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Market Power and the Laffer Curve?
Eugenio J. Miravete† Katja Seim‡ Jeff Thurk§
September 1, 2017
Abstract
We characterize the trade-off between consumption tax rates and tax revenue – the Laffer curve
– while allowing for re-optimization by both consumers and firms with market power. Using
detailed data from Pennsylvania, a state that monopolizes retail sales of alcoholic beverages,
we estimate a discrete choice demand model allowing for flexible substitution patterns between
products and across demographic groups while not imposing conduct among upstream distillers.
We find that current policy overprices spirits and that firms respond to reductions in the state’s
ad valorem tax rate by increasing wholesale prices. The upstream response thus limits the
state’s revenue gain from lower tax rates to only 14% of the incremental tax revenue predicted
under the common assumption of perfect competition. The burden of such naıve policy falls
disproportionately on older, poorer, uneducated, and minority consumers. Upstream collusion
exacerbates these effects.
Keywords: Laffer Curve, Market Power, Public Monopoly Pricing, Tax Incidence.
JEL Codes: L12, L21, L32
?
This paper supersedes an earlier version titled “Complexity, Efficiency, and Fairness of Multi-Product MonopolyPricing.” We thank the editor, Liran Einav, and three referees for their guidance and thorough reading of ourmanuscript. We also thank Thomas Krantz at the Pennsylvania Liquor Control Board as well as Jerome Janickiand Mike Ehtesham at the National Alcohol Beverage Control Association for helping us to get access to the data.We are also grateful for comments and suggestions received at several seminar and conference presentations, and inparticular to Jeff Campbell, Kenneth Hendricks, and Joel Waldfogel. We are solely responsible for any remainingerrors.
† The University of Texas at Austin, Department of Economics, 2225 Speedway Stop 3100, Austin, Texas 78712-0301;Centre for Competition Policy/UEA; and CEPR, London, UK. Phone: 512-232-1718. Fax: 512-471-3510. E–mail:[email protected]; http://www.eugeniomiravete.com
‡ Wharton School, University of Pennsylvania, Philadelphia, PA 19104-6372; CEPR and NBER. E–mail:[email protected]; https://bepp.wharton.upenn.edu/profile/712/
§ University of Notre Dame, Department of Economics, Notre Dame, IN 46556. E–mail: [email protected];http://www.nd.edu/ jthurk/
1 Introduction
Economic research rarely achieves the overnight policy influence of the Laffer curve – the famous
inverted U-shape function that relates tax rates and government revenues first scribbled on a napkin
(Wanniski, 1978). The concept proved to be a cornerstone of “Reaganomics”, inspired the 1981
Kemp-Roth tax cuts, and continues to be at the foundation of every discussion of tax reform. And
yet, there exists little quantitative evidence of its underlying economic mechanisms so the Laffer
curve remains more of an ethereal concept rather than an empirically well-understood fundamental.
Our objective is to empirically characterize the determinants of the Laffer curve in the
taxation of consumer goods – an area which accounts for 17.4% government revenues in the United
States and 32.7% of revenues in the average developed country.1 The industrial organization
literature has demonstrated that in many consumer goods categories, ranging from cereals to
icecream, soft drinks, and the alcoholic beverages we study, firms possess significant market power
in pricing, stemming in part from the differentiated nature of the products they offer and the
market segmentation these product offerings facilitate. We therefore build upon earlier work that
uses detailed data to study the Laffer curve via reduced-form estimation under the assumption of
perfect competition among firms (e.g., Auerbach, 1985; Chetty, 2009) to allow firms to respond
strategically in their choice of pre-tax prices to changes in tax policy. Foreshadowing our results,
allowing for the possibility that both consumers and imperfectly competitive firms respond to
changes in tax policy has significant impact on optimal taxation and the characterization of the
Laffer curve.
We first use a simple model of monopoly taxation to explore the equilibrium interactions
between firms and consumers in response to changes in the tax rate. We show that raising excise
tax rates beyond a critical level indeed decreases government revenues under very general demand
conditions and that the shape and location of the Laffer curve depends not only on the tax rate and
consumer demand elasticity but also on the firm’s strategic response. Moreover, we show that the
tax rate and the firm price response are strategic substitutes so the latter mutes the change in retail
price induced by a change in the tax rate. The effectiveness of tax policy therefore depend on the
government’s ability to anticipate the strategic pre-tax price response of the firm to tax changes.
More generally, incorporating the equilibrium response of the firm is vital to making correct policy
recommendations and failing to do so would result in the firm’s price response unraveling, at least
partially, the government’s objective.
We evaluate these predictions empirically within the context of alcohol taxation. The
production, distribution, and sale of alcoholic beverages is the second largest beverage industry in
the United States (behind soft drinks) and an important source of government tax revenues. Using
detailed price and quantity data for 2002-2004 across all retail liquor stores in Pennsylvania, we
estimate the response elasticities of both upstream firms and consumers to the state’s choice of ad
1 https://taxfoundation.org/sources-government-revenue-oecd-2016/.
– 1 –
valorem tax rate in the market for distilled spirits – a product category which generated substantial
tax revenue for the state’s general fund and represents the industry’s fastest growing segment.
Several remarkable features of the data enable us to estimate key parameters of the model
rather than impose them ex ante, thereby increasing the reliability of both our demand estimates
and the Laffer curves they generate. First, in Pennsylvania the state monopolizes both the wholesale
and retail distribution of alcoholic beverages and applies a simple pricing rule that translates
wholesale prices into retail prices via a single uniform ad-valorem tax. Thus, upstream distillers
effectively choose retail prices taking into account this tax. Second, as a product’s retail price is
common across the state at any point in time, differences in consumer preferences materialize in
differences in product purchases. This enables us to let consumer tastes vary systematically across
products and demographics leading to more flexible substitution patterns and better estimates of
both consumer demand and upstream market power. It also enables us to evaluate the effects
of tax policy on different consumer groups. Third, the fact that we observe both wholesale and
retail prices enables us to estimate consumer demand without placing any restrictions on upstream
conduct and market power ex ante. Our estimation therefore allows for the possibility that firms
are price-takers and cannot react strategically to changes in policy.
We lever these features to estimate product-level demand for 312 products produced by 37
firms across a variety of consumer types. The combination of robust demand estimates with data
on wholesale prices in a model of oligopoly pricing reveals that upstream firms in the industry enjoy
considerable market power, earning 35 cents in income for every dollar of revenue. To illustrate
the implications of not accounting for the strategic responses of these firms to changes in tax
policy, we compare market equilibria when the state can either perfectly anticipate the distillers’
response to changes in its taxation policy – a Stackelberg equilibrium – or, alternatively, assume that
firms do not respond at all to policy changes, our so-called “naıve” equilibrium. To complete this
counterfactual analysis we also evaluate how the optimal response of upstream firms to tax policy
varies with upstream firm market conduct, ranging from single-product pricing to full collusion,
and how such a wholesale pricing response translates into changes in the shape and position of the
Laffer curve.
We show that market power among firms has a significant effect on the shape of the Laffer
curve. The estimated Laffer curve for a naıve policymaker is steeper than for the policymaker who
correctly anticipates pre-tax price responses. This is particularly true as conduct among upstream
becomes more collusive. Not accounting for the strategic response of upstream firms, therefore,
leads to poor policy recommendations. For instance, a naıve regulator would have concluded that
the state could increase tax revenues 7.75% (or $28.74 million) by reducing the ad valorem tax
from 53.4% to 30.68%. This reduction in the ad valorem tax would have increased profits for all
upstream firms, but we show that they could do even better by increasing their wholesale prices
by 3.79%, or 34 cents, on average. Thus, the estimated model indicates that upstream prices and
the tax rate are strategic substitutes – a prediction of the simple theoretical model.
– 2 –
While this change in upstream price may appear small, the fact that upstream distillers
price on the elastic region of demand leads to a large change in quantity demanded by consumers.
Ultimately, the firm response enables upstream firms to convert 87% of the incremental tax revenue
into firm profits, or equivalently the response limits the PLCB to attain only 13.8% of the forecasted
incremental revenues ($3.73 million). It is important to note that this substantial undoing of the
state’s revenue objective requires no coordination among firms. Were distillers to collude in setting
wholesale prices, choosing the naıve optimal tax rate leads to a net decrease in tax revenues of
14.18% of current revenue.
Alternatively, a regulator attempting to maximize tax revenue and endowed with perfect-
foresight would have predicted the upstream response and instead would only decrease the tax rate
to 39.31%, or 42.07% in the event of collusion among upstream firms. While the state does increase
tax revenue roughly two percent, profits among upstream distillers increase 30.8% as does their
share of integrated industry profits (from 29.5% to 34.9%).
Finally, we show that the political ramifications of naıve policy – of assuming perfect compe-
tition among firms – are significant. Not only would such policy be largely ineffective at increasing
tax revenues, but the burden of the tax falls disproportionately on older, poorer, uneducated and
minority consumers. This highlights that the ability of policymakers to account for the responses of
firms and consumers to policies is of significance both from an equity and an efficiency standpoint.
It underscores the importance of recent efforts by, for example, the Congressional Budget Office
to consider Dynamic Scoring of new proposed legislation by accounting for the response of firms,
workers, and consumers to changes in government policy, a direct – albeit delayed – response to
the Lucas Critique. The major handicap then resides in correctly predicting how agents will react
to changes in fiscal policy across different industries.2
1.1 Related Literature
The current paper contributes to several strands of literature, including the characterization of the
Laffer curve, optimal taxation, the analysis of pass-through in non-competitive markets, and the
analysis of alcohol pricing regulation.
Theoretical analysis of the Laffer curve has fallen mostly within the reign of macroeconomics,
which has focused on the possibility of the Laffer curve arising as a result of a general equilibrium
effect induced by taxation on the supply of labor and capital.3 Early empirical attempts such as
Stuart (1981) or Fullerton (1982) build upon static two-sector general equilibrium models where
households allocate their time between taxed labor and non-taxed leisure. Pecorino (2011) adds
a dynamic component as hours worked entail human capital accumulation. Trabandt and Uhlig
(2011) allow for household preference heterogeneity within a neoclassical growth model to generate
2 See the presentation by Wendy Edelberg, the CBO’s Assistant Director for Macroeconomic Analysis, to the FederalReserve Bank of Chicago at https://www.cbo.gov/publication/50730.
3 See Ireland (1994), Novales and Ruiz (2002), or Schmitt-Grohe and Uribe (1997) to name a few.
– 3 –
labor and capital Laffer curves for the U.S. and fourteen European countries assuming calibrated
country-specific Frisch elasticities of labor supply and intertemporal elasticities of substitution.
Relative to this literature we focus on excise taxation with particular attention to the
responses of not only consumers but also suppliers with market power. Consequently within this
literature, our analysis is more related to optimal capital rather than labor taxation. Our results
then indicate that modifications of the capital tax rate could be largely undone by providers of
capital if they have market power – a likely scenario. The advantage of our approach is that we
have detailed industry data that allows us not to impose any restrictions on the model such as a
predetermined objective of the state. As our model generates robust estimates of consumer demand
and upstream market power, this approach increases the reliability of our conclusions.
We show that the existence, shape, and location of the Laffer curve in our context depends
not only on the interaction of the tax rate and consumers’ downstream product demand responses
(via demand elasticities) but also on upstream market power and firms’ strategic pre-tax price
setting. This is a commonly overlooked aspect of the analysis of taxation since the empirical public
finance literature deals primarily with perfectly competitive scenarios despite the well-documented
market power of firms in the studied industries.4 Our data enables us to evaluate this assumption by
drawing a distinction between the mechanical effects of and behavioral responses to taxation (Saez,
2001, §3.2). Specifically, we allow the policymaker to be well aware of downward sloping retail
demands but potentially naıve regarding the upstream firms’ reaction to taxes/pricing regulations.
A comparison of the Laffer curve with this naıve policy design to the one generated by a policymaker
who chooses the tax rate in anticipation of the optimal firm responses (Stackelberg equilibrium)
allows us to evaluate the implications of this assumption. Our results indicate that assuming perfect
competition among firms, i.e., assuming upstream firms cannot respond to changes in policy, has
substantial equilibrium effects on firms, consumers, and overall tax revenue across a variety of
assumptions regarding upstream conduct.5,6
Finally, we are not the first to address the implications of policy in the regulation of
alcoholic beverages. Seim and Waldfogel (2013) evaluate the potential welfare effects of free entry
in Pennsylvania. Aguirregabiria, Ershov and Suzuki (2016) study the case of partial entry in the
wine segment where state-run stores sell side by side with private, yet price regulated, retailers.
Illanes and Moshary (2015) take advantage of the privatization of the alcohol distribution system in
Washington state to evaluate the effect of potential retail entry on pricing and product offering. In
a related paper (Miravete, Seim and Thurk, 2017), we show that current policy is largely consistent
4 For instance, Chetty, Looney and Kroft (2009) and Evans, Ringel and Stech (1999) both assume competitive supplyin the beer and cigarette industries, respectively.
5 Weyl and Fabinger (2013) show the impact of imperfect competition on tax pass-through under a variety of modelenvironments but do not address asymmetric firms with horizontally-differentiated products. Consequently, ourresults provide an empirical extension.
6 There are other papers that address the market conduct in the alcoholic beverage industry. Conlon and Rao (2015)document how the “post and hold” regulation in some states help wholesalers set collusive prices. Miller andWeinberg (2015) use mergers in the brewing industry to identify collusive behavior.
– 4 –
with tax-revenue maximization (versus managing ethanol consumption) and compare the current
uniform policy to a subsidy-free taxation policy with optimal product-specific ad valorem taxes. We
find that the one-size-fits-all policy employed by the state generates significant redistribution within
upstream firms and downstream consumers. Griffith, O’Connell and Smith (2017) evaluate the use
of product-specific corrective taxes to minimize health externalities related to ethanol consumption
under the assumption that all firms, including suppliers and retailers, do not respond. In this paper,
we abstract from modeling the motivation behind the state’s tax code to more clearly illustrate the
key determinants of the tax rate/revenue trade-off and to characterize the shape and location of
the Laffer curve empirically while accounting for re-optimization by both firms and consumers.
1.2 Organization of the Paper
The paper is organized as follows. In Section 2 we provide a simple model of taxation under
imperfect competition to illustrate the key mechanisms underlying our results. In Section 3 we
present the data, discuss the details of the Pennsylvania pricing rule, address the interaction with
the upstream distillers, and document heterogeneous consumption patterns across demographic
groups. In Section 4 we present an equilibrium discrete choice model of demand for horizontally
differentiated spirits. The model allows preferences to be correlated across products of similar
characteristics and incorporates the features of the current pricing regulations while allowing for
(but not imposing) imperfect competition in the upstream distillery market. In Section 5 we discuss
the estimation procedure and how the unique features of our data help identify the rich substitution
patterns across products in our econometric specification. We pay particular attention to dealing
with the potential endogeneity of prices using retail price information from other control states and
variation in input costs. We also show how we use the estimated model to infer upstream market
power among distillers. In Section 6 we show that this market power has significant implications
for the shape and location of the Laffer curve while also documenting the variation in Laffer curves
across consumer types. We conclude and discuss avenues for future research in Section 7. We
include additional data sources, descriptive statistics, robustness of demand estimates, and other
results in the Appendices.
2 A Simple Model of the Laffer Curve Under Market Power
In this section we present a simple model of monopoly excise taxation to provide an economic
framework for the interpretation of our empirical analysis in an oligopolistic environment. Our goal
is to illustrate how a regulator’s tax rate choice affects its tax revenue when allowing for optimal
price responses by taxed firms to changes in policy. We show that tax revenue is not monotonic in
the tax rate and that certain tax rates fall into what Arthur Laffer called the “Prohibitive Range,”
when an increase in the tax rate leads to a reduction in tax revenue. To this end, we investigate how
the optimal pre-tax price responds to a change in the tax rate, and show that whenever demands are
less convex than in the isoelastic case, the pre-tax price and the tax rate are strategic substitutes.
– 5 –
Consider the case of a single product sold by a monopoly supplier and produced at a constant
marginal cost. Focusing on the single-product monopoly case allows us to avoid accounting for
cross-product substitution as the excise tax and tax-inclusive prices change; instead we simply
consider the marginal consumer’s decision to switch between the inside and outside good. Our
empirical analysis in the context of multi-product oligopoly upstream suppliers agrees, nevertheless,
with all predictions of the model. The monopolist chooses the pre-tax price pw (wholesale price
in our empirical context) for a given tax rate τ ≥ 0, which impacts the tax-inclusive price the
consumer pays, pr (retail price),
pr = (1 + τ)pw . (1)
In setting its optimal pre-tax price, the monopolist chooses pw to maximize profits Π(pw) = (pw −c)D(pr), given the retail demand D(pr), constant marginal cost c, and the chosen tax rate τ , which
requires:
D(pr) + (pw − c)D′(pr)(1 + τ) = 0 , (2)
or equivalently, in terms of the Lerner index,
pw − cpw
=−D(pr)
D′(pr)(1 + τ)· 1 + τ
pr=−1
ε(pr). (3)
This inverse-elasticity pricing rule relates the pre-tax (wholesale) markup of the monopolist
to the inverse of the demand elasticity evaluated at the tax-inclusive (retail) price. The monopolist
thus sets the pre-tax price pw so that the tax-inclusive price falls in the elastic region of demand.
This result is behind the optimal pricing response of the taxed firm to changes in the tax rate
shown below. We argue that under general conditions, for any demand that is less convex than an
isoelastic demand function, a tax rate increase induces the non-competitive taxed firm to reduce
its pre-tax price in order to keep the tax-inclusive market price in a region of demand that is not
too elastic. Thus, tax rates and non-competitive firm prices move in opposite directions, i.e., they
are strategic substitutes.
To characterize the monopolist’s optimal price response to a change in tax policy we make
use of the retail price definition in equation (1) and totally differentiate the first order condition in
equation (2) with respect to pw and τ to obtain:
dpw
dτ=−1
1 + τ· (2pw − c)D′(pr) + pr(pw − c)D′′(pr)
2D′(pr) + (pw − c)(1 + τ)D′′(pr). (4)
For convenience we define η(τ) as the elasticity of the monopolist’s optimal pre-tax price to a
change in the tax rate τ . We make use of the inverse-elasticity rule (3) to express the firm’s
optimal response elasticity as
η(τ) ≡ dpw
dτ· τpw
=−1
1 + τ·
(pw − pw
ε(pr)
)D′(pr)− pw×pr
ε(pr) D′′(pr)
2D′(pr)− pr
ε(pr)D′′(pr)
· τpw
. (5)
– 6 –
Further simplification using the retail price definition (1) yields:
η(τ) =−τ
1 + τ·
(1− 1
ε(pr)
)− κ(pr)
2− κ(pr), (6)
where κ(pr) is the curvature of demand given by
κ(pr) =D′′(pr)D(pr)
[D′(pr)]2. (7)
The curvature of demand κ(pr) is the key element that determines the sign of η(τ). We are
interested in characterizing demand conditions under which the pre-tax price response elasticity
η(τ) is negative, given that the firm prices in the elastic region of demand, ε(pr) < −1. We explore
first the case of linear and concave demand followed by somewhat convex demand functions.
It is straightforward to show that η(τ) < 0 in equation (6) under profit-maximizing pricing
with ε(pr) < −1 whenever demand is linear or concave as D′′(pr) ≤ 0 ensures that κ(pr) ≤ 0. Linear
demand is commonly used for algebraic convenience but concave demand is frequently assumed in
theoretical models, see Tirole (1989, §1.1).
There is however a larger set of demand systems that entails the strategic substitutability
of pw and τ . For instance, equation (6) indicates that η(τ) is always negative when κ(pr) ∈ [0, 1)
and the monopolist prices on the elastic region of demand. The curvature condition of κ(pr) < 1
describes the class of log-concave demand functions, including both concave and somewhat con-
vex demand functions.7 Log-concavity characterizes the vast majority of demand specifications
commonly used in economic analysis, including discrete choice models of demand based on Type
I extreme value distributed errors so widely used in empirical work, including ours, e.g., Fabinger
and Weyl (2016, Appendix 3).
Even for demand systems with higher curvature, with κ(pr) ∈ [1, 2), it is possible for η(τ)
to be negative, depending on the relative magnitudes of(1− 1
ε(pr)
)and κ(pr).8 Isoelastic demand, a
popular choice in the macro literature (e.g., Dixit-Stiglitz CES preferences), amounts to a limiting
case as it is straightforward to show that for these demand functions κ(pr) =(
1− 1ε(pr)
)and
thus, η(τ) = 0 according to equation (6). Thus, firms in these models do not alter their pricing
decisions in response to changes in tax policy by assumption. But whenever demand is less convex
than this popular limiting case, we characterize a large and empirically relevant class of demand
specifications where the optimal response of the monopolist to an increase in the tax rate always
is to reduce the pre-tax price, i.e., η(τ) < 0 so that the pre-tax prices and tax rates are strategic
substitutes.
7 If κ(pr) < 1, it follows from the definition of curvature that D′′(pr)D(pr) − [D′(pr)]2 < 0, which is the conditionfor demand to be log-concave.
8 We restrict attention to demand systems with κ < 2 since κ(pr) ∈ [0, 2) ensures that the revenue function R(pr) =prD(pr) is concave in pr, or equivalently, that the marginal revenue function is decreasing, a common demandrestriction in models of imperfect competition.
