Survey design

We designed our survey to randomize several aspects of a hypothetical ballot to causally test each of our hypotheses. We add to the existing literature to date by using a randomized survey experiment. Although the previous political science literature uses strong real-world natural experiments, those natural experiments have some limitations. Namely, they do not allow for a randomization of costs, only order and length, and are limited to studies in Texas. Additionally, they find conflicting evidence. Further, the economics data uses only observational data that may be correlated with observed and unobserved community factors. Certainly, randomized surveys have benefits and downsides. The benefit is that we can truly control and randomize all factors for which we are interested while taking into account unique effects for each factor for each bond issue we include. The downside is that people may behave differently on surveys than in the actual voting booth. Unfortunately, given there is no way to randomize bond amounts in the real world, a survey experiment is the best way to test our hypotheses.

First, to test the effect of bond order and the number of bonds on the ballot, we randomized whether the respondent was shown a ballot with one, three, or five referendums. If multiple referendums were present (ballot length three or five), the order of the referendums was randomly assigned. The referendums included five different program investment types that are common among real ballot propositions (especially in the location of our survey experiment): Land Conservation, Affordable Housing, K-12 School Construction, Higher Education Buildings Construction, and Transportation. We chose these topics to increase recognition of the policy proposals among participants to elicit more precise results by mirroring what would occur during an actual election. In addition, we wanted to include ballot issues that both tend to generate a large magnitude of support (e.g., Land Conservation, Transportation, and K-12 construction) and those that tend to be less popular (Affordable Housing and Higher Education) to make sure our results were not a product of choosing valence issues (e.g., Dyck and Pearson-Merkowitz Reference Dyck and Pearson-Merkowitz2019; Pearson-Merkowitz and Lang Reference Pearson-Merkowitz and Lang2020), or due to underlying popularity.

Ballots with only one bond presented were constrained to show only the Land Conservation Bond or the Affordable Housing Bond. Ballots with three referendums included both Land Conservation and Affordable Housing bonds, plus an additional randomly chosen third bond from the remaining three topics (K-12, Higher Ed, or Transportation). Ballots with five referendums included all five issues. Each of these configurations had a 25% chance of being shown to a respondent.

Each bond proposal included a randomly generated bond amount. Bond amounts included $20, $50, $100, $200, $300, and $500 million, with each amount equally likely to appear. We chose the dollar amounts based on historical amounts of bonds that appeared on Rhode Island ballots (the location of our survey experiment) in recent elections. Since 2010, 21 of the 23 bonds in the state on these topics were priced between $10 and $110 million and all passed. The two referendums outside of that range (both $250 million state school construction bonds) were also both successful.These amounts are also not outside the range voters in other states would see on the ballot. As we were trying to determine if the dollar amount is truly a factor, and as no bond had failed in recent history, we included bond amounts that were much larger than those typically put on the ballot. Below the bond title and amount was a brief description of what the money would be used for if approved, mimicking the way bonds typically appear on ballots in Rhode Island. For reference, Table 1 shows the possible levels that bond amount, type, number of bonds, and bond order could be presented given randomization of these variables. The respondents were shown the full ballot (all the bonds with their associated dollar amounts) on a single screen to mirror the paper ballot used in the state.

Table 1. Possible levels after randomization by variable type

Note. We present the possible levels for each variable after randomization took place. Each possible amount point had an equal chance of being randomly selected (17%). Each possible length had an equal chance of selection (25%). Conditional on length, the ordering was randomized equally. Ballots of length 1 had a 100% chance of order spot 1, ballots of length 3 had an equal 33% chance of being ordered anywhere in spots 1–3, and ballots of length 5 had an equal 20% chance of being ordered anywhere from 1 to 5.

