured
within a narrow window of time prior to the advertisement. This “pre” period serves as a
baseline against which the ad’s effect is measured. The same variables are measured again in a
“post” window of the same length immediately following the ad’s insertion. Systematic
differences between the pre- and post-windows are attributed to the ad insertion. The
identification strategy is similar to the regression discontinuity approach of Hartmann, Nair and
Narayan (2011).
We also measure advertising effects on online shopping in broader two-hour windows of
time. In order to partial out unobserved category-time interactions, we use online shopping on
nonadvertising competitors’ websites as control variables in a difference-in-differences
regression framework.
3
We find clear evidence that television advertising influences online shopping. Direct
response content increases direct website visitation (e.g., directly using a URL) with a smaller
corresponding decrease in search engine referrals (e.g., indirectly via a search engine). It also
raises conversion probability. Arguments and emotional content reduce direct traffic while
simultaneously increasing purchase probabilities; the net result of these two offsetting effects is
positive for most brands. Imagery content reduces direct traffic and does not significantly change
purchase probabilities. In sum, the results suggest that advertisers must select advertising content
carefully according to their objectives.
The paper proceeds by reviewing literature on TV advertising and proposing a simple
conceptual framework. It then describes the data, model specification and the results. A general
discussion of the implications for television advertisers concludes.
2. Background Literature and Conceptual Framework
Our work is directly related to research on multimedia advertising effectiveness. Several recent
studies found evidence of synergistic effects between television advertising and internet
advertising on offline sales (Kolsarici and Vakratsas 2011, Naik and Peters 2009, Naik and
Raman 2003, Ohnishi and Manchanda 2012). Dagger and Danaher (2013) built a single-source,
customer-level database of ten advertising media and retail sales for a large retailer. They found
that single-medium advertising elasticities were highest for catalogs, followed by direct mail,
television, email and search, suggesting that direct-response channels are more effective at
increasing short-term sales than other advertising channels.
.
4
The sum of the evidence suggests that significant cross-media effects exist. However,
researchers are just starting to understand how the content of advertising in one medium might
influence consumers’ behavior in another. In an early effort, Godes and Mayzlin (2004) showed
that online discussions of new television programs had explanatory power in a dynamic model of
those program’s ratings. More recently, Gong et al. (2013) designed a field experiment to
measure the causal impact of tweets and retweets on ratings of a television program. They found
that the content of promotional messages on the internet influenced the number of people
estimated to view the promoted television program.
2.1 TV Advertising and Online Behavior
Television ads are valuable for generating awareness, knowledge and interest in new products. A
direct consequence is that effective television ads may lead viewers to seek out more information
about these products and brands (Rubinson 2009). To date, the most studied online behavior
among TV viewers has revolved around searching for advertised brands and products using
search engines (e.g., Joo et al. 2014).
Lewis and Reiley (2013) found that advertisements during the Super Bowl tend to trigger
online searches for the advertised brands immediately, within one minute, with smaller effects
noticeable up to an hour after the ad’s broadcast time. However, their analysis did not include
direct traffic to the brand’s website or online purchases, making it impossible to separate interest
in the ad’s entertainment value from interest in the advertised product. They suggested that
“other user data such as site visitation and purchase behavior could provide a more holistic
perspective…” This paper follows up on this suggestion.
Following this observation, we posit in Figure 1 that consumers have two major decisions
in response to TV ad exposure. First, they choose whether to visit the brand’s website or not. If
5
the brand’s website is very salient, this action may be achieved by a direct route, such as entering
the website address directly into the browser or clicking a bookmark. If the brand website is
unknown or not salient, the consumer might instead need to visit a search engine and then click a
referring link to the brand’s website. Second, upon arrival at the website, the consumer decides
whether to purchase or not.
[Figure 1 about here]
Zigmond and Stipp (2010, 2011) offered several case studies showing that large increases
in Google searches for branded keywords corresponded to the precise timing of brands’ TV ads
aired during the Olympics. They speculated that heterogeneity in search response to TV ads was
partly due to the brand and partly due to the ad content. They reasoned that new-product ads
should generate more online search while call-to-action ads should generate fewer searches and
more direct website visits. Therefore, we allow for differential effects of TV ad content on
consumers’ two major routes of visitation to the brand website. Next, we review the literature on
television advertising content.
2.2 Typology of TV Ad Content
Prior research has claimed that advertising content is a first-order determinant of advertising
effects. For example, Wind and Sharp (2009) said that “the most dramatic influence on short-
term effect is creative copy.”
Tellis (2004) summarized the advertising literature by explaining that advertising effects
can be classified as either behavioral or attitudinal. Behavioral effects act instantaneously, at the
moment of exposure, or shortly thereafter. Attitudinal effects operate by changing the
consumer’s attitudes and memory over a longer period of time. Using this simple dichotomy,
prior research has categorized ads into those that predominantly seek a behavioral response and
6
those that predominantly seek to influence attitudes. An ad need not focus on just one purpose;
many TV ads exhibit some elements of both types. However, in practice they are negatively
correlated as ad time is expensive and different tactics are used to reach these two goals.1 Ads
that primarily seek to elicit behavioral responses are normally called “direct-response” (Danaher
and Green 1997) while those that intend to cause attitudinal changes are often called “brand-
image” (Peltier et al. 1992).
Direct-response ads possess three characteristic elements. In order to elicit a behavioral
response from the viewer, they provide (i) a solicitation of a specific action(s), (ii) supporting
information to encourage a decision, and (iii) a response device or mechanism to facilitate action
(Danaher and Green 1997, Bush and Bush 1990). About 20% of the TV ads in the U.S. are
estimated to be primarily direct-response (Danaher and Green 1997, Peltier et al. 1992). The
literature has shown that these ‘gimmicks’ are indeed effective at eliciting immediate responses.
On the other hand, brand-image ads are used to reinforce or change attitudes regarding
how consumers perceive the brand. They do so by appealing to two processing mechanisms, the
cognitive and the affective system. Brand-image ads constitute about 75% of all TV ads in the
U.S. (James and Vanden Bergh 1990).
Ads that involve cognitive (or central route of) persuasion do so through the use of
arguments. These argument-based ads persuade by appealing to reason and relying on evidence
about the product, the price and brand information whereby viewers evaluate the merits of the
proposed arguments against their counterarguments (Petty and Cacioppo 1986, Tellis 2004).
1 A related literature uses similar typology and focuses on the trade-off between informative and persuasive roles of
advertising (e.g., Ackerberg 2001, Anderson et al. 2013, Bagwell 2007, Ching and Ishihara 2012).
7
Ads that appeal to the affective (or peripheral) system attempt to persuade customers of
the brand’s value either through the use of emotionally engaging content (Gross and Thomson
2007, Hajcak and Olvet 2008) or through visual imagery. We term the former emotion-based
ads as they attract attention and engage viewers by using emotion-inducing content such as
creative stories, warmth and humor tactics (Teixeira et al. 2012, Tellis 2004). On the other hand,
the use of multiple perceptual or sensory representations of ideas (predominantly visual) is
intended to excite the senses using sensory stimuli, concrete words, and vivid pictures. This
approach, in turn, evokes visual imagery processing in consumers and incites a process of
memorization, intent formation, or affect (MacInnis and Price 1987, Peltier et al. 1992). We refer
to this as imagery-based ad content.
[Figure 2 about here]
While all the tactics may be used within the same advertisement, constraints (e.g., air
time or production budget) typically require advertisers to focus primarily on one technique.
Figure 2 summarizes the four types of TV advertisements. Next, we use this classification to
develop expectations about how ad content affects online shopping.
2.3 TV Ad Content and Online Shopping
We expect the effect of TV ads on online shopping to be driven by media multitasking, an
activity in which consumers divide attention between the television set and a secondary screen,
the computer.2 Therefore, we expect the level of attention needed to process each type of
advertising content to influence how that content affects online shopping behavior (Teixeira
2 ComScore only measured internet usage only on desktops and laptops in 2010; at that time it had not yet developed
tracking technology for tablets or smartphones.
8
2014). Because there is no extensive literature on which to base formal hypotheses, we only
provide informal conjectures.
In thinking through the possible influence of TV ads on online shopping, it is necessary
to consider the role the brand’s website might play. Broadly speaking, the brand website can
serve two roles: it could be a channel for selling (e.g. providing product information and further
persuasion), or it could be a channel for order fulfillment. Ad content that stimulates interest
without providing much information would be more effective in conjunction with a brand
website that is a channel for selling. Ad content that provides extensive information would be
more effective in conjunction with a website that is a channel for order fulfillment. For example,
Hans et al. (2013) showed that some claims in text search ads are more effective for generating
click-through (promoting the site) while others generate less traffic but are better at increasing
conversions (persuading to buy). Similarly, Wu et al. (2005) found that some magazine ad
formats were more effective at generating site traffic while other formats brought less traffic to
the site but that traffic converted at higher rates. Anderson and Renault (2006) formally modeled
this trade-off; in equilibrium, a rational consumer’s willingness to incur a search cost (e.g. visit a
website) is greater when the firm provides partial information about product attributes and price
than when it provides full information.
Although we do not observe brand website content in the dataset described below, these
thoughts about the role of the website helped to shape our expectations about how TV ad content
might influence online shopping. Similar to magazine and search engine ads, TV commercials
may attempt to persuade viewers to visit a brand’s website or to make a purchase online. While
both approaches might result in a purchase, it is important to distinguish the ad’s ability to
9
generate traffic from the ad’s ability to generate sales. Next, we relate the four types of TV ad
content to their expected impacts on website visitation.
We expect direct-response ads to increase website visitations because, by their nature,
they are created to cause consumers to act immediately. Immediate action lends itself well to
media multitasking as these ads actively encourage their viewers to make use of another medium
to respond (e.g., “call now,” “go online,” “visit us,” etc.). We also expect this time of advertising
to make the web address more salient in consumers’ minds, leading to a greater impact on direct
traffic than on search engine referrals. Argument-based ads, on the other hand, make use of
content that requires heightened attention and cognitive processing. For this reason, some
viewers might not be motivated to exert the necessary effort to process the arguments in the ad
and this will reduce the likelihood that media multitaskers actively seek additional information
from the advertiser on the Internet by directly visiting the website or via search engines. This is
not to say that argument ads do not trigger interest. Rather, we expect that the desire to act
quickly is much less than from direct-response ads, which induce an impulsive act (Doyle and
Saunders 1990, Wood 2009).
