2. Conceptual FrameworkFootnote ¹

Equation (1) is formulated to present the relationship in which companies increase product sales by increasing market participation of the product and/or sales to existing customers:

(1) $$\begin{equation} \frac{q}{N} = \frac{q}{{NB}}.\frac{{NB}}{N}, \end{equation}$$

where q is quantity consumed, N is the number of potential customers, and NB is the number of actual consumers. Therefore, $\frac{q}{N}$ means consumption per capita; $\frac{q}{{NB}}$ is consumption intensity of existing consumers, or the average weight of purchase (awp); and $\frac{{NB}}{N}$ is the ratio of actual consumers to total potential consumers, or market participation (mp). Per capita consumption, therefore, equals awp multiplied by mp.

Consumption intensity and market participation could both be influenced by the same factors—namely, price (p), consumer income (y), and advertising (a), which is illustrated by

(2) $$\begin{equation} \frac{q}{{NB}} \equiv awp = f(p,y,a)\\ \end{equation}$$

(3) $$\begin{equation} \frac{{NB}}{N} \equiv mp = g(p,y,a). \end{equation}$$

Taking the logarithmic total differential of equations (1) to (3) yields:

(4) $$\begin{equation} d\ln \frac{q}{N} = d\ln awp + d\ln mp\\ \end{equation}$$

(5) $$\begin{equation} d\ln awp = {\alpha _p}d\ln p + {\alpha _y}d\ln y + {\alpha _a}d\ln a\\ \end{equation}$$

(6) $$\begin{equation} d\ln mp = {\beta _p}d\ln p + {\beta _y}d\ln y + {\beta _a}d\ln a, \end{equation}$$

(7) $$\begin{equation} d\ln \frac{q}{N} = {\eta _p}d\ln p + {\eta _y}d\ln y + {\eta _a}d\ln a, \end{equation}$$

where η_p, η_y, and η_a are elasticities of market demand with respect to price, income, and advertising, respectively. These elasticities conform to the following identities:

(8a) $$\begin{equation} {\eta _p} = {\alpha _p} + {\beta _p}\\ \end{equation}$$

(8b) $$\begin{equation} {\eta _y} = {\alpha _y} + {\beta _y}\\ \end{equation}$$

(8c) $$\begin{equation} {\eta _a} = {\alpha _a} + {\beta _a}. \end{equation}$$

Equations (8a)–(8c) indicate that the elasticity of demand with respect to any demand shifter i (i.e., price, income, or advertising) is the sum of the corresponding elasticity of consumption intensity (α_i) and market participation (β_i). Thus, given the estimates of any two of the elasticities in equations (8a)–(8c), the third elasticity can be obtained by addition or subtraction. For example, given estimates of consumption intensity elasticity α_i and market participation elasticity β_i, market demand elasticity η_i can obtained by addition. Furthermore, it can be implied that that if α_i > β_i, this suggests that marketers should focus on persuading current consumers to buy more. On the other hand, if α_i < β_i, it suggests that market strategies aimed at attracting new customers will be more effective. The elasticities in equations (5)–(7) will be estimated using the Rotterdam model.

3. Extended Rotterdam Model

The Rotterdam demand model (Barten, Reference Barten1964, Reference Barten1968, Reference Barten1977; Theil, Reference Theil1965, Reference Theil1975, Reference Theil1976) was selected because it allows us to implement both awp and mp as dependent variables in replacement of quantity. A similar extension of the AIDS model (Deaton and Muellbauer, Reference Deaton and Muellbauer1980) is not as straightforward. Following Brown and Lee (Reference Brown and Lee2010), the basic specification of the Rotterdam model incorporating advertising is