Figure 1 shows a portion of a sample ballot from the 2018 Rhode Island General Election. We designed our hypothetical ballots to have similar layout and descriptions. Figure 2 presents the way a respondent would have seen the questions for three hypothetical ballots, with 1, 3, and 5 questions, respectively. Respondents who were only asked to vote on one question, would have seen the top box, respondents who were asked to vote on three bonds would have seen the second box, and respondents who were asked to vote on five bonds would have seen the bottom box. The entire ballot was visible on a single screen, mirroring Rhode Island’s paper ballot format (as seen in Figure 1), so participants could compare and contrast referendums and amounts as they normally could in the real-world. The wording and presentation of each ballot question was the same regardless of the number of bonds included on the ballot.

Figure 1. Sample Ballot from the 2018 Rhode Island General Election.

Figure 2. “How Would you Vote on the Following Bonds?” Example Ballots of Length 1, 3, and 5.

The remainder of the survey consisted of questions regarding standard demographics (age, race, education, income), political party affiliation, voting frequency, homeowner status, and city of residence which have been shown to affect bond referendum support in other studies (e.g., Brunner, Robbins, and Simonsen Reference Brunner, Robbins and Simonsen2021; Pearson-Merkowitz and Lang Reference Pearson-Merkowitz and Lang2020; Prendergast, Pearson-Merkowitz, and Lang Reference Prendergast, Pearson-Merkowitz and Lang2019).Footnote ³ These questions appeared after the respondent finalized their vote and had proceeded to the next page.

Data collection

We conducted the survey in the fall of 2019. The survey was administered at five of the six Department of Motor Vehicle (DMV) registries in the state of Rhode Island. Motor Vehicle Licensing offices have been shown to be effective locations for conducting intercept surveys among the general public (see for example, these studies also using the motor vehicle offices as a representative survey site: Borchers, Duke, and Parsons Reference Borchers, Duke and Parsons2007; Lang et al. Reference Lang, Weir and Pearson-Merkowitz2021; McGonagle and Swallow Reference McGonagle and Swallow2005). Most importantly, the DMV is an efficient way to reach a large number of people in one place, increasing the sample size, and it offers a broad swath of the population given there are a variety of tasks that require an in-person visit to the DMV. In our particular case, this helps reduce potential selection bias often associated with convenience sampling as all residents who drive or need a “walkers license” must visit the DMV. During this time, the DMV was also requiring people to upgrade to a REAL ID, which required an in-person visit instead of an online renewal.

Our research protocol was as follows: teams of two surveyors were stationed in the waiting room of DMV locations throughout the standard work week during open hours. Hours of operation for the DMV locations varied with the largest location open between 8 am and 6 pm Monday–Friday and satellite locations open limited hours and days. The surveyors were instructed to only survey visitors who had already checked in and were waiting for their number to be called. In addition, surveyors only asked prospective participants waiting in the standard waiting room locations. Surveyors approached and asked every person in each waiting room to participate in the survey. The potential respondents were asked if they would be willing to take a 5-minute, anonymous survey to be used for research purposes only. If the person gave verbal consent, they were offered a touchscreen tablet to take the survey. Respondents could omit responses if they felt inclined, but only after a prompt asked them if they wanted to continue with the survey and leave the question blank. If the respondent was under 18 years of age, they were stopped from taking the survey. All surveyors received extensive training in in-person survey methodology, interviewer bias, selection bias, and research ethics. We dropped observations that were missing responses to any of the bond or demographic questions, and those that completed the survey in under 1 minute as this likely means they were not engaging with the questions. After these exclusions, our final sample includes 732 respondents.

Table 2 presents summary data of the survey respondents, as well as statewide statistics from the 2018 American Community Survey (ACS) and the Rhode Island voter registration database (Rhode Island Department of State 2019) for comparison purposes. Respondents represented the state well in terms of geography; Rhode Island has 39 towns and we had respondents from each one. Overall, our sample includes a wide range of participants and reflects the state population demographics fairly well. Our sample includes fewer seniors (age 65+), but otherwise tracks the age distribution well for younger adults. Although the frequencies of almost all income groups and race were similar to the state, our sample was substantially more educated, with over half of the respondents reporting bachelor’s degree or higher compared to only 31.7% in the statewide estimation. Our sample also includes more voters who identify as Republicans relative to statewide voter registration (19.9% versus 12.2%) and a lower percentage of Democrats. However, we see this as beneficial for statistical inference because Rhode Island leans so heavily toward the Democratic Party.