As for emotion-based ads, they do not require an intense cognitive processing. We expect
emotional ads to increase both routes to website visitations by media multitaskers as they do not
require heightened attention to process the message. Further, by changing attitudes, emotions act
as a trigger for action (Gross and Thomson 2007). Lastly, while imagery-based ads also generate
affect, they can reduce people’s desire to go online as the sensory stimulation is likely to keep
viewers’ attention focused on the TV screen and less on other competing media. Thus, by
evoking strong visuals and sensory stimulation, viewers may feel less compelled to switch from
10
television, a stimulating and fast-paced medium, to the internet, a slower and self-paced medium
(Berlyne 1971). Next, we conjecture the impact of the four types of TV ad content on purchase.
We expect that, by focusing on consumer actions, direct-response ads that use the web as a
fulfilment channel will increase online purchases above and beyond that which results from more
website visits. Argument-based ads are expected to increase online purchases as well, but
because they focus on the product and brand. As for the affective-laden ads, emotion-based ads
should also increase purchases as they provide peripheral cues that entertain and persuade
viewers to evaluate the brand favorably (Teixeira et al. 2013). Contrary to the other ads however,
we expect that imagery-focus ads will reduce the viewer’s likelihood of purchasing online in the
short run as imagery offers a positive sensory experience that acts as a palliative substitute for
actual product consumption, delaying purchase (MacInnis and Price 1987). In the next section
we describe the data, sample selection and key measures used in the empirical model.
3. Data
We merge two large datasets of television advertising and internet behavior in 2010 and
construct a database of advertising content. Given the huge databases involved, the analysis
focuses on 20 brands in five product categories with extensive online shopping activity: dating,
pizza delivery, retailers, telecommunications, and travel.
3.1. Web Traffic and Transactions Data
Online traffic and transactions data were collected from comScore Media Metrix. ComScore
used proprietary software to passively track all web usage on a sample of two million internet-
connected desktops and laptops. The data contained information about the Uniform Resource
Locators (URL), date and time of each web page visited. Due to the substantial costs of data
11
retrieval, comScore randomly selected 100,000 machines each day and only retrieved internet
usage data from these machines (Coffey 2001).
ComScore reports the web browsing data at the level of the user/website session.
Consistent with standard industry practice, a new session is recorded when a user first initiates a
page view from a particular domain (e.g., Amazon.com) after not viewing any page from that
domain in the past 30 minutes. The choice of 30 minutes is commonly made because many users
stop looking at webpages without closing a browser tab, so some assumption is required about
the point at which the user stopped interacting with the site.
For each user/website session, comScore reported an anonymous user ID, the domain
name (brand website), domain name of a referral website (if any), and the exact date and start
time. Further, comScore identified paid transactions by analyzing the structure of confirmatory
URLs for all but a few brands it tracked.3
The internet usage database has several limitations that are important for interpreting the
results below. First, the data are a daily cross-section drawn from a panel, but not a panel in and
of themselves. Therefore, we analyze the data by aggregating users’ session data within specific
windows of time; we refer to traffic and transactions as the aggregate counterparts to individual
visitation/browsing and purchasing decisions. Second, the data do not track individuals across
computers (a common issue in internet usage data). Third, at the time the data were collected,
comScore only measured internet usage on desktops and laptops; it had not yet developed
tracking technology for tablet computers. In 2010, smartphone penetration was 22% and major
brands of tablet computers had just come on the market; both devices were generally less
3 Prior research in marketing has analyzed comScore data from 2002-2004 (e.g., Moe and Fader 2004, Park and
Fader 2004, Montgomery, Li, Srinivasan, and Liechty 2004, Danaher 2007, Johnson et al. 2004).
12
suitable for online shopping than desktops and laptops (Nielsen 2010). By 2014, smartphones
and tablets had become more capable and their respective penetration rates had risen to 65% and
29% (Nielsen 2014). One might suspect that the effects estimated in this paper are a conservative
estimate of the current importance of online response to television ads.
Figure 3 summarizes the online shopping data by plotting traffic and transactions within
each product category by hour of the day. In four of five categories, brand website traffic and
transactions are surprisingly flat throughout the day, from about 9 A.M. until 9 P.M., with a peak
in the early evening at 7 P.M. Eastern Time. The exception is pizza, which has a more
pronounced peak in online shopping at dinnertime.
[Figure 3 about here]
3.2. Television Advertising Data
Television advertising data were recorded by Kantar Media. Kantar continuously monitored all
national broadcast and cable networks in the U.S and identified advertisements using codes
embedded in networks’ programming streams. Each unique combination of a commercial
message, television channel, date and time is referred to as an advertising “insertion.” For each
insertion in 2010, the database reports the commercial’s duration, the brand, the date and start
time (in hours, minutes, and seconds E.S.T.), and an estimated cost of the insertion. Cost
estimates were reported to Kantar by the networks after ads aired and are commonly used by
large advertisers to plan upcoming media buys. The data also record the specific product
advertised within the advertisement, as many brands advertised multiple different products.
Finally, the database report several properties of the program into which the ad was inserted: the
“property” (defined as a national television network or program syndication company), program
13
name, program genre, the number of the slot during the commercial break when the appeared,
and the number of the commercial break within the program.4
The data included more than 750,000 insertions of 4,153 unique advertising creatives in
national networks. We dropped the bottom 5% of creatives by total expenditure, and all
insertions whose estimated cost to broadcast was less than $1,000, as these corresponded to
channels and dayparts with very small audiences. These two refinements reduced the number of
insertions by about half but eliminated just 6% of total observed ad spending. The final
estimation sample consists of 365,017 insertions of 1,269 unique advertisements accounting for
$4.1 billion of TV ad spending by 20 brands in 2010.
Like the online shopping activity in Figure 3, Figure 4 shows numerous advertising
insertions occurred between about 9 A.M. and 7 P.M. The number of ad insertions dropped but
advertising expenditures rose considerably during the prime time hours of 8-10 P.M.
[Figure 4 about here]
3.3. Research Design, Model-Free Evidence and Descriptive Statistics
We measure brand-specific shopping variables twice for each ad insertion and each window
length. The baseline rates of online shopping variables are measured in a “pre” window of time
just prior to the insertion of the advertisement. These same variables are measured again in a
“post” window of time just after the ad starts. Any systematic differences between the online
shopping variables measured in the “pre” and “post” windows will be attributed to the
advertisement itself.
4 The database did not report program name, genre, break number or slot number for 36,805 ad insertions carried by
a particular group of program syndication companies. We decided to drop these 10% of insertions from the sample.
The results of primary interest (tables 5 and 6) are essentially invariant to including or excluding these insertions.
14
The online shopping variables of interest are brand website traffic, either direct or via
search engines, and transactions. They are defined as follows.
Direct Traffic (DIR): the number of new sessions on a brand’s website that were initiated by
direct means (e.g., URL entry or clicking a bookmarked link) within a particular time window.
Search Engine Referrals (SE): the number of new user sessions on a brand’s website that were
initiated by search engine referrals within a particular time window. Six search engines (AOL,
Ask, Bing, Google, MSN and Yahoo) are included, accounting for 99% of U.S. searches.5
Transaction Count (TC): the number of new sessions on a brand’s website that are initiated
within a particular time window and where a transaction is completed within 24 hours. Purchase
decisions may take much longer than site visits, as they may be delayed by time spent reading
reviews, researching competing options or consulting other members of the household. Thus, a
one-day window was employed similarly to Blake et al. (2013).
It is important to note that the difference between sessions and pageviews (described
earlier) ensures that the same machine will not be counted in both the pre and post windows in
the two-minute data. If a given machine initiates a new session during the two-minute “pre”
window, comScore’s definition of a session ensures it will not be counted again in the two-
minute “post” window, as 30 minutes have not elapsed between pageviews.6
Several exploratory analyses were conducted using subsets of the data. In one, we plotted
traffic to brand websites corresponding to different ad creatives. Figure 6 shows Amazon.com
traffic for two distinct ads: (a) “available now” and (b) “Kindle.” The data showed a large spike
5 A limitation of this the data is that this measure does not indicate when the user initiated the search.
6 It is possible but highly unusual for a single machine to be counted in both the “pre” and “post” windows in the
two-hour dataset. If a machine’s last visit to a brand webpage is more than 30 minutes prior to an ad insertion, and
then the machine is observed to visit the brand’s webpage again during the two hours following the ad insertion,
those will be counted as one new session during the two-hour “pre” window and one new session during the two-
hour “post” window.
15
in the minute following the start of the ad and a small, enduring increase thereafter. The
magnitude of these lift patterns seemed to depend on the ad content, highlighting the importance
of more formal investigation of the impact of ad content on web visitations.
The second exploratory exercise involved plotting browsing activity within shorter time
windows for a wider selection of brands. Figure 7 illustrates this for Target and JC Penney’s.
Most of the immediate uptick in browsing activity was observed within two minutes after the ad,
with some effects persisting up to two hours after the ad. A similar pattern appeared for all of the
brands analyzed in this manner. This is how we chose the two particular window lengths of two
minutes and two hours.7 The online appendix offers a concrete example of how the online
shopping variables are measured within each of these two windows.
[Figures 6 and 7 about here]
Table 1 provides advertising and online shopping data for the 20 brands in the dataset.
The average brand created 64 different commercials to advertise 7 distinct products, and spent
$204 million to air those commercials 18,251 times. Consumers initiated 49,402 direct sessions
on the average brand’s website, with an additional 23,061 sessions coming from search engine
referrals. 6.3% of the machines that were observed to initiate those sessions completed a paid
transaction or subscription within 24 hours. Table 2 offers some back-of-the-envelope
7 Although an ideal approach would be to gauge the sensitivity of the analysis to the length of the window chosen,
this was judged to be infeasible due to computational costs. This was an unusually complex data merge; to our
knowledge, it has not previously been offered by any commercial research firm. Due to the sheer size of the
datasets, our merge routine required 3*1013
computational queries and about 45 days to run. Section 5 indicates
some agreement in the results based on the two chosen window lengths, suggesting that small adjustments the
window lengths might be unlikely to change the qualitative findings.