(9) $$\begin{equation} {w_i}d\ln {q_i} = {\delta _i} + {\theta _i}d\ln Q + \sum\nolimits_j {{\pi _{ij}}} d\ln {p_j} + \sum\nolimits_j {{\omega _{ij}}} d\ln {a_j}\quad i = 1, \ldots ,n, \end{equation}$$

where the preference variable z in Brown and Lee (Reference Brown and Lee2010) is redefined here to be advertising (a_j); while n is the number of goods in the system, and i indexes the equation. Here, ${w_i} = {{{p_i}{q_i}} / x}$ is the budget share for good i;p_i and q_i are market price and per capita consumption for good i; dln Q = ∑ⁿ_{i = 1}w_idln q_i is the Divisia volume index to measure the effect of real income; and θ_i = p_i(∂q_i/∂x) is the marginal propensity to consume the good i. π_ij = (p_ip_j/x)s_ij is the Slutsky coefficient, where s_ij = (∂q_i/∂p_j + q_j∂q_i/∂x). This implies that the elasticities estimated by the Rotterdam model are Hicksian elasticities, or, in other words, compensated elasticities.

Substituting equation (4) into equation (9) results in

(10) $$\begin{equation} {w_i}(d\ln aw{p_i} + d\ln m{p_i}) = {\delta _i} + {\theta _i}d\ln Q + \sum\nolimits_j {{\pi _{ij}}} d\ln {p_j} + \sum\nolimits_j {{\omega _{ij}}} d\ln {a_j}. \end{equation}$$

Therefore, the Rotterdam model can be further decomposed to distinguish consumption intensity (awp) and market participation (mp) as separate dependent variables:

(11) $$\begin{eqnarray} {w_i}d\ln aw{p_i} & =& {\xi _{1i}} + {\vartheta _{1i}}d\ln \,Q + \sum\nolimits_j {\sigma {}_{1ij}} d\ln {p_j} + \sum\nolimits_j {\gamma {}_{1ij}} d\ln {a_j}\nonumber\\ {w_i}d\ln m{p_i} & =& {\xi _{2i}} + {\vartheta _{2i}}d\ln \,Q + \sum\nolimits_j {\sigma {}_{2ij}} d\ln {p_j} + \sum\nolimits_j {\gamma {}_{2ij}} d\ln {a_j}. \end{eqnarray}$$

In the Rotterdam model, corresponding elasticities are calculated by the estimated parameters divided by the mean of the market share of good i in each equation. Hence the elasticities presented by equations (8a)–(8c) imply that the parameters in equation (10) and equation (11) have the following relationships:

(12a) $$\begin{equation} {\pi _{ij}} = {\sigma _{1ij}} + {\sigma _{2ij}}\quad \quad i = 1,2,...,n\,{\rm{and}}\,j = 1,2,...,n\\ \end{equation}$$

(12b) $$\begin{equation} {\theta _i} = {\vartheta _{1i}} + {\vartheta _{2i}}\\ \end{equation}$$

(12c) $$\begin{equation} {\omega _i}_j = {\gamma _{1ij}} + {\gamma _{2ij}}. \end{equation}$$

Theory implies that the restrictions on the price and expenditure parameters in equation (10) are as follows (Brown and Lee, Reference Brown and Lee2010):

(13) $$\begin{eqnarray} \sum\limits_{j = 1}^n {\pi _{ij}} & =& 0\quad \quad i = 1,2,...,n\,\left( {\hbox{Price homogeneity}} \right)\nonumber\\ \pi _{ij} & =& {\pi _{ji\,}}\quad i \ne j\,\left( {\hbox{Price symmetry}} \right)\nonumber\\ \sum\limits_{i = 1}^n {{\theta _i}} & =& 1,\,\sum\limits_{i = 1}^n {{\pi _{ij}}} = 1,\,{\rm and}\,\sum\limits_{i = 1}^n {{\omega _{ij}}} = 1\quad j = 1,2,...,n\,\left( {{\hbox{Adding up}}} \right)\!, \end{eqnarray}$$

