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Учебные пособия > Mathematics for the Liberal Arts

Preference Ballot Voting

In many decision making situations, it is necessary to gather the group consensus. This happens when a group of friends decides which movie to watch, when a company decides which product design to manufacture, and when a democratic country elects its leaders. While the basic idea of voting is fairly universal, the method by which those votes are used to determine a winner can vary. Amongst a group of friends, you may decide upon a movie by voting for all the movies you’re willing to watch, with the winner being the one with the greatest approval. A company might eliminate unpopular designs then revote on the remaining. A country might look for the candidate with the most votes. In deciding upon a winner, there is always one main goal: to reflect the preferences of the people in the most fair way possible. In this lesson, we will study Preference Schedules and Preference Ballots as a means of deciding upon the winner of an election. A preference ballot is a ballot in which the voter ranks the choices in order of preference.

Plurality Method

Preference Schedules

To begin, we’re going to want more information than a traditional ballot normally provides. A traditional ballot usually asks you to pick your favorite from a list of choices. This ballot fails to provide any information on how a voter would rank the alternatives if their first choice was unsuccessful.

Preference ballot

A preference ballot is a ballot in which the voter ranks the choices in order of preference.

Example

A vacation club is trying to decide which destination to visit this year: Hawaii (H), Orlando (O), or Anaheim (A). Their votes are shown below:
Bob Ann Marv Alice Eve Omar Lupe Dave Tish Jim
1st choice A A O H A O H O H A
2nd choice O H H A H H A H A H
3rd choice H O A O O A O A O O
These individual ballots are typically combined into one preference schedule, which shows the number of voters in the top row that voted for each option:
1 3 3 3
1st choice A A O H
2nd choice O H H A
3rd choice H O A O
Notice that by totaling the vote counts across the top of the preference schedule we can recover the total number of votes cast: [latex]1+3+3+3=10[/latex] total votes.
The following video will give you a summary of what issues can arise from elections, as well as how a preference table is used in elections. https://youtu.be/6rhpq1ozmuQ

Plurality

The voting method we’re most familiar with in the United States is the plurality method. In this method, the choice with the most first-preference votes is declared the winner. Ties are possible, and would have to be settled through some sort of run-off vote. This method is sometimes mistakenly called the majority method, or “majority rules”, but it is not necessary for a choice to have gained a majority of votes to win. A majority is over 50%; it is possible for a winner to have a plurality without having a majority.

Example

In our election from above, we had the preference table:
1 3 3 3
1st choice A A O H
2nd choice O H H A
3rd choice H O A O
For the plurality method, we only care about the first choice options. Totaling them up: Anaheim: [latex]1+3=4[/latex] first-choice votes Orlando: 3 first-choice votes Hawaii: 3 first-choice votes Anaheim is the winner using the plurality voting method. Notice that Anaheim won with 4 out of 10 votes, 40% of the votes, which is a plurality of the votes, but not a majority.
44 14 20 70 22 80 39
1st choice G G G M M B B
2nd choice M B G B M
3rd choice B M B G G

Try It Now

Three candidates are running in an election for County Executive: Goings (G), McCarthy (M), and Bunney (B)[footnote]This data is loosely based on the 2008 County Executive election in Pierce County, Washington. See http://www.co.pierce.wa.us/xml/abtus/ourorg/aud/Elections/RCV/ranked/exec/summary.pdf[/footnote] The voting schedule is shown below. Which candidate wins under the plurality method?
44 14 20 70 22 80 39
1st choice G G G M M B B
2nd choice M B G B M
3rd choice B M B G G
Note: In the third column and last column, those voters only recorded a first-place vote, so we don’t know who their second and third choices would have been.

What’s Wrong with Plurality?

The election from the above example may seem totally clean, but there is a problem lurking that arises whenever there are three or more choices. Looking back at our preference table, how would our members vote if they only had two choices? Anaheim vs Orlando: 7 out of the 10 would prefer Anaheim over Orlando
1 3 3 3
1st choice A A O H
2nd choice O H H A
3rd choice H O A O
Anaheim vs Hawaii: 6 out of 10 would prefer Hawaii over Anaheim
1 3 3 3
1st choice A A O H
2nd choice O H H A
3rd choice H O A O
This doesn’t seem right, does it? Anaheim just won the election, yet 6 out of 10 voters, 60% of them, would have preferred Hawaii! That hardly seems fair. Marquis de Condorcet, a French philosopher, mathematician, and political scientist wrote about how this could happen in 1785, and for him we name our first fairness criterion.