16
calculations showing that, under conservative assumptions, 13.5% of the online purchases in the
data may have been a direct result of in-sample advertisements.8
3.4. Television Advertising Content Data
The third dataset was created specifically for this paper by coding the contents of the 1,269 TV
advertisements. Most prior academic efforts to analyze advertising content have manually coded
a few dozen ad creatives9. Our data collection effort contained 1,269 unique ad creatives, 21 ad
content items per creative and spanned multiple brands and categories. Given the size of the task
at hand, we opted for a three-step procedure involving item coding, assessment of reliability and
classification validation.
We first used the literature to identify and define the four ad types (Direct-response,
Argument-based, Emotion-based and Imagery-based) by which each TV commercial in our
dataset to be classified. This ad typology is defined and presented in Section 2.2 and summarized
in Figure 2.
Using these definitions, we selected 21 ad content elements to code from prior academic
analyses of advertising content. All ads were coded on the basis of these items. Given the large
number of ads to be coded, we recruited ten coders and assigned each ad to only one coder who
viewed it multiple times and coded it on the basis of the items chosen. A subsample of ads was
later re-coded by a new group of six independent coders following the same procedure to
measure inter-coder reliability. Finally, we submitted the proposed classification along with the
8 We advise strong caution in interpreting these calculations as they rely on several untested assumptions and they
are intended solely as an illustration. However, they do suggest that a significant number of the observed
transactions were caused by TV ads in the sample. 9 Unusually large exceptions are Buijzen and Valkenburg (2004), who identified the presence of 41 types of humor
in 316 advertisements, and Anderson et al. (2013) and Liaukonyte (2013), who coded the product attributes
communicated by 1,571 OTC pain medication ads..
17
items pertaining to each ad type to an expert panel of 14 academics to validate or refute the
groupings. The details of each step follow.
Item selection. 21 question items were created to measure the prevalence of the four types
of content features in each ad. The features were chosen to identify direct-response elements
(e.g., call to go online, online contact information, call to purchase), arguments (e.g., product-
related, price-related, brand-related), emotion-inducing elements (e.g., story, humor, warm
feeling content) and sensory elements (e.g., visually pleasing, sensory stimulation).10
Feature coding. Ten research assistants were trained to code the advertisements. Coders
were instructed to watch each ad at least twice and then answer the 21-item questionnaire for that
ad. During coding, they could watch, pause and rewind the ad as many times as needed. If they
still remained unsure about how to code a particular ad, they were instructed to inform a research
associate. Over 99% of ads were coded completely the first time. Coders worked independently,
were paid hourly, and instructed not to work more than two hours at a time in order to avoid
respondent fatigue.
Coding reliability. A separate group of six assistants were hired to code a random sample
of 150 ads for eight of the brands (12% of the original 1,269) following the same procedure. We
dropped two survey items (“Is the product demonstrated in the ad?” and “Is the focus of the ad
more on the product or on the brand?”) due to low inter-coder reliability. The percentage match
among the remaining 19 survey items was 78%. We judged this figure to be acceptable given the
subjective nature of some of the survey items and the coders’ inability to resolve discrepancies
through discussion.
10
19 of the 21 survey items used binary response scales (presence/absence of element). For two items a three-point
scale (predominance of one element, predominance of another element or neither) was used.
18
Classification validation. In order to validate the choice of items used for each ad type,
we surveyed 14 academics from top-tier schools around the world who are experts on consumer
behavior research. We asked whether each item was applicable, somewhat applicable or not
applicable to the ad type that it was associated with. Only one of the items (“Would you judge
this to be an expensive or cheap ad to make?”) had a high rate of disagreement with the original
classification, at 50%, and was therefore dropped from the study. On average, the academics
surveyed agreed with the applicability in 97% of the remaining item/grouping combinations,
with every item-specific agreement score exceeding 85%. In the end, 18 survey items were used
to create indices based on the sum of each advertisement’s item responses within each group.
The survey items by ad type are provided in Table 3.
[Table 3 about here]
Descriptive Statistics. Table 4 describes how brands differ in their use of advertising content. For
example, Papa John’s made the heaviest use of direct-response ads in the sample, while
Victoria’s Secret ads rated the lowest on this type. However, while there are differences across
brands, standard deviations across creatives within a brand are sometimes comparable to the
standard deviations across the entire sample. In sum, every brand used every type of ad content
in its advertisements.
[Table 4 about here]
4. Model and Estimation
We model the causal effects of TV advertisements on three online shopping variables—search
engine referrals (SE), direct traffic (Dir) and transaction counts (TC)—using a system of linear
equations. Let i index advertisement insertions. Each insertion i promotes a particular brand and
19
product in a particular product category and corresponds to a particular date and time; we denote
these ib , ip , ic and it , respectively.
Let ),,( POST
i
POST
i
POST
i
POST
i TCDirSEY be a vector of the three online shopping variables
for brand ib measured within a window of time (either two minutes or two hours) immediately
following it . Let PRE
iY denote a vector of the same three variables for brand ib measured in a
window of time (of the same duration) immediately preceding insertion i.
In explaining our approach to estimating causal effects, we adapt the notation of Angrist
and Pischke (2009). We distinguish the online shopping variables we observe after an ad
insertion, denoted POST
iY1 , from the same online shopping variables we would have observed in
the same “post” time window had insertion i never occurred, denoted POST
iY0 . In other words,
POST
iY0 is the baseline level of online shopping while POST
iY1 is this baseline plus the treatment
effect of the television advertisement.
In the absence of an ad insertion, then we would expect the online shopping variables
(POST
iY0 ) to be influenced by their past realizations (PRE
iY ), as well as brand effects (ib ),
observed category-time interactions (iitcX ), and possibly unobserved category-time interactions (
iitc ). We make the conventional assumption that the conditional expectation of POST
iY0 is a linear
function of these variables:
Y
itc
Y
tcb
Y
b
PRE
i
POST
i UXYYiiiiii0 (1)
where Y
bi and
Y are matrices of parameters to be estimated and Y
iU is a random deviation of
the realization of POST
iY0 from its conditional expectation. We supplement the model in equation
20
(1) to allow the traffic variables (SE and Dir) to directly impact sales (TC), as this relationship is
directly implied by the definition of TC:
Y
itc
Y
tcb
Y
b
PRE
ib
POST
i UXYYiiiiiii0 (2)
wherein ib is a 3x1 vector with zeroes in its first two rows and
DT
b
POST
i
ST
b
POST
i iiDirSE in its
third row, and ST
bi and DT
bi capture the likelihood that search-engine referral or direct visitation
to brand ib ’s website is observed to result in a purchase within 24 hours.
We use i to refer to the treatment effect of advertisement insertion i and assume it also
enters linearly:
],,,,|[],,,,|[ 01 iiiiiiiiiiii tctctb
PRE
i
POST
iitctctb
PRE
i
POST
i XYYEXYYE . (3)
Therefore, the conditional expectation of the shopping variables in the “post” window is
Y
itc
Y
tcb
Y
b
PRE
ibi
POST
i UXAYYiiiiiii . (4)
In the following subsections, we describe each term in equation (4) in full detail. Before
doing so, we focus on the assumptions required for consistent estimation of the parameters using
data from each of the two time windows (two minutes and two hours).
4.1. Endogeneity Concerns
In order to obtain consistent estimates of the parameters without further modification of the
model, it must be the case that the unobserved category/time interactions (iitc ) are orthogonal to
the treatment effect ( i ). The possibility that they may be correlated arises from the idea that
21
brands may be able to anticipate unobserved category/time interactions and purchase ad
insertions at particular times to profit from those unobserved category/time interactions.11
Fortunately, when we use online shopping data measured in two-minute windows of
time, typical advertising business practices ensure that this is not a concern. The reason is that,
when a brand buys a television commercial, it pays for a network/quarter-hour combination, for
example ESPN between 8:45:00-8:59:59 P.M. on January 1, 2010. The advertiser does not know
the specific time within the quarter-hour that the ad will air, for three reasons. First, the actual
timing of commercial break within that quarter hour is not specified in the contract between the
network and the advertiser. Second, unless the advertiser has taken the unusual step of
purchasing a specific slot within the break, it does not know which slot its advertisement will
occupy (Wilbur et al. 2013). Third, 80% of advertisements are sold during the May “upfront”
market, 3-15 months prior to the ads’ air dates. Advertisers and networks often do not even know
what programs the ads will be on the air, much less the specific times that the ads themselves
will run.
For all three reasons, it strains credibility to argue that an advertiser could time a specific
ad insertion to profit from changes in online shopping behavior between a two-minute “pre”
window and an immediately following two-minute “post” window. Any systematic differences
in online shopping variables between the two-minute pre and post windows should be directly
attributable to the treatment effect, because it is not possible for a brand to time an ad insertion
within any four-minute block of time. In other words, iitb and i are uncorrelated in the two-
11
For example, suppose that many people subscribe to online dating sites on Monday afternoons with the hope of
finding dates during the following weekend. If a dating website was aware of this behavior, then the website might
tend to air particular types of ads on Mondays more than at other times. It then would be difficult to distinguish
dating-Monday-afternoon effect from a treatment effect for a dating website on a Monday afternoon.
22
minute window data. Equation (4) can be estimated directly using Two-Stage Least Squares
(2SLS) using the online shopping variables measured in two-minute intervals.
However, when using online shopping data measured in two-hour windows of time,
standard industry practices provide no such assurances; one might suspect that advertisers choose
treatment effects i with some knowledge of unobserved category-time trends iitc . In this case,
we use a difference-in-difference approach to control for unobserved category trends that vary
over time.
The idea is to use changes in online shopping variables for brands that (i) are in the same
product category as brand ib , and (ii) did not advertise during the sample period, to control for
unobserved category-time interactions corresponding to each insertion in the sample. Let
),,( POST
c
POST
c
POST
c
POST
c iiiiTCDirSEZ be a vector of the three online shopping variables for a set of
control brands in category ic measured in a two-hour window of time following ad insertion i,
and let PRE
ciZ be its counterpart in the two-hour period preceding ad insertion i. We denote the set
of control brands corresponding to product category ic as iz and discuss the selection of those
control brands below.