– 7 –
We can now explore how total tax revenue collected by the government varies as a function
of the tax rate τ when we account for the firm’s optimal price response. The government tax
revenue function is given by
T (τ) = (pr − pw)D(pr) = τpwD((1 + τ)pw
), (8)
where pr and pw are implicit functions of τ , pr(τ) and pw(τ), through the definition of the tax-
inclusive price (1) and the pre-tax price response elasticity (6). The effect of a change in the tax
rate on government tax revenue is
dT (τ)
dτ= pwD(pr) + τpwD′(pr)pw +
dpw
dτ
(τD(pr) + τpwD′(pr)(1 + τ)
)
= pw(D(pr) + τpwD′(pr)
)+ η(τ)pw
(D(pr) + ε(pr)D(pr)
)
= pwD(pr)
[(1 +
τ
1 + τε(pr)
)+ η(τ)
(1 + ε(pr)
)]. (9)
Note that the sign of dT (τ)/dτ is ambiguous and depends on the relative magnitudes of
the tax rate, demand elasticity, and the pre-tax price response elasticity. The prohibitive range of
the Laffer curve arises for a given tax rate τ when the equilibrium price elasticity of demand ε(pr)
and the equilibrium pre-tax price response elasticity η(τ) are such that:
dT (τ)
dτ< 0 ⇐⇒ 1 +
τ
1 + τε(pr) + η(τ)
(1 + ε(pr)
)< 0 . (10)
When are tax, demand, and upstream conduct conditions such that equation (10) is sat-
isfied? We consider first the case of a naıve policymaker who mistakenly believes that – akin to
the case of perfect competition – the monopolist will not modify its pre-tax (wholesale) price in
response to an increase in the ad valorem tax rate τ . When η(τ) = 0, condition (10) will not hold
for sufficiently low τ . However, this condition eventually holds as τ increases by reducing the total
value of sales receipts as higher tax rates push the price pr into a more elastic region of demand
for all demand systems other than the isoelastic limiting case. The macro literature relies on a
similar incentive mechanism to generate a Laffer curve: higher income taxation reduces workers’
labor supply to eventually reduce the labor tax base and income tax revenues. See Trabandt and
Uhlig (2011, Proposition 2).
Rewriting equation (9) when η(τ) = 0 shows that all we require to be on the prohibitive
region of the Laffer curve under a naıve policymaker is that consumer demand is sufficiently elastic
at the tax-inclusive equilibrium price,
ε(pr(τ)) < ε◦(τ) = −1 + τ
τ, (11)
– 8 –
For instance, for a tax rate of 50% (similar to the 53.4% tax charged by the PLCB) to be in the
prohibitive region of the Laffer curve of a naıve policymaker, the demand elasticity ε(pr) at the
corresponding equilibrium tax-inclusive price needs to be lower than ε◦(0.5) = −3 (a value that
many of our demand estimates exceed). The higher the tax rate and thus final retail prices, the less
elastic demand needs to be to reach the prohibitive range of the Laffer curve. Thus, tax revenue will
fall if a naıve policymaker increased taxes from a starting tax rate of 70% and the good’s demand
elasticity at the equilibrium price is at least ε(pr) < ε◦(0.7) = −2.43. Conversely, for many, more
moderate, taxation schemes, such as sales taxes, which in the U.S. across states reach only 9.45%
in 2015, demand for the affected products is unlikely to be sufficiently elastic for the observed tax
rates to be near or beyond the peak of the Laffer curve.9
To complete the analysis we compare the features of the Laffer curve for a naıve policymaker
described above with that of a policymaker with perfect foresight, capable of anticipating how the
monopolist re-optimizes its pricing decision after a change of the tax rate. Substituting (6) for η(τ)
in condition (10), the prohibitive range of the Laffer curve arises when
2− κ(pr) + 2τ
τ+ ε(pr) +
1
ε(pr)< 0 . (12)
For this inequality to hold over the elastic range of demand, ε < −1, it suffices that
ε(pr) < ε?(τ, κ) = −2− κ(pr) + τ
τ. (13)
How does the implicit relationship between the tax rate and the elasticity of demand that entails
a tax rate beyond tax revenue maximizing levels compare to the above, when η(τ) = 0? A general
comparison is dependent on the chosen demand system, which dictates a choice of κ(pr) and ε(pr).
However, when demand is log-concave and κ(pr) ∈ [0, 1), as in our empirical setting, we can show
that for any given tax rate τ :
ε?(τ, κ) = −2− κ(pr) + τ
τ< −1 + τ
τ= ε◦(τ) . (14)
When allowing for a strategic response by the monopolist to chosen tax rates, demand at tax-
inclusive retail prices thus needs to be more elastic than under the naıve scenario for any particular
tax rate to push tax revenues down the slippery slope of the Laffer curve. For example, for the above
tax rate of 50% to be in the prohibitive region for a policymaker with perfect foresight, demand
at the resulting tax-inclusive prices needs to be more elastic than −5 or −4 for κ(τ) equal to 0 or
0.5, respectively. This compares to the above critical value for the elasticity of −3 when η(τ) = 0.
For a given tax rate, the difference between the elasticity cutoff values for the perfect foresight and
naıve cases converges to zero as demand becomes more convex, reflecting that ε?(τ, κ)→ ε◦(τ) as
κ(pr)→ 1, and is highest when demand is linear and κ(pr) = 0.
9 See https://taxfoundation.org/state-and-local-sales-tax-rates-2015/. A rate of τ = 10% falls beyond thepeak of the Laffer curve if the demand elasticity at tax inclusive prices would need to be smaller than −11.
– 9 –
The flip side of this result is that a policymaker with perfect foresight may need to set a
higher tax rate to maximize tax revenues when compensating for the reduction in pre-tax price by
the monopolist, η(τ) < 0, than the naıve policymaker would have chosen. Expressing equation (14)
in terms of the optimal tax rate that maximizes tax revenue given the demand responsiveness at
the tax-inclusive prices, we have that
τ?(ε, κ) = −2− κ(pr)
1 + ε(pr)> − 1
1 + ε(pr)= τ◦(ε(pr)) (15)
Note that τ◦(ε) is not necessarily equal to τ◦(ε), the tax revenue maximizing tax rate for
the naıve policymaker, since the demand elasticities are evaluated at different tax-inclusive retail
prices, pr = (1 + τ?)pw in the case of the sophisticated policymaker and pr = (1 + τ◦)pw for the
naıve case. Locally, with small changes in the tax-inclusive retail price, however, and supported
by the empirical evidence we present below, the difference between τ◦(ε) and τ◦(ε) is sufficiently
small that τ?(ε, κ) > τ◦(ε(pr)).
Moving from the naıve scenario, η(τ) = 0, to one where the policymaker has perfect
foresight, η(τ) < 0, not only tends to shift the Laffer curve to the right, but also makes it flatter.
This is evident when inspecting the last term in equation (9), η(τ)(1+ε(pr)
)> 0, which equals zero
in the naıve scenario. This is the case because of the strategic substitutability of the tax rate and
wholesale prices, η(τ) < 0, under perfect foresight and the monopolist’s optimal pre-tax pricing on
the elastic region of demand, 1 + ε(pr) < 0. Thus, the stronger the firm response, the flatter the
slope of the Laffer curve becomes.
In summary, the theoretical model suggests that the downward sloping part of the Laffer
curve arises if demand is sufficiently elastic relative to the tax rate and the elasticity of the pricing
response of the taxed firm to changes in the tax policy. Even for the monopoly case, empirical
analysis is needed to determine the elasticity of demand under alternative tax-inclusive prices and
characterize the effective tax revenue function. Similarly, accounting for the firm’s price response
to excise taxation, which implies a possible shift and flattening of the Laffer curve relationship
between tax rates and revenue, requires estimates of firm market power via η(τ) and the slope of
consumer demand via ε(pr). Our analysis of PLCB pricing of spirits allows us to empirically assess
the necessary equilibrium responses of upstream firms and consumers.
This analysis could be extended to various homogeneous good oligopoly models along the
lines of the framework for analyzing tax incidence put forward by Weyl and Fabinger (2013). In our
context, however, the PLCB deals with horizontally-differentiated products for which theoretical
results do not exist, e.g., Fabinger and Weyl (2016, Appendix E). The main difficulty in evaluating
the effect of a tax rate increase in this context is that it not only induces substitution to the outside
option but also to other products that are taxed and therefore also generate tax revenues. In
consequence, addressing our research objective requires evaluating the determinants of the Laffer
curve empirically, accounting for the fact that the overall change in tax revenue after a change in the
tax rate reflects unequally induced changes in product sales due to heterogeneity in product costs
– 10 –
and characteristics. Further, firms and consumers can respond differently to a tax rate change based
on differences in market power and heterogeneous preferences, respectively. We account for these
effects empirically in characterizing the Laffer curve across not just one, but all spirits products,
both in aggregate and for different consumer types. In doing so, we are particularly interested in
comparing the tax revenue expected by a naıve regulator who mistakenly neglects the ability of
firms to re-optimize after a tax change, η(τ) = 0, to that realized by a policymaker who correctly
anticipates firm responses to its actions, η(τ) < 0.
3 PLCB Pricing and Sales Data
In this section we describe our data and institutional details that inform our theoretical modeling
and econometric specification. We first describe the data we obtained from the state of Pennsylvania
and other sources on the sales, prices, and characteristics of all products sold through the state-run
network of stores. We then summarize Pennsylvania’s current pricing regulations of alcoholic bev-
erages. We document how upstream firms’ pricing is constrained by rules regarding the frequency
and duration of temporary wholesale price adjustments. The fact that distillers need to decide far
in advance when to put their products on sale temporarily significantly reduces the endogeneity
concerns common in the estimation of models of demand for differentiated products. Next, we
explore the nature of competition in the upstream distiller market that mitigates the effectiveness of
any tax/pricing policy adopted by the PLCB . Finally, we document the heterogeneity of consumer
preferences for different types of spirits, a key source of identification in our empirical strategy.
3.1 Data: Quantities Sold, Prices, and Characteristics of Spirits
We obtained store-level panel data from the Pennsylvania Liquor Control Board (PLCB) under
the Pennsylvania Right-to-Know Law. The data contain daily information on quantities sold and
gross receipts at the UPC and store level for all spirits and wines carried by the PLCB from 2002
to 2004. We chose this sample because there were no mergers or acquisitions of relevance in the
upstream distiller industry segment resulting in a stable competitive environment. As a result,
pricing follows the “normal” pattern contemplated in the PLCB ’s rules. In addition, we received
information on the wholesale price of each product. These wholesale prices are constant across
stores, but vary over time according to well defined pricing periods.
As of January of 2003, the PLCB operated a system of 593 state-run retail stores spread
across the state.10 We combine sales of stores in the same zip code and drop several wholesale and
outlet stores, resulting in a total of 456 local markets. We then match combined store purchases with
consumer demographics by linking store locations with data on local population and demographic
characteristics using the 2000 Census. The PLCB opened and closed several stores over the time
10See Seim and Waldfogel (2013, §2) for a detailed account of the welfare losses induced by the very limited entryallowed in the wine and spirit segment of the Pennsylvania market. Pennsylvania also has a private system for thesale of beer, allowing the controlled entry of private retailers.
– 11 –
period of our sample. We take these entry/exit decisions as exogenous shifts in the demographic
composition of the potential pool of customers of each store. This feature of the data helps in
identifying the demographic interactions in our estimated model.11
Each store carries a multitude of wine and spirit products. We focus on the spirits category
as it represents a majority of PLCB off-premise sales, 60.8% of store revenue. These products
further constitute a well-defined and mature product category that can be described by few, easily
measurable product characteristics, including the type of spirit, the alcohol content, whether or not
a fruit or other flavor is added, and whether or not the product is imported.12
We further focus on sales of popular 375 ml, 750 ml, and 1.75 L bottles of products in the
spirits category, representing 80.9% of total spirit category sales by volume and 91.6% by revenue.
The resulting sample exhibits a long right tail common to consumer goods, where many products
are available to consumers but are rarely purchased. We therefore restrict the sample to only include
the most popular products in each bottle size, spirit type pairing. Consequently, a 750 ml bottle of
E&J Brandy (average retail price of $9.95) is in our final sample while a 750 ml bottle Remy Martin
Louis XIII Cognac (average retail price of $1,078) is not.13 Our final sample consists of 3,377,659
observations of market and time-period level purchases of 312 products that span brandy, cordials,
gin, rum, vodka, and whiskey for three bottle sizes. The final sample represents 56.8% and 63.2%
of the total off-premise bottle sales and revenue from spirits, respectively.
Table I reports the average characteristics of products in our sample. The average proof
is 75.33; 37.40% of products are imported; and 16.3% of products contain flavor add-ins.14 Table
I summarizes these product characteristics further by type of spirit. Vodkas and whiskeys have
significantly larger market shares (31.88% and 24.41%, respectively) than rum (16.18%), cordials
(13.38%), brandy (7.24%), or gin (6.91%). The differences in product variety within each category
mirror the differences in market shares, with only approximately one half as many brandy and
gin varieties as vodkas while 28.9% of the products are whiskeys. Flavored products are primarily
cordials and brandies and to a lesser extent vodkas and rums. We also see variation in domestic
11Appendix A describes how we assign Census block groups to their closest store and how we deal with store openingsand closings, and provides detail on the construction of the demographic variables. We also document that thelarge majority of spirits are sold at every store; this alleviates concerns about assortment differences between storesleading to potential competition for consumers between stores.
12This contrasts favorably with wines whose quality determinants are mostly unobserved, with a large number ofproducts with limited life cycles. This leads to tiny, highly volatile market shares of wines with frequent entry andexit of products of different vintages. For example, within the popular 750 ml bottle category, the top-100 sellingwines (out of 4,675) constitute 45% of total 750 ml wine revenue.
13We define popular products as the highest selling products that together account for 80% of total off-premise spiritsales of a bottle size, spirit type pair. By this definition, a 375 ml bottle of Captain Morgan could theoretically beexcluded from the sample, if it sales rank among 375 ml bottles is too low, while the 750 ml and 1.75 L versionsare included. In practice this did not occur. We also drop the Tequila segment as it accounts for few products.Together, these two restrictions allow us to drop a total of 1,240 products from our sample.
14 In 16th century England, if a pellet of gunpowder soaked in a spirit could still burn determined whether the spiritwas “proof” and thus taxed at a higher rate. Only if the alcohol by volume in rum exceeds 57.15% will gunpowderignite. To simplify, since 1848 in the U.S., a 100 proof corresponds to a spirit with 50% alcohol by volume content.See Jensen (2004).
– 12 –
Table I: Product Characteristics by Spirit Type
Products Price Share % Flavored % Imported Proof
By Spirit Type:
brandy 26 14.37 7.24 30.77 26.92 76.15cordials 62 14.02 13.38 32.26 51.61 55.82gin 28 15.03 6.91 3.57 28.57 83.42rum 40 13.61 16.18 10.00 17.50 74.03vodka 66 16.75 31.88 21.21 40.91 81.60whiskey 90 16.67 24.41 0.00 58.89 80.98
By Price and Size:
expensive 150 20.30 46.89 12.00 64.67 77.82cheap 162 10.92 53.11 17.90 22.84 72.46375 ml 48 8.89 15.19 8.33 47.92 75.10750 ml 170 14.44 50.20 21.76 44.71 72.951.75 L 94 20.56 34.61 6.38 37.23 78.77
all products 312 15.07 100.00 16.30 37.40 75.33
Notes: “Price” is the simple average price between 2002 and 2004 and across products in each category. “Share” isbased on number of bottles sold. “Cheap” (“Expensive”) products are those products whose mean price is below(above) the mean price of other spirits in the same spirit type and bottle size.
versus imported varieties across spirit types: 58.89% of whiskeys and 51.61% of cordials in our
sample are imported, but imported products comprise less than half of the products of the other
spirit types. We complement these product characteristics obtained from the PLCB with data on
spirit product quality from Proof66.com, a spirits ratings aggregator. The product score is largely
informative within, but not across, spirit types and is therefore not reported in Table I.
We denote spirits as expensive when their simple averaged price exceeds the mean price of
other spirits of the same type and bottle size. Table I shows that expensive spirits are purchased
nearly as often as cheaper varieties, but are less likely to be flavored or domestically produced and
have higher proof. The 750 ml bottle is the most popular size of product in terms of unit sales
and product variety, accounting for 50.20% of bottles sold and 54.9% of available spirits products,
closely followed by the 1.75 L bottle with a share of 34.61% of bottles sold and 30.1% of available
spirit products. The smallest bottles we consider, those in the 375 ml format, account for 15.1% of
bottles sold and 15.4% of spirit varieties.
Some of this variation is driven by the product set as upstream firms manufacture brands
in particular bottle sizes. For instance, our final sample is composed of 198 brands (e.g., Captain
Morgan) but 88 of these brands were available only in the 750 ml bottle size while 1 and 31 brands
were offered only in the 375 ml and 1.75 L size, respectively. The remaining 78 brands were offered
in several bottle sizes (e.g., Diageo sold Captain Morgan in 375 ml, 750 ml, and 1.75 L sizes).15
15This pattern is reflected in the raw data as well where 958 of the potential 1, 192 brands were offered only in onebottle size, usually the 750 ml format. Table B.I in Appendix B provides additional descriptive statistics on thedistribution of spirit prices by type and size of bottle.
– 13 –
3.2 The Mechanics of the Pricing Regulation
The PLCB acts as a monopolist in the retail distribution of wine and spirits where the Pennsylvania
State Legislature exerts regulatory oversight over several aspects of the daily operations of the
stores. Most notably, as per the Pennsylvania Liquor Code (47 P.S. §1-101 et seq.) and the
Pennsylvania Code Title 40, the legislature imposes a uniform markup rule upon the retail prices
the PLCB charges both across products and across stores. Prices of spirits are thus identical across
the state at a point in time and follow a common pricing/taxation rule known to all consumers and
upstream manufacturers.
This rule has been modified only infrequently over the years. From 1937 until 1980, the
retail price for all products was based on a 55% markup over wholesale cost for all gins and whiskeys
and 60% markup for other spirits. In 1980, the markup was reduced to 25% for all products and
a per-unit handling fee, the Logistics, Transportation, and Merchandise Factor (LTMF ), of $0.81
was introduced and later increased to $0.85 in 1982. The agency instituted the current 30% markup
in 1993 when it also modified the unit fee to vary by bottle size to better reflect transportation
costs from the PLCB ’s centralized warehouses to the retail stores. The LTMF unit fee for the
375 ml, 750 ml, and 1.75 L bottles in our sample amounts to $1.05, $1.20, and $1.55, respectively.
For the average product, the LTMF fee accounts for 26.7% of the final retail markup. In addition,
consumers also have to pay an 18% sales tax, the “Johnstown Flood Tax,” on all liquor purchases.16
Accordingly, the retail price pr of a given product with wholesale price, pw, is calculated as:17
pr = [pw × 1.30 + LTMF ]× 1.18 . (16)
Of primary concern for this paper is the uniform markup, an ad valorem tax, applied to all products,
amounting to (1.30× 1.18− 1), or 53.4%.
The PLCB has limited ability to depart from this uniform percent markup rule. It operates
seven outlet stores close to the state’s borders, in an effort to address any border bleed of consumers
who illegally import lower-priced products into Pennsylvania from neighboring states. While these
stores offer wines and spirits at discounted prices, the PLCB remains within the uniform markup
policy by selling products in the outlet stores not found in regular stores, for example multi-packs
or unusual bottle sizes for a particular product. Controlling for these stores has little qualitative
or quantitative effects on our results. Related robustness checks are reported in Appendix C.1.
The PLCB purchase bottles of spirits directly from upstream distillers at wholesale prices
pw. Because of the legislated pricing formula, retail price pr is driven by the wholesale pricing
decisions pw of the PLCB ’s suppliers and any change in the wholesale price results in a change
to the retail price passed on to consumers. A new product’s wholesale price remains fixed for
16The original 10% tax was instituted in 1936 to provide $41 million for the rebuilding of the flood-ravaged town ofJohnstown. Despite reaching the funding goal after the initial six years, the tax was never repealed, but insteadrose twice to 15% in 1963 and to 18% in 1968.
17An additional 6% sales tax is then applied to the posted price to generate the final price paid by the consumer.
– 14 –
one year after its introduction. For mature products, distillers can modify the wholesale price they
charge the PLCB at set intervals called “pricing periods” which last four or five weeks and typically
coincide with the month of year. We can therefore aggregate daily data on prices and quantity
sold to the level of these pricing intervals without concern of introducing aggregation bias into our
demand estimates – a useful aspect of our data.
The PLCB places some limitations on how often distillers can change the wholesale price for
mature products. Temporary wholesale price changes, typically price reductions or sales, amount
to 84.8% of price changes in our sample. Distillers can temporarily adjust their wholesale prices up
to four times a year, or once per quarter, but need to submit such proposed price changes to the
PLCB at least five months before the start of the promotion. A product can thus go on sale for
one month, but not for two in a row.
Upstream firms can also permanently change the wholesale price of a product, i.e., a change
in the reference price for temporary price changes. A permanent price change takes place at the
beginning of four-week long reporting periods which, for accounting purposes, occur at a slightly
different periodicity than the pricing periods. These price changes are instituted at the beginning
of the quarter’s first full reporting period, with some discretion on the part of the PLCB as to
the choice of actual reporting period. There is a time lag, however: distillers have to submit the
request for a permanent price increase by the start of the previous quarter. Permanent wholesale
price decreases may be submitted at any time and take effect at the beginning of the next period.
We discuss the periodicity of the price series further in Appendix A. The pricing periods we use
in our analysis below follow the periodicity of sales, resulting in 34 periods from 2002 to 2004.
Note that the delay between the request and effectiveness of either permanent or temporary price
adjustments limits the ability of the distillers to respond to temporary demand shocks – an issue
we revisit when discussing price endogeneity concerns in Section 5.