Table 2. Respondent summary statistics

Note: Summary statistics are presented for demographic controls collected from the respondents. Columns 1 and 2 show for each variable, the percent of the population and the standard deviation, respectively. Column 3 presents statewide demographic mean estimates from the 2018 American Community Survey (ACS) for the over 18 population and party affiliation from the 2019 Rhode Island voter registration data.

Table 3 presents summary data for the ballots presented to respondents. Mean approval for both the Land Conservation Bond (80% approval) and the Affordable Housing Bond (70.2% approval) was high, and higher than typically seen in historical referendum votes. In 2016 both Land Conservation and Affordable Housing bonds were on the ballot and passed with 67.6% and 58.0% approval, respectively. Both the Land Conservation and Affordable Housing bonds in our experiment had a mean dollar amount of around $190 million (range is $20–$500 million). The mean and outward bound of the range is larger than the real-world amount of typical bonds on these two issues in Rhode Island, which has never exceeded $70 million in the state and are typically less than $50 million (Ballotpedia 2018).

Table 3. Ballot summary statistics

We explore relative bond dollar amounts by creating a variable called cumulative amount all else, which equals the sum of the dollar amounts listed for all the other bonds on that ballot. This allows us to examine if the total cost of the other bonds influences support for one of the main referendums. To illustrate this variable, consider the ballot with three referendums in Figure 2. When trying to understand the determinants of approval for the Land Conservation bond as the focal referendum, cumulative amount all else is equal to the sum of the other two bonds, $20 million for Affordable Housing plus $100 million for K-12 School Construction (sum $120 million). When Affordable Housing is the focal bond, cumulative amount all else takes on a value of $600 million. The same process holds for ballots with five referendums and cumulative amount all else naturally has a higher average value due to there being more bonds on the ballot. Ballots with only one referendum are coded as cumulative amount all else equal to zero. Table 3 shows that the mean of cumulative amount all else for Land Conservation is about $296 million and for Affordable Housing is about $400 million. This large difference is just a result of realized values in the randomization process, nothing in the survey design implied a difference.

Our survey design randomized across the four possibilities of ballot length with equal probability, and Table 3 shows that each outcome was realized about 25% of the time. However, ballot length 1 (Land Conservation) was realized slightly more often than the others, with 27.5% of respondents seeing this version. Given cumulative amount all else is coded zero for ballot length 1, this helps explain the large difference in that variable between our two main referendums. The second variable that measures non-amount influences of referendum support is order, which is the spot on the ballot in which the bond appears. If the main bond is listed first, then order is coded as 1, if second 2, and so on. Order is always coded as 1 on ballots with only one referendum. To reiterate our survey design, ballot order is randomized, so our main referendums appeared in every position on the ballot. Table 2 shows that the mean order is 2.2 for Land Conservation and 2.4 for Affordable Housing. When examining ballots of length 3 or 5 only, mean order is 2.4 and 2.6 for Land Conservation and Affordable Housing, respectively.

Empirical models

The first model we estimate simultaneously tests the influences of absolute dollar amount, relative dollar amount, and bond order and total number of bonds on approval of our two main referendums. We estimate the following linear probability model for both the Land Conservation Bond and the Affordable Housing Bond separately:

(1) $$ {approve}_i={\displaystyle \begin{array}{l}\alpha +{\beta}_1{amount}_i+{\beta}_2cumulative\ amount\hskip2pt all\hskip2pt {else}_i+{\beta}_3{order}_i\\ {}+\hskip2px {\beta}_4ballot\ length\hskip2pt {3}_i+{\beta}_5ballot\ length\hskip2pt {5}_i+{\boldsymbol{X}}_{\boldsymbol{i}}\boldsymbol{\delta} +{\varepsilon}_i\end{array}} $$