Because the control brands did not advertise at all, including at time it , and therefore did
not experience any treatment effect, the conditional expectation of POST
ciZ takes the same form as
POST
iY0 :
Z
itc
Z
tcz
Z
b
PRE
iz
POST
i UXAZKZiiiiiii . (6)
23
where the first two elements of izK are zero and the third is
DT
z
POST
z
ST
z
POST
z iiiiDirSE . To
finalize the difference-in-difference regression model, we subtract equation (6) from the
conditional expectation of POST
iY1 in equation (4) so that the unobserved category-time
interactions (iitc ) drop out of the model:
itci
Z
z
PRE
i
Y
b
PRE
iii
POST
i
POST
i UBXAZAYKZYiiii
)( (7)
where ii zbi KKK ,
ii zbi , ZY BBB and Z
i
Y
ii UUU . The system of
equations described by (7) is estimated via 2SLS using the two-hour window data.
We chose the control brands by selecting the largest brands within each product category
that did not advertise on television. That resulted in the following sets of control brands: (1)
Dating: OKCupid.com, Plentyoffish.com; (2) Retailers: Abercrombie, Roamans, American
Eagle, Children’s Place; (3) Telecom: Letstalk, Cricket, Wirefly; (4) Travel: Airtran,
ChoiceHotels, Cheaptickets, JetBlue. For the fifth product category (pizza), we were not able to
find any non-advertising brands that seemed to offer services comparable to pizza delivery.
Therefore, the difference-in-difference regressions exclude advertising insertions for pizza.
4.2. Exogenous Variables
The model contains two types of explanatory variables: baseline (in ib and
iitcX ) and treatment
(in i ). The baseline variables include brand fixed effects and a rich set of interactions between
category dummies and time variables. For each of four intervals of time—week of the year, day
of the week, hour of the day, and minute of the hour—we interact a fixed effect for each time
interval with a product category dummy. Therefore each online shopping variable equation in
conditional expectation (2) contains 714 categorical variables: an intercept, 19 brand effects, 259
24
category-week interactions, 34 category-weekday interactions, 119 category-hour interactions,
and 299 category-minute interactions. The purpose of including such a flexible conditional
expectation function is to avoid mistakenly attributing systematic variation in the online
shopping variables to advertising insertions.
The treatment effect i includes the advertising content variables described in section
3.4, and an additional 266 fixed effects for nearly everything we are able to observe about the
advertising insertion: the product that was advertised (137); the property (national network or
syndication company) in whose program the ad was inserted (96); the program genre during
which the ad was inserted (15); the number of the commercial break during which the ad was
inserted (9); and the number of the slot during the break during which the ad ran (9).
Moreover, the treatment effect contained additional controls: the estimated expenditure
on the advertisement, interacted with a brand dummy; the sum of all prior observed expenditures
on advertising creative ic (to control for possible ad wearout); the total expenditure by the brand
on other insertions during insertion i’s PRE and POST windows; and within-category
competitors’ total ad expenditures during insertion i’s PRE and POST windows. These final four
variables are included to control for clustering, that is, occurrences of neighboring insertions.12
Investigations showed that the results of primary interest (in Tables 5 and 6) are qualitatively
unaffected by the inclusion or exclusion of these controls.
4.3. Total Effects on Transactions
A quantity of particular interest is the total effect of advertising content on transactions. The
model allows each advertising content element j to affect sales (TC) of brand b directly and
12
To illustrate the clustering concern, suppose AT&T inserts an advertisement on CBS at 8:41:00 P.M. and another
ad on ESPN at 8:42:00 P.M. In this case, the POST window of the CBS ad will include some traffic caused by the
ESPN ad and both the PRE and POST windows of the ESPN ad will include some traffic caused by the CBS ad.
25
indirectly through either route of visitation (SE and Dir). Therefore, the total effect of ad content
element j on brand b transactions is
TC
j
DT
b
Dir
j
ST
b
SE
bj jtTotalEffec . (5)
The right-hand side of equation (5) sums the direct effect of ad content element j on search
engine referral traffic, multiplied by the brand-specific effect of search engine referrals on
transactions; the direct effect of ad content element j on direct traffic, multiplied by the brand-
specific effect of direct traffic on transactions; and the direct effect of ad content element j on
transactions. Standard errors of these total effects are calculated by bootstrapping from the
asymptotic distribution of the parameter estimates. The next section presents the econometric
findings.
5. Results
The first question to consider is whether advertising influences online shopping. Table 5 reports
the proportion of the variation explained in the three online shopping variables by several
alternative models.
[Table 5 about here]
Several conclusions emerge. First, in all cases, the model shows a greater ability to
explain direct traffic than search engine referrals, perhaps because of the time required to
conduct an internet search and evaluate the results. Second, if we include only data about the
advertising insertion treatment effect (excluding all baseline variables), the model can explain
48.7% and 62.2% of the variation in search engine referrals and direct traffic, respectively, in the
two-hour window data, and 3.5% and 13.6% of those variables in the two-minute window data.
Third, the baseline model (excluding treatment effect variables) explains more of the variation in
26
the dependent variables than the treatment effect alone. When we add the treatment effect to the
baseline variables, the model does indeed show an increased ability to explain all three
dependent variables in both the two-minute and two-hour datasets, thereby answering the first
question (whether TV advertising influences online shopping) in the affirmative.
Finally, we estimated a model with category-specific treatment effects. This was done by
interacting the treatment effect variables with category dummies, thereby increasing the number
of treatment effect parameters by factors of 5. However, the R-square statistics showed no
meaningful increase when we included the category-specific treatment effects. Evaluating all
models, the Akaike Information Criterion (AIC) and Bayesian Information Criterion (BIC) are
both minimized by the model with the common treatment effect, suggesting that the richer
category-specific parameterization does not justify the increase in model complexity.13
Therefore, we proceed by presenting and interpreting the findings from the common treatment
effects model, starting with advertising content.
5.1. Effects of Television Advertising Content on Online Shopping
Table 6 presents the effects of TV advertising content on direct traffic, search engine referral
traffic, and transactions. There are twelve such effects—four advertising content variables times
three online shopping variables—within each of the two regressions. In the two-hour regression,
9 of the 12 parameters are statistically significant at the 95% confidence level, while 6 of the 12
are significant in the two-minute regression. Four effects correspond in sign and significance
level between the two regressions, and there are no cases of contradictory findings between the
two-minute and two-hour window regressions, indicating some convergent validity. We proceed
13
The model was also subjected to a random 80% hold-out validation exercise. This was done to check for
overfitting because of the large number of fixed effects included. The results indicated a high degree of reliability.
The R-square and RMSE statistics were comparable between the full sample, a model estimated with a random 80%
subsample, and the predictions from that latter model when compared to the remaining 20% validation subsample.
27
by discussing the two-hour results, as summarized in Figure 8, as the slightly longer time
window includes more consumer search and purchase activity.
[Table 6 and Figure 8 about here]
Direct-response. Ads that make heavy use of direct-response tactics are found to have three
effects. First, they reduce the number of new sessions at the brand website initiated by search
engine referrals. Second, as expected, they increase the number of visitors coming through direct
means. The positive effect on direct visitation is more than six times larger than the drop in
search engine referrals. Taken together, these two results suggest that direct-response tactics both
bring new visitors to the site and encourage direct means of visitation over indirect means
(similar to Joo et al. 2014). This is likely a positive consequence for the brand, as it suggests that
television advertising makes the brand more salient to consumers, helping them to bypass search
engines and thereby reducing the “toll” the brand has to pay for search engine referral traffic.
Third, direct-response content is found not only to increase traffic overall, it leads to a higher
purchase probability among those who visit the website. These effects combine to create a
positive, significant total effect of direct response advertising on purchases for all 17 brands.
Argument and Emotion. Arguments and emotion-based content in ads are associated with two
seemingly contradictory effects: they simultaneously reduce traffic to the website while
increasing purchase probability among those who do visit. The most likely explanation for these
phenomena is that this type of advertising content is effective at resolving consumer uncertainty
about whether the advertised product fits their needs. In such a case, low-fit consumers would
forego visiting the brand website, while high-fit consumers would visit and buy, as suggested by
Wu et al. (2005) and Hans et al. (2013). The positive effect on purchase probability outweighs
the negative effect on traffic for most brands, leading to positive total effects argument-based
28
content on sales which are statistically significant for most brands. The same is true for emotion-
based content.
Imagery. Imagery content is associated with reduced direct visitation to the website in the two-
hour dataset. We suspect the reason for this is the effect of imagery on multitasking; intense
images are normally used in television advertisements to arrest the viewer’s attention and to
discourage them from disengaging with the medium. This suggests a possible downside for
brands that would benefit from triggering multitasking behaviors, as this is the only type of ad
content to trigger a negative total effect on transactions for most brands.
5.2 Additional Results
Table 7 presents additional predictors of the treatment effect of an advertising insertion.
Advertising insertions that appear within particular genres lead to significantly different
conversion rates. Relative to the excluded program genre (Animation), the largest increase in
purchase probability were observed for insertions during live sports. However, our ability to
interpret this result is limited. More research will be needed to determine whether the effect on
purchases comes from program genre itself, which may affect viewer engagement, or whether
they are attributable to the particular target audience attracted by those programs.
The break number and slot number results are more easily interpreted. The results
indicate that ad breaks that occur later in the program generate fewer new website sessions than
the first break in the program, with little or no apparent impact on purchase probability. There
does not appear to be any systematic variation in traffic or transactions across slots within
commercial breaks within the two-hour regression, though later ad slots produced fewer direct
visits in the two-hour regression (two-minute results are omitted for brevity).
29
The data show interesting findings for advertisements that have been aired repeatedly.
More past spending on an advertisement is associated with a reduced ability to generate new
direct traffic, but a higher purchase probability among those who do visit. This goes in line with
the dual purpose of TV ads for multitaskers: to generate an impulsive action to visit the website
and to build up a desire to go buy the brand.
[Tables 7-9 about here]
Table 8 shows that television networks vary in their effects on internet shopping. For
example, ads carried on CNBC are associated with reduced visitation across all three shopping
variables, while those appearing on Adult Swim or E! show a large increase in new brand
website traffic. As was the case for program genre, it is not clear whether these effects are caused
by the networks per se or by the types of viewers the networks attract.