where the advertising coefficients also conform to the adding-up restriction, because in order to satisfy the budget constraint, demand increase for some goods because of advertising must be offset by the demand decrease for other goods (Brown and Lee, Reference Brown and Lee2010, p. 889). Brown and Lee (Reference Brown and Lee2010) have also used Tintner-Ichimura-Basmann relationship as a source of restrictions on preference variables (Basmann, Reference Basmann1956; Ichimura Reference Ichimura1950–1951; Tintner, Reference Tintner1952). However, we did not impose these restrictions because different from Brown and Lee (Reference Brown and Lee2010) whereby advertising is assumed to affect demand by raising the marginal utility of the ith goods and therefore advertising enters the demand system as a modifier of the price terms (Xie, Myrland, and Kinnucan, Reference Xie, Myrland and Kinnucan2009), we have followed Xie, Myrland, and Kinnucan (Reference Xie, Myrland and Kinnucan2009) to assume advertising to affect the “baseline” pattern of consumption. Therefore, advertising was incorporated into the model via modification of the intercept terms.

Parameter relationships illustrated by equations (12a)–(12c) imply the corresponding theoretical restrictions in the awp and mp equation (11):

(14) $$\begin{eqnarray} \sum\limits_{j = 1}^n {({\sigma _{1ij}} + {\sigma _{2ij}} )} &=& 0\quad i = 1,2,3\left( {{\hbox{Price homogeneity}}} \right)\nonumber\\ {\sigma _{1ij}} + {\sigma _{2ij}} &=& {\sigma _{1ji}} + {\sigma _{2ji}}\,\left( {{\hbox{Price symmetry}}} \right)\nonumber\nonumber\\ \sum\limits_{i = 1}^n {({\sigma _{1ij}} + {\sigma _{2ij}})} &=& 1\quad j = 1,2,3\nonumber\\ \sum\limits_{i = 1}^n {({\vartheta _{1i}} + {\vartheta _{2i}} )} &=& 1\nonumber\\ \sum\limits_{i = 1}^n {({\gamma _{1ij}} + {\gamma _{2ij}})} &=& 1\,( {{\hbox{Adding up}}}). \end{eqnarray}$$

Elasticities are calculated using the following formulas:

(15) $$\begin{eqnarray} e_{ii}^{awp} &=& {\sigma _{1ii}}/{w_i}\quad \quad e_{ij}^{awp} = {\sigma _{1ij}}/{w_i}\,\left( {{\hbox{Price elasticities of}}\,awp} \right)\nonumber\\ e_i^{awp} &=& {\vartheta _{1i}}/{w_i}\,\left( {{\hbox{Expenditure elasticities of}}\,awp} \right)\nonumber\\ ADV_{ij}^{awp} &=& {\gamma _{1il}}/{w_i}\,\left( {{\hbox{Advertising elasticities of}}\,awp} \right)\nonumber\\ e_{ii}^{pene} &=& {\sigma _{2ii}}/{w_i}\quad e_{ij}^{pene} = {\sigma _{2ij}}/{w_i}\,\left( {{\hbox{Price elasticities of}}\,mp} \right)\nonumber\\ e_i^{pene} &=& {\vartheta _{2i}}/{w_i}\,\left( {{\hbox{Expenditure elasticity of}}\,mp} \right)\nonumber\\ ADV_{ij}^{pene} &=& {\gamma _{2ij}}/{w_i}\,\left( {{\hbox{Advertising elasticities of}}\,mp} \right)\nonumber\\ e_{ii}^* &=& ({\sigma _{1ii}} + {\sigma _{2ii}})/{w_i}\quad \quad e_{ij}^* = ({\sigma _{1ij}} + {\sigma _{2ij}})/{w_i}\,\left( {{\hbox{Price elasticity of demand}}} \right)\nonumber\\ e_i^* &=& ({\vartheta _{1ij}} + {\vartheta _{2ij}})/{w_i}\,\left( {{\hbox{Expenditure elasticity of demand}}} \right)\nonumber\\ ADV_{ij}^{} &=& ({\gamma _{1ij}} + {\gamma _{2ij}})/{w_i}\,\left( {{\hbox{Advertising elasticity of demand}}} \right). \end{eqnarray}$$