Table II: Percent of Products Placed on Sale Over the Year
Spring Summer Fall Winter Holiday Year Times
By Spirit Type:
brandy 30.77 50.00 34.62 26.92 34.62 59.26 2.37cordials 40.32 48.39 30.65 45.16 43.55 61.29 2.35gin 46.43 39.29 50.00 39.29 39.29 63.64 2.24rum 47.50 40.00 50.00 32.50 42.50 57.45 2.12vodka 50.00 60.61 57.58 39.39 50.00 76.81 2.24whiskey 58.89 51.11 48.89 42.22 53.33 65.71 2.51
By Price and Size:
expensive 40.32 48.39 30.65 45.16 43.55 71.66 2.14cheap 45.68 41.36 41.98 32.10 37.65 30.91 1.39375 ml 14.58 18.75 20.83 8.33 6.25 72.28 2.91750 ml 50.59 53.53 45.88 46.47 51.18 75.44 2.221.75 L 61.70 59.57 59.57 42.55 58.51 55.23 2.50
all products 48.40 50.00 46.15 39.42 46.47 65.31 2.34
Notes: “Cheap” (“Expensive”) products are those products whose mean price is below (above) the mean price ofother spirits in the same spirit type and bottle size. We define the “Holiday” season as the two pricing periods thatencompass Thanksgiving through the end of the year. Statistics reflect the percent of products with a temporaryprice reduction during the corresponding season except for “Times,” which denotes the average number of timesthat spirits in each category are on sale during a year.
– 15 –
Table II presents descriptive statistics for changes in temporary price. First, distillers
temporarily change a product’s price 2.3 times a year on average. While not all products experience
a temporary price change, the majority do; 65.31% of spirits are on sale at least once in a given
year. This is true across spirit types, with distillers changing the price of vodkas, expensive varieties,
and all but the largest bottles more frequently than the rest. There is also a seasonal pattern of
price changes across spirit types as distillers are more likely to change a product’s price during
the Summer and less likely during the Winter. Over the holidays, defined as pricing periods that
overlap with Thanksgiving through the end of the year, distillers place 46.47% of our spirit products,
ranging from 34.62% of brandies to 53.33% of whiskeys, on sale at least once, but change the price
of 375 ml bottles rarely. The combination of variation in monthly price changes, both temporary
and permanent, and differences in the amount of the price changes is the primary source of price
variation that we exploit in the estimation of our demand model.
3.3 The Upstream Distillers
While the distiller market saw several large mergers post 2004, it is relatively unconcentrated
during our sample period. Table III shows that the market leader, Diageo, accounted for 21.60%
of revenues and 24.48% of bottle sales in the sample; more than double the size of its two largest
competitors, at the time: Bacardi and Beam. Meanwhile, 34 smaller firms hold significant market
shares: 59.62% of by revenue and 56.72% of bottle sales.
Table III: The Upstream Market
Share of Spirit Market Top Selling Product
Firm Products By Revenue By Quantity Name Type
Diageo 63 21.60 24.48 Captain Morgan Rum
Bacardi 22 8.92 9.79 Bacardi Light Dry Rum
Beam 32 9.86 9.01 Windsor Canadian Whiskey
Other Firms (34) 195 59.62 56.72 SKYY (Campari) Vodka
Notes: Upstream distillers sorted in descending order according to quantity (bottles) share.
The largest upstream firms – Diageo, Bacardi, and Beam – operate extensive product
portfolios that extend into all spirit types and bottle sizes while 21 of the 34 smaller distillers
operate product portfolios of less than 5 products and 8 are single product firms. There is, however,
substantial heterogeneity in product offerings even among the top three distillers. For example,
Diageo has a relatively balanced portfolio where rums, vodkas, and whiskeys generate 19.6%, 31.8%,
and 24.4% of its total revenue, respectively. In contrast, 70.2% of Bacardi’s revenue comes from
rums compared to just 4.1% for Beam.18
18Bacardi acquired Grey Goose from Sidney Frank in August 2004. Since PLCB requires a five-month advancenotice for any temporary price reduction, we assume that Sidney Frank manages the brand in our estimation andcounterfactuals. Table B.II in Appendix B reports the market shares by spirit type, bottle size, and price range.
– 16 –
While the overall market appears competitive with a Herfindahl-Hirschman Index (HHI)
based on bottle sales of only 930.3, distillers may have more market power within some regions
of the product space than others. For example, the HHI is approximately 3,000 for rums, while
the brandy and gin segments are moderately concentrated with HHIs of approximately 2,000.
The cordial, vodka, and whiskey segments have low concentration measures (all less than 1,400)
suggesting these segments are the most competitive. Horizontal differentiation of products within
a spirit class would provide further market power. An accurate characterization of the response
of distillers to changes in government tax policy therefore requires estimation of rich substitution
patterns underlying demand that motivates the observed extent of differentiation across and within
these different product segments.
3.4 Evidence of Heterogeneity of Preferences for Liquor
To conclude the description of the primary data features, we now document systematic variation
in consumer preferences along different demographic profiles. Throughout the analyses, we rely on
four primary demographic attributes of stores’ market areas: income, educational attainment, and
the prevalence of minority and young consumers. We used categorical data on income by minority
status to fit generalized beta distributions, which allow us to draw random samples of income for
our estimation from market-specific continuous distributions that vary by demographic trait and to
estimate the share of high-income households with incomes above $50,000. We similarly obtained
information on educational attainment by minority status to derive the share of the minority
and white population with at least some college education in each area. Lastly, we employ the
unconditional share of each market’s population between the ages of 21 and 29.
We show differences in preferences by assigning the store markets into quintiles based on
each demographic trait – the share of high-income households, the share of non-white or minority
households, the share of residents with some college education, and the share of residents in their
twenties. Figure 1 compares the purchase patterns of the top and bottom quintiles. Markets
with a greater share of minorities have substantially higher sales of vodka, gin, and brandy but
lower sales of whiskey. In areas where the population has more residents with college experience,
however, not only vodka but also whiskey is more popular, while rum and brandy have lower sales.
In markets with a larger share of high income residents, we observe larger purchases of expensive
spirits indicating that high income consumers are more willing to buy expensive spirits, presumably
because these spirits tend to be of higher quality.19 Finally, as the share of young residents increases,
so do sales of smaller bottles.
In our analysis, we exploit this wide variation in observable preferences across demographic
groups in three ways. First, this preference heterogeneity allows us to capture rich substitution
patterns to best reflect the purchase decisions of consumers, leading to more robust elasticity
19Our Proof66.com indicators confirm that price and quality are positively correlated, particularly for cordials, gins,and whiskeys.
– 17 –
Figure 1: Spirit Consumption and Demographics
12.2
12.2
9.3
16.8
31.7
17.8
5.2
15.24.8
16.4
27.2
31.3
0
10
20
30
40
50
60
70
80
90
100
Ma
rke
t S
ha
re (
%)
High Low
Minority
Brandy Cordials GinRum Vodka Whiskey
(a) Minority and Spirit Type
5.4
12.0
7.7
14.0
36.7
24.2
11.3
14.5
7.9
18.0
26.8
21.3
0
10
20
30
40
50
60
70
80
90
100
Mar
ket S
hare
(%
)
High Low
College
Brandy Cordials GinRum Vodka Whiskey
(b) Level of Education and Spirit Type
46.6
53.4
59.2
40.8
0
10
20
30
40
50
60
70
80
90
100
Ma
rke
t S
ha
re (
%)
High Low
Income
ExpensiveCheap
(c) Income and Price
20.7
51.3
28.0
10.9
48.9
40.2
0
10
20
30
40
50
60
70
80
90
100
Mar
ket S
hare
(%
)
High Low
Young
375 ml 750 ml1.75 ltr
(d) Age and Bottle Size
Notes: We compare markets in the top (“High”) and bottom (“Low”) quintile of each demographic trait. “Minority” is thepercent of the market population who identifies as “non-white.” “‘Education” is defined as the percent of the population withsome college experience. “Income” is the percent of households with income greater than $50,000. “Age” is the percent of thepopulation between 21 and 29 years of age.
estimates both across products and for spirits as a whole. This, in turn, results in more accurate
estimates of upstream firm market power and thus, the distillers’ ability to respond to changes in
the downstream tax rate, η(τ) of the model in Section 2. Second, the large amount of heterogeneity
among products and distillers combined with heterogenous consumer preferences suggests that the
upstream response to changes in tax policy will vary by firm and product leading to heterogenous
effects across consumers. Therefore, a novel feature of our research is to explore how naıve tax
policy, i.e., policy which does not account for the upstream response, yields different impacts across
consumer types. Finally, the wide variation in observed preferences provides us with an opportunity
to explore the characteristics of the Laffer curve, such as location and shape, across consumer
segments. We can then confirm that an inverted U-shaped curve characterizes the relationship
between the tax rate and tax revenue generated by any particular demographic group. We thus
rule out that our aggregate characterization of the Laffer curve is the result of combining the
responses of heterogeneous consumers to price variation induced by a change in tax policy.
– 18 –
4 Empirical Model
In this section we describe a static model of oligopoly price competition with differentiated goods.
We assume that each period upstream spirit manufacturers simultaneously choose wholesale prices
{pw} to maximize profits. The downstream firm, the PLCB , takes these prices as given and gener-
ates the final retail price by applying a 30% markup, a per-unit handling fee that varies by bottle
size, and an 18% liquor tax. Finally, consumers in each market choose the product that maximizes
their utility. We solve the model backwards, first presenting downstream consumer demand and
then progressing to the profit-maximization problem of the upstream spirit manufacturers.
4.1 Downstream Market - A Discrete Choice Model of Demand for Spirits
In modeling demand for spirits as a function of product characteristics and prices, we follow the
large literature on discrete-choice demand system estimation using aggregate market share data
(cf. Berry (1994), Berry, Levinsohn and Pakes (1995) (BLP), and Nevo (2001)). This facilitates
the estimation of robust own and cross-price elasticities for a large set of products while accounting
for systematic differences in consumer preferences across demographics.
In pricing period t, consumer i in market l obtains the indirect utility from consuming a
bottle of spirit j ∈ Jlt given by
uijlt = xjβ∗i + α∗i p
rjt + [ht q3t]γ + ξjlt + εijlt ,
where i = 1, . . . ,Mlt; j = 1, . . . , Jlt; l = 1, . . . , L; t = 1, . . . , T .(17)
The n× 1 vector of observed product characteristics xj is identical in all markets l where product
j is available and fixed over time, though the availability of different spirits may change over
time due to product introductions/removals or store closings/openings. We also include a holiday
dummy variable ht that indicates whether period t coincides with the end-of-year holiday season
from Thanksgiving to the New Year and a summer dummy variable q3t for the July, August, and
September periods. We denote the retail price of product j at time t by prjt where, in accordance
with the PLCB ’s pricing mandate, the retail price does not vary across markets l within period t.
We further allow utility to vary across products, markets, and time via the time and location-specific
product valuations ξjlt, which are common knowledge to consumers, upstream firms, and the PLCB
but unobserved by the econometrician.
We characterize consumer i in market l by a d-vector of observed demographic attributes
including education, race, youth, and income, that we denote by Dil. To allow for individual hetero-
geneity in purchase behavior, we model the distribution of consumer preferences over characteristics
and prices as multivariate normal with a mean νil that shifts with these consumer attributes,(α∗iβ∗i
)=
(α
β
)+ ΠDil + Σνil , νil ∼ N(0, In+1) , (18)
– 19 –
where Π is a (n + 1) × d matrix of coefficients that measures the effect of observable individual
attributes on the consumer valuation of spirit characteristics, while Σ measures the covariance in
unobserved preferences across characteristics. We restrict Σjk = 0 ∀k 6= j, and estimate only the
variance in unobserved preferences for characteristics. Introducing unobserved preferences for a
given characteristic j allows higher cross-price elasticities among products with similar characteris-
tics, e.g., flavored or imported, thereby relaxing the restrictive substitution patterns generated by
the Independence of Irrelevant Alternatives (IIA) property of the multinomial logit model. Simi-
larly, matrix Π captures the contribution of demographic and product characteristic interactions
that allows cross-price elasticities to vary differentially in markets with observed differences in
demographics. For instance, we expect expensive vodkas to have higher cross-price elasticities in
markets with a large fraction of high-income consumers.
Next, we follow Grigolon and Verboven (2014) in modeling the unobserved individual pref-
erences and assume that they are correlated across spirits of the same type, resulting in the random
coefficient nested logit model or RCNL. The term εijlt follows the distributional assumptions of
the nested logit model, thereby increasing the valuations of products within the same group (nest),
here given by spirit type. There are g = 0, 1, ..., G distinct groups to whom we assign each product;
we define group zero to be the outside good. We can therefore write the idiosyncratic valuation by
consumer i for product j in market l and period t as
εijlt = ζigt + (1− ρ)εijlt , (19)
where ρ ∈ [0, 1] and we assume that the distribution of ε is i.i.d. multivariate type I extreme value
and the distribution of ζigt is such that εijlt is also distributed extreme value. We define groups
according to spirit type (brandy, cordials, gin, rum, vodka, and whiskey), and call ρ the “nesting
parameter” as its value modulates the importance of spirit type in explaining consumer purchases.
As ρ goes to one, consumers view products within each spirit type as perfect substitutes while ρ
converging to zero reduces within-type correlation to zero. Plugging (19) into (17) yields
uijlt = xjβ∗i + α∗i p
rjt + [ht q3t]γ + ξjlt +
G∑g=1
1(j ∈ g)ζigt + (1− ρ)εijlt , (20)
where 1(j ∈ g) is a group indicator variable equal to one when product j belongs to spirit type
g. Together, equations (18) and (20) encompass several demand specifications allowing for a wide
arrange of substitution patterns. When Σ = 0 and ρ > 0 the model collapses to the nested logit.
Alternatively, when ρ = 0 but Σ > 0 the model collapses to the random coefficients model of BLP .
When both Σ = 0 and ρ = 0 the model returns the simple multinomial logit choice probabilities.
We assume that during a particular time period, each consumer selects either one bottle of
the Jlt spirits available in her market l or opts to purchase the outside option denoted by j = 0. We
– 20 –
define the potential market, Mlt, as all off-premise purchases, i.e., those purchases not consumed
in a restaurant or bar, of alcoholic beverages, including spirits, beer, and wine.20
The annual potential market for location l then is the number of drinking-age residents
scaled by per-capita off-premise consumption, which we calculate as follows. According to Haugh-
wout, Lavallee and Castle (2015) the average drinking-age Pennsylvanian consumed 124.2, 120.5,
and 121.0 liters of alcoholic beverages in 2002, 2003, and 2004, respectively. Of this consumption,
79.8% on average was purchased off-premise, resulting in per-capita off-premise consumption of
132.1, 128.3, and 128.7 bottle-equivalents of 750 ml, respectively.21 To put these figures in
perspective, beer accounts for approximately 90% of total consumption by volume so the average
drinking-age Pennsylvanian consumes the equivalent of nearly five 375 ml bottles of beer per week
vs. approximately four 750 ml bottles of both wine and liquor during the year.
The potential market Mlt for location l in period t is simply the prorated potential con-
sumption according to the number of days included in pricing period t. A consumer opting for
the outside option then consumes a 750 ml “bottle” of beer (i.e., two 375 ml bottles) or a 750
ml bottle of wine. Note that this definition of the potential market accounts for the total volume
of alcoholic beverages but not for the different ethanol contents of beer (4.5% on average), wine
(12.9% on average), and spirits (37.9% on average in our sample). Thus, policy can reduce total
ethanol consumption by increasing retail prices of spirits leading consumers to substitute towards
beer and wine.
Next, we address consumers’ choice decisions. The set of individual-specific characteristics
leading to the optimal choice of spirit j is given by
Ajt (pr·t, x·, ξ·t; θ) = {(Dil, νil, ε·lt) |uijlt ≥ uiklt ∀k = 0, 1, . . . , Jlt} , (21)
where we summarize all model parameters by θ. We follow the literature in decomposing the
deterministic portion of the consumer’s indirect utility into a common part shared across consumers,
δjlt, and an idiosyncratic component, µijlt. These mean utilities of choosing product j and the
idiosyncratic deviations around them are written as follows:
δjlt = xjβ + αprjt + [ht q3t]γ + ξjlt , (22a)
µijlt =(xj prjt
)(ΠDil + Σνil) . (22b)
In estimating the model, we take advantage of the additive specification of normally-
distributed deviations from mean utility and extreme-value random shocks to integrate over the
20The present static discrete choice approach has limitations when instead, individuals purchase several productsor multiple bottles of the same product at the same time. See Nevo (2000, p.401) and Hendel (1999). Hendeland Nevo (2006a) further show that static demand estimates overestimate own-price elasticities and underestimatecross-price elasticities when consumers make dynamic purchase decisions. We discuss potential issues and biasesassociated with stockpiling in Appendix C.4 as well as provide evidence that stockpiling is not an issue in our data.
21Authors’ calculations based on data from the National Alcohol Beverage Control Association.
– 21 –
distribution of εit giving rise to Ajt analytically. The probability that consumer i purchases product
j in market l in period t is then
sijlt =
exp
(δjlt + µijlt
1− ρ
)exp
(Iiglt
1− ρ
) ×exp(Iiglt)
exp(Iilt), (23)
where
Iiglt = (1− ρ) ln
Jg∑m=1
exp
(δmlt + µimlt
1− ρ
), (24a)
Iilt = ln
1 +G∑g=1
exp(Iiglt)
. (24b)
Deriving product j’s aggregate market share in each location requires integrating over the
distributions of observable and unobservable consumer attributes Dil and νil, which we denote by
PD(Di) and Pν(νi), respectively. Thus, the model predicts a market share for product j in market
l at time t of
sjlt =
∫νl
∫Dl
sijltdPD(Di)dPν(νi) , (25)
which we evaluate by Monte Carlo simulation. For each market l we simulate the consumption
choices of 200 randomly drawn heterogeneous consumers who vary in their demographics and
income. We construct the sample for each market using the previously discussed census data
on race, age, educational attainment, and income. We simulate whether each randomly drawn
consumer is a minority or in their twenties based on the prevalence of these demographic groups
in each market. Conditional on the consumer’s realized minority status, we then take a random
draw from the corresponding estimated continuous distribution of income and discrete distribution
of educational attainment. See Appendix A for further details. Since the ambient population
of stores changes with store openings and closings over the course of the sample, we allow the
simulated set of agents to also change. Lastly, we account for the unobserved preferences (ν) via
Halton draws in order to reduce simulation bias as recommended by Judd and Skrainka (2011).
4.2 An Oligopoly Model for Upstream Distillers
Wholesale prices pw are the outcome of an upstream market equilibrium given the PLCB ’s pricing
rule. We now present a flexible model of upstream behavior that places few restrictions on firm
conduct while allowing for robust estimates of upstream market power. Each firm f ∈ F produces
a subset Jft of the j = 1, . . . , Jt products and faces several competitors from the set F of upstream
distillers. In each period t the upstream firms simultaneously choose the vector of wholesale prices
{pwjt}j∈Jft to maximize period t profit
– 22 –
max{pwjt}
∑j∈Jft
(pwjt − cjt)×L∑l=1
Mltsjlt(pr(pw), x, ξ; θ
)︸ ︷︷ ︸
statewide demand forproduct j in period t
, (26)
where Mlt is the size of market l and cjt denotes the marginal cost of producing spirit j in period t.
Given the static nature of the firms’ pricing decisions, we omit the period t subscripts for the sake
of clarity going forward.22 Define as sj(pr, x, ξ; θ) =
∑Ll=1Mlsjl(p
r, x, ξ; θ) the state-wide demand
for product j. Assuming a pure strategy Bertrand-Nash equilibrium in wholesale prices, profit
maximization in the upstream market implies that upstream firm f chooses prices pwj ∀j ∈ Jf to
solve the set of first-order conditions
sj(pr(pw), x, ξ; θ
)+∑m∈Jf
(pwm − cm)sm(pr(pw), x, ξ; θ
)× ∂sm∂pwj
= 0 . (27)
The term ∂sm∂pwj
is the change in quantity sold for product m in response to a change in the wholesale
price and, through the pricing rule, the retail price of product j.23 Converting (27) into vector
notation yields
pw = c+ [Ow ∗∆w]−1 × s(pr(pw), x, ξ; θ)︸ ︷︷ ︸vector of wholesale markups
, (28)
where Owt denotes the ownership matrix for the upstream firms with element (j,m) equal to one
if goods j and m are in Jf . We define ∆w as a matrix that captures changes in demand due to
changes in wholesale price as follows
∆w=∆d∆p′=
∂s1∂pr1
. . . ∂s1∂prJ
.... . .
...∂sJ∂pr1
. . . ∂sJ∂prJ
dpr1dpw1
. . .dpr1dpwJ
.... . .
...dprJdpw1
. . .dprJdpwJ
′
=
∂s1∂pr1
. . . ∂s1∂prJ
.... . .
...∂sJ∂pr1
. . . ∂sJ∂prJ
1.534 . . . 0...
. . ....
0 . . . 1.534
, (29)
where ∆d is the matrix of changes in quantity sold in period t due to changes in retail price with
element (r,m) equal to ∂sr∂prm
and ∆p is the matrix of changes in retail price due to changes in
wholesale price with element (m, j) equal to dprmdpwj
.
22Table II documents that the PLCB limits the number of times distillers can temporarily reduce a product’s price.In the data, the average product goes on sale only 2.3 times per year and 76.6% of products go on sale three timesor less in a year, indicating that this regulation does not constrain upstream pricing for the majority of products.We thus do not address any dynamic considerations to the timing of pricing decisions over the course of the year,but employ a simpler and more tractable static pricing model instead.
