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'''Step3''': Count ranking score
 
'''Step3''': Count ranking score
Suppose we want to calculate the ranking score of the following ranking:
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<br>Suppose we want to calculate the ranking score of the following ranking:
 
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Revision as of 11:29, 29 November 2013

Ballots: what is out there?

A team project for MA279, Fall 2013

Team members: Qianyu Deng, Sui Fang, Weichen Gai, Chenkai Wang, Bolun Zhang


Introduction (Chenkai Wang)

The main purpose of using ballots in an election is to record the opinions of electorates and their preferences of the candidates. The goal is to determine a winner from the candidates. Ballots come in many physical forms, such as a piece of paper or a digital document stored in a computer. The actual format of a ballot is called voting system or voting method. A voting system has several built-in rules in order to ensure fair voting during the election. Another functionality of a voting system is counting the voting from ballots to determine a final winner. So to specify a valid voting system, we have to describe two key ingredients: allowable votes, i.e., ballots and the algorithms of collecting votes. In this study, we will study how various voting systems are designed and reveal the mathematical reasons in designing these voting systems.

Fairness Criteria

In order to minimize biased opinions in a voting system, we use fairness criteria to measure the "fairness" of a particular voting system. A fairness criteria is a mathematical description of the rules a voting systems uses. In a formal mathematical treatment, we can define the mathematical meaning of the word "fairness" according to these criteria. Here we describe three important criteria and end with Arrow's impossibility theorem. First, we have the following definition.

Definition Let $ C $ be the finite set of candidates and $ N $ be the finite set of voters. Let $ L $ be the set of all total (linear) ordering on $ C $, i.e., it's the space of all possible ballots submitted by voters. Note since all underlying sets are finite, there is no difference between total ordering and well ordering. Each total ordering assigns a unique natural number $ 1\leq\mathrm{rank}(a)\leq|C| $ to all candidates $ a\in C $. A social welfare function is a function $ f:L^N\rightarrow L $. The domain of $ f $ is called the set of preference profiles. A generic element of $ L^N $ has the form $ \langle \leq_1, \leq_2,\cdots,\leq_N \rangle $, where $ \leq_i $ are total ordering on $ C $, i.e., one generic element (preference profile) represents a possible outcome of all voters. A social welfare function represents the process of choosing the winner from one generic preference profile, i.e., giving the final total ordering of the candidates. Let's denote $ f(\leq_1,\cdots,\leq_N) $ by the single symbol $ \leq $.

Unanimity

Definition Let $ a,b\in C $, if $ \forall i\in N(a<_ib) $, then $ a<b $. In words, if every voters prefer one candidate to another, this order should be preserved in the final decision.

Independence of Irrelevant Alternatives

Definition Let $ r,s\in L^N $ and $ a\in C $, if $ \mathrm{rank}_r(a)=\mathrm{rank}_s(a) $, then $ \mathrm{rank}_{f(r)}(a)=\mathrm{rank}_{f(s)}(a) $. In other words, if one candidate has the same ranks in two preference profiles, the rank should also be the same in two corresponding final decisions.

Non-dictatorship

Definition There is no $ i\in N $ such that if $ \langle\leq_1,\cdots,\leq_N\rangle\in L^N $, we have $ f(\leq_1,\cdots,\leq_N)=\leq_i $. In words, the final decision should be different from all elements in a preference profile.

Arrow's Impossibility Theorem

Theorem There is no social welfare function satisfies the criteria of unanimity, independence of Irrelevant Alternatives, and non-dictatorship for candidates of size greater than three.


Method 1

  1. Background
  2. Method
  3. Abortion reason

Kemeny-Young Method(Qianyu Deng)

History Kemeny-Young method is a voting system first developed by John Kemeny in 1959 and showed as the unique neutral method satisfying reinforcement and the Condorcet Criterion by Peyton Young and Arthur Levenglick in 1978. It uses preferential ballots and pairwise comparison to find the most popular ranking in an election. This method satisfying Condorcet Criterion since if there is a Condorcet winner, then it is always the most popular one.

How it works?

  • step1 pairwise comparison
  • step2 Create a tally table of the pairwise comparison
  • step3 Count ranking score
  • step4 Find the ranking which gets the highest ranking score

    Now,let's look at a previous example of the election on the location of capital of Tennessee we use before to explain how it works.

    Example

    42% of voters(close to Memphis) 26% of voters(close to Nashville) 15% of voters(close to Chattanooga) 17% of voters(close to Knoxville)
    1. Memphis
    2. Nashville
    3. Chattanooga
    4. Knoxville
    1. Nashville
    2. Chattanooga
    3. Knoxville
    4. Memphis
    1. Chattanooga
    2. Knoxville
    3. Nashville
    4. Memphis
    1. Knoxville
    2. Chattanooga
    3. Nashville
    4. Memphis

    Step1:Find the pairwise comparison in terms of the population percentage

    over Memphis over Nashville over Chattanooga over Knoxville
    prefer Memphis \ 42% 42% 42%
    prefer Nashville 58% \ 68% 68%
    prefer Chattanooga 58% 32% \ 83%
    prefer Knoxville 58% 32% 17% \

    Step 2: Create a tally table of the pairwise comparison

    prefer X over Y equal preference prefer Y over X
    X = Memphis,Y = Nashville 42% 0 58%
    X = Memphis,Y = Chattanooga 42% 0 58%
    X = Memphis,Y = Knoxville 42% 0 58%
    X = Nashville,Y = Chattanooga 68% 0 32%
    X = Nashville,Y = Knoxville 68% 0 32%
    X = ChattanoogaY = Knoxville 83% 0 17%

    Step3: Count ranking score
    Suppose we want to calculate the ranking score of the following ranking:


    Method 3

    1. Background
    2. Method
    3. Abortion reason

    Conclusion


    Bibliography

    1. Ballots. Retrieved from Wikipedia: http://en.wikipedia.org/wiki/Ballot

    Back to MA279 Fall 2013
  • Alumni Liaison

    Questions/answers with a recent ECE grad

    Ryne Rayburn