Multi-product brands often have distinct creatives for different products. In those cases,
the product advertised sometimes has a substantial effect on how the advertisement influences
online shopping. The products found to have statistically significant effects are shown in Table 9.
They come mostly from the telecommunications category, wherein brands often market broad
lines of related products. It is perhaps unsurprising that these products may vary in their ability to
bring consumers to the brand website, as various plans offer substantially different value
propositions to consumers.
Table 10 presents autocorrelation and cross-equation correlation parameters. These
effects should not be interpreted as causal, but they do describe some interesting patterns. For
most brands, website traffic (through either route) in the POST window is positively correlated
with traffic counts in the PRE window. Similarly, transactions in the POST window are
30
positively associated with traffic in the POST window for most brands, with larger effects for
direct traffic than for search engine referrals.14
[Table 10 about here]
6. Discussion
The debate in the advertising industry has focused on the potentially negative effects of media
multitasking: distracting consumer attention from advertisements. In this research, we hope to
emphasize a potentially positive aspect: the viewer’s “second screen” enables an immediate and
measurable response to television advertising. The question then becomes, how can brands alter
their traditional television advertising efforts to influence online shopping?
The purpose of this paper is to estimate how television advertising content affects traffic
to the advertiser’s website, immediately or shortly after it appears on TV, and subsequent
transactions. This research contributes to the literature on cross-media advertising effects by
showing how brands can benefit from increased media multitasking, particularly the consumer
habit of simultaneously watching TV and browsing the internet.
The results showed that television advertising influences online shopping. In particular,
ads that use direct response tactics are found to increase both direct traffic and conversion
probability with a smaller reduction in search engine referrals. Argument- and emotion-based
content reduce traffic while simultaneously increasing conversions. Imagery is found to reduce
direct visitation without changing purchase probability.
6.1. Implications for Advertising Management
14
The effect of advertising expenditure is included as a control variable, but is 1 difficult to interpret. Recall that the
regression includes a large number of category/time interactions, plus dummies for TV property and program type.
Due to ad pricing practices, the estimated cost of each insertion is highly correlated with these variables.
31
Managers have to make three major decisions in planning their advertising campaigns: how
much to spend, how to spend it (i.e., what media to use) and what to say (i.e., what ad content to
use). This research deals primarily with the last question. Although ads may contain countless
executional elements, the majority of advertisers use only a handful of broad conceptual
categories. We have identified how four such categories influence online shopping.
Perhaps the most striking finding is the fact that advertising content can have opposite
effects on traffic and transactions. Internet sales data are typically sparse and highly variable
(Lewis and Rao 2013), so an advertising manager who wants to optimize the online effects of her
TV advertising budget might naturally consider using website traffic as a success metric.
However, our results suggest that such a success metric might lead to precisely wrong
conclusions if she is using argument- or emotion-based ad content, as these types of ad content
reduce traffic while simultaneously increasing total sales for most brands.
One clear recommendation is that advertisers seeking to influence media multitaskers in
the short run should not make heavy use of imagery in their ads. While they may work for
consumers of a single medium, these ads have no identifiable cross-media benefits.
These recommendations should be applied with caution as they only apply to the two-
hour windows within which we monitored online responses. Also, the total effects on sales was
found to vary across brands for each type of ad content. Finally, our data only measure online
sales, so our estimates do not distinguish incremental sales from those that may cannibalize
traditional channels such as offline retail or telephone contact.
6.3. Caveats and Future Research
As with all research, our analysis is subject to caveats. The first one is that, despite the massive
size of our database, we do not directly observe which ads were viewed or attended to by which
32
households. We designed the research to prevent this unobserved factor from influencing our
findings; however, because we did not control what TV or online content consumers were
exposed to, we avoid attempting to associate TV advertising content and online shopping over
time horizons longer than two hours. An especially important question is how brand and brand
image advertising will change in an era of media multitasking? Future research will ideally be
able to study multi-brand, multi-media single-source panel data of advertising exposure, online
traffic and sales, and look for longer-term effects. We hope our findings help to stimulate further
interest in creating and sharing such resources.
Another limitation of our approach is that we do not observe brands’ website content or
online advertising efforts. While these variables are held constant by our research design, one
would naturally expect they influence the probability that a consumer purchases after browsing a
brand’s website. A next logical step would be to quantify the effect of website content on sales,
and investigate how it might interact with television advertising content. It would also be
desirable to collect data on additional TV ad content variables to uncover additional insights.
In conclusion, brand managers have to deal with two effects of media multitasking. On
the one hand, it divides consumer attention and diverts it away from advertising. On the other,
the rise of online commerce enables a more immediate reaction to traditional advertising. This
paper shows how marketers can design their traditional television advertising to influence online
shopping, by managing the related goals of maximizing website traffic and transactions. In the
long run, we expect that marketers will develop a more sophisticated understanding of how
communication efforts in various media impact consumers at different stages of the purchase
funnel. We hope our findings can offer some initial progress in that direction by showing how
brands can achieve new goals with old methods.
33
References
Ackerberg, D. A. 2001. Empirically Distinguishing Informative and Prestige Effects of
Advertising. RAND Journal of Economics, 32 (2) 316-333.
Anderson, S.P., F. Ciliberto, J. Liaukonyte. 2013. Information content of advertising: Empirical
evidence from the OTC analgesic industry. International Journal of Industrial Organization
31(5) 355-367.
Anderson, S.P., R. Renault. 2006. Advertising Content. The American Economic Review, 39(1)
305-326.
Angrist, J.D., J.-S. Pischke. 2009. Mostly Harmless Econometrics. Princeton University Press:
Oxfordshire, UK.
Bagwell, K., 2007. The Economic Analysis of Advertising. In: Armstrong, M. and Porter, R.
(eds.), Handbook of Industrial Organization, North Holland, Amsterdam, 3 1701–1844.
Berlyne, D.E. 1971. Aesthetics and Psychobiology. East Norwalk, CT: Appleton-Century-Crofts.
Blake, T., C. Nosko, S. Tadelis. 2013. Consumer heterogeneity and paid search effectiveness: A
large scale field experiment. Mimeo, University of Chicago.
Buijzen, M. and Valkenburg, P. M. 2005. Parental mediation of undesired advertising effects.
Journal of Broadcasting & Electronic Media 49(2): 153-165.
Chaney, Paul K., T. M. Devinney, R.S. Winer. 1991. The impact of new product introductions
on the market value of firms. Journal of Business 64(4) 573-610.
Ching, A.T.,Ishihara, M. 2012. Measuring the Informative and Persuasive Roles of Detailing on
Prescribing Decisions. Management Science, 58(7) 1374-1387
Coffey, S. 2001. Internet Audience Measurement: A Practitioner's View. Journal of Interactive
Advertising 1(2) 10-17.
Dagger, T., P.J. Danaher. 2013. Comparing the Relative Effectiveness of Advertising Channels:
a Case Study of a Multimedia Blitz Campaign. Journal of Marketing Research, 50(4) 517-534.
Danaher, P.J., B.J. Green. 1997. A comparison of media factors that influence the effectiveness
of direct response television advertising. Journal of Interactive Marketing 11(2) 46-58.
Doyle, P., J. Saunders. 1990. Multiproduct advertising budgeting. Marketing Science 9(2) 97-
113.
Godes, D., D. Mayzlin. 2004. Using Online Conversations to Study Word-of-Mouth
Communication. Marketing Science 23(4) 545-560.
Gong, S., J. Zhang, P. Zhao, X. Jiang. 2013. Tweets and Sales: A Field Experiment. Mimeo,
Massachusetts Institute of Technology.
Gross, J.J., R.A. Thomson. 2007. Emotion Regulation: Conceptual Foundations. Handbook of
Emotion Regulation, James J. Gross, ed. New York: Guilford Press 3-26.
Haans, H., N. Raassens, R. van Hout. 2013. Search engine advertisements: The impact of
advertising statements on click-through and conversion rates. Marketing Letters 24(2) 151-163.
Hajcak, G. and Olvet, D. M. 2008. The persistence of attention to emotion: brain potentials
during and after picture presentation. Emotion 8(2): 250.
Hartmann, W., H. Nair, S. Narayanan. 2011. Identifying Causal Marketing Mix Effects Using a
Regression Discontinuity Design. Marketing Science 30(6) 1079-97.
34
James, E. L., B. G. Vanden Bergh. 1990. An information content comparison of magazine ads
across a response continuum from direct response to institutional advertising. Journal of
Advertising 19(2) 23-29.
Johnson, E. J., W. Moe, P. Fader, B. Steven, J. Lohse. 2004. On the depth and dynamics of
online search behavior. Management Science, 50(3), 299-308.
Joo, M., K.C. Wilbur, B. Cowgill, Y. Zhu. 2014. Television Advertising and Online Search.
Management Science, 60(1) 56-73.
Kolsarici C., D. Vakratsas. 2011. The complexity of multi-media effects. Marketing Science
Institute Working Paper Series 2011 Report No. 11-100. Marketing Science Institute.
Lee, D., K. Hosanagar, H. S. Nair. 2013. The effect of advertising content on consumer
engagement: Evidence from Facebook. Mimeo, University of Pennsylvania.
Lewis, R , J. Rao. 2013. On the near impossibility of measuring returns to advertising. Mimeo,
Microsoft Research. http://www.justinmrao.com/lewis_rao_nearimpossibility.pdf.
Rossiter, J.R. 1982. Visual imagery: applications to advertising. Advances in Consumer Research
9(1) 101-106.
Lewis R., D. Reiley. 2013. Down-to-the-Minute Effects of Super Bowl Advertising on Online
Search Behavior. ACM Conference on Electronic Commerce 639-656.
Liaukonyte, J. 2014. Is Comparative Advertising an Active Ingredient in the Market for Pain
Relief? Working Paper, School of Applied Economics and Management, Cornell University.
Lin, C., S. Venkataraman, S.D. Jap. 2013. Media Multiplexing Behavior: Implications for
Targeting and Media Planning. Marketing Science 32(2) 310-324.
MacInnis, D.J., L.L. Price. 1987. The role of imagery in information processing: Review and
extensions. Journal of Consumer Research. 13(4) 473-491.
Moe, W. W. and Fader, P. S. 2004. Capturing evolving visit behavior in clickstream data.
Journal of Interactive Marketing 18(1): 5-19.