23For simplicity, we assume that firms observe the distribution of consumer preferences. We thus abstract fromsecond-degree price discrimination across bottle sizes as in in McManus (2007) and instead focus on horizontaldifferentiation between products.
– 23 –
Villas-Boas (2007) shows that in vertical retail pricing markets, ∆p can be a complicated
object. In our context, however, the state’s regulation of alcohol sales simplifies this matrix
significantly by committing downstream stores to a uniform pricing policy and by eliminating
off-diagonal terms. For example, under the current pricing rule,dprjdpwj
is simply 1.30×1.18, reflecting
the 30% uniform tax and the 18% liquor tax that translate a change in the wholesale price for
product j to a change in the product’s retail price. Further, the retail price for product m does
not respond to a change in the wholesale price for product j: dprmdpwj
= 0 ∀m 6= j. The uniform tax
rule from equation (16) thus limits the PLCB ’s ability to respond to changes in wholesale prices
chosen by the upstream firms, resulting in a diagonal price response matrix ∆p.
We rely on this model of firm behavior in the following ways. First, we use the firms’
first-order necessary conditions for profit-maximization in equation (28) to back out product-level
marginal costs given demand estimates and observed wholesale and retail prices. This enables us to
measure wholesale markups and thus the degree of market power in the upstream market. Second,
we use equation (28) to evaluate the optimal distiller response to changes in PLCB tax policy,
which we denote as η above. Third, the upstream model allows us to consider alternative forms of
upstream conduct, by varying the definition of the ownership matrix Ow. We exploit this flexibility
to explore how different conduct assumptions impact upstream market power, our estimates of the
upstream response to taxes η, and ultimately the shape and location of the Laffer curve.
5 Identification, Estimation, and Demand Model Results
In this section we outline an estimation approach similar to Nevo (2000) but adapted to the
institutional features surrounding the price regulation of spirits in Pennsylvania. We present a
three-step estimation procedure that takes advantage of the fact that distillers set a single wholesale
price that the PLCB translates into a single retail price across all local markets. This allows
us to identify the contribution to demand of unobserved Σ and observed Π demographic taste
heterogeneity across the state at a point-in-time and the nesting parameter ρ defined over spirit
type separately from the contribution of common, but time varying, shifters of each product’s mean
utility (α, β). In identifying the price coefficient α we discuss potential sources of price endogeneity,
which in our case stem from the response of distillers to downstream consumer demand shocks
rather than from the PLCB ’s pricing behavior. We then present the model estimates and discuss
the implied demand elasticities ε(pr) and upstream response elasticities η(τ).
5.1 Estimating the Random Coefficients and Demographic Interactions
We begin with a description of the first of the three stages of our estimation procedure where
we estimate the contributions of product characteristics Σ and demographic interactions Π to the
deviations from mean utility, µijlt, controlling for location and product by time fixed effects and
the spirit type via ρ. We follow the earlier literature in using a generalized method of moments
– 24 –
estimator, GMM , that interacts a structural demand side error ω(Σ,Π, ρ) with instruments Z. To
define ω, we decompose the unobserved product valuations, ξjlt, as follows:
ξjlt = ζ1l + ξjt + ∆ξjlt . (30)
In equation (30), ζ1l is a location fixed effect that captures systematic variation across
markets in the preference for spirits consumption relative to beer and wine. This also accounts for
the fact that while per-capita consumption of alcoholic beverages likely varies across Pennsylvania,
such disaggregated data is not available and we define the potential market to be the average
Pennsylvanian’s consumption of off-premise alcoholic beverages. We control for systematic variation
in preferences for a given product over time via ξjt, to reflect the fact that across the state, a
product’s mean demand varies over the course of the year. With this specification, the mean utility
of product j, δjlt in equation (22a), simplifies to
δjlt = ζ1l + ζ2
jt + ∆ξjlt , (31)
where the product and time specific fixed effect ζ2jt subsumes the effect of product characteristics,
seasonal buying, and price on a product’s mean utility.
Equation (31) highlights an advantage to our setting: since price does not vary across
locations l, we are able to control for its mean contribution to utility via product by time fixed
effects, which we then use in a second stage estimation to isolate α. The remaining structural error
ω therefore represents deviations in unobserved product valuations within a store, ∆ξjlt, from these
mean product-time valuations after controlling for the average taste for spirits in market l.
We define our parameters of interest in this estimation stage as θA = {Σ,Π, ρ}, and we solve
for the structural error ω(θA) = ∆ξjlt using the following algorithm. For a given guess at θA, we
find the mean-utility levels δjlt(ζ1l , ζ
2jt, Sjlt; θA) that set the predicted market share of each product,
sjlt in equation (25), equal to the market share observed in the data, Sjlt.24 We follow Somaini
and Wolak (2015) and use a within transformation of δ to remove the store and product-period
fixed effects ζ1l and ζ2
jt, leaving only ω. Define Z+ as the within transformation of the instruments
matrix Z; e.g., for instrument k, Z+,kjlt = Zkjlt − Zkjt − Zkl . The GMM estimator exploits the fact
that at the true value of the parameters (Σ?,Π?, ρ?), the instruments Z+ are orthogonal to the
structural errors ω(Σ?,Π?, ρ?), i.e., E[Z+′ω(θ?)
]= 0, so that the GMM estimates solve
θA = argminθA
{ω(θA)′Z+W+Z+′ω(θA)
}, (32)
where W+ is the weighting matrix, representing a consistent estimate of E[Z+′ωω′Z+]. Finding
a global solution to a highly nonlinear problem such as this is difficult and any line, gradient, or
24We rely on the contraction mapping outlined in Appendix I of BLP . In order to ensure convergence to consistentstable estimates we follow the advice of Dube, Fox and Su (2012, §4.2) and set the norm for the mean valuecontraction equal to 1e-14.
– 25 –
simplex search would likely only result in a local solution. To increase the likelihood of achieving a
global minimum, we employ the Knitro Interior/ Direct algorithm suggested by Dube et al. (2012)
starting from several different initial conditions to ensure robustness of our results.25
5.1.1 Identification of Random Coefficients and Demographic Interactions
Identification of Σ and ρ comes from correlation between a product’s market share and its character-
istics relative to other more or less similar products – see Berry and Haile (2014). We construct two
instruments similar to those used in Bresnahan, Stern and Trajtenberg (1997). First, we employ the
number of products in the market that share product j’s characteristic. For example, to identify a
random coefficient for imported varieties, we use the total number of competing imported products
of the same bottle size in market l as the instrument for a given imported product. To identify the
nesting parameter, ρ, we use the total number of competing products of the same spirit type in
market l, separately for each spirit type. Second, we use spirit product scores from Proof66.com as
a measure of product quality and compute the average distance, measured in squared deviations,
of product j to other products that share its characteristic. Thus, for the above imported product,
this would be the average distance in product score space from other imported products in location
l. This instrument provides additional identifying power since it allows for differential effects
of introducing a high-quality imported product into a market with other high-quality imported
products versus into a market populated by largely low-quality imported products.26
We base identification of Π on correlation between a product’s market share in a given store
market and the demographics of the population served by each store. We thus interact the above
instruments with the prevalence of a given demographic attribute in each market. For example, we
identify the differential taste of young households for vodkas by interacting our earlier instruments
for vodka with the share of young consumers in each market. In the case of the interaction of
income with price, we construct the first instruments based on the product’s price category (cheap
vs. expensive) and interact them with the share of households in the market with income about
$50,000. Berry and Haile (2010) point out that these instruments proposed by Waldfogel (2003)
are valid provided there exist no demand spillovers from consumers in other similar markets.
5.2 Estimating Mean Utility Coefficients
In the second and third stages of estimation, we estimate mean utility coefficients given the
estimated first-stage coefficients θA and the resulting product-by-time fixed effects ζ2jt(θA). We
project ζ2jt onto price and the seasonal indicators, controlling for product fixed effects ζj ,
25 In constructing our optimal weighting matrix, we first assume homoscedastic errors and use W+ = [Z+′Z+]−1
to derive initial parameter estimates. Given these estimates, we solve for the structural error ω and constructE[Z+′
ωω′Z+]−1 as a consistent estimate for W+.26For example, the introduction of a high-quality Scotch whiskey into a location can therefore have differential effects
on the market shares of other Scotch whiskeys and the market shares of lower-quality Canadian whiskeys.
– 26 –
ζ2jt = [ht q3t]γ + αpjt + ζj + ξjt . (33)
Equation (33) highlights the potential for price endogeneity, to the extent that price re-
sponds to time-varying preference variation for a given product that is common across locations,
in the form of, for example, seasonal variation in consumption. Since the PLCB ’s pricing rule
applies a fixed markup to wholesale price irrespective of local or seasonal demand responses, its
pricing cannot respond to such unobserved demand shocks. But the predictable link between
wholesale and retail prices opens the possibility to spirit prices being endogenous not because of
the pricing practices of the PLCB , but because of the pricing behavior of upstream distillers whose
chosen wholesale prices reflect, through market shares, the unobserved common tastes for product
characteristics of spirits, ξjt. Recall the pricing optimality conditions in equation (28).
In principle, the fact that distillers need to request both temporary and permanent changes
to their wholesale price a number of months before the new price takes effect mitigates such
endogeneity concerns. Prices thus only respond to predictable variation in a product’s demand
over time. At the same time, none of our product characteristics vary across time, limiting our
ability to flexibly represent such time varying preference heterogeneity at the level of the product.
We therefore use instrumental variables techniques to estimate the parameters in equation (33)
using two sets of instruments for price.
First, we rely on the contemporaneous average price of a given product from liquor control
states outside of the Northeast and Mid-Atlantic regions.27 Our identifying assumption is that
cost shocks are national, since products are often produced in a single facility, but demand shocks
are largely regional, linked to differences in climate and demographics, which correlate with con-
sumption as we establish in Section 3.4. We thus focus on product prices in control states that
are distant from Pennsylvania and have sufficiently different demographic profiles and climates
to support the assumption that their demand shocks are uncorrelated with Pennsylvania’s. For
example, states such as Idaho, North Carolina, Oregon, and Wyoming have at least a 50% higher
share of Hispanics than Pennsylvania’s low six percent, while only North Carolina has a significant
prevalence of African Americans (at 22% double Pennsylvania’s 11% share), but also a very different
climate. The latter is helpful since, e.g. whiskey consumption peaks during colder months and the
appeal of whiskey thus varies significantly between Pennsylvania and the states used to construct
the instrument. Given that most price changes in the data are temporary, rather than permanent,
a concern with this instrument would be possible coordination of sales across the control states.
We find little evidence of such coordination, however.28
27An “alcohol control state” is a state that has monopoly over the wholesale or retail sales of some or all categoriesof alcoholic beverages. As of 2016, this list includes: Alabama, Idaho, Iowa, Maine, Maryland (Montgomery,Somerset, and Wicomico counties), Michigan, Mississippi, Montana, New Hampshire, North Carolina, Ohio,Oregon, Pennsylvania, Utah, Vermont, Virginia, West Virginia, and Wyoming. Washington state privatized itsalcohol retail distribution in 2012.
28We define a price reduction in our price instruments as “temporary” when price falls for one month. We then testwhether these indicators are correlated with temporary price reductions in Pennsylvania using Kendall’s τ , which
– 27 –
Figure 2: Changes in 2003 Retail Price ($)
10
12
14
16
18
20
22
24
26
28
Mar May Aug Sep Dec
Bacardi Limon - 750 ml ($12.79)
Bacardi Limon - 1.75 ltr ($25.70)
Beefeater - 750 ml($18.03)
Jameson Irish Whiskey - 750 ml($22.67)
Shelf Price Across Time(Select Products)
We add to this instrument changes in input prices, sugar and corn, interacted with spirit type
indicators to account for exogenous cost shifts across spirit types, e.g., a major input for cordials
and rums is sugar, while corn is an input to gins, vodkas, and whiskeys. Including input price
interactions for barley, glass, oats, rice, rye, sorghum, and wheat did not improve the estimates; we
therefore do not use them in our primary specification.
Next we collapse the second stage parameters into vector θB as follows
θB = (XB′XB)−1XB
′ζ2 (34)
where XB = ZB(Z ′BZB)−1Z ′BXB, XB = [ht q3t pjt ζj ], and ZB is the matrix of price instru-
ments. In the third and final estimation step, we recover product fixed effects ζj from equation (34)
and project the vector ζ onto the matrix of observable product characteristics x, resulting in:
θC = (x′x)−1x′ζ . (35)
Variation in prices over time identifies the price coefficient, exploiting the fact that distillers
do not change the wholesale prices pw for all products at the same time. This introduces variation in
relative prices depicted in Figure 2. We identify seasonality and mean preferences for time-invariant
product characteristics such as proof and spirit type from systematic variation in market shares of
spirits by time period or characteristic.
we find to be low (on average 0.03 across state-pairs). This indicates that these temporary price changes do notappear to be correlated.
– 28 –
5.3 Estimation Results
Table IV presents the demand estimates of our preferred specification of the RCNL model using the
three-step procedure outlined above. Parameters are very precisely estimated. Estimated demand
for spirits increases during the summer and the holiday season. On average, consumer valuations
of brandy, cordials, and whiskey exceed gin (our reference category), while rums and vodkas are,
on average, less valued. Consumers prefer 1.75 L to smaller bottles driven by the fact that when a
Table IV: RCNL Demand Estimates
Mean Utility Random Coeff. Demographic Interactions (Π)
(β) (Σ) Income Young Minority College
price -0.3062 0.1151(0.0036) (0.0036)
holiday 0.3153(0.0057)
summer 0.0557(0.0049)
375 ml -2.9554(0.5608)
750 ml -7.5816 0.5939 22.7684 0.4025 4.9886(0.4037) (0.3061) (3.2953) (0.0844) (0.2976)
brandy 0.3882 0.8616 1.3978 -0.8738(0.6902) (0.2288) (0.0231) (0.0518)
cordials 0.2977(0.7163)
rum -4.7646 11.5406 -0.1628 0.6795(0.8355) (2.9485) (0.0146) (0.0426)
vodka -1.9611 4.9747 -0.3713 4.2314(0.4835) (0.6656) (0.0233) (0.2701)
whiskey 0.3875 1.2203 -0.9270 0.9549(0.5123) (0.2059) (0.0231) (0.0554)
flavored 3.7007 -4.9731 -0.5111 -3.2395(0.4848) (0.7219) (0.0374) (0.1943)
imported 1.3598 0.1912(0.3519) (0.5134)
proof 15.1897 1.2575 -26.0064 1.6695 -5.5765(1.6844) (0.2505) (4.2377) (0.0913) (0.4402)
quality 3.9347(2.1101)
constant -15.3884(1.8244)
Nest (ρ) 0.1225(0.0139)
Notes: Robust standard errors are reported in parentheses. Estimates for random coefficients Σ,demographic interactions Π, and nesting parameter ρ based on GMM estimation using 3,377,659observations in 12,957 markets given by store-period pairs and 200 simulated agents in each market.Mean utility estimates for price, holiday, and summer are based on the projection of estimated product-period fixed from the GMM estimation onto corresponding characteristics plus product fixed effectsafter controlling for price endogeneity. Remaining mean utility estimates based on the projection ofestimated product fixed effects onto the remaining observable product characteristics.
– 29 –
brand is available in several bottle sizes, the 1.75 L is more popular, all else equal. Consumers also
prefer imported, flavored, and high proof products.
These are only average valuations. We also allow for rich variation across demographics
by interacting the young, minority, and college-educated indicators with spirit type, bottle size,
and proof. The estimates of Π reveal significant differences in tastes for spirits across demographic
groups. We find that demand becomes steeper as consumers become wealthier, consistent with
the increased consumption of expensive spirits by “high income” consumers presented in Figure 1.
Consumers of different demographic groups often do not favor the same spirits: Although the
average consumer values vodkas less than gins, individuals with some college education strongly
favor them. These consumers also dislike brandy but favor whiskeys, while minorities rank brandy
over gin and then whiskey. Young consumers have a marked preference for rum and 750 ml bottles.
Despite the large number of demographic interactions included in Π, we still find statistically
significant values for the random coefficients (Σ) for proof and 750 ml bottles. We also obtain a
significant estimate of the spirit type nesting parameter ρ, indicating that although products within
a spirit type are far from being perfect substitutes to each other, they are better substitutes than
those of a different spirit category. Figure 3 corroborates this point. In the figure we present the
ratio of the average cross-price elasticity between each product and products of its own spirit type
(e.g., rums) to that between the product and all other products (brandies, cordials, gins, vodkas,
and whiskeys). The results indicate the demand estimates generate sensible cross-price elasticities
where the best substitute for a Captain Morgan is another rum, say a Bacardi.29
Figure 3: Cross-Price Elasticities by Type
17.1
6.5
18.1
9.8
7.4
5.8
0
2
4
6
8
10
12
14
16
18
20
Avg
. Cro
ss-P
rice
Ela
stic
ity (
In)
/ Avg
. Cro
ss-P
rice
Ela
stic
ity (
Out
)
BRANDY CORDIALS GIN RUM VODKA WHISKEY
29 In Table D.I in Appendix D we document the best estimated substitutes for a variety of popular products.
– 30 –
Table V: Price Endogeneity
OLS IV1 IV2 IV3 IV4
price -0.2673 -0.3062 -0.3073 -0.3114 -0.3128(0.0027) (0.0036) (0.0036) (0.0037) (0.0037)
First-Stage F-Stat.: — 1,333.19 1,297.06 1,217.18 1,196.74
Instruments:- Input Prices X X X X- Alabama X- Iowa X X- Idaho X X X X- Michigan X- Mississippi X- Montana X X X- North Carolina X X- Oregon X X X X- Utah X- Wyoming X X X X
Notes: All estimates based on 10, 532 observations. Specifications include the same covariates asin Table IV. Price instruments based on the average contemporaneous price among alternative setsof control states outside the Northeast and Mid-Atlantic regions. “Input Prices” corresponds tocontemporaneous commodity prices for inputs (corn, sugar) interacted with spirit type to furtherseparate cost and demand shocks.
This comparison relies in part on our estimated price coefficient. As discussed above, we
use the contemporaneous average price in distant control states and commodity prices for corn and
sugar interacted with spirit type dummies as price instruments. In Table V, we document that our
estimate of the price coefficient is both sensible and robust. In particular, we compare the estimated
price coefficient using alternative two-stage least squares results of the estimated first stage product-
period fixed effects projected onto price, seasonal dummies, and product fixed effects. Relative
to IV1, our preferred specification, the estimated price coefficients are stable across alternative
instruments, and, as expected, entail larger price responses than a simple OLS specification. Each
estimated price coefficient is significant at the 95% level, each IV price coefficient is significantly
different than the OLS specification, and the set of IVs generates significant F-statistics for all
specifications.
Table VI presents descriptive statistics for product elasticities using the IV1 price coefficient.
Overall, our product elasticities are sensible and similar to Conlon and Rao (2015) and Aguirre-
gabiria et al. (2016) who estimate alcohol demand using disaggregate data. At the product-level,
we estimate an average own-price elasticity of −3.86 although there is substantial heterogeneity
in elasticities that correlates with spirit types and bottle sizes. Rums, brandies, and cordials tend
to be less elastic compared to vodka and whiskey products, though the empirical distribution of
estimated price elasticities is most spread for whiskeys and gin and most concentrated for rums.
The bottom of Table VI shows that the demand for 375 ml bottles is more inelastic than for the 1.75
L bottles, with the medium-sized 750 ml bottles in-between. We also find that expensive products
have more elastic demands than cheap spirits.
– 31 –
Table VI: Estimated Product Elasticities, Upstream Marginal Costs, and UpstreamMarket Power
ε(pr) c Lerner
Price Avg SD Avg SD Avg SD
By Spirit Type:
brandy 15.41 -3.65 1.49 5.92 4.49 37.56 17.00cordials 14.57 -3.64 1.22 5.78 3.74 35.26 12.23gin 15.15 -3.86 1.54 6.69 5.10 34.86 13.78rum 13.15 -3.57 1.08 5.36 2.97 36.66 12.86vodka 16.66 -4.05 1.47 7.11 4.77 34.67 18.73whiskey 16.65 -4.07 1.50 7.29 4.95 32.51 12.90
By Price and Size:
expensive 20.37 -4.73 1.37 9.43 4.62 25.94 8.15cheap 11.04 -3.04 0.84 3.79 1.98 42.92 14.75375 ml 9.16 -2.54 0.83 2.71 2.07 53.54 20.32750 ml 14.43 -3.76 1.23 5.99 3.57 34.35 11.281.75 L 21.16 -4.68 1.39 9.34 5.13 26.30 6.80
all products 15.63 -3.86 1.41 6.53 4.51 34.66 14.70
Notes: “Price” is measured in dollars; “Average” refers to the simple average of the corresponding category while “SD” is thestandard deviation. Appendix D presents the full elasticity distributions by spirit type and bottle size. Estimated marginalcosts (c) based on product-level marginal costs for each pricing period using the firm first-order conditions in equation (28)under the assumption that firms set prices for products in their observed product portfolios. “Lerner” is the average Lerner
index defined as 100× pw−cpw
.
In Table VII we demonstrate that our demand estimates translate into variation in the
estimated elasticities by consumer demographics. For each market we calculate average elasticities
across simulated consumers, and, as in Section 3.4, we compare markets in the top and bottom 20%
for each demographic trait. Markets with high concentrations of wealthy and educated consumers
exhibit product demands that are relatively less elastic, while markets with concentrations of young
people tend to have more elastic demands for spirits. Demand for spirits as a category is less elastic
in markets with large minority populations and markets with greater levels of income and education.
