New Simple Condorcet Method - Basically Copeland+Margins
@jack-waugh Sure! It uses standard preference matrices and basic addition and subtraction. Perfectly precinct summable and hand-countable.
I shouldn't have asked about tallying without computers, because you are only trying here to compete against IRV. I believe computers would be required, because people would take way too long to update the preference matrix when examining a single ballot. I think no single voting system will impress both IRV supporters (however renamed it may be) and the Trump supporters who assume (with some merit) that anything that runs software can be rigged. But maybe most of the latter don't want the Americans to have democratic representation, anyway. They just pretend that is the issue when their real issue is they don't want anyone to the left of Mussolini to win.
In regard to the method overall and the power relations it would generate, if I read everything right, a comparison of this to Llull/Copeland could say that your method throws away less information in case of a cycle, in such a way that ties are less likely as the electorate grows larger.
I wonder what strategy produces better results for those who practice it than ranking according to preference would produce for them. The Gibbard theorem implies that this exists.
Marylander last edited by Marylander
Here's the first prototype for ballot language:
I would make the language:
- Rank as many candidates as you would like
- You may rank multiple candidates equally.
- Ranked candidates are considered better than unranked candidates.
- Skipped ranks are ignored.
Finding the winner:
- Candidates are compared in one-on-one matchups against each other.
- The candidate who wins the most matchups is elected.
- If multiple candidates tie for most wins, the tie will be broken by total margin of victory in matchups against the other tied candidates.
It's usually better to use fewer words for this sort of thing.
Adding the information about unranked candidates ensures that there is no ambiguity.
I don't think it's necessary to explain that Copeland's is a Condorcet method, I think it's fairly obvious from the "most wins" definition. I also don't think it is appropriate to make predictions in ballot text, such as "In most elections, a single candidate will be preferred over all others".
People know what a margin is from sports. The fewer new concepts you have to define, the better.
By framing the last step as a tiebreaker, the elimination becomes implicit.
@jack-waugh It’s easy for poll workers who count by hand. There are three different ways to make preference matrices, so poll workers can use whichever they are most comfortable with. The most efficient procedure is to have the poll worker simply add one for each pairwise win on a ballot in the corresponding box in a matrix. This takes a bit of training, but for those with a sharp mind, it will likely be the preferred procedure. A middle approach is to list each pair of candidates and have the poll worker go through each ballot and add one to the winner between each pair, if there is one. The longest way that is probably best for recounts is to pick one pair of candidates and sort each ballot into one of three piles: one pile for the first picked candidate’s pairwise wins, the second pile for the second picked candidate’s pairwise wins, and the third pile for ballots that show no preference between the two picked candidates; then, count how many ballots are in each pile.
I would guess that a Borda strategy might work the best since the finalist margins are mathematically equivalent to tournament-style Borda. I'd love for some to run some simulations for me using that strategy.
I like your note on unranked candidates.
Saying "in most elections" is an appropriate prediction that I think would help to put many voter's minds at ease about understanding how the method works.
"Margin" is not well defined here, i.e. voters may think it means that a bigger difference in ranks affects the calculation. Even with the note about skipped ranks, it's important that we make it clear that the focus is simply on finalists being ranked higher or lower than each other and that the magnitude (greater than 0) of the distance between their ranks is irrelevant. My latest language is as follows:
- Rank as many candidates as you would like.
- You are free to rank multiple candidates equally.
- Skipped ranks are simply ignored and will neither hurt nor help your vote.
- Ranked candidates are considered better than candidates left unranked.
<candidates and rankings>
- Candidates are compared in one-on-one matchups against every other candidate. In most elections, a single candidate will be preferred over all others, in which case that candidate is elected.
- Otherwise, all the candidates who tie for having won the most matchups become finalists; all other candidates are eliminated.
- For each finalist, subtract the number of times they lost to each other finalist from the number of times they beat each other finalist. The finalist with the highest total difference is elected.
While I like short and concise language, I think the extra clarity (redundancy) sprinkled throughout would be helpful voters.
I only mentioned Copeland to get people on this forum to click.
I like the method, in general. I think Condorcet compliance is more important than most other things, and if we can make it simpler for voters to understand (both before adoption, and following a specific election) awesome.
I think your wording and explanations could use improvement, since it doesn't really come off as simple to me. I don't know if the problem is the method or just the wording and explanation, my mind is open on that.
But your general approach -- make a Condorcet compliant method marketable -- I wholeheartedly support.
Don't worry if certain people want to argue that Score is better. Score is dead in the water, in my opinion. Pro-Score arguments are fine, but I wish they weren't use to derail every other discussion.
@rob I'm down to keep working on ballot language. I think we need to come up with several different versions and do real field testing because every voting enthusiast seems to have a different idea about how to shift it. The shortest explanation of the tally is actually a single sentence with two clauses:
Among the candidates who tie for winning the most head-to-head matchups, elect the candidate with the best average rank.
There's some ambiguity in there in my opinion because the word "among" is being leaned on heavily, and I don't like using the mathematically equivalent "best average rank" explanation because I think it's misleading to voters despite the line saying that skipped ranks are ignored. The point is there's definitely a range of how descriptive we can be with it.
@sass Yes that gets to the point quickly. I like.