Montgomery, A. L., Li, S., Srinivasan, K. and Liechty, J. C. 2004. Modeling online browsing
and path analysis using clickstream data. Marketing Science 23(4): 579-595.
Naik, P. A., K. Peters. 2009. A Hierarchical Marketing Communications Model of Online and
Offline Media Synergies. Journal of Interactive Marketing, 23 288-299.
Naik, P. A., K. Raman. 2003. Understanding the Impact of Synergy in Multimedia
Communications. Journal of Marketing Research, 13(4) 25-34.
Nielsen (2010) Three Screen Report, 1st Quarter 2010. White paper,
http://www.nielsen.com/us/en/newswire/2010/what-consumers-watch-nielsens-q1-2010-three-
screen-report.html, accessed August 8, 2013.
Nielsen (2011) 40% of Table and Smartphone Owners Use Them While Watching TV.
http://www. nielsen.com/us/en/newswire/2011/40-of-tablet-and-smartphone-owners-use-them-
while-watching-tv.html, accessed August 8, 2013.
Nielsen (2012) State of the Media: Advertising & Audiences Part 2.
http://nielsen.com/content/dam/corporate/us/en/reports-downloads/2012-Reports/nielsen-
advertising-audiences-report-spring-2012.pdf, accessed April 2014.
Nielsen (2014) The U.S. Digital Consumer Report. White paper, http://www.nielsen.com/
us/en/reports/2014/the-us-digital-consumer-report.html, accessed March 14, 2014.
Ofcom (2013) Communications Market Report 2013. White paper.
Ohnishi, H., P. Manchanda. 2012. Marketing Activity, Blogging and Sales. International Journal
of Research in Marketing 29(2012) 221-234.
35
Park, Y. H. and Fader, P. S. 2004. Modeling browsing behavior at multiple websites. Marketing
Science 23(3): 280-303.
Peltier, J.W., B. Mueller, R.G. Rosen. 1992. Direct response versus image advertising:
Enhancing communication effectiveness through an integrated approach. Journal of Direct
Marketing 6(1) 40-48.
Petty, R. E., and Cacioppo, J. T. 1986. The elaboration likelihood model of persuasion. Springer
New York.
Rubinson, J. 2009. VIEWPOINT-The New Marketing Research Imperative: It's about Learning.
Journal of Advertising Research 49(1) 7.
Teixeira, T.S. 2014. The Rising Cost of Consumer Attention: Why You Should Care, and What
You Can Do about It. Harvard Business School Working Paper, No. 14-055.
Teixeira, T.S., R. Picard, R. el Kaliouby. 2014. Why, when and how much to entertain
consumers in advertisements? A web-based facial tracking field study. Forthcoming Marketing
Science.
Teixeira, T.S., M. Wedel, R. Pieters. 2012. Emotion-induced engagement in internet video ads.
Journal of Marketing Research 49(2) 144-159.
Television Bureau of Advertising (TVB). 2013. TV Basics.
http://www.tvb.org/media/file/TV_Basics.pdf, accessed August 8, 2013
Tellis, G. J. 2004. Effective advertising: Understanding when, how, and why advertising works.
Sage Publications.
Tellis, G.J., R.K. Chandy, P. Thaivanich. 2000. Which ad works, when, where, and how often?
Modeling the effects of direct television advertising. Journal of Marketing Research 37(1) 32-
46.
U.S. Census. 2012. E-stats. http://www.census.gov/econ/estats/2010/2010reportfinal.pdf,
accessed May 2013.
Wilbur, K.C., L. Xu, D. Kempe. 2013. Correcting Audience Externalities in Television
Advertising. Marketing Science, 32(6): 892-912.
Wind, Y.J., B. Sharp. 2009. Advertising empirical generalizations: implications for research and
action. Journal of Advertising Research, 49(2) 246-252.
Wood, L. 2009. Short-term effects of advertising: Some well-established empirical law-like
patterns. Journal of Advertising Research 49(2) 186-192.
Wu, J., V. J. Cook Jr, E. C. Strong. 2005. A two-stage model of the promotional performance of
pure online firms. Information Systems Research 16(4) 334-351.
Xu, L., K.C. Wilbur, S. Siddarth, J. Silva-Risso. 2014. Price Advertising by Manufacturers and
Dealers. Management Science, forthcoming.
Zigmond, D., H. Stipp. 2010. Assessing a New Advertising Effect: Measurement of the Impact
of Television Commercials on Internet Search Queries. Journal of Advertising Research 50(2)
162-168.
Zigmond, D., H. Stipp. 2011. Multitaskers may be advertisers' best audience. Harvard Business
Review 12(1/2) 32-33.
36
Table 1. Descriptive Statistics
Table 2. Back-of-the-envelope Sampling Calculations
Sector BrandAdvertised
Products
Unique
Ad
Creatives
Ad
Insertions
Total Ad
Spendin
g ($MM)
Search
Engine
Referrals
Direct
Visit
Sessions
Trans-
actions
Conversion
Rate
Dating Chemistry 1 4 2,264 7 2,196 2,220 15 0.34%
eHarmony 1 48 16,124 53 7,793 19,430 58 0.21%
Match.com 1 22 7,192 25 24,629 40,500 384 0.59%
Pizza Domino's 5 50 23,904 150 7,210 12,203 10,806 55.66%
Papa John's 14 25 6,709 55 3,019 10,817 6,740 48.71%
Pizza Hut 13 65 22,783 168 5,388 10,227 3,373 21.60%
Retailers Amazon 1 3 672 8 151,745 244,022 35,134 8.88%
JC Penney's 13 99 18,159 174 23,208 32,596 5,137 9.21%
Macy's 14 159 21,378 211 18,607 29,790 1,953 4.04%
Overstock 1 12 3,866 18 17,108 20,112 1,396 3.75%
Sears 16 161 26,512 210 16,816 22,266 919 2.35%
Target 28 125 20,540 278 52,337 65,369 1,720 1.46%
Victoria's Secret 1 16 4,657 51 10,605 21,662 4,755 14.74%
Telecom. AT&T 8 180 83,919 1,126 41,928 166,335 3,889 1.87%
Sprint 5 46 22,920 484 12,110 37,053 836 1.70%
Verizon 7 168 57,442 826 24,731 138,073 8,206 5.04%
Travel Expedia 3 30 12,938 66 15,972 46,832 1,611 2.57%
Orbitz 1 12 4,876 17 6,461 22,791 786 2.69%
Priceline 1 21 7,464 55 8,619 22,995 1,064 3.37%
Southwest 3 23 698 106 10,732 22,747 2,026 6.05%
Total 137 1,269 365,017 4,088 461,214 988,040 90,808
Average 7 63 18251 204 23061 49402 4540 6.27%
ComscoreKantar
Variable Value Comment
Number of total purchases in the sample 90,808 Source: comScore
ComScore daily sample size 100,000 Source: comScore
Number of computers in the US 470,850,000 Assumption: 1.5 desktops and laptops per person
Sampling probability 0.02% Calculation
Total ad spend 4,088,000,000$ Source: Kantar estimates
Cost/person/exposure $0.01 Assumption; typical TV ad cost
Average response rate to direct response ads 0.10% Assumption; typical for DR TV ads
Average response rate to brand ads 0.01% Assumption; 1/10 typical DR TV ad response rate
Proportion of direct response ads 20.00% Assumption; Danaher and Green (1997)
Proportion of ad responders who buy online 50.00% Assumption; 47% of our sample is online only
Number of person-exposures to sample ads 408,800,000,000 Calculation
Number of person-exposures delivered to comScore
panelists 86,821,705
Calculation; assumes no correlation between
sampling probability and ad exposures
Number of purchases by comScore panelists stimulated by
sample ads 24,310 Calculation: avg. response rate * num. exposures
Number of online purchases caused by sample ads 12,155 Calculation: num. purchases * proportion online
37
Table 3. Survey Items by Ad type
Table 4. Ad Content Descriptives by Brand
Direct Response
Is there a call to go online (e.g., shop online, visit the web)?
Is there online contact information provided (e.g., URL, website)?
Is there a visual or verbal call to purchase (e.g., buy now, order now)?
Does the ad portray a sense of urgency to act (e.g., buy before sales ends, order before ends)?
Is there an incentive to buy (e.g., a discount, a coupon, a sale or “limited time offer”)?
Is there offline contact information provided (e.g., phone, mail, store location)?
Is there mention of something free?
Argument
Does the ad mention at least one specific product (e.g., model, type, item)?
Is there any visual or verbal mention of the price?
Does the ad show the brand or trademark multiple or few times?
Emotion
Is the ad intended to be emotional? (You may not agree. But was that the intention of the ad?)
Does the ad give you a warm feeling about the brand?
Does the ad tell a story (e.g., with characters, a plot, an ending)?
Is the ad creative, clever?
Is the ad intended to be funny? (You may not agree. But was that the intention of the ad?)
Imagery
Does this ad provide sensory stimulation (e.g., cool visuals, arousing music, mouth-watering)?
Is the ad visually pleasing?
Is the ad cute? (e.g., baby, puppy, animated characters)
Sector BrandAdvertise
d Products
Num.
Unique Ad
Creatives
Direct Resp.
min=0,max=7
avg. (st.dev.)
Argument
min=0,max=3
avg. (st.dev.)
Emotion
min=0,max=5
avg. (st.dev.)
Imagery
min=0,max=3
avg. (st.dev.)