The model estimates imply an average price elasticity of off-premise spirit demand of −2.8.
That is, a one percent increase in the retail price of all spirits leads to a 2.8% decrease in the
aggregate quantity of off-premise spirits demanded. Earlier literature, however, documents less
elastic demand estimates for alcoholic beverages in general, and spirits in particular. Based on
a review of the literature, Leung and Phelps (1993) conclude that the price elasticity of demand
for distilled spirits is −1.5. Two effects likely drive the discrepancy between our results and this
work. First, rather than estimating the elasticity of total alcohol consumption, we exclude the
presumably less price sensitive consumption in bars and restaurants. Second, the earlier studies
use state or national consumption data whereas we have detailed local data on consumption choices.
In Appendix C.1 we show that aggregation in our data drives the price coefficient and consequently
the estimated elasticity for spirits towards zero. We also show in Table C.III that values of the
price coefficient that generate elasticities consistent with Leung and Phelps (1993) imply demand
curves which are inconsistent with upstream profit-maximization.
– 32 –
Table VII: Estimated Product Elasticities Across Demographics
Income Young Minority College
Low High Low High Low High Low High
Outside Good -2.98 -2.64 -2.74 -2.83 -3.06 -2.78 -3.07 -2.61
By Spirit Type:
brandy -4.01 -3.24 -3.40 -3.86 -3.61 -3.94 -3.87 -3.33cordials -4.06 -3.18 -3.43 -3.79 -3.80 -3.85 -4.00 -3.24gin -4.19 -3.48 -3.70 -3.94 -4.11 -3.93 -4.18 -3.50rum -3.96 -3.12 -3.36 -3.71 -3.72 -3.76 -3.91 -3.18vodka -4.42 -3.60 -3.84 -4.18 -4.18 -4.24 -4.38 -3.62whiskey -4.43 -3.64 -3.87 -4.21 -4.24 -4.26 -4.42 -3.68
By Price and Size:
expensive -5.17 -4.21 -2.85 -3.18 -4.94 -4.93 -5.15 -4.23cheap -3.39 -2.64 -4.49 -4.86 -3.18 -3.21 -3.34 -2.70375 ml -2.80 -2.22 -2.37 -2.68 -2.58 -2.70 -2.73 -2.29750 ml -4.18 -3.29 -3.53 -3.93 -3.89 -4.00 -4.12 -3.351.75 L -5.08 -4.21 -4.44 -4.83 -4.84 -4.90 -5.05 -4.25
all products -4.24 -3.43 -3.66 -4.00 -4.01 -4.05 -4.19 -3.47
Notes: Statistics are the simple average product elasticity in the relevant category-demographic pair. Demographic categoriesare defined in Section 3.4. “High” refers to markets in the top 20% while “Low” refers to markets in the bottom 20% for thecorresponding demographic trait.
5.4 The Upstream Marketplace
Of central interest for characterizing the Laffer curve in this industry are estimates of upstream
market power and therefore an estimate of the upstream response elasticities η. To be able to
simulate an upstream response to changes in the downstream tax rate, we require estimates of
distiller marginal cost. Using our demand estimates and the data on price and quantity sold
alongside the above model of distiller conduct of Section 4.2, we back out product-level marginal
costs for each pricing period using the firm first-order conditions in equation (28).30 In the absence
of allegations of collusion among distillers during the sample period, we assume that they compete in
setting wholesale prices by internalizing the effect of a change on a product’s price on the remaining
products in their portfolio. Thus, as in Section 4.2, the ownership matrix Ow simply reflects the
firms’ portfolios during the sample period.31
The cost estimates c that result from firm optimization under the observed wholesale prices
and estimated demand are reasonable (see middle columns of Table VI). The marginal cost of
expensive products is on average 2.5 times that of inexpensive products; for a subset of brandies
and whiskeys with detailed product information, we find that those products that are aged for five
or more years have marginal costs of 1.3 for brandies and 1.4 times for whiskeys that of non-aged
products. Lastly, imported products are 1.8 times more costly than non-imported products on
average.
30The fact we observe both wholesale and retail price data allows us not to impose any supply-side restrictions onprices during estimation which alleviates the identification concerns of Villas-Boas and Hellerstein (2006).
31A comparison of marginal cost estimates across a variety of conduct assumptions did not provide any clear evidencein favor a non-competitive equilibrium.
– 33 –
We use these cost estimates to assess market power in the upstream distillery market,
which we summarize in the last columns of Table VI. We find that upstream firms do indeed
have significant market power, enjoying an average Lerner index of 34.66%: For every one dollar
of product sold to the PLCB distillers take home 35 cents in profits. Diageo, Bacardi, and
Beam products generate average margins of 32.5%, 32.2%, and 38.1%, respectively.32 Small bottle
products have higher margins (54% on average) than large bottles (26% on average) due to their
substantially less elastic demand (third column of Table VI). There is less heterogeneity across
spirit types as the average whiskey generates a margin of 32.5% compared to 37.6% and 36.7% for
the average brandy and rum, respectively.
Table VIII: The Upstream Firm Response toChanges in Tax Policy
Wholesale Price ConsumerResponse (η) Pass-Through
Avg SD Avg SD
By Spirit Type:
brandy −0.20 0.12 0.41 0.12cordials −0.19 0.08 0.42 0.09gin −0.21 0.10 0.42 0.10rum −0.20 0.09 0.40 0.09vodka −0.18 0.12 0.43 0.12whiskey −0.17 0.09 0.44 0.10
By Price and Size:
expensive −0.13 0.06 0.49 0.06cheap −0.24 0.10 0.36 0.09375 ml −0.31 0.13 0.30 0.13750 ml −0.18 0.07 0.42 0.081.75 L −0.13 0.04 0.48 0.06
all products −0.19 0.10 0.42 0.10
Notes: “Avg” and “SD” are the simple average and standard deviation forproducts within the spirit type, bottle size, or price range. “Price Response”corresponds to the wholesale price response of the upstream firms defined asthe percent change in wholesale price given a one percent increase in the advalorem tax rate. “Consumer Pass-Through” is the percent change in retailprice from a one percent increase in the ad valorem tax rate. All statistics arecalculated at the estimated equilibrium assuming upstream conduct basedon product ownership.
These estimates of upstream market power suggest that upstream firms can do much to
counteract changes in PLCB policy. Table VIII shows that overall, a one percent increase in the
tax rate at the current equilibrium induces upstream firms to reduce wholesale price by 0.19% on
average. We see significant heterogeneity within and across product categories as the reduction in
wholesale price is greatest among cheap and 375 ml products, but varies little across spirit types.
32We test the validity of these estimates against the financial disclosures for seven public firms in our sample and findthat our estimates of the Lerner index compare favorably to these firms’ gross profit margins during the period.For instance, we estimate that firms earn 34.66 cents per dollar of revenue on average compared to an average grossprofit margin of 37.80% among public distillers. We also see a similar pattern across firms, e.g., Diageo’s grossprofit margin (30.04%) is lower than Beam’s (46.06%).
– 34 –
In terms of retail pass-through the upstream wholesale price response limits retail price increases to
0.42% on average, significantly less than the 1% tax increase that would have been added to prices
were firms pricing at marginal cost. In the remaining section we assess the quantitative significance
of upstream market power for correctly characterizing the Laffer curve and investigate how the
ability of distillers to re-optimize their wholesale pricing might undo the objective of the regulator.
6 Laffer Curves: Policymaker Foresight and Market Conduct
We now use our estimates of spirit demand and upstream marginal costs to assess distiller responses
to changes in the PLCB ’s tax policy and their effect on the revenue the PLCB earns from its pricing
policy. The goal of this section is thus to characterize the Laffer curve as the PLCB varies its ad
valorem tax, τ , while holding other aspects of the pricing regulation fixed. The ad valorem tax is
used by most control and non-control states in the regulation of alcohol. Throughout our analysis
we focus on the ability of the PLCB to generate tax revenue. In line with our focus on maximizing
tax revenue are ongoing efforts at reforming the Pennsylvania wine and spirits retail markets.
For example, the Pennsylvania Legislature’s Act 39, which took effect in August 2016, granted
the PLCB limited pricing flexibility in allowing it to price its best-selling items, defined as the
top-selling 150 SKUs, “in a manner that maximizes the return on the sale of those items.”33
We first characterize the Laffer curve by assuming the regulator is naıve and mistakenly
believes that upstream firms lack the interest or ability to react to changes in policy. In the
notation of the model of Section 2, η(τ) = 0. We then allow upstream firms to respond to changes
in policy under different assumptions regarding upstream conduct – multi-product, single-product,
or monopoly pricing – enabling us to characterize the effect of the degree of imperfect competition
on the location and shape of the Laffer curve not only in aggregate but also for different consumer
groups. Finally, we contrast the Naıve equilibrium with one where the regulator fully anticipates
distillers’ strategic responses to reveal the implications of assuming perfect competition among
firms. Our analysis shows that the location and shape of the Laffer curve fundamentally depend on
the degree to which the regulator rightly anticipates the response of distillers to changes in PLCB
policy. Moreover, abstracting from firm responses (i.e., the Naıve equilibrium) leads to policy
recommendations that not only miss aggregate objectives but also generate inequitable effects
across different consumers.
6.1 The Laffer Curve and Naıve Policymakers
A regulator and 37 firms producing 312 products may interact in multiple ways. The degree to
which the PLCB understands and internalizes the optimal responses of distillers and consumers
to changes in tax policy is unclear. Rather than taking a stand on the ability of the PLCB to
33Omnibus Amendment to Pennsylvania’s Liquor Code, Act of Jun. 8, 2016, P.L. 273, No. 39. Full text available athttp://www.legis.state.pa.us/cfdocs/legis/li/uconsCheck.cfm?yr=2016&sessInd=0&act=39. At the time ofthis writing, the PLCB has taken advantage of this pricing flexibility only a limited number of times.
– 35 –
anticipate agents’ responses, we choose to use the model to evaluate the influence of distillers on
the final outcome of the policy under different beliefs or information assumptions on the part of
the regulator.
6.1.1 Mechanical Effect
The first alternative we consider is an application of the famous critique of Lucas (1976) in which the
PLCB naıvely believes distiller behavior is invariant to its policy. This is the so-called “mechanical
effect” of taxation where we assume firms do not respond to changes in the tax policy though
we do allow for re-optimization of consumers to changes in retail price. We call this the “Naıve”
equilibrium.
We solve for this equilibrium by varying the PLCB ’s tax rate from ten to ninety percent
using a one percentage point grid. Throughout we incorporate into the markup the Johnstown
alcohol tax of 18% so current policy corresponds to a tax rate of 53.4%. For each tax level and
fixed vector of wholesale prices, we solve for the new vector of retail prices in equation (16) and
rely on the estimated demand system to predict consumer spirit purchases and PLCB tax revenue.
Figure 4: Tax Rate, Spirit Demand Elasticity, and the Laffer Curve
2.5
2.6
2.7
2.8
2.9
3
Spi
rits
Ela
stic
ity
10 15 20 25 30 35 40 45 50 55 60 65 70 75 80 85 90
PLCB Tax Rate (%)
Spirits Elasticity
(a) Spirit Demand Elasticity
260
280
300
320
340
360
380
400
420
Dol
lars
(in
Mill
ons)
10 15 20 25 30 35 40 45 50 55 60 65 70 75 80 85 90
PLCB Tax Rate (%)
Naive Laffer Curve - PLCB
(b) Laffer Curve – Naıve
Notes: Spirit demand elasticity and the PLCB Laffer curve under constant wholesale prices. “PLCB Tax Rate” is in percentand includes the 18% Johnstown Flood tax. The solid vertical line corresponds to the current policy; the dashed line to thetax revenue maximizing policy.
Figure 4 plots the resulting absolute value of the demand elasticity of spirits as a category
(ε in Section 2) and the PLCB ’s tax revenue as a function of the ad valorem tax τ when the PLCB
believes that upstream firms will not respond in any way to its tax policy and will keep their
wholesale prices unchanged. Panel (a) shows that off-premise spirit demand becomes increasingly
elastic as the tax (and retail price) increases. We observe that spirit demand is elastic for even
small values of the tax, indicating that the wholesale prices in the data, assumed constant here,
always generate retail prices on the elastic portion of the demand curve for a wide variety of tax
rates.
– 36 –
In panel (b) we plot the associated tax revenue the PLCB would generate under the
alternative rates, presenting a first Laffer curve. For small values of the tax, the Laffer curve
is steep reflecting lower demand elasticities for spirits as a category. As we move past the peak
into the “prohibitive” range, the slope becomes flatter as the demand elasticity stabilizes. We
also see that the current 53.4% tax rate forgoes significant tax revenue by overpricing spirits. The
PLCB could maximize tax revenue by choosing a tax rate of 30.7% forecasting an increase in tax
revenue of 7.8%, or $28.7 million, and a decrease in retail prices of 13% leading to a large increase
in consumption of 47.5%, or 28.6 million bottles.
This large increase in consumption leads to a 51% increase in upstream profits, or $79.7
million. Table IX reports percent changes in consumption, prices, profits, and tax revenue from
moving to the tax revenue maximizing tax rate, together with the average demand elasticity at the
equilibrium prices ε(pr) for the Naıve and other equilibria that we analyze below. Detailed results
including statistics on equilibrium wholesale and retail prices by product type, profits by firms, and
consumption of spirits in liters are reported in Appendix E.
Table IX: Maximizing Tax Revenue and Regulator Foresight
Response Stackelberg
Naıve Base Product Monopoly Base Product Monopoly
Markup (%) 30.68 30.68 30.68 30.68 39.31 39.18 42.07
Percent Change:
- Bottles 47.52 34.59 38.05 8.11 19.62 22.89 −6.48
- Distiller Price (pw) 0.00 3.79 2.80 13.19 2.21 1.31 10.03
- Retail Price (pr) −13.36 −10.45 −11.21 −3.22 −6.48 −7.29 1.72
- Distiller Profit 51.33 56.22 55.43 50.57 30.80 30.30 20.37
- Tax Revenue (T ) 7.75 1.01 2.78 −14.18 2.23 3.99 −12.40
Elasticities:
- Spirits (ε) −2.63 −2.73 −2.72 −2.78 −2.76 −2.75 −2.80
- Upstream Response (η) 0.00 −0.24 −0.23 −0.36 −0.21 −0.21 −0.32
Notes: “Markup” is in percent and includes the 18% Johnstown Flood tax. Other statistics are percent changes from thedata. “Response” and “Stackelberg” equilibria based on estimates of upstream marginal costs consistent with the relevantconduct assumption. We use Bertrand-Nash pricing under the products’ observed ownership structure in “Base”, under aproduct-by-product basis in “Product”, and under joint-ownership of all products in “Monopoly”.
6.1.2 Behavioral Response
Thus far we have abstracted from any upstream wholesale price response to changes in τ . In this
section, we allow distillers to exploit their market power by responding to the PLCB ’s naıve policy.
Our estimates of market power of Section 5.4 and equation (28) illustrate how any modification in
PLCB policy generates incentives for the upstream firms to modify their wholesale pricing decisions
in an oligopolistic environment. Any change in PLCB tax policy impacts distiller pricing decisions
through ∆w, the effect of wholesale prices on retail demand; through the effect of the induced retail
price pr on market shares; and finally through the ability of firms to coordinate prices via Ow.
– 37 –
Pricing rule (16) then determines the retail price. A simple inspection of equation (6) shows that
solving for the upstream response η is more complicated than in the simple model of Section 2
because in an oligopoly there is always the possibility of substitution across products rather than
just to the outside option. Still, results shown below indicate that the intuition and basic economic
trade-offs of the simple monopoly model of Section 2 remain intact.
The difference between the intended goal analyzed in the Naıve equilibrium and the realized
goal in the “Response” equilibrium identifies the degree to which upstream firms can unravel the
PLCB ’s policy. This is commonly known as the “behavioral response” in the taxation literature,
e.g., Saez (2001). There is an important difference, however. In the taxation literature, the
behavioral response is limited to the general equilibrium effect of taxation of a perfectly competitive
industry through entry and exit of firms and consumer re-optimization. Thus, as we consider firms
with market power, it encompasses the wholesale pricing response to taxes as well as the nature of
competition among upstream firms. Here, the difference between Naıve and “Response” equilibrium
ultimately establishes the cost of assuming perfect competition among firms.
Figure 5: Distiller Response and the Laffer Curve
-0.60-0.55-0.50-0.45-0.40-0.35-0.30-0.25-0.20-0.15-0.10-0.050.00
Firm
Res
pons
e E
last
icity
10 15 20 25 30 35 40 45 50 55 60 65 70 75 80 85 90
PLCB Tax Rate (%)
Average 95/5 CI Current Policy
Upstream Response Elasticity
(a) Upstream Firm Response Elasticity (η)
260
280
300
320
340
360
380
400
420
Dol
lars
(in
Millo
ns)
10 15 20 25 30 35 40 45 50 55 60 65 70 75 80 85 90
PLCB Tax Rate (%)
Naive (30.68%) Base Response (39.31%)
Laffer Curves - PLCB
(b) Naıve and Response Laffer Curves
Notes: In Panel (a), the solid line represents the average upstream response elasticity. The shaded region indicates themiddle 90% of responses across all products. We solve for the response elasticity numerically by comparing Bertrand-Nashequilibrium wholesale prices given a one percent change in the PLCB ad valorem tax rate assuming pricing decisions arebased on the observed product portfolio. In Panel (b), the “Response” Laffer curve presents total tax revenue by solvingfor the Bertrand-Nash equilibrium at the given naıve policy. Revenue-maximizing tax rate for each Laffer curve indicated inparentheses.
Figure 5 presents the firm response and its aggregate implication to the characteristics of the
PLCB Laffer curve. In constructing Figure 5, we consider the case where upstream firms optimally
set wholesale prices within their product portfolios for each tax rate chosen by the PLCB . We
denote the multi-product pricing form of upstream conduct as the “Base Response” in the figure.
In panel (a) we present the upstream firm response elasticity η under different choices
of the tax rate. As in the simple model from Section 2, the tax rate and upstream wholesale
prices are strategic substitutes, i.e., η < 0. Thus as the PLCB increases the tax rate τ , firms
respond by lowering the wholesale price pw. Panel (a) reveals three important characteristics of
the upstream response. First, the dispersion in responses, which we illustrate through the shaded
– 38 –
90% response range, representing all responses between the fifth and 95th percentiles, demonstrates
that the upstream response to changes in the PLCB tax rate varies significantly across products
reflecting differences in product elasticities, which in turn are a function of differences in product
characteristics, firm portfolios, and consumer demand. Second, the upstream firm response becomes
more muted at higher tax rates as consumers become increasingly sensitive to changes in price
(Figure 4). Finally, at no point in the set of tax rates we consider do the firms choose not to
respond.
In panel (b) we compare the Naıve and “Base Response” Laffer curves to assess the aggregate
implications to ignoring firm market power. Relative to the Naıve Laffer curve, the “Base Response”
Laffer curve becomes flatter and shifts down and to the right, crossing the Naıve Laffer curve at the
observed equilibrium in the data. In both cases we observe that current taxation policy overprices
spirits. The change in location and shape reflects distillers maximizing profits by moving their
wholesale prices in the opposite direction of any change in the PLCB tax rate.
The consequences of naıve policy making are stark. Suppose the PLCB chose to reduce its
tax rate to 30.7%, which it naıvely believes to be the revenue maximizing tax level. In response,
upstream firms increase wholesale prices, entailing a decrease in retail prices of only 10.5%, rather
than the anticipated 13.4% under constant wholesale prices (Table IX). The distiller response,
which garners them an additional five percent of profit relative to the naıve scenario, limits the
PLCB ’s gain in tax revenue to 1% relative to the current level, or only 13.8% of the envisioned
tax revenue gains of 7.8%. The optimal wholesale pricing response to changes in τ nearly fully
undermines the achievement of the PLCB ’s tax revenue goal. Hence, not accounting for market
power among regulated firms leads to a suboptimal policy recommendation.
We now extend the analysis to account for different assumptions of upstream conduct in
Figure 6. We do so by introducing two extreme forms of upstream conduct. In the first, we
consider the case where a product manager in each firm chooses the price for her product without
internalizing the effects of that price choice on the demand for other products in the firm’s portfolio.
We call this form of conduct “Single Product” to represent the most competitive behavior possible
within a Bertrand pricing oligopoly with differentiated products. In the second we allow all firms to
collude in setting price and we call this form of conduct “Monopoly.” In each alternative conduct
scenario, we solve for the upstream response using the prior marginal cost estimates under pricing
based on the observed product portfolio.
We plot these response Laffer curves alongside the Naıve and “Base Response” Laffer curves
to demonstrate that the results from the base scenario survive as the Laffer curves shift down and
to the right and flatten under all three conduct scenarios. This indicates that with imperfectly
competitive market conduct generally, the response of distillers erodes or undoes the PLCB ’s naıve
policy. At best, in the most competitive, single-product pricing scenario for distillers, the upstream
response to the above reduction in the tax rate to 30.7% enables the PLCB to retain only 35.9%
of the forecasted Naıve tax revenue. At the other end, monopoly conduct in the upstream market
results in a 14.2% reduction in expected aggregate tax revenue relative to levels at current prices.
– 39 –
Figure 6: The Laffer Curve and Upstream Conduct
260
280
300
320
340
360
380
400
420
Dol
lars
(in
Mill
ons)
10 15 20 25 30 35 40 45 50 55 60 65 70 75 80 85 90
PLCB Tax Rate (%)
Naive (30.68%) Base (39.31%)Single Product (39.18%) Monopoly (42.07%)
Laffer Curves - PLCB
Notes: PLCB Laffer curves under the Naıve and three distiller response scenarios. “PLCB Tax” is thead valorem tax rate in percent and includes the 18% Johnstown Flood tax. Vertical line correspondsto the current policy. Revenue-maximizing tax rate for each indicated in parentheses.