$ {approve}_i $ is a binary variable equal to 1 if individual $ i $ voted to approve the main referendum, and zero otherwise. $ {amount}_i $ is the cost that the respondent was shown for the main referendum, and we expect $ {\beta}_1 $ to be negative in sign. $ cumulative\ amount\; all\;{else}_i $ is the relative cost measure, and we are ambiguous on the expected sign of $ {\beta}_2 $ , given the opposing forces discussed above. $ {order}_i $ is the order in which the bond appeared on the ballot for each individual. To be clear, $ {order}_i $ always takes on the value 1 for ballots of length 1. $ {order}_i $ ranges from 1 to 3 for ballots of length 3 and from 1 to 5 for ballots of length 5. We hypothesize that $ {\beta}_3 $ will be negative as bonds appearing further down the ballot will be less likely to be approved. We then control for the number of bonds on the ballot by using two indicator variables, $ ballot\ length\;3 $ and $ ballot\ length\;5 $ , which are equal to 1 if the ballot presented to the individual showed 3 or 5 bonds, respectively. We expect $ {\beta}_5<{\beta}_4<0 $ for the same reason as $ {\beta}_3 $ , the more referendums a voter faces, the less likely they are to approve. $ {\boldsymbol{X}}_{\boldsymbol{i}} $ is a vector of control variables including political party affiliation, trust in state government, voting frequency, race and ethnicity, homeowner status, income, education, sex, and city of residence. Although these variables are not our focus, they are important determinants of approval and are included to improve model fit (Prendergast, Pearson-Merkowitz, and Lang Reference Prendergast, Pearson-Merkowitz and Lang2019; Pearson-Merkowitz and Lang Reference Pearson-Merkowitz and Lang2020). In additional specifications, we also include interactions between $ {amount}_i $ and dummy variables for ballot length 1, 3 and 5. This allows us to test if dollar amount responsiveness changes as the length of the ballot grows, which has never been tested to date.

Equation (1) demonstrates the power of our analysis. We can include all of these variables in a single equation because they are all orthogonal given randomization. Analysis of real-world ballots and outcomes are limited in this way. Thus, we expect novel findings not possible in previous analysis.

The second model we estimate examines cost responsiveness across all five bond types in a single, pooled model. We only include choices from respondents who were shown a ballot of length five, but we include all of their five votes as observations. We include respondent fixed effects to capture any individual factors that affect approval across bond types. The initial model we estimate is:

(2) $$ {approve}_{ib}={\delta}_1+{\delta}_2 amoun{t}_{ib}+{\alpha}_i+{\varepsilon}_{ib} $$

where $ {approve}_{ib} $ is a binary variable equal to 1 if respondent $ i $ voted to approve bond $ b $ and zero otherwise, $ amoun{t}_{ib} $ is the amount shown to respondent $ i $ for bond $ b $ , and $ {\alpha}_i $ is the respondent fixed effect. $ {\delta}_2 $ is the measure of amount responsiveness across all bond types combined and $ {\delta}_1 $ is the common intercept, interpreted literally as expected approval if amount was zero.

We expand Equation 2 to allow for bond-specific amount responsiveness and intercepts:

(3) $$ {approve}_{ib}={\boldsymbol{\delta}}_{\mathbf{1}\boldsymbol{b}}+\sum \limits_{b\in B}{\delta}_{2b} amoun{t}_{ib}\ast I\left(b=B\right)+{\alpha}_i+{\varepsilon}_{ib} $$

where $ {\boldsymbol{\delta}}_{\boldsymbol{1b}} $ is now a vector with one intercept for each bond type, $ I\left(b=B\right) $ is an indicator variable equal to one if bond $ b $ equals bond type $ B $ , the set of which are the five bond types in our survey (Land Conservation, Affordable Housing, K-12 School, Higher Education, and Transportation), and $ {\delta}_{2b} $ is now the bond-specific amount responsiveness of approval. In this specification, there is no omitted, or reference, group, so each coefficient is interpreted as amount responsiveness in absolute terms, not relative to some other bond type.