4. Empirical Specification

The extended Rotterdam model will be applied to monthly household data of salmon consumption in France from 2006 through 2009. A dominant share of salmon in the French market is farmed Atlantic salmon. One important advantage of fish farming over capture fisheries is its ability to pace harvests in response to expected changes in price and costs. The greater flexibility in harvesting suggests an elastic supply. A Hausman test conducted by Xie, Myrland, and Kinnucan (Reference Xie, Myrland and Kinnucan2009) affirms the hypothesis that global salmon prices in a monthly model are predetermined. Moreover, France is just one segment of the world's salmon market. The supply to the French market is therefore more elastic. A large share of the smoked salmon in France is processed in eastern European countries by using raw fish imported from Norway, Scotland, and the Faroe Islands. When raw fish is farmed, and processed smoked salmon can be put in stock for a much longer period than fresh salmon, we think the price of smoked salmon is predetermined as well. We therefore assume the salmon prices in our study to be predetermined, and the ordinary Rotterdam model can be applied.

In the empirical model, we have n = 3 to index demand for fresh salmon, frozen salmon, and smoked salmon, respectively. In each equation, a single advertising variable is specified because among the main salmon producers/exporters, only the Norwegian salmon industry has promoted its product category through generic advertising. Advertising incorporated into the model is the expenditure of the generic advertising conducted by the NSC.

A large body of literature suggests that both current and past advertising efforts affect the purchase behaviors of consumers (e.g., Forker and Ward, Reference Forker and Ward1993; Schmit et al., Reference Schmit, Dong, Chung, Kaiser and Gould2002). At the same time, seasonality needs to be taken into account when monthly data are used. To conserve degrees of freedom and to mitigate any multicollinearity problems among the lagged advertising variables, the lag structure for advertising is constrained to follow a second-degree polynomial distribution (PDL) (Schmit et al., Reference Schmit, Dong, Chung, Kaiser and Gould2002), and seasonality is modeled by using harmonic variables (Doran and Quilkey, Reference Doran and Quilkey1972). The empirical modes to be estimated finally take the following form:

(16) $$\begin{eqnarray} {w_i}d\ln {q_{i,t}} &=& {\delta _i} + {\theta _i}d\ln {Q_t} + \sum\limits_{j = 1}^3 {{\pi _{ij}}} d\ln {p_{j,t}} + \sum\limits_{m = 0}^2 {{\tau _{im}}d\ln {z_{m,t}}}\nonumber\\ && +\, {h_{i1}}{H_{11,t}} + {h_{i2}}{H_{12,t}} + {h_{i3}}{H_{21,t}} + {\varepsilon _{i,t}}\nonumber\\ {w_i}d\ln aw{p_{i,t}} &=& {\xi _{1i}} + {\vartheta _{1i}}\,d\ln \,{Q_t} + \sum\limits_{j = 1}^3 {{\sigma _{1ij}}} d\ln {p_{j,t}} + \sum\limits_{m = 0}^2 {{\varphi _{1im}}} d\ln {z_{m,t}}\nonumber\\ && +\, {h_{1i1}}{H_{11,t}} + {h_{1i2}}{H_{12,t}} + {h_{1i3}}{H_{21,t}} + {\varepsilon _{1i,t}}\nonumber\\ {w_i}d\ln m{p_{i,t}} &=& {\xi _{2i}} + {\vartheta _{2i}}\,d\ln \,{Q_t} + \sum\limits_{j = 1}^3 {{\sigma _{2ij}}} d\ln {p_{j,t}} + \sum\limits_{m = 0}^2 {{\varphi _{2im}}} d\ln {z_{m,t}}\nonumber\\ && + {h_{2i1}}{H_{11,t}} + {h_{2i2}}{H_{12,t}} + {h_{2i3}}{H_{21,t}} + {\varepsilon _{2i,t}}\quad i = \ 1,{\rm{ }}2,{\rm{ }}3, \end{eqnarray}$$

where dln z _{m, t} are the advertising variables computed by using the PDL structure. The Appendix illustrates how these advertising variables were constructed. H _{11, t}, H _{12, t}, and H _{21, t} are the harmonic variables, calculated as follows (Doran and Quilkey, Reference Doran and Quilkey1972; Gould, Cox, and Perali, Reference Gould, Cox and Perali1991):

