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Price 3.0

From Evolution and Games

Revision as of 22:25, 18 September 2010 by Julian.garcia (Talk | contribs)

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1 A model with frequency dependence
2 An A mutant in a population of B's
3 A B mutant in a population of A's
4 Comparing the two covariances

A model with frequency dependence

We go back to the asexual model, but now we will take a model with frequency dependence. This will be a bit more complicated, but we can still use a basic, well known model. Suppose there are $N$ individuals. They are paired randomly, and play a game in those pairs. The game gives them payoffs according to the following payoff matrix

$\begin{array}{ccc} & A & B \\ A & 1 & 0 \\ B & 0 & 1 \end{array}$

If $q i = 1$ , then that means that individual $i$ plays strategy $A$ , and $q i = 0$ means that individual $i$ plays strategy $B$ . Depending on the match, each individual gets a payoff $π i$ . The next generation is drawn, as before, one individual at a time. But now the probability that $i$ is drawn as a parent depends on the payoff, and not just on the own genotype.

$\mathbb{P}\left( i\text{ is chosen}\right) =\frac{\alpha \pi _{i}+\beta }{\sum_{j=1}^{N}\left( \alpha \pi _{j}+\beta \right) }$

We do the same procedure as before, but with a few different starting points.

An A mutant in a population of B's

Suppose $q 1 = 1$ and $q i = 0$ for $i = 2,..., N$ . The probability of any individual $i = 2,..., N$ to be matched with individual $1$ is $1 / (N - 1)$ .

The probability with which an individual $i$ with $q i = 1$ , who is matched to an individual $j$ with $q j = 0$ , is chosen is:

$p_{1,0,1}=\frac{\beta }{\left( N-2\right) \alpha +N\beta }$

The probability with which an individual $i$ with $q i = 0$ , who is matched to an individual $j$ with $q j = 0$ , is chosen is:

$p_{0,0,1}=\frac{\alpha +\beta }{\left( N-2\right) \alpha +N\beta }$

The probability with which an individual $i$ with $q i = 0$ , who is matched to an individual $j$ with $q j = 1$ , is chosen is:

$p_{0,1,1}=\frac{\beta }{\left( N-2\right) \alpha +N\beta }$

We can also compute the covariance of these two actual random variables. Let us start by computing expectations...

$\mathbb{E}\left[ X\right] =\frac{1}{N}$

[show details]

For symmetry reasons...

$\mathbb{E}\left[ Y\right] =1$

$\mathbb{E}\left[ XY\right] =\frac{\beta }{\left( N-2\right) \alpha +N\beta }$

[show details]

The Covariance is thus...

$Cov\left( X,Y\right) =\mathbb{E}\left[ XY\right] -\mathbb{E}\left[ X\right] \mathbb{E}\left[ Y\right] =\frac{\beta }{\left( N-2\right) \alpha +N\beta }-\frac{1}{N}$

A B mutant in a population of A's

Suppose $q 1 = 0$ and $q i = 1$ for $i = 2,..., N$ . The probability of any individual $i = 2,..., N$ to be matched with individual $1$ is $1 / (N - 1)$ .

The probability with which an individual $i$ with $q i = 0$ , who is matched to an individual $j$ with $q j = 1$ ...

$p_{0,1,N-1}=\frac{\beta }{\left( N-2\right) \alpha +N\beta }$

The probability with which an individual $i$ with $q i = 1$ , who is matched to an individual $j$ with $q j = 1$ ...

$p_{1,1,N-1}=\frac{\alpha +\beta }{\left( N-2\right) \alpha +N\beta }$

The probability with which an individual $i$ with $q i = 1$ , who is matched to an individual $j$ with $q j = 0$ ...

$p_{1,0,N-1}=\frac{\beta }{\left( N-2\right) \alpha +N\beta }$

So...

$\mathbb{P}\left( Y=k|X=0\right) =\binom{N}{k}\left( p_{0,1,N-1}\right)^{k}\left( 1-p_{0,1,N-1}\right) ^{N-k}=$

$\mathbb{P}\left( Y=k|X=1\right) =\frac{1}{N-1}\binom{N}{k}\left(p_{1,0,N-1}\right) ^{k}\left( 1-p_{1,0,N-1}\right) ^{N-k}+\frac{N-2}{N-1}\binom{N}{k}\left( p_{1,1,N-1}\right) ^{k}\left( 1-p_{1,1,N-1}\right) ^{N-k}$

This is pretty well defined, so we can also compute the covariance of these two actual random variables. Let us start with the expectations... $\mathbb{E}\left[ X\right] =\frac{N-1}{N}$

[show details]

For symmetry reasons...

$\mathbb{E}\left[ Y\right] =1$

$\mathbb{E}\left[ XY\right] = \frac{\left( N-2\right) \alpha +\left( N-1\right) \beta }{\left(N-2\right) \alpha +N\beta }$

[show details]

Thus....

$Cov\left( X,Y\right) =\mathbb{E}\left[ XY\right] -\mathbb{E}\left[ X\right] \mathbb{E}\left[ Y\right] =\frac{\left( N-2\right) \alpha +\left( N-1\right)\beta }{\left( N-2\right) \alpha +N\beta }-\frac{N-1}{N}$

Comparing the two covariances

If we compare these two covariances, for instance for $β = 0$ and $α = 1$ , then in the first case $C o v (X, Y) = - 1 / N$ , while in the second case $C o v (X, Y) = + 1 / N$ . This should not feel strange; it is a coordination game, and if everyone plays $B$ , then playing $A$ is a bad idea, but if everyone else plays $A$ too, then playing $A$ is a good idea. The model covariance is therefore not constant, and changes with the frequency of strategy $A$ .

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Category: Price equation

Price 3.0

From Evolution and Games

Contents

A model with frequency dependence

An A mutant in a population of B's

A B mutant in a population of A's

Comparing the two covariances