This seems similar in spirit to the one I was proposing recently. The main difference is that mine used cardinal ballots (intended to be identical to STAR ballots, such as if the STAR people might want to offer a Condorcet version of STAR). But otherwise it was like yours in that it ran pairwise matchups first, and if there was a tie, fell back on the simplest way to resolve it.
So your single sentence could change one word and describe mine:
Among the candidates who tie for winning the most head-to-head matchups, elect the candidate with the best average score.
That said, I think yours makes more sense for pitching it to Yang's crew, since they seem to like ranked ballots.
I would guess that a Borda strategy might work the best
W'pedia lists for Borda: "When a voter utilizes compromising, they insincerely raise the position of a second or third choice candidate over their first choice candidate, in order to help the second choice candidate to beat a candidate they like even less. When a voter utilizes burying, voters can help a more-preferred candidate by insincerely lowering the position of a less-preferred candidate on their ballot. "
If the system incents such strategies, it's no better than FPtP.
@jack-waugh To me, a Borda strategy is more like filling the upper middle ranks with unknown fringe candidates. This backfires horribly when everyone does it.
I thought about it more today, though. There are five differences between my method and traditional Borda:
- The Borda calculations are performed only within the finalist set, which is extremely restrictive
- Equal ranks are allowed
- Skipped ranks are ignored
- There's no ballot completion requirement
- It uses tournament-style Borda count, which is a bit different
I think all of this combined is what allowed my method to hold up so well against Marcus' Borda strategies (which I didn't mention earlier). Regardless, the more rigorous testing, the better.
Marylander last edited by
@jack-waugh The fact that it's only a Borda count among the tied candidates matters. It would be easier to try to cheat Copeland's directly than to cheat the Borda count at the end. Although Copeland strategy and Borda strategy do have a fair bit in common.
@marylander Very much agree that it being Borda only to resolve ties is very significant.
I'm personally of the view that being "hard to cheat" almost requires it to be Condorcet compliant. This does that, of course. I don't want to distract from this discussion to argue that point further, but I just think it needs to be said that the important things here are a) it is Condorcet and b) it is easy to explain.
I'm not a fan of the name Ranked Advantage Voting (advantage doesn't mean much to me), but I like the idea: Voters rank the candidates, choose the candidate that beats the most pairwise, if there is a tie, the highest average ranking candidate wins.
There are two ways to relax ranking toward rating. One is to allow equal ranking, and the other is to allow skipped ranks (so they would make a difference). It would be conceivable to include either of these relaxations without the other. Include both, and you have rating rather than ranking. Your system allows equal ranking, but ignores skipping of ranks. The Arrow theorem states that ranking systems (i. e. system that relax neither restriction) cannot satisfy all of certain conditions that the theorem lists, all of which, incidentally, sound desirable. Can a system like yours, that allows equal ranking but ignores skipped ranks, meet all the conditions listed in the theorem? If not, which condition does your system fail?
@jack-waugh It fails Independence of Irrelevant Alternatives. Unlike Ranked STAR, Ranked Robin (the official name of this method) is not a score method disguised as a ranked method -- that's what Ranked STAR is for. Ranked Robin fills a different need.
Is IIA of the essence for confidence that a system is sufficiently resistant to spoiler effects or vote splitting, to be worthy of any attention based on a common goal of defeating two-party dominance and defeating the absolute control of all three branches of both levels of government by a system motivated only by quarterly corporate book profits?
Marylander last edited by
@jack-waugh I doubt full compliance with the mathematical definitions of criteria are incredibly important to the public perception of a system, because most of the public won't understand the formal definition of a criterion. IRV supporters who haven't dug too deep into voting theory will insist to you that it solves the spoiler problem.
On the other hand, when a pathological outcome occurs in practice, then people will get upset when the problem gets pointed out to them. If you talk to an IRV advocate about the "Lizard vs Wizard" race for Louisiana governor in 1991, they may well be able to see how the outcome reflects poorly on top-two runoff, yet not make the connection as to how that race reflects poorly on IRV as well.
@jack-waugh Like most criteria, looking at Independence of Irrelevant Alternatives through a pass/fail lens is reductive. The question is how independent of irrelevant alternatives is Ranked Robin? I think the answer to that, in practice, is "enough". The finalist set (typically just 1 candidate) is based on how many other candidates are beaten. If you add a weak candidate into the mix, then all of the top candidates who would make it into the finalist set each gain exactly 1 more win, which doesn't change anything meaningful. Only when we start getting into a 2nd Degree tiebreaker (see the electowiki page) that an irrelevant alternative could realistically swing what would be an unrealistic election.
multi_system_fan last edited by
@sass I think tiebraking rules are complex and based on intuitions, values, assumptions, (mis)understandings, personal hisorical experiences (good and bad) and this fuzziness. This makes them them very vulnerable to say bad press or campaigning of other voteting-method activists. Therefore I would prefer to adjust your method: remove all tiebraking rules and let voters vote about it on the same ballot as the main vote:
Most elections have a unique winner but sometimes ties can occur what shoud happen according to you?
1 new election
2 random selection
3 highest average ranking
4 some other tiebreak variant a
5 some other tiebreak variant b
what should happen according to you?
That's an interesting proposal. I note that your example offers a selection of procedures for breaking a tie. Is the voter to choose just one of those?
multi_system_fan last edited by
@jack-waugh yeah just simple choose one, most wins. I know in theory also ties could occur, you could argue for more expression or more complex, but I think this is fair and simple enough.