(17) $$\begin{eqnarray} {H_{1kt}} &=& COS({\lambda _k}t)\quad (k = 1,{\rm{ }}2)\ \quad t = \left( {1, \ldots ,T}\right)\!,\nonumber\\ {H_{21t}} &=& SIN({\lambda _1}t), \end{eqnarray}$$

where

$$\begin{equation*} {\lambda _k} = 2\pi k/13\,\left( {{\rm{k}} = 1,{\rm{ }}2} \right)\!. \end{equation*}$$

The estimated φ_1im and φ_2im are used to solve back for parameters γ_1il and γ_2il according to equation (A-7) in the Appendix, where γ_1il and γ_2il are the current and lag-period effects of advertising on consumption intensity and market participation, respectively.

The corresponding advertising elasticities are calculated using the following formulas:

(18) $$\begin{eqnarray} ADV_{il}^{awp} &=& {\gamma _{1il}}/{w_i}\quad l = 0,1,...,13\,\left( {{\hbox{Short-run advertising elasticities of}}\,awp} \right)\nonumber\\ ADV_{il}^{pene} &=& {\gamma _{2il}}/{w_i}\,\left( {{\hbox{Short-run advertising elasticities of}}\,mp} \right)\nonumber\\ ADV_{il}^{} &=& ({\gamma _{1il}} + {\gamma _{2il}})/{w_i}\,\left( {{\hbox{Short-run advertising elasticity of demand}}} \right)\nonumber\\ ADV_i^{awp} &=& \sum\limits_{l = 0}^{13} {{\gamma _{1il}}} /{w_i}\quad l = 0,1,...,13\,( {{\hbox{Long-run advertising elasticities of }}}\nonumber\\ && {awp} )\nonumber\\ ADV_i^{pene} &=& \sum\limits_{l = 0}^{13} {{\gamma _{2il}}} /{w_i}\,\left( {{\hbox{Long-run advertising elasticities of }}mp} \right)\nonumber\\ ADV_i^{} &=& \sum\limits_{l = 0}^{13} {({\gamma _{1il}} + {\gamma _{2il}}} )/{w_i}\,\left( {{\hbox{Long-run advertising elasticity of demand}}} \right).\nonumber\\ \end{eqnarray}$$

5. Data and Estimation Procedure

Europanel is a global partnership venture between GFK Panel Services and Kantar Worldpanel, two of the world's largest marketing information companies (Europanel, 2016). A data set of the French household purchase of salmon products between 2006:1 and 2009:13 was provided by Europanel via NSC. The data presented have been grossed by Europanel to the total population on a “monthly” level, with 4 weeks in a month. Therefore, there are 13 such “months” in a year. The original data set has the purchase value in euro, quantity, average weight of purchase (awp), and market participation (mp). Prices were calculated by dividing value by quantity. Each year, 20,000 households were selected by Europanel to represent the entire population of France. These households were randomly selected after basic family characteristics such as income, education, age, family size, and district of residence were controlled for. These households were asked to report what they had purchased each shopping trip by immediately scanning their purchased items using the machines provided by Europanel at their homes. Europanel updated 25% of the households each year, and the remaining 75% would continue their reports in the following year (Europanel, 2014). Advertising data between January 2005 and December 2009 were provided by NSC. We adjusted the advertising expenditure of 13 “months” by moving the weekly averages into a calendar month. The reason for including advertising expenditures for 2005 was to account for carryover effects of advertising on consumer purchases.