We again see the importance of accounting for the response of firms under imperfect competition,
with unanticipated effects on tax collection being more important the less competitive the taxed
industry is.
Thus far we have focused our efforts towards characterizing the location and shape of the
aggregate Laffer curve under different assumptions regarding firm conduct. A concern could be
that these Laffer curves are the result of pooling behavior of individuals with different demographic
attributes and thus different distributions of demand elasticities. In Figure E.1 in Appendix E we
show our results are robust across demographic subgroups.
6.2 The Laffer Curve and Policymakers with Perfect Foresight
We now compare the Naıve and Response equilibria to one in which the regulator has perfect
foresight and correctly anticipates the distiller response. Graphically, we observe this “Stackelberg”
equilibrium as the tax rate that maximizes tax revenue of the response Laffer curve, conditional
on our assumption of upstream conduct. Thus, the Stackelberg equilibrium under our preferred
conduct assumption “Base Response” will be different than under “Single Product” or “Monopoly”
conduct. This strategic pricing game between upstream distillers and the PLCB as the downstream
retailer resembles the classic double-marginalization problem considered in the vertical contracting
literature (cf. Villas-Boas (2007) and Mortimer (2008)). Since the PLCB has traditionally commit-
ted to a tax rate through legislative oversight, we assume – in contrast to the contracting literature
– 40 –
– that the PLCB moves first in choosing the tax rate τ (equivalent to a downstream markup),
before upstream firms respond by setting the wholesale price pw. In practice, for each conduct
assumption we solve for the tax rate that maximizes PLCB tax revenue given the firm wholesale
price response, that is, the tax rate τ that maximizes tax revenues in each of the Response Laffer
curves of Figure 6. All results are reported in the right columns of Table IX.
The comparison of the Naıve, Response, and Stackelberg equilibria reveals how the regulator
has to alter its policy in order to counteract the optimal distiller response and still achieve the
objective of maximizing tax revenues. Under the Stackelberg equilibrium and assuming upstream
firms choose prices for products in their portfolio, “Base Response,” the PLCB correctly forecasts
the firm response and maximizes tax revenue by choosing to lower its tax rate from 53.4% to
only 39.3% – rather than 30.7% under the naıve equilibrium. We find that current PLCB policy
overprices spirits under both sets of beliefs as average retail price falls 6.48% ($1.00) – vs. 10.45%
Figure 7: Differential Impact of Tax Policy Across Equilibria and Demographics
19.921.3
28.7
22.323.7
32.0
17.518.8
25.4
22.223.5
31.7
0
5
10
15
20
25
30
35
Perc
ent C
hang
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Dis
tille
r Pro
fits
All BACARDI BEAM INC DIAGEO
Increase Tax Revenue: Distiller ProfitNaive Response Stackelberg
(a) Distiller Profits
10.3
4.2
10.9
8.4
11.8
3.7
5.0
7.9
0123456789
101112
Perc
ent C
hang
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PLC
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Income Minority College Young
Increase Tax Revenue: Naive DistillersLow High
(b) Tax Revenue by Demographics,Naıve Equilibrium
2.4
-1.4
3.2
1.2
3.6
-1.8
-0.8
0.8
-2
-1
0
1
2
3
4
5
6
Perc
ent C
hang
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PLC
B Ta
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Income Minority College Young
Increase Tax Revenue: Distiller ResponseLow High
(c) Tax Revenue by Demographics,Response Equilibrium
3.0
0.9
3.6
2.3
3.8
0.6
1.2
2.1
0
1
2
3
4
5
6
Perc
ent C
hang
e in
PLC
B Ta
x R
even
ue
Income Minority College Young
Increase Tax Revenue: Stackelberg EquilibriumLow High
(d) Tax Revenue by Demographics,Stackelberg Equilibrium
Notes: Panel (a) represents the percent change in distiller profits from moving to tax-revenue maximizing markups relative toprofits under current prices. Panels (b)-(d) represent associated percent changes in tax revenue contributed by each demographicgroup based on the definitions in Figure 1. Response and Stackelberg equilibria assume distiller pricing decisions internalizethe current product ownership patterns.
– 41 –
($1.61) in the “Response” equilibrium. Thus, current policy is in the “prohibitive range” of the
Laffer curve regardless of whether our regulator is naıve or has perfect foresight.34 While the PLCB
is able to generate higher revenue under this lower tax rate, distillers are the clear winners as the
30.8% increase in distiller profits far outpaces the PLCB ’s two percent growth in tax revenue. As
a consequence, distillers account for 34.9% of integrated profits in the Pennsylvania spirit industry
while they only account for 29.5% under current prices. We find similar results for alternative
assumptions on upstream firm conduct. See Appendix E for detailed results.
Figure 7 addresses whether naıve policy implicitly targets particular consumers or firms.
As before, we compare the percent change in tax revenue generated by markets in the bottom and
top quintiles of the distribution of each demographic trait under each information assumption. We
also display the change in profit for upstream distillers as a group and separately for the top three
distillers to illustrate heterogeneity across distillers.
In Panel (a) we compare distiller profits when firms internalize current portfolio effects
in pricing across the three information assumptions. Total distiller profits increase as the PLCB
lowers tax rates, particularly when the regulator accounts for the distiller response in the Stackelberg
equilibrium. The effect is not uniform across distillers, however, as Diageo and Bacardi are able
to benefit from their large product portfolios in extracting a greater share of the industry profit
across all scenarios, e.g., see Appendix Table E.I.
Panels (b)-(d) show that the impact of such a tax rate reduction varies widely across a
heterogeneous consumer base. Panel (b) demonstrates that decreasing tax rates and retail prices
leads to an increase in tax revenue generated via greater consumption by all consumer types under
constant wholesale prices. Relative to the current market outcome, however, tax contributions stem
disproportionately from markets with consumers who are low income, minority, poorly educated,
and/or no longer in their twenties. Similar results arise in the Stackelberg equilibrium – Panel (d)
– though the market power of the upstream distillers leads to a smaller reduction in retail prices
and limits the increase in tax revenue payments by all consumer types. These results indicate that
any revision to PLCB policy would have to acknowledge the inequitable effects such a policy would
likely have on consumers – an important avenue for future research.35 Should the regulator be
naıve and not account for the upstream distiller response – Panel (c) – the political implications
are significant. Not only would such a policy be largely ineffective at increasing tax revenues,
the burden of the tax is still borne disproportionately by older, poorer, uneducated and minority
consumers while wealthy and educated consumers contribute a smaller share to state coffers.
6.3 Alternative Policy Goal: Ethanol Consumption Reduction
Our analysis has shown that there is a trade-off between tax rate and tax revenue and that the
magnitude of this trade-off, the shape and position of the Laffer curve, depends critically on the
34We investigate the robustness of this result in Appendix C.3.35Miravete et al. (2017) addresses the redistribution effects of the single markup policy.
– 42 –
policymaker’s ability to anticipate the optimal response of taxed firms to the chosen tax rate τ .
Given that at current prices, we are on the downward sloping part of the Laffer curve, the PLCB ’s
objective of raising tax revenue – our focus so far – is not aligned with an alternative policy objective
the PLCB might pursue in light of public health concerns around excessive alcohol consumption.
In this Section, we consider the alternative objective of reducing aggregate ethanol consumption
of off-premise spirits by a targeted amount through an increase in τ . Our goal is to evaluate the
ability of distillers to unravel the achievement of this consumption reduction target, similar to the
above analyses of raising tax revenues analyzed before. This amounts to measuring consumption
effects of the Behavioral Response following distiller re-optimization of wholesale pricing. We also
evaluate the impact that the undoing of this policy has on heterogeneous producers and consumers.
In conducting the counterfactuals below it is worth discussing briefly our treatment of the
outside option. Recall that we define the potential market as all off-premise consumption of alcohol,
including spirits, beer, and wine. Consequently, the objective of the policy we have in mind is not
to decrease aggregate consumption of alcoholic beverages, which is constant by assumption, but
rather to shift consumption from spirits (41.1% ethanol on average) to drinks with lower alcohol
content, such as beer (4.5%) and wine (12.9%).36 We also hold the value of the outside option, beer
and wine, fixed, implicitly assuming that modifications to the PLCB ’s pricing policy for spirits has
no effect on taxation or retail prices of beer and wine.37
6.3.1 Unraveling the Regulator’s Consumption Target
For our analysis, we assume that the PLCB chooses to increase taxes to reach a particular ethanol
consumption reduction target – we choose, arbitrarily, 5%. We focus on the ability of upstream
distillers to undo the PLCB ’s success at reaching this target in responding by lowering wholesale
prices; we thus assume, as above, that the PLCB acts as a naıve policy-maker. Table X shows that
for our demand estimates, a naıve policy-maker would increase the tax rate about three percentage
points, from 53.40% to 56.17%, to meet the 5% ethanol consumption reduction objective. The
anticipated impact on consumers, the PLCB , and the distillers is significant. The new policy
increases raw retail prices 1.62% on average across products, which, due to the reduction in sales,
induces a tax shortfall of 1.59% for the PLCB , or approximately $5.9 million. The 5% reduction in
ethanol consumption from spirits also shrinks aggregate distiller profits by 4.71%, or $7.3 million.
The PLCB ’s increase in the tax rate moves retail pricing into an even more elastic region
of demand, thus reducing revenues for distillers who compensate by lowering their wholesale prices
0.39% on average in the “Base Response” scenario. Again, we see that distiller wholesale prices
and PLCB ’s taxation decisions are strategic substitutes, and the reduction in wholesale price
36Our choice of aggregate consumption is meant to be a simple, feasible target for the regulator.37We implicitly assume consumers do not substitute from off-premise to on-premise consumption as the PLCB varies
the single markup it applies to the off-premise spirits sales. Evidence suggests that the elasticity of substitutionbetween the on-premise and off-premise markets is small (Meng, Brennan, Purshouse, Hill-McManus, Angus,Holmes and Meier, 2014) so this assumption is likely innocuous.
– 43 –
Table X: Equilibria When PLCB Attempts to Reduce Consumption
Response Stackelberg
Naıve Base Product Monopoly Base Product Monopoly
Markup (%) 56.16 56.16 56.16 56.16 56.93 56.89 57.46
Percent Change:
- Distiller Price (pw) 0.00 −0.39 −0.37 −0.59 −0.49 −0.46 −0.86
- Retail Price (pr) 1.62 1.27 1.28 1.08 1.62 1.62 1.60
- Distiller Profit −4.71 −4.96 −4.99 −4.69 −6.28 −6.26 −6.83
- Tax Revenue −1.59 −0.83 −0.87 −0.44 −1.08 −1.12 −0.69
- Ethanol −5.00 −3.94 −3.98 −3.42 −5.00 −5.00 −5.00
Notes: “Markup” is in percent and includes the 18% Johnstown Flood tax. Other statistics are percent changes fromthe data. All statistics are based on distiller marginal costs that result from the relevant upstream conduct assumption.We use Bertrand-Nash pricing based on the products’ observed ownership structure in “Base”, on a product-by-productbasis in “Product”, and joint-ownership of all product in “Monopoly”.
mechanically translates into a smaller increase in average retail prices via the pricing rule than
the PLCB naıvely anticipated (78.4% of the anticipated increase, about 6 cents less on average).
This limits the reduction in aggregate consumption to 3.94%, or 21.4% less than intended by the
policymaker.
Similar results hold for total ethanol consumption after accounting for the lower ethanol
content of the outside option.38 Here, the 5% reduction in ethanol consumption of spirits generates
a 0.88% reduction in total ethanol consumed while the upstream distiller response limits this
reduction to only 0.69%, or 78.81% of the intended target.
We find that our results are robust to different upstream conduct assumptions. The degree
to which the firms can limit the regulator’s objective is significant, even in the most competitive
“Product” case, where we assume each product’s price is set independently. There, consumption
falls by 20.4% less than intended by the PLCB . In practice, distillers with large product portfolios
thus appear to have a limited desire to increase prices beyond single-product firms. Possible
explanations for the lack of significant portfolio-level business stealing effects that multi-product
pricing would internalize include the crowded product space, with close competitors from other large
distillers and numerous smaller distillers, and the fact that, as discussed in Section 3.3, the market
leader Diageo’s portfolio covers a large range of heterogeneous spirits with limited within-portfolio
substitution between products. As a result, the internalization of business stealing effects only
occurs when we consider a single upstream monopoly (the “Monopoly” column), when we observe
a substantially larger unraveling effect with a 31.5% smaller consumption reduction than intended.
38We compute total ethanol consumption by assuming the composition of beer and wine is constant across markets(94.4% and 5.6%, respectively) and assume that the ethanol content in beer and wine is 4.5% and 12.9%, respectively.
– 44 –
Figure 8: Variation in Upstream Firm and Consumer Responses to ConsumptionReduction Policies
-4.7-4.9
-6.3
-5.2-5.4
-6.9
-4.3-4.5
-5.7
-5.2-5.4
-6.9-7
-6
-5
-4
-3
-2
-1
0
Per
cent
Cha
nge
in D
istil
ler P
rofit
s
All BACARDI BEAM INC DIAGEO
Reduce Consumption: Distiller ProfitNaive Response Stackelberg
(a) Distiller Profits
5.1
4.7
5.35.0
5.3
4.6 4.85.0
0
1
2
3
4
5
6
Perc
ent R
educ
tion
in V
olum
e So
ld
Income Minority College Young
Reduce Consumption: NaiveLow High
(b) Naıve
4.03.8
4.13.9
4.13.7 3.8 3.9
0
1
2
3
4
5
6
Perc
ent R
educ
tion
in V
olum
e So
ld
Income Minority College Young
Reduce Consumption: Distiller ResponseLow High
(c) Distiller Response
5.04.8
5.34.9
5.2
4.7 4.8 4.9
0
1
2
3
4
5
6
Perc
ent R
educ
tion
in V
olum
e So
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Income Minority College Young
Reduce Consumption: Stackelberg EquilibriumLow High
(d) Stackelberg
Notes: Panel (a) represents percent change in profits relative to benchmark profits under the observed product ownershipstructure. Statistics in panels (b)-(d) represent percent change in ethanol consumed in top and bottom quintile of eachdemographic group following the definitions presented in Figure 1. Distiller Response and Stackelberg equilibria assume pricingdecisions based on observed product ownership.
6.3.2 Differential Responses of Upstream Firms and Consumers
To conclude the analysis of a policy targeting a 5% ethanol reduction from spirits consumption, we
evaluate whether its effect is evenly distributed across heterogenous distillers and consumers in our
market. Panel (a) of Figure 8 compares distiller profits across the Naıve, Response, and Stackelberg
equilibria in our hypothetical policy experiment under the base conduct assumption. The first
striking result is that the impacts to profits across the three largest firms – Bacardi, Beam, and
Diageo – largely track the impacts on total distiller profits, though we find some evidence that the
PLCB ’s desire to reduce consumption impacts these large distillers more than the smaller distillers.
This finding is robust across the three scenarios. Panels (b)-(d) of Figure 8 document that there
is little variation in the change in ethanol consumption across demographic groups, which implies
that the effect of a consumption reduction policy implemented via a raise of the single markup
appears to be felt equitably by individuals with different socioeconomic characteristics.
– 45 –
7 Concluding Remarks
We have estimated a demand system for differentiated spirits and combined it with a game theoretic
model of distiller pricing to assess the response of upstream firms to changes in tax policy. We
use the estimated model to characterize Laffer curves in a variety of scenarios. We find that
upstream market power and price responses mitigate the effect of any tax policy change on tax
revenue, reducing the ability of the regulator to drive revenue generation via tax policy changes.
Abstracting from firm responses to policy, equivalent to assuming perfect competition among firms
as is common in the literature, therefore has the potential to generate poor policy recommendations
that not only impact aggregate goals in the form of, e.g., tax revenue forecasts, but also generate
heterogeneous burdens across consumers.
The PLCB has historically used simple linear contracts in purchasing inventory from
upstream suppliers – a contracting arrangement that we maintain in our analysis of optimal tax
rates. As a result, we do not consider more efficient forms of vertical contracting that would allow
the PLCB to extract surplus from its upstream suppliers via, e.g., license fees combined with
downstream marginal cost pricing. In such contexts, however, the traditional regulation literature
(Abito, 2016; Brocas, Chan and Perrigne, 2006; Gagnepain and Ivaldi, 2002; Wolak, 1994) has
highlighted incentives for firms to misrepresent their marginal costs when the regulator observes it
imperfectly; thus setting license fees, and designing nonlinear purchase contracts more broadly, is
a challenging problem.
Similarly, due to the sizable public health costs of excessive alcohol consumption, alcohol
markets are subject to a myriad of different regulations across the country, not all of whom we do
justice in this paper. Out of equity concerns, most states – including Pennsylvania – use a single tax
regime that increases the price of all products by an equal amount or percentage. Our findings here
demonstrate a significant degree of heterogeneity in both demand levels and price responsiveness
across demographic groups, suggesting – despite the apparent horizontal and vertical equity of a
single tax rate – that the purchase behavior of some demographic groups will be more affected than
that of others under such a one-size-fits-all policy. At the same time, a large public health literature
finds that the incidence of the external costs of alcohol consumption are not uniformly distributed
across the population. Whether the markets most affected by a simplified taxing rule happen to be
the ones with the highest external costs, or whether instead, a simple tax redistributes across local
markets and how such redistribution is affected by an increasingly concentrated upstream distiller
market, are questions we leave to future research.
– 46 –
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Appendix
A Data
In this section we discuss the data in more detail. We begin with a discussion of how we aggregate
the initial daily, store-level PLCB data and how we define market areas served by each store. To
reduce the size of the estimation sample, we aggregate over days where prices remain unchanged.
PLCB regulation allows price to change only for two reasons: permanent and temporary wholesale
price changes. Both follow set timing requirements. Permanent price changes can take effect on the
first day of one of the PLCB ’s thirteen four-week long accounting reporting periods. Temporary
sales, on the other hand, begin on the last Monday of each month and last for either four or
five weeks until the day before the last Monday of the following month. Reporting periods and
temporary sales periods thus align largely, but not perfectly, with the vast majority of days in a
typical sales period overlapping with an initial reporting period, and the remainder with the next.
Since temporary price reductions are more prevalent than permanent ones (84.8% of price changes
in the sample are temporary in nature), we use sales periods as our time interval to avoid having
multiple very short periods. This results in 34 pricing periods during which prices remain constant.
For permanent price changes in a reporting period that bisects two sales periods, we assume that
the price change takes effect in the sales period that most overlaps with the given reporting period.
In aggregating our daily sales data to the level of the sales pricing period, we treat a product as
being available in a store if it sold at least once during a given period. The length of the pricing
period alleviates concern about distinguishing product availability from lack of sales in the period.
Stores exhibit significant variation in the product composition of purchases. These dif-
ferences reflect heterogeneity in consumer preferences more than differences in the availability of
products across stores: Of the 100 best selling products statewide in 2003, the median store carried
98.0%, while a store at the fifth percentile carried 72.0% of the products. Similarly, of the 1000
best selling products statewide in 2003, the median store carried 82.03%, while a store at the fifth
percentile carried 44.2% of the products. The product availability at designated “premium” stores
is somewhat better than the average, with the median premium store carrying all of the top 100
products and 95.1% of the top 1000 products. A customer can also request to have any regular
product in the PLCB ’s product catalog shipped to his local store for free, should that store not
carry the product.
The fact that most stores carry most popular products and can provide access to all
products in the catalog easily, together with the absence of price differences across stores, supports
an assumption underlying our demand model: Differences in product availability do not drive
customers’ store choices to a significant degree and as a result, consumers visit the store closest
to them. In making this assumption, which allows us to focus on the consumer’s choice between
different liquor products available at the chosen store, we follow previous studies using scanner data
such as Chintagunta and Singh (2003).
In assigning consumers to stores, we calculate for each of Pennsylvania’s 10,351 regular block
groups the straight-line distance to each store and assign consumers to the closest open store for
each pricing period. In instances where the PLCB operates more than one store within a ZIP code,
– i –
we aggregate sales across stores to the ZIP code level; there are 114 such ZIP codes out of a total
of 1,775. Note that these instances include both store relocations, where a store moved from one
location in a ZIP code to another during our sample period, but the data contain separate records
for the store in the two locations, and instances where the PLCB operates two stores simultaneously
within a ZIP code.39 We consider the resulting block group zones as separate markets. Figure A.1
illustrates this aggregation of block groups into markets and shows the markets as of January 2003.
We repeat this procedure for each pricing period to account for changes in demographics after store
openings and closings. In total, we observe two permanent store closings and 19 permanent store
openings over the three year period. 125 stores are closed for at least one pricing period; these
temporary store closings last on average 2.73 pricing periods. Store closings and openings introduce
variation in the demographics of the population served by each store that we exploit, in addition
to cross-sectional variation in demographics, to identify heterogeneous tastes for spirits.
Figure A.1: Pennsylvania Markets as of January 2003
We derive consumer demographics for the store’s zone by calculating the total population
of drinking age and population-weighted average demographics, including the percent of the popu-
lation that is non-white, has at least some college experience, and is between the ages of 21 and 29
years, as well as the population-weighted income distribution. In the case of income, we obtained
detailed information on each block group’s discrete income distribution by racial identity of the
head of household, with household income divided into one of 16 categories. We aggregate across
racial groups and across block groups in a store’s market area to derive the income distribution
for white households separately from non-white households. We construct two income measures.