Fairness Criteria

The fairness criteria are statements that seem like they should be true in a fair election.

Condorcet Criterion

If there is a choice that is preferred in every one-to-one comparison with the other choices, that choice should be the winner. We call this winner the Condorcet Winner, or Condorcet Candidate.

Example

In the election, what choice is the Condorcet Winner? We see above that Hawaii is preferred over Anaheim. Comparing Hawaii to Orlando, we can see 6 out of 10 would prefer Hawaii to Orlando.
1 3 3 3
1st choice A A O H
2nd choice O H H A
3rd choice H O A O
Since Hawaii is preferred in a one-to-one comparison to both other choices, Hawaii is the Condorcet Winner.

Example

Consider a city council election in a district that is historically 60% Democratic voters and 40% Republican voters. Even though city council is technically a nonpartisan office, people generally know the affiliations of the candidates. In this election there are three candidates: Don and Key, both Democrats, and Elle, a Republican. A preference schedule for the votes looks as follows:
342 214 298
1st choice Elle Don Key
2nd choice Don Key Don
3rd choice Key Elle Elle
We can see a total of [latex]342+214+298=854[/latex] voters participated in this election. Computing percentage of first place votes: Don: 214/854 = 25.1% Key: 298/854 = 34.9% Elle: 342/854 = 40.0% So in this election, the Democratic voters split their vote over the two Democratic candidates, allowing the Republican candidate Elle to win under the plurality method with 40% of the vote. Analyzing this election closer, we see that it violates the Condorcet Criterion. Analyzing the one-to-one comparisons: Elle vs Don: 342 prefer Elle; 512 prefer Don: Don is preferred Elle vs Key: 342 prefer Elle; 512 prefer Key: Key is preferred Don vs Key: 556 prefer Don; 298 prefer Key: Don is preferred So even though Don had the smallest number of first-place votes in the election, he is the Condorcet winner, being preferred in every one-to-one comparison with the other candidates.
If you prefer to watch a video of the previous example being worked out, here it is. https://youtu.be/x6DpoeaRVsw?list=PL1F887D3B8BF7C297

Try It Now

Consider the election from the previous Try It Now. Is there a Condorcet winner in this election?
44 14 20 70 22 80 39
1st choice G G G M M B B
2nd choice M B G B M
3rd choice B M B G G

Insincere Voting

Situations when there are more than one candidate that share somewhat similar points of view, can lead to insincere voting. Insincere voting is when a person casts a ballot counter to their actual preference for strategic purposes. In the case above, the democratic leadership might realize that Don and Key will split the vote, and encourage voters to vote for Key by officially endorsing him. Not wanting to see their party lose the election, as happened in the scenario above, Don’s supporters might insincerely vote for Key, effectively voting against Elle. The following video gives another mini lesson that covers the plurality method of voting as well as the idea of a Condorcet Winner. https://youtu.be/r-VmxJQFMq8

Instant Runoff Voting

Instant Runoff Voting (IRV), also called Plurality with Elimination, is a modification of the plurality method that attempts to address the issue of insincere voting. In IRV, voting is done with preference ballots, and a preference schedule is generated. The choice with the least first-place votes is then eliminated from the election, and any votes for that candidate are redistributed to the voters’ next choice. This continues until a choice has a majority (over 50%). This is similar to the idea of holding runoff elections, but since every voter’s order of preference is recorded on the ballot, the runoff can be computed without requiring a second costly election. This voting method is used in several political elections around the world, including election of members of the Australian House of Representatives, and was used for county positions in Pierce County, Washington until it was eliminated by voters in 2009. A version of IRV is used by the International Olympic Committee to select host nations.