Dating Chemistry 1 4 3.8 (2.0) 1.0 (1.0) 1.5 (0.9) 0.3 (0.4)
eHarmony 1 48 3.9 (1.2) 1.2 (0.5) 2.2 (0.9) 1.1 (0.9)
Match.com 1 22 1.9 (0.8) 0.5 (0.6) 2.9 (1.0) 1.5 (1.1)
Pizza Domino's 5 50 3.6 (1.5) 2.9 (0.4) 2.0 (1.2) 1.5 (0.7)
Papa John's 14 25 5.6 (1.0) 3.0 (0.1) 1.0 (0.9) 1.4 (0.5)
Pizza Hut 13 65 3.1 (1.3) 3.0 (0.2) 1.3 (1.4) 1.5 (0.7)
Retailers Amazon 1 3 3.6 (1.1) 2.7 (0.7) 3.0 (0.0) 2.1 (0.4)
JC Penney's 13 99 3.4 (1.7) 2.0 (0.8) 0.8 (1.0) 1.4 (1.0)
Macy's 14 159 3.6 (1.7) 2.1 (1.1) 0.9 (1.4) 1.2 (0.9)
Overstock 1 12 2.7 (1.0) 2.3 (0.7) 2.3 (0.8) 1.8 (0.8)
Sears 16 161 3.8 (1.2) 2.0 (0.8) 1.7 (1.4) 1.0 (0.8)
Target 28 125 1.3 (1.0) 1.2 (1.0) 2.1 (1.1) 1.7 (0.9)
Victoria's Secret 1 16 0.9 (0.8) 1.2 (0.7) 0.3 (0.6) 1.6 (0.5)
Telecom. AT&T 8 180 2.5 (1.6) 1.5 (1.0) 2.4 (1.2) 1.6 (0.9)
Sprint 5 46 2.9 (1.2) 2.0 (0.8) 1.7 (0.9) 1.3 (0.7)
Verizon 7 168 3.2 (1.9) 1.9 (1.0) 1.4 (1.2) 1.3 (0.6)
Travel Expedia 3 30 3.4 (1.5) 1.5 (0.8) 1.6 (1.2) 1.6 (1.0)
Orbitz 1 12 1.4 (0.6) 1.2 (0.4) 2.1 (1.1) 0.8 (0.8)
Priceline 1 21 2.6 (1.5) 1.6 (0.6) 2.4 (1.2) 1.0 (0.5)
Southwest 3 23 2.8 (1.2) 0.8 (0.9) 2.4 (0.9) 0.9 (0.6)
3.0 (1.7) 1.9 (1.0) 1.8 (1.3) 1.4 (0.8)Average (st. dev.) across all insertions
38
Table 5. R-Square Statistics by Online Shopping Variable and Model Specification
Table 6. Effects of Ad Content on Online Traffic and Transactions
SE DIR TC AIC BIC SE DIR TC AIC BIC
Treatment Effect Only 0.487 0.622 0.087 0.037 0.138 0.002
Baseline Only 0.693 0.868 0.206 862,555 887,457 0.044 0.172 0.154 2,030,240 2,050,468
Baseline + Treatment Effect 0.698 0.873 0.212 858,202 891,283 0.055 0.191 0.158 2,024,186 2,051,297
0.698 0.873 0.212 858,215 891,809 0.055 0.191 0.158 2,024,205 2,051,695
Number of Observations
2 Minutes (Quasi-Diff.)
Baseline + Category-Specific
Treatment Effect
328,212277,573
R-square R-square
2 Hours (Diff.-in-Diff.)
SE DIR TC SE DIR TC
-.0170*** 0.106*** .0165*** -.0010** .0046*** .0005
(.0069) (.0142) (.0048) (.0007) (.0012) (.0005)
Argument -.0260** -.2970*** .0360*** .0000 -.0110*** 1.02e-
(.0119) (.0246) (.0083) (.0013) (.0021) (.0009)
Emotion .0036 -.0980*** .0262*** .0003 -.0010 .0001
(.0078) (.0160) (.0054) (.0008) (.0013) (.0005)
Imagery -.0120 -.1680*** -.0040 -.0020** -.0130*** .0020***
(.0108) (.0223) (.0075) (.0011) (.0019) (.0008)
Standard errors in parentheses. *** p<0.01, ** p<0.05
Direct
Response
2 Hours (Diff.-in-Diff.) 2 Minutes (Quasi-Diff.)
39
Table 7. Additional Treatment Effects
Table 8. Effects of Television Network (Significant Effects Only)
Break # Slot #
Program Type SE DIR TC (in prog.) SE DIR TC (in break) SE DIR TC
Documentary -.2310** -.0020 0.177*** 2 .0391 .0264 -.0130 2 -.0090 -.0350 .0316
(.1130) (.2310) (.0782) (.0268) (.0551) (.0186) (.0282) (.0580) (.0196)
Drama/Adventure -.2060 .0867 0.139*** 3 -.0210 -.1270** -.0110 3 -.0310 -.0560 .0147
(.1080) (.2220) (.0749) (.0286) (.0588) (.0199) (.0285) (.0586) (.0198)
Entertainment -.0220 -.1430 0.202*** 4 -.0710** -.1090 -.0130 4 .0006 -.0830 .0003
(.1090) (.2240) (.0758) (.0309) (.0636) (.0215) (.0294) (.0604) (.0204)
Feature Film -.1510 -.1600 0.143*** 5 -.0510 -.0940 -.0500** 5 -.0470 -.1250** .0282
(.1060) (.2180) (.0735) (.0346) (.0712) (.0241) (.0310) (.0637) (.0215)
Instruction/Advice -.1590 .1090 0.153*** 6 -.1170*** -.1200 -.0140 6 .0091 -.0840 -.0140
(.1250) (.2560) (.0865) (.0428) (.0880) (.0297) (.0331) (.0681) (.0230)
News -.1280 .0776 0.148*** 7 -.0380 .0743 .0364 7 -.0150 -.0900 -.0280
(.1120) (.2300) (.0776) (.0493) (.1020) (.0343) (.0366) (.0754) (.0255)
Olympics .1920 2.335*** -.4350*** 8 -.1380** -.2190 .0294 8 .0007 -.0360 .0749***
(.2190) (.4510) (.1520) (.0588) (.1210) (.0409) (.0424) (.0872) (.0295)
Other -.3360*** -.1890 0.188*** 9 -.1510** -.2500 -.0520 9 .0599 .0579 .0418
(.1290) (.2650) (.0894) (.0674) (.1390) (.0468) (.0506) (.1040) (.0352)
Sitcom -.1370 .0819 0.134*** -.0630 -.3320*** -.0080 .0952*** .0193 .0580**
(.1020) (.2100) (.0709) (.0463) (.0952) (.0321) (.0458) (.0941) (.0318)
Slice of Life -.2080 -.2080 .1000
(.1070) (.2190) (.0740)
Sports -.3430*** -.2110 0.231*** -5.68e-10 -3.60e-08*** 5.58e-09***
(.1180) (.2430) (.0821) (1.61e-09) (3.32e-09) (1.12e-09)
Suspense/Mystery -.0060 .3590 0.132***
(.1120) (.2300) (.0776)
Talk -.2700** -.8310*** 0.162*** -9.92e-07*** -3.21e-06*** 1.03e-07*** 1.13e-07*** -2.63e-07*** 1.07e-07***
(.1140) (.2350) (.0792) (3.52e-08) (7.25e-08) (2.45e-08) (1.84e-08) (3.79e-08) (1.28e-08)
Unknown -.2870** -.0610 .1640 3.46e-07*** -3.94e-07*** -1.09e-07*** 9.17e-08*** 3.81e-07*** 2.12e-08
(.1460) (.3000) (.1010) (3.63e-08) (7.47e-08) (2.50e-08) (1.90e-08) (3.91e-08) (1.32e-08)
Variety Music -.1410 -.0820 .1150
(.1220) (.2510) (.0849)
10 or more 10 or more
Past Spend
on Creative
Own "Pre"
Window
Own "Post"
Window
Comp. "Pre"
Window Spend
Comp. "Post"
Window Spend
2 Hours (Diff.-in-Diff.) 2 Hours (Diff.-in-Diff.) 2 Hours (Diff.-in-Diff.)
SE DIR TC SE DIR TC SE DIR TC
ADSM 0.273*** 0.520** 0.115 FNEW -0.0836 -0.415** 0.0328 NGC 0.0196 -0.461** -0.0771
(0.104) (0.215) (0.0725) (0.0942) (0.194) (0.0654) (0.0931) (0.192) (0.0647)
AMC 0.309*** -0.0456 0.00471 FX 0.0909 0.486*** 0.130*** SPK -0.0683 -0.334** 0.0859
(0.0989) (0.204) (0.0687) (0.0687) (0.141) (0.0478) (0.0652) (0.134) (0.0453)
BET -0.0709 -0.321** 0.0692 GALA 0.0565 -0.451** 0.0892 TLC 0.0435 0.347** 0.0113
(0.0727) (0.149) (0.0505) (0.0900) (0.185) (0.0625) (0.0780) (0.160) (0.0542)
BRAV 0.0677 0.316** 0.0613 HIST -0.0158 -0.330** 0.0744 TNNK 1.386*** 0.396 -0.300
(0.0766) (0.158) (0.0532) (0.0702) (0.145) (0.0488) (0.335) (0.690) (0.233)
CNBC -0.457*** -2.504*** -0.237*** MNTV 0.106 1.205** -0.225 TOON 0.560** 0.863 0.160
(0.124) (0.255) (0.0861) (0.273) (0.561) (0.190) (0.246) (0.506) (0.171)
CNN -0.109 -0.781*** 0.0726 MTV 0.0887 0.376*** 0.0657 TRU 0.290*** 0.114 0.107
(0.0888) (0.183) (0.0617) (0.0613) (0.126) (0.0426) (0.0957) (0.197) (0.0664)
CW -0.100 -0.732*** 0.0316 NAN -0.115 -0.359** 0.0610 TWC -0.127 0.641*** -0.159**
(0.0969) (0.199) (0.0673) (0.0827) (0.170) (0.0574) (0.106) (0.219) (0.0738)
E! 0.197*** 0.372*** -0.0394 NBC 0.0911 0.326** 0.0203 USA 0.0254 -0.0228 0.102**
(0.0658) (0.135) (0.0457) (0.0775) (0.159) (0.0539) (0.0685) (0.141) (0.0476)
ESP2 0.188** -0.0916 0.0307 NFLN 0.517*** 1.750*** -0.583*** VH-1 0.0731 0.253** 0.108***
(0.0950) (0.195) (0.0660) (0.156) (0.320) (0.108) (0.0594) (0.122) (0.0413)
ESPN 0.296*** 0.201 -0.0908
(0.0856) (0.176) (0.0595)
