2.1. Position Effects

First, I consider the causal effect of candidate $j \ (=1,\ldots ,J)$ shown in a specific position $O_{ij}=t$ (treated) as opposed to another position $O_{ij}=t^{*}$ (control) for voter $i \ (=1,\ldots ,n)$ . To define quantities of interest, I rely on the potential-outcomes framework for ranking data considered in Atsusaka (Reference Atsusaka2023).

Let voter i’s potential rankings be $\textbf {Y}_{i}(O_{ij}=t)$ and $\textbf {Y}_{i}(O_{ij}=t^{*})$ , respectively (e.g., $\textbf {Y}_{i}(O_{ij}=t)=(1,4,2,3)$ ). Let $\boldsymbol {O}_{i[-j]}$ be the ordering (position) of the other $J-1$ candidates. Finally, let $g()$ be a summary function that maps rankings into scalar values.

One causal quantity of interest is the average treatment effect of position t for candidate j on voters’ rankings with respect to counterfactual position $t^{*}$ and the order of the remaining candidates $\boldsymbol {o}$ . I call it the conditional position effect:

(1)

While various summary functions can be used, the following application focuses on two functions for $g()$ : (1) the marginal rank of candidate j (e.g., candidate A was ranked third) and (2) the indicator function that denotes whether candidate j was ranked or not (e.g., candidate B was not ranked).Footnote ⁴ Thus, I study the position effects on the average rank of each candidate and the probability that each candidate is selected, both of which are useful quantities in elections with ordinal ballots.

In many applications, however, researchers may wish to study the overall effect of position t for candidate j on voters’ rankings averaged over all possible counterfactual position $t^{*}$  and all possible ordering of the remaining candidates $\boldsymbol {o}$ . I call it the average position effect of position t:

(2)

The average position effect is the probability-weighted average of all possible conditional position effects.Footnote ⁵ Appendix A of the Supplementary Material shows that researchers can identify and estimate the average position effect by fully randomizing ballot orders. Here, one challenge is that the number of comparisons proliferates as the number of candidates increases. For example, with 10 candidates and a given treatment position t (e.g., t = 1) for a target candidate, researchers need to consider 9 counterfactual control positions $t^{*}$ (e.g., $t^{*} \in \{2, 3, \ldots,10\}$ ) and $9!$ ways to permute the other nine candidates. Accordingly, researchers need at least $9 \times 9! = 3,265,920$ control units to estimate the above effect.

To resolve this issue, Appendix A of the Supplementary Material shows that analysts can estimate the average position effect with considerably fewer control units by making two additional assumptions. Researchers can estimate the average position effect on candidate ranks, for example, for each position-candidate pair by regressing each candidate’s rank (or any function of it) on a dummy variable denoting a specific ballot position.

2.2. Pattern Ranking

Pattern ranking refers to when voters provide ranked ballots by following specific geometric patterns independent of their preferences. A special case of pattern ranking—(1, 2, …, J)—has been known as “donkey voting” (Orr Reference Orr2002; Reilly Reference Reilly2001, 158). Figure 2 visualizes that pattern ranking generalizes the idea of donkey voting by accommodating many more geometric patterns, including what I call diagonal vote (Panel A, no angle), zigzag vote (Panel B, two or more major angles), and dogleg vote (Panel C, one major angle).

Figure 2 Examples of pattern ranking.

Appendix B of the Supplementary Material shows that when (1) ballot order is randomized and (2) no voter performs pattern ranking, raw responses (recorded rankings with respect to given candidate orders) follow a uniform distribution regardless of people’s underlying preference. Thus, deviation from uniformity can be treated as potential evidence for pattern ranking. More formally, researchers can apply Pearson’s $\chi ^2$ test to this problem with test statistic:

(3) $$\begin{align} \chi^2 = \sum_{r=1}^{J!}\frac{\big( N\widehat{p}_{r} - N\frac{1}{J!} \big)^2}{N\frac{1}{J!}}, \end{align}$$

where $\widehat {p}_{r}$ is the observed proportion of recorded ranking $r \ (=1,\ldots ,J!)$ , $\frac {1}{J!}$ is the expected proportion of the same ranking under the null, and N is the number of observations. Here, one limitation is that applying the test to ranking data with more than five or six items becomes challenging. I leave future research to address the limitation.

3.1. Position Effects

Figure 3 visualizes the average position effects on average ranks (upper panels) and candidate selection probabilities (lower panels) for all candidate-position combinations in the three elections. The blue (red) results represent positive (negative) effects, denoting higher (lower) average ranks and selection probabilities, while the gray results suggest nonsignificance.

I find that about 91% (240/264) of the average position effects are statistically insignificant. Although some effects are statistically significant, I find almost no consistent pattern among them. Indeed, 5% of all effects can be significant purely by chance. The results are conservative in the sense that we should observe less significant effects (stronger evidence) if I correct statistical inference for multiple comparisons. The result suggests that respondents were hardly susceptible to average position effects in the experiments.

3.2. Pattern Ranking

Panel A of Figure 4 plots the empirical distributions of all recorded rankings in the U.S. House (left) and U.S. Senate (right) races in Alaska. The panel shows the results from the forced (filled) and optional (non-filled) ranking questions. There are 4! = 24 different ways to rank, and each recorded ranking (given a particular candidate order) should be selected with probability 1/24 = 0.042 without pattern ranking. In Panel B, I visualize all 24 rankings, which are categorized into either the diagonal vote (solid line), zigzag vote (dashed line), or dogleg vote (dotted line).Footnote ⁸

Panel A shows nonuniform distributions of recorded rankings, implying the presence of pattern ranking. Some geometric patterns, notably (1, 2, 3, 4), are selected significantly more often than others. This means that although some of the ballots reflect people’s genuine preferences, many of them may be based solely on a diagonal line. Pearson’s $\chi ^2$ test rejects the null hypothesis that each of the four distributions is uniform at the $\alpha = 0.05$ level. Moreover, in Tables F1 and F2 in the Supplementary Material, I find that the dogleg vote is more prevalent than the zigzag vote in almost all cases.

Panel B of Figure 4 provides additional evidence for pattern ranking—31% and 37% of respondents offered the same recorded ranking across the two questions, even though only 3% (House) and 1.6% (Senate) of respondents saw the same candidate order. Namely, many people selected the same geometric pattern even though they were exposed to different orders of candidates. While it requires additional information to estimate the proportion of pattern rankers (Atsusaka and Kim Reference Atsusaka and Kim2024), the results offer partial evidence for pattern ranking.