Table 1 shows that the mean purchase quantity of salmon products per 4 weeks were 1,829 metric tons (mt) of fresh salmon, 1,425 tons of smoked salmon, and 738 tons of frozen salmon. Smoked salmon is the most expensive at €21.62/kg, followed by frozen salmon at €12.24/kg, and fresh salmon at €11.48/kg. These numbers yield the expenditure shares of smoked, fresh, and frozen salmon at 49%, 36%, and 15%, respectively. From Table 1, we can see that the market participation for smoked salmon is actually quite low; only 28%, compared with 78% for fresh salmon and 63% for frozen salmon. This means that the large market share of smoked salmon is mainly attributed to high purchase volume of existing consumers. The average per household purchase by existing consumers of smoked salmon is 19.10 kg in contrast to 8.92 kg for fresh salmon and 4.50 kg for frozen salmon. NSC has, on average, spent €136,289 per 4 weeks to promote Norwegian salmon in the French market.

Table 1. Descriptive Statistics of Variables

Estimation was conducted in five steps: (a) We estimated the awp and mp equations in equation (16) in one systemFootnote ² and quantity equations in another separate system. (b) The theoretical restrictions on both systems were then tested to see if they were compatible with the data. (c) The aforementioned two systems were reestimated with the theoretical restrictions imposed suggested by the test results. (d) The hypothesis of the parameter relationships between the two systems, presented by equations (12a)–(12c), were tested. (e) Finally, the elasticities in both the demand and the awp and mp systems were computed according to equations (15) and (18).

The models were estimated by statistical analysis software LIMDEP using seemingly unrelated regression (SUR) estimator. To avoid singularity in the variance-covariance matrix, in each of the three systems, first, the equation for fresh salmon was omitted. Then, to recover the parameters for the fresh salmon equation, we reestimated the systems with the equation for smoked salmon omitted. The results are identical if we recover the parameters in the fresh salmon equations by using the adding-up restriction specified in equation (14).

7. Concluding Remarks

In this study, the Rotterdam model is extended to permit separate estimates of how consumption intensity and market participation respond to price, income, and other demand determinants such as market promotion. Specifically, the dependent variable in the Rotterdam model is shown to consist of two additive components: the proportional change in the average product weight consumed by existing consumers and the proportional change in the share of total consumers in the market who actually purchase the product. By doing so, we can estimate how demand determinants affect purchases by current customers and potential customers, separately. When such data are available, the extended Rotterdam model is useful in revealing more detailed information about market structure and thus improving the efficacies of industries’ marketing strategies. For example, this model helps marketers understand whether they should concentrate their market strategies on persuading existing customers to purchase more or on attracting new customers.

Applying the extended model on the French household demand for salmon, we find that salmon prices overall are more significant in affecting customers’ market participation than in affecting how much existing customers buy. In the short run, the NSC advertised successfully, triggering an increased purchase amount by existing customers, but it was not successful in getting new customers. New customers are usually important for an industry to expand its market share; therefore, the results suggest that in addition to keeping the loyalty of old customers, the NSC should adjust its advertising strategies in order to attract new customers.

Our statements regarding the French salmon market are based on the following findings: First, seven price elasticities are significant in the market participation equations, versus only three in the consumption intensity equations (Table 8). Second, the magnitudes of the price elasticities in the market participation equations are generally larger than the magnitudes of the corresponding price elasticities in the consumer intensity equations. The estimated parameters to capture the short-term advertising effects in consumption intensity equations are statistically significant, versus the insignificant corresponding estimated parameters of advertising in the market participation equations.

Some caution should be taken when interpreting the results of the Norwegian advertising. First, although the advertising is found to have effects in the short run, we failed to identify its long-run effects. The demand models only capture how advertising affects the distribution of the French households’ demand for the different product forms in question, but do not capture the result regarding how the advertising might increase the French households’ total demand for salmon. Third, it is difficult to draw a conclusion about the effectiveness of generic advertising conducted by the NSC, even if this advertising has a positive effect on the French household demand for smoked salmon at the cost of fresh salmon. Because salmon industries in the EU import the fresh Norwegian salmon as raw material from which to produce smoked salmon, the net benefit of the Norwegian salmon industry from its own promotional activities in France depends on the relative proportion of the imported Norwegian fresh salmon used directly as household meals and as raw materials for smoked salmon processing.