Example

Consider the preference schedule below, in which a company’s advertising team is voting on five different advertising slogans, called A, B, C, D, and E here for simplicity. Initial votes
3 4 4 6 2 1
1st choice B C B D B E
2nd choice C A D C E A
3rd choice A D C A A D
4th choice D B A E C B
5th choice E E E B D C
If this was a plurality election, note that B would be the winner with 9 first-choice votes, compared to 6 for D, 4 for C, and 1 for E. There are total of 3+4+4+6+2+1 = 20 votes. A majority would be 11 votes. No one yet has a majority, so we proceed to elimination rounds. Round 1: We make our first elimination. Choice A has the fewest first-place votes, so we remove that choice
3 4 4 6 2 1
1st choice B C B D B E
2nd choice C D C E
3rd choice D C D
4th choice D B E C B
5th choice E E E B D C
We then shift everyone’s choices up to fill the gaps. There is still no choice with a majority, so we eliminate again.
3 4 4 6 2 1
1st choice B C B D B E
2nd choice C D D C E D
3rd choice D B C E C B
4th choice E E E B D C
Round 2: We make our second elimination. Choice E has the fewest first-place votes, so we remove that choice, shifting everyone’s options to fill the gaps.
3 4 4 6 2 1
1st choice B C B D B D
2nd choice C D D C C B
3rd choice D B C B D C
Notice that the first and fifth columns have the same preferences now, we can condense those down to one column.
5 4 4 6 1
1st choice B C B D D
2nd choice C D D C B
3rd choice D B C B C
Now B has 9 first-choice votes, C has 4 votes, and D has 7 votes. Still no majority, so we eliminate again. Round 3: We make our third elimination. C has the fewest votes.
5 4 4 6 1
1st choice B D B D D
2nd choice D B D B B
Condensing this down:
9 11
1st choice B D
2nd choice D B
D has now gained a majority, and is declared the winner under IRV.
The following video provides another view of the example from above. https://youtu.be/C-X-6Lo_xUQ?list=PL1F887D3B8BF7C297

Try It Now

Consider again this election. Find the winner using IRV.
44 14 20 70 22 80 39
1st choice G G G M M B B
2nd choice M B G B M
3rd choice B M B G G
Here is an overview video that provides the definition of IRV, as well as an example of how to determine the winner of an election using IRV. https://youtu.be/6axH6pcuyhQ

What’s Wrong with IRV?

Example

Let’s return to our City Council Election.
342 214 298
1st choice Elle Don Key
2nd choice Don Key Don
3rd choice Key Elle Elle
In this election, Don has the smallest number of first place votes, so Don is eliminated in the first round. The 214 people who voted for Don have their votes transferred to their second choice, Key.
342 512
1st choice Elle Key
2nd choice Key Elle
So Key is the winner under the IRV method. We can immediately notice that in this election, IRV violates the Condorcet Criterion, since we determined earlier that Don was the Condorcet winner. On the other hand, the temptation has been removed for Don’s supporters to vote for Key; they now know their vote will be transferred to Key, not simply discarded.
In the following video, we provide the example from above where we find that the IRV method violates the Condorcet Criterion in an election for a city council seat. https://youtu.be/BCRaYCU28Ro?list=PL1F887D3B8BF7C297

Example

Consider the voting system below.
37 22 12 29
1st choice Adams Brown Brown Carter
2nd choice Brown Carter Adams Adams
3rd choice Carter Adams Carter Brown
In this election, Carter would be eliminated in the first round, and Adams would be the winner with 66 votes to 34 for Brown. Now suppose that the results were announced, but election officials accidentally destroyed the ballots before they could be certified, and the votes had to be recast. Wanting to “jump on the bandwagon,” 10 of the voters who had originally voted in the order Brown, Adams, Carter change their vote to favor the presumed winner, changing those votes to Adams, Brown, Carter.
47 22 2 29
1st choice Adams Brown Brown Carter
2nd choice Brown Carter Adams Adams
3rd choice Carter Adams Carter Brown
In this re-vote, Brown will be eliminated in the first round, having the fewest first-place votes. After transferring votes, we find that Carter will win this election with 51 votes to Adams’ 49 votes! Even though the only vote changes made favored Adams, the change ended up costing Adams the election. This doesn’t seem right, and introduces our second fairness criterion:

Monotonicity Criterion

If voters change their votes to increase the preference for a candidate, it should not harm that candidate’s chances of winning.
This criterion is violated by this election. Note that even though the criterion is violated in this particular election, it does not mean that IRV always violates the criterion; just that IRV has the potential to violate the criterion in certain elections. The last video shows the example from above where the monotonicity criterion is violated. https://youtu.be/NH78zNXHKUs?list=PL1F887D3B8BF7C297

Borda Count

Borda Count is another voting method, named for Jean-Charles de Borda, who developed the system in 1770.

Borda Count

In this method, points are assigned to candidates based on their ranking; 1 point for last choice, 2 points for second-to-last choice, and so on. The point values for all ballots are totaled, and the candidate with the largest point total is the winner.