TV Network
2 Hours (Diff.-in-Diff.)
TV Network
2 Hours (Diff.-in-Diff.)
TV Network
2 Hours (Diff.-in-Diff.)
40
Table 9. Effects of Advertised Product (Significant Effects Only)
Table 10. Brand-Specific Effects of Prior Traffic and Transactions
SE DIR TC SE DIR TC
-0.0535 1.620*** -0.183*** -1.671** 1.870 -0.539
(0.0777) (0.160) (0.0540) (0.664) (1.366) (0.461)
AT&T : Pre-Paid Wireless Service 0.327 5.794*** -0.871** -1.634*** -0.551** -0.103
(0.539) (1.109) (0.374) (0.117) (0.241) (0.0774)
-1.761*** -0.0111 0.201 -1.621*** -0.565** -0.167**
(0.481) (0.989) (0.334) (0.108) (0.223) (0.0709)
AT&T Inc : Corporate Promotion -0.900*** 2.040*** -0.0614 Verizon : Business Wireless Service -0.101 0.442 -0.513***
(0.107) (0.220) (0.0742) (0.124) (0.256) (0.0833)
0.218 5.226*** -0.753*** Verizon : Consumer Wireless Service -0.305*** 1.555*** -0.758***
(0.135) (0.278) (0.0939) (0.0952) (0.196) (0.0623)
0.340** 4.724*** -0.789*** Verizon : ISP/TV/Wireless 0.135 -0.571 -1.172*
(0.149) (0.307) (0.103) (0.920) (1.892) (0.638)
Eharmony.com : Online 0.594*** 3.028*** -0.0189 0.562*** 0.0360 -0.755***
(0.186) (0.413) (0.128) (0.173) (0.357) (0.118)
Match.com Dating Service : Online 1.906*** 4.989*** 0.0164 -0.633*** -0.958*** -0.0682
(0.208) (0.452) (0.141) (0.131) (0.270) (0.0885)
-2.233*** -1.989*** -0.730*** -0.873*** -6.013*** 0.452***
(0.163) (0.337) (0.110) (0.166) (0.343) (0.113)
-1.618*** -1.661*** -0.363***
(0.175) (0.361) (0.119)
2 Hours (Diff.-in-Diff.)
Sprint Wireless Service : Consumer
Wireless Service
Verizon Communications : Corporate
Promotion
Verizon Family Share Plan : Consumer
Wireless Service
Verizon Nationwide Unlimited Talk :
Consumer Wireless Service
Product
Sprint Everything Data Family Plan :
Consumer Wireless Service
AT&T Go Phone : Pre-Paid Wireless
Service
AT&T Mobile TV : Consumer Wireless
Service
AT&T Unlimited Calling Plan : Consumer
Wireless Service
Sprint Everything Data Plan : Consumer
Wireless Service
Product
2 Hours (Diff.-in-Diff.)
AT&T : Consumer Wireless Service
Sprint Any Mobile Anytime Plan :
Consumer Wireless Service
Sprint Corp : Corporate Promotion
2 Hrs. (D.-in-D.)DV:
Predictor: SEPRE
DirPRE
TCPRE
Est. Cost SEPRE
DirPRE
TCPRE
Est. Cost SEPOST
DirPOST
TCPRE
Est. Cost
Dating Chemistry .0289 0.138*** -2.2350 4.63e-05 -.1780 0.243*** -2.3750 -0.000215** -.0020 -.0110 .0550 1.05e-05
(.0672) (.0615) (1.2650) (5.27e-05) (.1380) (.1270) (2.6020) (0.000109) (.0509) (.0504) (.8800) (3.65e-05)
eHarmony 0.150*** 0.104*** -.4060** -7.78e-06 0.267*** 0.204*** -.4940 -2.32e-05 .0016 .0060 .1080 -1.64e-06
(.0165) (.0092) (.1580) (1.49e-05) (.0340) (.0189) (.3250) (3.07e-05) (.0124) (.0066) (.1090) (1.04e-05)
Match.com 0.388*** .0391*** 0.210*** -2.39e-05 0.156*** 0.263*** 0.547*** -8.58e-05** .0027 .0139*** .0214 -6.84e-06
(.0114) (.0091) (.0984) (1.65e-05) (.0238) (.0190) (.2020) (3.39e-05) (.0086) (.0065) (.0678) (1.14e-05)
Retailers Amazon 0.561*** 0.152*** -.0280 -9.26e-05*** 0.539*** 0.487*** -.0410 -0.000161*** 0.107*** .0786*** 0.128*** -6.87e-06
(.0122) (.0078) (.0250) (5.34e-06) (.0256) (.0160) (.0514) (1.10e-05) (.0091) (.0060) (.0147) (3.65e-06)
JC Penney's 0.187*** .0851*** -.0500*** 1.62e-06 0.300*** 0.262*** -.1470*** 6.68e-06*** .0797*** 0.172*** .0185** 5.16e-07
(.0081) (.0060) (.0152) (8.60e-07) (.0168) (.0127) (.0314) (1.77e-06) (.0059) (.0041) (.0095) (5.97e-07)
Macy's .0508*** .0673*** 0.104*** 5.35e-06*** 0.179*** 0.228*** .0983*** 4.23e-06 .0920*** 0.104*** .0392*** -1.32e-06
(.0082) (.0060) (.0181) (1.11e-06) (.0169) (.0125) (.0373) (2.29e-06) (.0057) (.0041) (.0120) (7.71e-07)
Overstock .0681*** .0599*** .0238 5.11e-06 .0538 0.106*** .0719 1.28e-05 .0508*** .0802*** .0110 -1.54e-06
(.0182) (.0166) (.0720) (3.22e-06) (.0378) (.0345) (.1480) (6.62e-06) (.0127) (.0120) (.0488) (2.25e-06)
Sears .0174*** .0725*** .0204 1.67e-06 .0368*** 0.312*** .0763** 2.30e-06 .0519*** .0792*** .0253** 7.75e-07
(.0076) (.0054) (.0222) (8.75e-07) (.0158) (.0111) (.0458) (1.80e-06) (.0055) (.0038) (.0149) (6.07e-07)
Target 0.289*** 0.253*** -.0920*** -9.81e-06*** 0.250*** 0.441*** -.2180*** -1.12e-05*** -.0040 .0822*** .0763*** 6.57e-07
(.0047) (.0040) (.0213) (8.97e-07) (.0096) (.0083) (.0438) (1.84e-06) (.0035) (.0029) (.0142) (6.20e-07)
Victoria's S. 0.104*** .0359*** .0329 1.03e-05*** .0776*** 0.297*** -.1300*** 1.05e-05*** 0.153*** 0.257*** .0015 -1.57e-06
(.0145) (.0121) (.0217) (1.91e-06) (.0299) (.0251) (.0450) (3.93e-06) (.0110) (.0077) (.0134) (1.32e-06)
Telecom. AT&T .0739*** .0860*** -.0990*** -7.63e-07** 0.210*** 0.569*** -.3050*** -3.63e-06*** .0973*** .0216*** -.0090*** -4.28e-07
(.0031) (.0010) (.0049) (3.16e-07) (.0064) (.0021) (.0100) (6.49e-07) (.0023) (.0007) (.0033) (2.19e-07)
Sprint -.0670*** -.0470*** .0006 1.39e-06*** -.0180 .0484*** -.0240 8.21e-06*** 0.105*** .0791*** .0843*** -1.75e-07
(.0117) (.0058) (.0279) (4.63e-07) (.0243) (.0119) (.0573) (9.52e-07) (.0087) (.0041) (.0189) (3.20e-07)
Verizon .0695*** .0098*** -.0130*** 4.79e-07 0.219*** 0.542*** -.4490*** -1.15e-06 0.184*** .0642*** -.0040 1.02e-06***
(.0044) (.0012) (.0037) (3.87e-07) (.0091) (.0025) (.0076) (7.95e-07) (.0034) (.0009) (.0025) (2.68e-07)
Travel Expedia .0797*** 0.110*** -.1090** -1.05e-06 0.155*** 0.262*** -.2030** -4.88e-06 .0381*** .0338*** .0746*** -1.87e-06
(.0185) (.0099) (.0486) (9.80e-06) (.0380) (.0209) (.1000) (2.02e-05) (.0132) (.0071) (.0325) (6.80e-06)
Orbitz -.0210 -.0140 .0921 -2.51e-05 .0569 .0253 .1210 -1.42e-05 .0358 .0269*** 0.114*** -1.01e-06
(.0300) (.0136) (.0848) (1.85e-05) (.0617) (.0284) (.1740) (3.80e-05) (.0222) (.0101) (.0580) (1.28e-05)
Priceline .0570*** .0212** -.0020 -2.63e-07 .0952*** .0027 0.207*** 4.74e-07 .0243 .0425*** .0751*** 2.31e-07
(.0190) (.0120) (.0535) (3.68e-06) (.0392) (.0251) (.1100) (7.57e-06) (.0148) (.0085) (.0363) (2.55e-06)
Southwest .0584 .0679** .0248 1.39e-06 -.0800 -.0080 0.589*** 5.93e-06*** .0557 .0645*** -.0590 -6.90e-07
(.0553) (.0389) (.1560) (9.32e-07) (.1140) (.0810) (.3210) (1.92e-06) (.0437) (.0265) (.1050) (6.62e-07)
DirPOST
SEPOST
TCPOST
41
Figure 1. Consumer Decisions Online
Figure 2. Conceptual Distinction among TV Advertisements
Direct-response Brand-image
Affective
Argument-based
Imagery-based Emotion-based
TV Advertisements
Cognitive
42
Figure 3. Traffic and Transactions by Product Category and Hour
43
Figure 4. Ad Timing and Frequency
Figure 5. Timing Illustration
44
Figure 6. Traffic by Window Length and Ad Content
Note: Increases prior to the start of the ad are an artifact of the discrete time interpolation in the graph.
Figure 7. Traffic within Shorter Window Lengths
Figure 8. Effects of Ad Content on Online Traffic and Transactions (2-hour data)
Total Effect is
pos. for all 17
brands
Total Effect
is pos. for 9
brands;
n.s. for 8
Total Effect
is pos. for
15 brands;
n.s. for 2
Direct ResponseTransactions
Search
Engine
Referrals
Direct
Traffic
+
+
+
EmotionTransactions
Search
Engine
Referrals
Direct
Traffic
+
+
n.s.
ArgumentTransactions
Search
Engine
Referrals
Direct
Traffic
+
+
ImageryTransactions
Search
Engine
Referrals
Direct
Traffic
+
n.s.
n.s.Total Effect
is neg. for
10 brands;
n.s. for 7