First, we calculate the share of high-income households, defined as households with incomes above
$50,000. Second, we fit continuous market-specific distributions to the discrete income distributions
39We drop wholesale stores, administrative locations, and stores without valid address information, for a total of 13stores.
– ii –
conditional on minority status. We employ generalized beta distributions of the second kind to fit
the empirical income distributions. McDonald (1984) highlights that the beta distribution provides
a good fit to empirical income data relative to other parametric distributions.
We similarly obtained information on educational attainment by minority status and ag-
gregated across several categories of educational attainment to derive the share of the population
above the age of 25 with at least some college education, by minority status and market area. We
obtained the share of young population between the ages of 21 and 29 by market area.
Our price instruments come from two sources. First, the data on retail prices in other
liquor control states is from the National Alcohol Beverage Control Association and consists of
monthly product-level shelf prices by liquor control state. We assign a month to our Pennsylvania
pricing periods to facilitate a match between the two data sets. Second, we obtained historical
commodity prices for corn and sugar from Quandl, a data aggregator. The prices are the monthly
price of a “continuous contract” for each commodity where a “continuous contract” is defined as
a hypothetical chained composite of a variety of futures contracts and is intended to represent the
spot market price of the given commodity. We also attained prices for rice, sorghum, wheat, barley,
oats, and glass (as a cost input for bottle size) but found these input costs provided little additional
explanatory power.
B Additional Descriptive Statistics
Table B.I presents the distribution of bottle prices contained in our sample of 312 products. The
average price is increasing across bottle sizes both within a category and for the whole sample.
Table B.I: Bottle Prices by Spirit Type and Bottle Size
Spirit Type Average Median SD Max Min
brandy 13.91 11.23 7.00 36.11 5.42
375 ml 9.19 6.01 4.42 15.31 5.42750 ml 14.47 9.93 7.63 36.11 9.251.75 L 18.68 19.25 1.72 22.24 16.70
cordials 14.94 14.99 5.78 38.47 5.99
375 ml 10.41 10.28 3.07 19.24 5.99750 ml 15.14 15.35 5.04 31.15 5.991.75 L 25.92 24.98 6.86 38.47 18.26
gin 15.63 14.54 7.59 39.50 4.79
375 ml 7.91 6.94 2.51 12.06 4.79750 ml 13.61 10.60 5.37 22.16 5.991.75 L 19.54 17.10 8.24 39.50 11.71
rum 14.25 13.56 5.30 26.44 5.07
375 ml 6.62 6.43 0.71 7.49 5.07750 ml 12.57 12.99 2.35 19.57 7.751.75 L 19.90 21.16 4.83 26.44 12.99
vodka 13.81 12.25 7.49 48.40 3.88
375 ml 5.13 4.06 2.38 14.34 3.88750 ml 15.18 14.82 5.04 26.58 6.171.75 L 16.84 12.90 7.53 48.40 10.83
whiskey 16.81 15.48 7.59 45.99 5.51
375 ml 8.75 9.63 2.53 15.45 5.51750 ml 14.98 13.09 6.2 31.84 5.961.75 L 20.74 18.34 7.57 45.99 12.97
– iii –
Whiskeys tend to be the most expensive products while Brandies, Rums, and Vodkas are less
expensive. These statistics mask heterogeneity across products. For instance, Vodkas tend to be
inexpensive on average, $13.82 per bottle, but average prices range from the 375 ml Nikolai Vodka
at $3.88 to the 1.75 L Grey Goose at $48.40.
Table B.II: Market Share by Type, Price, and Size
Share of Market
Products By Quantity By Revenue By Tax Revenue
By Spirit Type:
brandy 26 7.24 6.76 6.77cordials 62 13.38 13.42 13.24gin 28 6.91 7.25 7.23rum 40 16.18 15.55 15.64vodka 66 31.88 29.55 30.04whiskey 90 24.41 27.47 27.08
By Price and Size:
expensive 162 53.11 37.59 40.06cheap 150 46.89 62.41 59.94375 ml 48 15.19 7.34 8.14750 ml 170 50.2 48.82 48.421.75 L 94 34.61 43.85 43.43
all products 312 100.00 100.00 100.00
Notes: “Quantity” market share is based on bottles while “Revenue” and “Tax Revenue” are based ondollars. “Cheap” (“Expensive”) products are those products whose mean price is below (above) themean price of other spirits in the same spirit type and bottle size.“Tax Revenue” is defined as retailprice minus wholesale price times quantity sold.
C Robustness of Demand Estimates
This Appendix addresses a number of alternative specifications to highlight the robustness of our
reported estimates. We show that the inclusion of premium, border stores, or holiday periods
are mostly inconsequential. Aggregating sales across local markets leads to less elastic demand
estimates, well along the lines of other studies using only aggregate sales data. We also show
that the inclusion of brand fixed effects helps control for unobservable quality differences across
products.
An important robustness check deals with the equilibrium implications of flatter or steeper
demand estimates on markups, optimal tax rates, and optimal agents’ responses to changes in
tax policy. We show that our estimates are broadly consistent with profit maximization in the
upstream distiller segment while being on the prohibitive range of the Laffer curves. Thus, the
PLCB significantly overprices spirits if its goal is only to maximize tax revenues. Finally, we rule
out the existence of significant stockpiling that could bias our own-price elasticity estimates upward
and our cross-price elasticity estimates downward.
– iv –
Table C.I: OLS Demand Estimates Based on Different Samples
(i) (ii) (iii) (iv)
price −0.2296 −0.2370 −0.2151 −0.2252(0.0028) (0.0028) (0.0028) (0.0026)
Product FEs Y Y Y YPremium Stores Y N Y YBorder Stores Y Y N YHoliday Period Y Y Y N
Statistics:R2 0.9416 0.9418 0.9381 0.9582N 10,532 10,532 10,532 8,670
Elasticities:Average −3.5652 −3.6823 −3.3318 −3.4977% Inelastic 0.7430 0.7429 0.7563 0.7481Spirits −3.2351 −3.3800 −2.9816 −3.1684
Notes: The dependent variable for all models is the estimated product-period fixed effects from a first-stage regression of log(Sjmt)− log(S0mt) onto product-period fixed effects and demographic-productinteractions. Robust standard errors in parentheses. “% Inelastic” is the percent of products withinelastic demand. “Spirits” is the price elasticity of total PLCB off-premise spirit sales.
C.1 Alternative Demand Specifications
In Table C.I we use a simple multinomial logit demand system to highlight the robustness of our
demand estimation results to alternative samples. Model (i), the most similar to the full model,
employs a similar estimation strategy where we first regress the logged ratio of product to outside
share on product-period and store fixed effects and interactions between average demographics and
product characteristics (e.g., % minority × rum dummy). This model generates product elasticities,
both on average and for the spirit category, that are more inelastic than our preferred mixed-logit
model. In Models (ii)-(iv) we vary the number of markets to show that including markets with
premium and border stores and including the holiday period has little effect on our estimated price
coefficient and elasticities.
Table C.II: OLS Demand Estimates Using Aggregate Data
(i) (ii) (iii) (iv)
price −0.1218 −0.0508 −0.0822 −0.0109(0.0003) (0.0003) (0.0018) (0.0013)
Brand FEs Y N Y N
Statistics:R2 0.5052 0.2404 0.8101 0.1473N 3,377,659 3,377,659 10,532 10,532
Elasticities:Average −1.8910 −0.7885 −1.2764 −0.1686% Inelastic 13.1151 78.5863 39.6494 100.0000Spirits −1.7318 −0.7265 −1.1730 −0.1559
Notes: The dependent variable for models (i)-(ii) is log(Sjmt)−log(S0mt) while it is log(Sjt)−log(S0t) for models (iii)-(iv).Robust standard errors in parentheses. “% Inelastic” is the percent of products with inelastic demand. “Spirits” is theprice elasticity of total PLCB off-premise spirit sales.
– v –
In Table C.II we estimate demand using various levels of aggregation. In Model (i) we
deviate from our multi-step approach and estimate a one-step model, regressing the logged ratio
of product share to outside share on price, demographic interactions, and fixed effects for brand
(different bottle sizes of the same spirit label), bottle size, season, and store. Demand becomes
much steeper than under Model (i) in Table C.I. In Model (ii) we replace the brand fixed effects
with indicators for spirit type and for imported spirits. Demand becomes even more inelastic due
the coarseness of our observable characteristics that do not capture any quality differences between,
e.g., two imported rums, that would lead to different market shares and prices. In Models (iii)-(iv)
we aggregate consumption to the state-level requiring us to drop the demographic interactions but
otherwise using the same controls as in Models (i) and (ii). The inclusion of brand fixed effects
is important to absorb differences in unobservable (to the econometrician) characteristics across
brands. Table C.II also shows that aggregation leads to significantly less elastic estimates of product
demand and an elasticity of off-premise spirits well within the set of estimates reported in Leung
and Phelps (1993). Aggregation, though, also increases the prevalence of inelastic product demand
– a point which we show below is inconsistent with upstream profit-maximization in our data.
C.2 Consumer Demand, Product Elasticities, and Upstream Markups
An advantage of our data and estimation approach is that we can estimate (Σ,Π, ρ) independent
of the mean utility parameters, including the mean price coefficient (α). As α modulates the
consumer response to changes in prices, it also affects the ability of upstream firms to charge prices
that entail significant markups as well as respond to changes in the tax rate. In Table C.III, we
vary α exogenously to evaluate the equilibrium implications. This exercise serves two purposes.
First, it demonstrates how variation in the price coefficient impacts consumer demand, upstream
market power, and ultimately the ability of both consumers and firms to respond to changes in tax
policy. Second, it provides supporting evidence that current policy is indeed on the “prohibitive”
region of the Laffer curve.
Table C.III: Elasticities, Marginal Costs, and Market PowerUnder Alternative Price Coefficients (α)
Product Elasticities (ε) Upstream Firms
Price Coeff. (α) Spirits Average % Inelastic Lerner %MC < 0
-0.38 −3.70 −5.16 0.00 26.56 0.00-0.36 −3.46 −4.81 0.00 28.35 0.05-0.34 −3.22 −4.46 0.00 30.41 0.42-0.32 −2.97 −4.11 0.00 32.79 0.74-0.30 −2.73 −3.75 0.04 35.58 0.74-0.28 −2.49 −3.40 0.11 38.91 0.74-0.26 −2.24 −3.05 0.28 42.94 0.80-0.24 −2.00 −2.70 0.62 47.95 1.46-0.22 −1.75 −2.35 1.55 54.35 2.60-0.20 −1.50 −2.00 4.25 62.92 5.79
Notes: Estimated price coefficient under the preferred IV specification is ˆα = −0.3062. For a given αvalue we recover implied upstream marginal costs assuming upstream firm pricing based on observedproduct ownership. “Spirits” elasticity refers to the elasticity of spirits as a category. We solve forthis numerically by increasing the retail price of spirits one percent. “Average” is the average priceelasticity across the products. “% Inelastic” is the percent of products with estimated price elasticity
less than one. “Lerner” is the average Lerner index defined as 100× pw−cpw
. “%MC < 0” is the percent
of products with negative estimated marginal cost.
– vi –
As suspected, alternative values of α pivot consumer demand resulting in significant impacts
to the consumer demand elasticities both by product and for spirits as a category. For instance,
as we move towards zero from the estimated value of −0.3062, consumers become less sensitive to
changes in price leading to a decrease in the average product elasticity and a lower value for the
elasticity of spirits as a category. Ultimately, this pivoting leads to greater margins for upstream
firms while also enabling a PLCB focused on maximizing tax revenue to charge a higher tax rate.
The results presented in Table C.III also indicate the values for spirit demand documented in
the meta study by Leung and Phelps (1993) are improbable at least in our context and sample
period. To generate category level elasticities similar to the values found by researchers using state
or national data, α needs to be around −0.20 . At this point, however, 4.25% of products have
estimated inelastic demand while 5.79% of the implied upstream marginal costs are negative – both
of which are inconsistent with upstream profit-maximization.
C.3 Consumer Demand and the Prohibitive Region of the Laffer Curve
Our results indicate that regardless of regulatory foresight, the PLCB would choose to decrease
the tax rate below current levels to increase tax revenue, leading to a decrease in retail prices.
Apart from upstream conduct, this result reflects the demand elasticity we estimate from observed
consumer responses. Despite the fact that our demand estimates are robust to various alternative
specifications and instrumentation choices, in this section we investigate the sensitivity of this
overpricing result to our estimated mean price coefficient, α. In Table C.IV we repeat the analysis
from Table C.III and append statistics on the firm response elasticity as well as the PLCB ’s optimal
ad valorem tax τ? where we assume the PLCB operates under naıve beliefs.
Table C.IV: Over-Pricing Under Alternative Price Coefficients (α)
Product Elasticities (ε) Upstream Firms
Price Coeff. (α) Spirits Average % Inelastic Response (ε) Lerner %MC < 0 PLCB Mup (τ?)
Over-Pricing
-0.38 −3.70 −5.16 0.00 −0.14 26.56 0.00 20.91-0.36 −3.46 −4.81 0.00 −0.15 28.35 0.05 23.55-0.34 −3.22 −4.46 0.00 −0.16 30.41 0.42 26.70-0.32 −2.97 −4.11 0.00 −0.17 32.79 0.74 30.58-0.30 −2.73 −3.75 0.04 −0.19 35.58 0.74 35.34-0.28 −2.49 −3.40 0.11 −0.20 38.91 0.74 41.35-0.26 −2.24 −3.05 0.28 −0.22 42.94 0.80 49.26
Under-Pricing
-0.24 −2.00 −2.70 0.62 −0.24 47.95 1.46 60.10-0.22 −1.75 −2.35 1.55 −0.26 54.35 2.60 76.72-0.20 −1.50 −2.00 4.25 N/A 62.92 5.79 108.36
Notes: Estimated price coefficient under the preferred IV specification is α = −0.3062. For a given α value we recover impliedupstream marginal costs assuming upstream firm pricing based on observed product ownership. “Spirits” elasticity refers to theelasticity of spirits as a category. We solve for this numerically by increasing the retail price of spirits one percent. “Average”is the average price elasticity across the products. “% Inelastic” is the percent of products with estimated price elasticity lessthan one. “Response” is the average firm response elasticity (η) defined as the average percent change in wholesale price givena one percent increase in the tax rate. We solve for this value numerically. When α = −0.20 we were unable to find an interiorsolution to the firms’ pricing decision due to the large number of inelastic product demands.“Lerner” is the average wholesale
Lerner index defined as pw−cpw
. “%MC < 0” is the percent of products with negative estimated wholesale marginal cost. “PLCB
Mup” is the tax revenue-maximizing markup under naıve beliefs where a markup less (greater) than 53.4% implies that currentPLCB policy over-prices (under-prices) spirits. All upstream distiller statistics assume “Base” conduct.
– vii –
Varying the price coefficient from an implied aggregate spirits elasticity of −3.7 to −1.5, we
find that the category elasticity would need to rise to at least −2 before the current tax rate places
the PLCB on the upward sloping part of the Laffer curve. Such an aggregate elasticity, however, is
not consistent with profit maximizing behavior by upstream distillers given their observed prices:
For approximately 1% of products, we find that demand is inelastic; 1.5% of marginal costs are
negative, and upstream margins are on average 48%. This stands in contrast to industry estimates
which place the average wholesale margin earned by distillers at approximately 37%, in line with
what we obtain under our demand estimates which entail an average margin of 35%.
When α=−0.2452, the current PLCB policy maximizes tax revenue assuming the regulator
has Naıve beliefs.40 Since our OLS estimate is α=−0.2673 and instrumenting for price typically
makes demand more elastic (i.e., decreases α) this supports our finding that current PLCB policy
operates on the right-hand side of the Laffer curve, overpricing spirits to decrease consumption.
C.4 Stockpiling
Hendel and Nevo (2006a) show that static models of demand overstate own-price elasticities when
consumers hold inventories and make dynamic purchase decisions. In this study such a bias would
translate into not only poorly estimated consumer demand but also an underestimate of upstream
market power including suppliers’ ability to respond to changes in PLCB policy via η. Such a bias
would primarily show up in our estimate of the mean utility price coefficient (α), though in Appendix
C.2 above we document that less elastic estimates of consumer demand are also inconsistent with
upstream profit maximization under the observed wholesale prices.
We test for evidence of stockpiling following Pesendorfer (2002) and Hendel and Nevo
(2006b). The idea is to test whether consumers are increasingly likely to buy a good the more
time passes since the last sale. In other words, if consumers can indeed make several purchases
at a time when a product is on sale, the likelihood they have to make an additional purchase
increases with time since that purchase. In Table C.V we regress logged quantity sold (bottles)
on logged price and the duration since the last temporary sale. In the top panel, we use the
product-store-period data in our sample and include fixed effects for product, store, and period
heterogeneity. If our data exhibited a pattern of accumulation consistent with an inventory model,
the coefficient on duration from the last sale should be positive and significant. We, however, find
this coefficient is small, mostly insignificant and often negative. Further, there appears to be little
evidence of stockpiling across different product categories. We find similar results when we use the
more disaggregated daily sales data (bottom panel). We therefore conclude our data provides no
evidence of stockpiling. We do however observe unusual sales patterns in January as quantity sold
falls after the holiday season. Such behavior could be due to stockpiling, even though products
are less likely to go on sale during the holidays (see Table II), but could also be due to consumers
“burning off” their holiday inventory or adopting short-term New Year resolutions. Introducing a
January indicator could control for the change in demand caused by the latter two explanations.
Being unable to disentangle these explanations, though, we instead chose a conservative approach
and dropped all January observations from the estimation.
40The Stackelberg equilibrium in which current policy also maximizes tax revenue occurs when α=−0.2687.
– viii –
Tab
leC
.V:
Test
sfo
rS
tock
pilin
g:
Dem
an
das
aFu
ncti
on
of
Du
rati
on
from
Pre
vio
us
Sale
Sp
irit
Typ
eB
ott
leS
ize
Pri
ceR
an
ge
All
brandy
cordials
gin
rum
vodka
whiskey
375
ml
750
ml
1.7
5L
cheap
expensive
Perio
d-L
evel
Data
log(p
rice
)-3
.8618
-4.0
471
-3.0
719
-3.9
386
-3.5
453
-4.6
810
-4.0
561
-2.9
496
-3.6
632
-4.4
964
-4.0
967
-3.6
477
(0.0
496)
(0.1
364)
(0.0
969)
(0.1
287)
(0.1
281)
(0.1
191)
(0.0
798)
(0.1
350)
(0.0
668)
(0.0
661)
(0.0
738)
(0.0
669)
Du
rati
on
from
0.0
008
-0.0
054
0.0
065
0.0
021
0.0
061
-0.0
043
0.0
000
0.0
103
-0.0
040
0.0
039
-0.0
025
0.0
025
pre
vio
us
sale
(0.0
017)
(0.0
051)
(0.0
032)
(0.0
040)
(0.0
040)
(0.0
029)
(0.0
030)
(0.0
044)
(0.0
020)
(0.0
023)
(0.0
026)
(0.0
021)
R2
0.5
633
0.4
866
0.5
380
0.5
441
0.6
476
0.6
966
0.5
294
0.5
407
0.5
413
0.5
587
0.5
128
0.5
724
N3,3
76,2
93
259,4
72
677,1
33
288,0
61
451,4
72
716,5
29
983,6
26
48,4
761
1,8
67,4
37
1,0
24,0
95
1,7
34,5
93
1,6
41,7
00
Dail
yD
ata
log(p
rice
)-1
.1657
-1.4
532
-0.7
594
-1.0
414
-0.9
622
-1.7
140
-1.0
972
-0.8
615
-1.0
786
-1.3
500
-1.1
905
-1.1
498
(0.0
226)
(0.0
505)
(0.0
532)
(0.0
445)
(0.0
597)
(0.0
484)
(0.0
344)
(0.0
559)
(0.0
346)
(0.0
305)
(0.0
315)
(0.0
322)
Du
rati
on
from
0.0
000
0.0
002
0.0
003
0.0
003
-0.0
004
-0.0
001
0.0
000
0.0
002
-0.0
001
0.0
000
-0.0
001
0.0
000
pre
vio
us
sale
(0.0
001)
(0.0
001)
(0.0
002)
(0.0
001)
(0.0
002)
(0.0
001)
(0.0
001)
(0.0
001)
(0.0
001)
(0.0
001)
(0.0
001)
(0.0
001)
R2
0.2
621
0.2
901
0.2
052
0.2
384
0.2
858
0.3
344
0.2
039
0.3
767
0.2
194
0.2
636
0.2
76
0.2
296
N31,5
43,8
48
2,2
73,0
14
4,9
52,3
81
2,4
50,6
20
4,7
26,4
32
8,1
36,4
22
9,0
04,9
79
4,3
18,2
47
16,4
95,7
00
10,7
29,9
01
16,6
85,6
93
14,8
58,1
55
Note
s:T
he
dep
end
ent
vari
ab
lein
all
regre
ssio
ns
isth
elo
gof
qu
anti
typ
urc
hase
d(m
easu
red
inb
ott
les)
.In
the
top
pan
el(“
Per
iod
-Lev
elD
ata
”)
an
ob
serv
ati
on
isa
pro
du
ct-
store
-per
iod
trip
let.
Du
rati
on
inth
eto
pp
an
els
isth
enu
mb
erof
per
iod
s(a
pp
rox.
month
s)si
nce
the
last
sale
.A
llre
gre
ssio
ns
inth
eto
pp
an
elin
clu
de
pro
du
ct,
store
,an
dp
erio
dfi
xed
effec
ts.