Example

A group of mathematicians are getting together for a conference. The members are coming from four cities: Seattle, Tacoma, Puyallup, and Olympia. Their approximate locations on a map are shown below. A map of the Puget Sound. Seattle, Tacoma, Puyallup, and Olympia are marked. The votes for where to hold the conference were:
51 25 10 14
1st choice Seattle Tacoma Puyallup Olympia
2nd choice Tacoma Puyallup Tacoma Tacoma
3rd choice Olympia Olympia Olympia Puyallup
4th choice Puyallup Seattle Seattle Seattle
Use the Borda count method to determine the winning town for the conference.

Answer: In each of the 51 ballots ranking Seattle first, Puyallup will be given 1 point, Olympia 2 points, Tacoma 3 points, and Seattle 4 points. Multiplying the points per vote times the number of votes allows us to calculate points awarded

51 25 10 14
1st choice 4 points Seattle [latex]4\cdot51=204[/latex] Tacoma [latex]4\cdot25=100[/latex] Puyallup [latex]4\cot10=40[/latex] Olympia [latex]4\cdot14=56[/latex]
2nd choice 3 points Tacoma [latex]3\cdot51=153[/latex] Puyallup [latex]3\cdot25=75[/latex] Tacoma [latex]3\cdot10=30[/latex] Tacoma [latex]3\cdot14=42[/latex]
3rd choice 2 points Olympia [latex]2\cdot51=102[/latex] Olympia [latex]2\cdot25=50[/latex] Olympia [latex]2\cdot10=20[/latex] Puyallup [latex]2\cdot14=28[/latex]
4th choice 1 point Puyallup [latex]1\cdot51=51[/latex] Seattle [latex]1\cdot25=25[/latex] Seattle [latex]1\cdot10=10[/latex] Seattle [latex]1\cdot14=14[/latex]
Adding up the points: Seattle: [latex]204+25+10+14=253[/latex] points Tacoma: [latex]153+100+30+42=325[/latex] points Puyallup: [latex]51+75+40+28=194[/latex] points Olympia: [latex]102+50+20+56=228[/latex] points Under the Borda Count method, Tacoma is the winner of this vote.

Here is a video showing the example from above. https://youtu.be/vfujywLdW_s?list=PL1F887D3B8BF7C297

Try It Now

Consider again the election from earlier. Find the winner using Borda Count. Since we have some incomplete preference ballots, for simplicity, give every unranked candidate 1 point, the points they would normally get for last place.
44 14 20 70 22 80 39
1st choice G G G M M B B
2nd choice M B G B M
3rd choice B M B G G

What’s Wrong with Borda Count?

You might have already noticed one potential flaw of the Borda Count from the previous example. In that example, Seattle had a majority of first-choice votes, yet lost the election! This seems odd, and prompts our next fairness criterion:

Majority Criterion

If a choice has a majority of first-place votes, that choice should be the winner.
The election from the previous example using the Borda Count violates the Majority Criterion. Notice also that this automatically means that the Condorcet Criterion will also be violated, as Seattle would have been preferred by 51% of voters in any head-to-head comparison. Borda count is sometimes described as a consensus-based voting system, since it can sometimes choose a more broadly acceptable option over the one with majority support. In the example above, Tacoma is probably the best compromise location. This is a different approach than plurality and instant runoff voting that focus on first-choice votes; Borda Count considers every voter’s entire ranking to determine the outcome. Because of this consensus behavior, Borda Count, or some variation of it, is commonly used in awarding sports awards. Variations are used to determine the Most Valuable Player in baseball, to rank teams in NCAA sports, and to award the Heisman trophy.

Copeland’s Method

So far none of our voting methods have satisfied the Condorcet Criterion. The Copeland Method specifically attempts to satisfy the Condorcet Criterion by looking at pairwise (one-to-one) comparisons. In this method, each pair of candidates is compared, using all preferences to determine which of the two is more preferred. The more preferred candidate is awarded 1 point. If there is a tie, each candidate is awarded ½ point. After all pairwise comparisons are made, the candidate with the most points, and hence the most pairwise wins, is declared the winner. Variations of Copeland’s Method are used in many professional organizations, including election of the Board of Trustees for the Wikimedia Foundation that runs Wikipedia.

Example

Consider our vacation group example from the beginning of the chapter. Determine the winner using Copeland’s Method.
1 3 3 3
1st choice A A O H
2nd choice O H H A
3rd choice H O A O

Answer: We need to look at each pair of choices, and see which choice would win in a one-to-one comparison. You may recall we did this earlier when determining the Condorcet Winner. For example, comparing Hawaii vs Orlando, we see that 6 voters, those shaded below in the first table below, would prefer Hawaii to Orlando. Note that Hawaii doesn’t have to be the voter’s first choice—we’re imagining that Anaheim wasn’t an option. If it helps, you can imagine removing Anaheim, as in the second table below.

1 3 3 3
1st choice A A O H
2nd choice O H H A
3rd choice H O A O
1 3 3 3
1st choice O H
2nd choice O H H
3rd choice H O O
Based on this, in the comparison of Hawaii vs Orlando, Hawaii wins, and receives 1 point. Comparing Anaheim to Orlando, the 1 voter in the first column clearly prefers Anaheim, as do the 3 voters in the second column. The 3 voters in the third column clearly prefer Orlando.  The 3 voters in the last column prefer Hawaii as their first choice, but if they had to choose between Anaheim and Orlando, they'd choose Anaheim, their second choice overall. So, altogether [latex]1+3+3=7[/latex] voters prefer Anaheim over Orlando, and 3 prefer Orlando over Anaheim. So, comparing Anaheim vs Orlando: 7 votes to 3 votes: Anaheim gets 1 point. All together, Hawaii vs Orlando: 6 votes to 4 votes: Hawaii gets 1 point Anaheim vs Orlando: 7 votes to 3 votes: Anaheim gets 1 point Hawaii vs Anaheim: 6 votes to 4 votes: Hawaii gets 1 point Hawaii is the winner under Copeland’s Method, having earned the most points. Notice this process is consistent with our determination of a Condorcet Winner.

Here is the same example presented in a video. https://youtu.be/FftVPk7dqV0?list=PL1F887D3B8BF7C297

Example

Consider the advertising group’s vote we explored earlier. Determine the winner using Copeland’s method.
3 4 4 6 2 1
1st choice B C B D B E
2nd choice C A D C E A
3rd choice A D C A A D
4th choice D B A E C B
5th choice E E E B D C

Answer: With 5 candidates, there are 10 comparisons to make:

A vs B: 11 votes to 9 votes A gets 1 point
A vs C: 3 votes to 17 votes C gets 1 point
A vs D: 10 votes to 10 votes A gets ½ point, D gets ½ point
A vs E: 17 votes to 3 votes A gets 1 point
B vs C: 10 votes to 10 votes B gets ½ point, C gets ½ point
B vs D: 9 votes to 11 votes D gets 1 point
B vs E: 13 votes to 7 votes B gets 1 point
C vs D: 9 votes to 11 votes D gets 1 point
C vs E: 17 votes to 3 votes C gets 1 point
D vs E: 17 votes to 3 votes D gets 1 point
  Totaling these up: A gets 2½ points B gets 1½ points C gets 2½ points D gets 3½ points E gets 0 points Using Copeland’s Method, we declare D as the winner. Notice that in this case, D is not a Condorcet Winner. While Copeland’s method will also select a Condorcet Candidate as the winner, the method still works in cases where there is no Condorcet Winner.

Watch the same example from above being worked out in this video. https://youtu.be/sWdmkee5m_Q?list=PL1F887D3B8BF7C297

Try It Now

Consider again the election from earlier. Find the winner using Copeland’s method. Since we have some incomplete preference ballots, we’ll have to adjust. For example, when comparing M to B, we’ll ignore the 20 votes in the third column which do not rank either candidate.
44 14 20 70 22 80 39
1st choice G G G M M B B
2nd choice M B G B M
3rd choice B M B G G

What’s Wrong with Copeland’s Method?

As already noted, Copeland’s Method does satisfy the Condorcet Criterion. It also satisfies the Majority Criterion and the Monotonicity Criterion. So is this the perfect method? Well, in a word, no.