Inth
eb
ott
om
pan
els
(“D
ail
yD
ata
”)
an
ob
serv
ati
on
isa
pro
du
ct-s
tore
-day
trip
let
an
dw
ed
efin
ed
ura
tion
sin
ceth
ela
stsa
lein
wee
ks.
All
regre
ssio
ns
inth
eb
ott
om
pan
elin
clu
de
pro
du
ct,
store
,an
dw
eek
fixed
effec
ts.
Rob
ust
stan
dard
erro
rsin
pare
nth
eses
.
– ix –
D Elasticities
Figure D.1: Distribution of Demand Elasticities
0
5
10
15
20
25
Perc
ent
-15 -10 -5 0
(a) Brandy
0
5
10
15
20
25
Perc
ent
-15 -10 -5 0
(b) Cordials
0
5
10
15
20
25
Perc
ent
-15 -10 -5 0
(c) Gin
0
5
10
15
20
25
Perc
ent
-15 -10 -5 0
(d) Rum
0
5
10
15
20
25
Perc
ent
-15 -10 -5 0
(e) Vodka
0
5
10
15
20
25
Perc
ent
-15 -10 -5 0
(f) Whiskey
0
5
10
15
20
25
Perc
ent
-15 -10 -5 0
(g) 375 ml
0
5
10
15
20
25
Perc
ent
-15 -10 -5 0
(h) 750 ml
0
5
10
15
20
25
Perc
ent
-15 -10 -5 0
(i) 1.75 Ltr
0
5
10
15
20
25
Perc
ent
-15 -10 -5 0
(j) Expensive
0
5
10
15
20
25
Perc
ent
-15 -10 -5 0
(k) Cheap
0
5
10
15
20
25
Perc
ent
-15 -10 -5 0
(l) All Products
– x –
Tab
leD
.I:
Best
Su
bst
itu
tes
Close
rSubstitute
Pro
duct
Owner
Type
Ratio
Pro
duct
Owner
Type
εij
HENNESSY
V.S.COGNAC
-375
ML
MOET
HENNESSY
BRANDY
16.87
JACQUIN
’SBLACKBERRY
FLAV.BRANDY
-1.75
LTR
JACQUIN
BRANDY
0.0619
E&
JCAL.BRANDY
-750
ML
E.AND
J.GALLO
BRANDY
15.26
HENNESSY
V.S.COGNAC
-750
ML
MOET
HENNESSY
BRANDY
0.0984
THE
CHRIS
TIA
NBROS.CAL.BRANDY
-1.75
LTR
HEAVEN
HIL
LBRANDY
15.76
JACQUIN
’SBLACKBERRY
FLAV.BRANDY
-1.75
LTR
JACQUIN
BRANDY
0.0796
E&
JCAL.BRANDY
-375
ML
E.AND
J.GALLO
BRANDY
27.59
JACQUIN
’SBLACKBERRY
FLAV.BRANDY
-1.75
LTR
JACQUIN
BRANDY
0.0604
HENNESSY
V.S.COGNAC
-750
ML
MOET
HENNESSY
BRANDY
10.38
COURVOIS
IER
V.S.COGNAC
-750
ML
ALLIE
DDOM
ECQ
BRANDY
0.0637
E&
JCAL.BRANDY
-1.75
LTR
E.AND
J.GALLO
BRANDY
16.04
JACQUIN
’SBLACKBERRY
FLAV.BRANDY
-1.75
LTR
JACQUIN
BRANDY
0.0742
THE
CHRIS
TIA
NBROS.CAL.BRANDY
-375
ML
HEAVEN
HIL
LBRANDY
24.19
JACQUIN
’SBLACKBERRY
FLAV.BRANDY
-1.75
LTR
JACQUIN
BRANDY
0.0685
THE
CHRIS
TIA
NBROS.CAL.BRANDY
-750
ML
HEAVEN
HIL
LBRANDY
15.57
HENNESSY
V.S.COGNAC
-750
ML
MOET
HENNESSY
BRANDY
0.0900
JACQUIN
’SBLACKBERRY
FLAV.BRANDY
-1.75
LTR
JACQUIN
BRANDY
16.92
THE
CHRIS
TIA
NBROS.CAL.BRANDY
-1.75
LTR
HEAVEN
HIL
LBRANDY
0.0512
BAIL
EYS
IRIS
HCREAM
LIQ
UEUR
-375
ML
DIA
GEO
CORDIA
LS
13.80
SOUTHERN
COM
FORT
-76
PROOF
-1.75
LTR
BROW
NCORDIA
LS
0.0616
KAHLUA
IMP.COFFEE
LIQ
UEUR
-750
ML
ALLIE
DDOM
ECQ
CORDIA
LS
4.35
BAIL
EYS
IRIS
HCREAM
LIQ
UEUR
-750
ML
DIA
GEO
CORDIA
LS
0.0824
SOUTHERN
COM
FORT
-76
PROOF
-1.75
LTR
BROW
NCORDIA
LS
5.25
KAHLUA
IMP.COFFEE
LIQ
UEUR
-1.75
LTR
ALLIE
DDOM
ECQ
CORDIA
LS
0.0437
KAHLUA
IMP.COFFEE
LIQ
UEUR
-375
ML
ALLIE
DDOM
ECQ
CORDIA
LS
13.07
SOUTHERN
COM
FORT
-76
PROOF
-1.75
LTR
BROW
NCORDIA
LS
0.0630
SOUTHERN
COM
FORT
-76
PROOF
-750
ML
BROW
NCORDIA
LS
5.00
KAHLUA
IMP.COFFEE
LIQ
UEUR
-750
ML
ALLIE
DDOM
ECQ
CORDIA
LS
0.0633
DEKUYPER
PEACHTREE
SCHNAPPS
-1.75
LTR
BEAM
INC
CORDIA
LS
9.27
SOUTHERN
COM
FORT
-76
PROOF
-1.75
LTR
BROW
NCORDIA
LS
0.0858
JAGERM
EIS
TER
IMP.HERB
LIQ
UEUR
-375
ML
MAST-J
AGR
CORDIA
LS
9.89
SOUTHERN
COM
FORT
-76
PROOF
-1.75
LTR
BROW
NCORDIA
LS
0.0691
BAIL
EYS
IRIS
HCREAM
LIQ
UEUR
-750
ML
DIA
GEO
CORDIA
LS
4.42
KAHLUA
IMP.COFFEE
LIQ
UEUR
-750
ML
ALLIE
DDOM
ECQ
CORDIA
LS
0.0973
KAHLUA
IMP.COFFEE
LIQ
UEUR
-1.75
LTR
ALLIE
DDOM
ECQ
CORDIA
LS
5.19
SOUTHERN
COM
FORT
-76
PROOF
-1.75
LTR
BROW
NCORDIA
LS
0.0871
SEAGRAM
’SEXTRA
DRY
GIN
-375
ML
PERNOD
RIC
ARD
GIN
32.68
GORDON’S
DRY
GIN
-1.75
LTR
DIA
GEO
GIN
0.0798
TANQUERAY
IMP.DRY
GIN
-750
ML
DIA
GEO
GIN
15.47
BOM
BAY
IMP.SAPPHIR
EGIN
-750
ML
BACARDI
GIN
0.0452
GORDON’S
DRY
GIN
-1.75
LTR
DIA
GEO
GIN
18.57
TANQUERAY
IMP.DRY
GIN
-1.75
LTR
DIA
GEO
GIN
0.0581
TANQUERAY
IMP.DRY
GIN
-375
ML
DIA
GEO
GIN
24.24
GORDON’S
DRY
GIN
-1.75
LTR
DIA
GEO
GIN
0.0818
SEAGRAM
’SEXTRA
DRY
GIN
-750
ML
PERNOD
RIC
ARD
GIN
12.29
TANQUERAY
IMP.DRY
GIN
-750
ML
DIA
GEO
GIN
0.0651
BANKER’S
CLUB
DRY
GIN
-1.75
LTR
LAIR
DGIN
24.33
GORDON’S
DRY
GIN
-1.75
LTR
DIA
GEO
GIN
0.0831
GORDON’S
DRY
GIN
-PET
-375
ML
DIA
GEO
GIN
28.30
GORDON’S
DRY
GIN
-1.75
LTR
DIA
GEO
GIN
0.0859
GORDON’S
DRY
GIN
-750
ML
DIA
GEO
GIN
12.41
SEAGRAM
’SEXTRA
DRY
GIN
-750
ML
PERNOD
RIC
ARD
GIN
0.0675
SEAGRAM
’SEXTRA
DRY
GIN
-1.75
LTR
PERNOD
RIC
ARD
GIN
19.61
GORDON’S
DRY
GIN
-1.75
LTR
DIA
GEO
GIN
0.0812
BACARDILIG
HT-D
RY
P.R.RUM
-375
ML
BACARDI
RUM
21.24
BACARDILIG
HT-D
RY
P.R.RUM
-1.75
LTR
BACARDI
RUM
0.1226
CAPTAIN
MORGAN
P.R.SPIC
ED
RUM
-750
ML
DIA
GEO
RUM
5.59
BACARDILIG
HT-D
RY
P.R.RUM
-750
ML
BACARDI
RUM
0.0757
BACARDILIG
HT-D
RY
P.R.RUM
-1.75
LTR
BACARDI
RUM
10.15
CAPTAIN
MORGAN
P.R.SPIC
ED
RUM
-1.75
LTR
DIA
GEO
RUM
0.1360
CAPTAIN
MORGAN
P.R.SPIC
ED
RUM
-375
ML
DIA
GEO
RUM
22.61
BACARDILIG
HT-D
RY
P.R.RUM
-1.75
LTR
BACARDI
RUM
0.1223
BACARDILIG
HT-D
RY
P.R.RUM
-750
ML
BACARDI
RUM
6.86
CAPTAIN
MORGAN
P.R.SPIC
ED
RUM
-750
ML
DIA
GEO
RUM
0.1249
CAPTAIN
MORGAN
P.R.SPIC
ED
RUM
-1.75
LTR
DIA
GEO
RUM
9.33
BACARDILIG
HT-D
RY
P.R.RUM
-1.75
LTR
BACARDI
RUM
0.1403
BACARDILIM
ON
P.R.RUM
-375
ML
BACARDI
RUM
23.32
BACARDILIG
HT-D
RY
P.R.RUM
-1.75
LTR
BACARDI
RUM
0.1286
CAPTAIN
MORGAN
P.R.SPIC
ED
RUM
PET
-750
ML
DIA
GEO
RUM
6.40
CAPTAIN
MORGAN
P.R.SPIC
ED
RUM
-750
ML
DIA
GEO
RUM
0.1316
JACQUIN
’SW
HIT
ERUM
-1.75
LTR
JACQUIN
RUM
15.33
BACARDILIG
HT-D
RY
P.R.RUM
-1.75
LTR
BACARDI
RUM
0.1391
NIK
OLAIVODKA
-80
PROOF
-375
ML
SAZERAC
VODKA
17.25
JACQUIN
’SVODKA
ROYALE
-80
PROOF
-1.75
LTR
JACQUIN
VODKA
0.0559
ABSOLUT
IMP.VODKA
-80
PROOF
-750
ML
V&S
SPIR
ITS
VODKA
4.50
GREY
GOOSE
IMP.VODKA
-750
ML
SID
NEY
FRANK
VODKA
0.0882
JACQUIN
’SVODKA
ROYALE
-80
PROOF
-1.75
LTR
JACQUIN
VODKA
11.71
NIK
OLAIVODKA
-80
PROOF
-1.75
LTR
SAZERAC
VODKA
0.0391
JACQUIN
’SVODKA
ROYALE
-80
PROOF
-375
ML
JACQUIN
VODKA
17.53
JACQUIN
’SVODKA
ROYALE
-80
PROOF
-1.75
LTR
JACQUIN
VODKA
0.0564
SM
IRNOFF
VODKA
-80
PF.PORTABLE
-750
ML
DIA
GEO
VODKA
5.35
ABSOLUT
IMP.VODKA
-80
PROOF
-750
ML
V&S
SPIR
ITS
VODKA
0.1435
NIK
OLAIVODKA
-80
PROOF
-1.75
LTR
SAZERAC
VODKA
11.84
JACQUIN
’SVODKA
ROYALE
-80
PROOF
-1.75
LTR
JACQUIN
VODKA
0.0536
SM
IRNOFF
VODKA
-80
PROOF
-375
ML
DIA
GEO
VODKA
16.10
JACQUIN
’SVODKA
ROYALE
-80
PROOF
-1.75
LTR
JACQUIN
VODKA
0.0550
SM
IRNOFF
VODKA
-80
PROOF
-750
ML
DIA
GEO
VODKA
5.49
ABSOLUT
IMP.VODKA
-80
PROOF
-750
ML
V&S
SPIR
ITS
VODKA
0.1434
BANKER’S
CLUB
VODKA
-1.75
LTR
LAIR
DVODKA
12.73
JACQUIN
’SVODKA
ROYALE
-80
PROOF
-1.75
LTR
JACQUIN
VODKA
0.0544
JACK
DANIE
L’S
OLD
NO.7-375
ML
BROW
NW
HIS
KEY
11.33
WIN
DSOR
CANADIA
NSUPREM
EW
KY.-1.75
LTR
BEAM
INC
WHIS
KEY
0.0574
JACK
DANIE
L’S
OLD
NO.7-750
ML
BROW
NW
HIS
KEY
3.22
CROW
NROYAL
CANADIA
NW
KY.-750
ML
DIA
GEO
WHIS
KEY
0.0431
WIN
DSOR
CANADIA
NSUPREM
EW
KY.-1.75
LTR
BEAM
INC
WHIS
KEY
8.14
JIM
BEAM
STR.BOURBON
WKY.-1.75
LTR
BEAM
INC
WHIS
KEY
0.0495
CROW
NROYAL
CANADIA
NW
KY.-375
ML
DIA
GEO
WHIS
KEY
10.92
WIN
DSOR
CANADIA
NSUPREM
EW
KY.-1.75
LTR
BEAM
INC
WHIS
KEY
0.0584
JIM
BEAM
STR.BOURBON
WKY.-750
ML
BEAM
INC
WHIS
KEY
3.80
JACK
DANIE
L’S
OLD
NO.7-750
ML
BROW
NW
HIS
KEY
0.0849
JIM
BEAM
STR.BOURBON
WKY.-1.75
LTR
BEAM
INC
WHIS
KEY
7.40
WIN
DSOR
CANADIA
NSUPREM
EW
KY.-1.75
LTR
BEAM
INC
WHIS
KEY
0.0552
WIN
DSOR
CANADIA
NSUPREM
EW
KY.-375
ML
BEAM
INC
WHIS
KEY
13.25
WIN
DSOR
CANADIA
NSUPREM
EW
KY.-1.75
LTR
BEAM
INC
WHIS
KEY
0.0572
CROW
NROYAL
CANADIA
NW
KY.-750
ML
DIA
GEO
WHIS
KEY
3.40
JACK
DANIE
L’S
OLD
NO.7-750
ML
BROW
NW
HIS
KEY
0.0864
SEAGRAM
’S7
CROW
NW
KY.-1.75
LTR
DIA
GEO
WHIS
KEY
8.20
WIN
DSOR
CANADIA
NSUPREM
EW
KY.-1.75
LTR
BEAM
INC
WHIS
KEY
0.0569
Note
s:T
ab
lep
rese
nts
the
thre
eb
est-
sellin
gp
rod
uct
sby
nu
mb
erof
bott
les
for
each
spir
itty
pe,
bott
lesi
zep
air
,an
dth
eco
rres
pon
din
gb
est
sub
stit
ute
base
don
cross
-pri
ceel
ast
icit
y.“R
ati
o”
isth
era
tio
of
the
aver
age
cross
-pri
ceel
ast
icit
yb
etw
een
the
pro
du
ctan
dp
rod
uct
sof
its
spir
itty
pe
toth
eaver
age
cross
-pri
ceel
ast
icit
yb
etw
een
the
pro
du
ctan
dp
rod
uct
sou
tsid
eth
eit
ssp
irit
typ
e.
– xi –
E Detailed Counterfactual Results
Table E.I: Maximizing Tax Revenue and Regulator Foresight (Detail)
Distiller Response Stackelberg
Current Naıve Base Product Monopoly Base Product Monopoly
Markup (%) 53.40 30.68 30.68 30.68 30.68 39.31 39.18 42.07
Distiller Price ($) 9.08 9.08 9.42 9.33 10.27 9.28 9.19 9.99
- 375 ml 4.99 4.99 5.32 5.24 5.94 5.18 5.11 5.68- 750 ml 8.48 8.48 8.82 8.72 9.79 8.68 8.59 9.49- 1.75 L 12.22 12.22 12.58 12.51 13.34 12.43 12.37 13.06- brandy 8.43 8.43 8.75 8.66 9.52 8.61 8.53 9.25- cordials 8.20 8.20 8.54 8.48 9.42 8.40 8.34 9.14- gin 8.79 8.79 9.13 9.05 9.89 8.99 8.91 9.62- rum 7.88 7.88 8.23 8.09 9.06 8.09 7.95 8.77- vodka 9.92 9.92 10.28 10.17 11.17 10.13 10.03 10.87- whiskey 9.86 9.86 10.21 10.13 11.07 10.06 10.00 10.79
Distiller Profits ($M) 155.20 234.85 242.45 234.36 291.79 202.99 196.47 233.26
- Diageo 36.10 56.67 58.32 54.79 69.71 48.22 45.26 54.81- Bacardi 14.35 22.69 23.38 22.16 27.89 19.26 18.23 21.82- Beam 15.10 21.78 22.45 21.76 26.77 19.20 18.63 22.01
Retail Price ($) 15.44 13.37 13.82 13.71 14.94 14.44 14.31 15.70
- 375 ml 8.89 7.76 8.20 8.08 9.00 8.46 8.35 9.31- 750 ml 14.43 12.50 12.94 12.81 14.22 13.51 13.37 14.90- 1.75 L 20.58 17.80 18.26 18.17 19.26 19.14 19.04 20.39- brandy 14.40 12.48 12.89 12.78 13.90 13.46 13.34 14.61- cordials 13.98 12.12 12.56 12.48 13.71 13.10 13.01 14.38- gin 15.03 13.04 13.48 13.37 14.48 14.07 13.96 15.22- rum 13.61 11.82 12.28 12.09 13.36 12.79 12.59 13.98- vodka 16.77 14.52 14.98 14.84 16.15 15.66 15.51 17.00- whiskey 16.69 14.45 14.90 14.81 16.04 15.58 15.48 16.89
Consumption (M)
- Liters 62.67 96.91 88.53 90.55 71.85 77.24 79.15 60.60- Bottles 60.31 88.96 81.17 83.26 65.20 72.14 74.11 56.40
Tax Revenue ($M) 370.84 399.58 374.57 381.16 318.26 379.12 385.64 324.87
Notes: Retail price formula is “pr = pw× markup + unit fee” where we adjust both the markup and the unit fees to include the18% Johnstown Flood tax. “Response” and “Stackelberg” equilibria based on estimates of upstream marginal costs consistentwith the relevant conduct assumption. We estimate unreported distiller profits of $150.8 million and $193.8 million under“Product” and “Monopoly”, respectively.
E.1 Laffer Curves and Demographics
Here, we assess differences in the Laffer curve across different consumer groups. We do so by
decomposing the aggregate Naıve and “Base Response” Laffer curves of Figure 5. As in the text,
we consider alternative tax rates and, in the case of the “Base Response” equilibrium, wholesale
price responses to those tax rates that maximize aggregate distiller profit across all Pennsylvania
markets. We then consider purchase behavior under the implied retail prices in the bottom and
top quintile of markets for the pertinent demographic attributes. Lastly, we plot in Figure E.1 the
tax revenue the PLCB would realize from these purchases in the selected bottom and top markets
under varying tax rates, and indicate the tax rate that would maximize tax revenue in the select
set of markets. Results indicate that the negative trade-off between tax rate τ and tax revenues is
a common feature that affects the tax revenue collected from all demographic traits.
– xii –
Figure E.1: Laffer Curves Across Demographic Groups
2030405060708090
100110120
Dol
lars
(in
Mill
ons)
10 15 20 25 30 35 40 45 50 55 60 65 70 75 80 85 90
PLCB Tax Rate (%)
Low - Naive (29%) High - Naive (37%)Low - Response (38%) High - Response (45%)
Laffer Curve - PLCB
(a) Income
2030405060708090
100110120
Dol
lars
(in
Mill
ons)
10 15 20 25 30 35 40 45 50 55 60 65 70 75 80 85 90
PLCB Tax Rate (%)
Low - Naive (28%) High - Naive (37%)Low - Response (37%) High - Response (45%)
Laffer Curve - PLCB
(b) Education
2030405060708090
100110120
Dol
lars
(in
Mill
ons)
10 15 20 25 30 35 40 45 50 55 60 65 70 75 80 85 90
PLCB Tax Rate (%)
Low - Naive (29%) High - Naive (31%)Low - Response (37%) High - Response (40%)
Laffer Curve - PLCB
(c) Minority
2030405060708090
100110120
Dol
lars
(in
Mill
ons)
10 15 20 25 30 35 40 45 50 55 60 65 70 75 80 85 90
PLCB Tax Rate (%)
Low - Naive (35%) High - Naive (32%)Low - Response (44%) High - Response (41%)
Laffer Curve - PLCB
(d) Young
Notes: The x-axis for each graph is the PLCB ad valorem tax rate (%) including the 18% Johnstown Flood tax. The verticalline corresponds to the current policy. Demographic categories are defined in Section 3.4. “High” refers to markets in the top20% while “Low” refers to markets in the bottom 20% for the corresponding demographic trait. Revenue-maximizing tax ratefor each demographic sub-group indicated in parentheses.
– xiii –