Example

A committee is trying to award a scholarship to one of four students, Anna (A), Brian (B), Carlos (C), and Dimitry (D). The votes are shown below:
5 5 6 4
1st choice D A C B
2nd choice A C B D
3rd choice C B D A
4th choice B D A C
Making the comparisons:
A vs B: 10 votes to 10 votes A gets ½ point, B gets ½ point
A vs C: 14 votes to 6 votes: A gets 1 point
A vs D: 5 votes to 15 votes: D gets 1 point
B vs C: 4 votes to 16 votes: C gets 1 point
B vs D: 15 votes to 5 votes: B gets 1 point
C vs D: 11 votes to 9 votes: C gets 1 point
Totaling:
A has 1 ½ points B has 1 ½ points
C has 2 points D has 1 point
So Carlos is awarded the scholarship. However, the committee then discovers that Dimitry was not eligible for the scholarship (he failed his last math class). Even though this seems like it shouldn’t affect the outcome, the committee decides to recount the vote, removing Dimitry from consideration. This reduces the preference schedule to:
5 5 6 4
1st choice A A C B
2nd choice C C B A
3rd choice B B A C
A vs B: 10 votes to 10 votes A gets ½ point, B gets ½ point
A vs C: 14 votes to 6 votes A gets 1 point
B vs C: 4 votes to 16 votes C gets 1 point
Totaling:
A has 1 ½ points B has ½ point
C has 1 point
Suddenly Anna is the winner! This leads us to another fairness criterion.

The Independence of Irrelevant Alternatives (IIA) Criterion

If a non-winning choice is removed from the ballot, it should not change the winner of the election. Equivalently, if choice A is preferred over choice B, introducing or removing a choice C should not cause B to be preferred over A.
In the election from the last example, the IIA Criterion was violated. Watch this video to see the example from above worked out again, https://youtu.be/463jDBNR-qY?list=PL1F887D3B8BF7C297 This anecdote illustrating the IIA issue is attributed to Sidney Morgenbesser: After finishing dinner, Sidney Morgenbesser decides to order dessert. The waitress tells him he has two choices: apple pie and blueberry pie. Sidney orders the apple pie. After a few minutes the waitress returns and says that they also have cherry pie at which point Morgenbesser says "In that case I'll have the blueberry pie." Another disadvantage of Copeland’s Method is that it is fairly easy for the election to end in a tie. For this reason, Copeland’s method is usually the first part of a more advanced method that uses more sophisticated methods for breaking ties and determining the winner when there is not a Condorcet Candidate.

So Where’s the Fair Method?

At this point, you’re probably asking why we keep looking at method after method just to point out that they are not fully fair. We must be holding out on the perfect method, right? Unfortunately, no. A mathematical economist, Kenneth Arrow, was able to prove in 1949 that there is no voting method that will satisfy all the fairness criteria we have discussed.

Arrow’s Impossibility Theorem

Arrow’s Impossibility Theorem states, roughly, that it is not possible for a voting method to satisfy every fairness criteria that we’ve discussed. To see a very simple example of how difficult voting can be, consider the election below:
5 5 5
1st choice A C B
2nd choice B A C
3rd choice C B A
Notice that in this election: 10 people prefer A to B 10 people prefer B to C 10 people prefer C to A No matter whom we choose as the winner, 2/3 of voters would prefer someone else! This scenario is dubbed Condorcet’s Voting Paradox, and demonstrates how voting preferences are not transitive (just because A is preferred over B, and B over C, does not mean A is preferred over C). In this election, there is no fair resolution. It is because of this impossibility of a totally fair method that Plurality, IRV, Borda Count, Copeland’s Method, and dozens of variants are all still used. Usually the decision of which method to use is based on what seems most fair for the situation in which it is being applied.

Licenses & Attributions

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CC licensed content, Shared previously

  • Voting Theory: Plurality Method and Condorcet Criterion. Authored by: Sousa, James (Mathispower4u.com). License: CC BY: Attribution.
  • Introduction to Voting Theory and Preference Tables. Authored by: Sousa, James (Mathispower4u.com). License: CC BY: Attribution.
  • Condorcet winner and insincere voting with plurality method. Authored by: Lippman, David. License: CC BY: Attribution.
  • Voting Theory: Instant Runoff Voting. Authored by: Sousa, James (Mathispower4u.com). License: CC BY: Attribution.
  • Instant Runoff Voting . Authored by: Lippman, David. License: CC BY: Attribution.
  • Instant Runoff Voting 2 . Authored by: Lippman, David. License: CC BY: Attribution.
  • IRV and Monotonicity . Authored by: Lippman, David. License: CC BY: Attribution.
  • Borda Count . Authored by: Lippman, David. License: CC BY: Attribution.
  • Copeland's method / Pairwise comparison 1 . License: Public Domain: No Known Copyright.
  • Copeland's method / Pairwise comparsion 2 . Authored by: Lippman, David. License: CC BY: Attribution.
  • Copelands and the IIA criterion . Authored by: Lippman, David. License: CC BY: Attribution.