Distance from root of random walk on regular tree
$begingroup$
Let $G$ be the $k$-regular tree (a tree where every vertex has degree $k$), and let $X_n$ be a random walk on $G$ that follows the transition probabilities induced by the edge weights of $G$, which are uniformly 1. Let $d_n$ be the distance of $X_n$ from it's starting position after $n$ steps.
I am trying to show that $d_n/n$ almost surely converges to some limit, and I am also trying to find this limit (as a function of $k$).
I tried computing the case where $X_n$ starts from the root by finding the number of ways that $d_n = m$ for some $m < n$, and using that to get an expression for $E(d_n)$. I ended up getting an incredibly complicated expression, that was not at all illustrative in terms of solving the above problem.
I figure that I must be approaching this problem wrong, and that there must be some other way to look at it, which is why I am posting here, hoping that somebody can point me in the right direction.
probability probability-theory graph-theory markov-chains random-walk
$endgroup$
add a comment |
$begingroup$
Let $G$ be the $k$-regular tree (a tree where every vertex has degree $k$), and let $X_n$ be a random walk on $G$ that follows the transition probabilities induced by the edge weights of $G$, which are uniformly 1. Let $d_n$ be the distance of $X_n$ from it's starting position after $n$ steps.
I am trying to show that $d_n/n$ almost surely converges to some limit, and I am also trying to find this limit (as a function of $k$).
I tried computing the case where $X_n$ starts from the root by finding the number of ways that $d_n = m$ for some $m < n$, and using that to get an expression for $E(d_n)$. I ended up getting an incredibly complicated expression, that was not at all illustrative in terms of solving the above problem.
I figure that I must be approaching this problem wrong, and that there must be some other way to look at it, which is why I am posting here, hoping that somebody can point me in the right direction.
probability probability-theory graph-theory markov-chains random-walk
$endgroup$
$begingroup$
What are the edge weights of $G$? You mention that you follow the transition probabilities they induce, but you never say what they are.
$endgroup$
– Misha Lavrov
Dec 2 '18 at 6:53
$begingroup$
Sorry. We can take all edge weights to be 1.
$endgroup$
– jackson5
Dec 2 '18 at 18:00
add a comment |
$begingroup$
Let $G$ be the $k$-regular tree (a tree where every vertex has degree $k$), and let $X_n$ be a random walk on $G$ that follows the transition probabilities induced by the edge weights of $G$, which are uniformly 1. Let $d_n$ be the distance of $X_n$ from it's starting position after $n$ steps.
I am trying to show that $d_n/n$ almost surely converges to some limit, and I am also trying to find this limit (as a function of $k$).
I tried computing the case where $X_n$ starts from the root by finding the number of ways that $d_n = m$ for some $m < n$, and using that to get an expression for $E(d_n)$. I ended up getting an incredibly complicated expression, that was not at all illustrative in terms of solving the above problem.
I figure that I must be approaching this problem wrong, and that there must be some other way to look at it, which is why I am posting here, hoping that somebody can point me in the right direction.
probability probability-theory graph-theory markov-chains random-walk
$endgroup$
Let $G$ be the $k$-regular tree (a tree where every vertex has degree $k$), and let $X_n$ be a random walk on $G$ that follows the transition probabilities induced by the edge weights of $G$, which are uniformly 1. Let $d_n$ be the distance of $X_n$ from it's starting position after $n$ steps.
I am trying to show that $d_n/n$ almost surely converges to some limit, and I am also trying to find this limit (as a function of $k$).
I tried computing the case where $X_n$ starts from the root by finding the number of ways that $d_n = m$ for some $m < n$, and using that to get an expression for $E(d_n)$. I ended up getting an incredibly complicated expression, that was not at all illustrative in terms of solving the above problem.
I figure that I must be approaching this problem wrong, and that there must be some other way to look at it, which is why I am posting here, hoping that somebody can point me in the right direction.
probability probability-theory graph-theory markov-chains random-walk
probability probability-theory graph-theory markov-chains random-walk
edited Dec 2 '18 at 18:01
jackson5
asked Dec 2 '18 at 4:13
jackson5jackson5
606512
606512
$begingroup$
What are the edge weights of $G$? You mention that you follow the transition probabilities they induce, but you never say what they are.
$endgroup$
– Misha Lavrov
Dec 2 '18 at 6:53
$begingroup$
Sorry. We can take all edge weights to be 1.
$endgroup$
– jackson5
Dec 2 '18 at 18:00
add a comment |
$begingroup$
What are the edge weights of $G$? You mention that you follow the transition probabilities they induce, but you never say what they are.
$endgroup$
– Misha Lavrov
Dec 2 '18 at 6:53
$begingroup$
Sorry. We can take all edge weights to be 1.
$endgroup$
– jackson5
Dec 2 '18 at 18:00
$begingroup$
What are the edge weights of $G$? You mention that you follow the transition probabilities they induce, but you never say what they are.
$endgroup$
– Misha Lavrov
Dec 2 '18 at 6:53
$begingroup$
What are the edge weights of $G$? You mention that you follow the transition probabilities they induce, but you never say what they are.
$endgroup$
– Misha Lavrov
Dec 2 '18 at 6:53
$begingroup$
Sorry. We can take all edge weights to be 1.
$endgroup$
– jackson5
Dec 2 '18 at 18:00
$begingroup$
Sorry. We can take all edge weights to be 1.
$endgroup$
– jackson5
Dec 2 '18 at 18:00
add a comment |
1 Answer
1
active
oldest
votes
$begingroup$
Finding an exact expression for $d_n$ is invariably going to lead to a messy formula that's probably the one you discovered, but it's not necessary to know the exact value of $d_n$ to find the limit.
First, there is a way to simplify the random walk. For our purposes, all vertices of $G$ at distance $d$ from the root are functionally identical: they all have a $frac1k$ probability of going up to a vertex at distance $d-1$ from the root, and a $1-frac1k$ probability of going down to a vertex at distance $d+1$ from the root. So instead of considering a random walk on $G$, we can consider a biased random walk on the states ${0,1,2,dots}$ where each step is $+1$ with a probability of $1-frac1k$ and $-1$ with a probability of $frac1k$. (Except at $0$, which goes to $1$ with probability $1$.)
It's easier to solve for the behavior of a related Markov chain, which is the same random walk, but on the integers ${dots,-2,-1,0,1,2,dots}$, with no awkward boundary condition. Here, the expected state after $n$ steps is $frac nk cdot (-1) + n cdot(1-frac1k) cdot (+1) = n(1 - frac2k)$. To go from this to the statement $lim_{n to infty} frac{d_n}{n} = 1 -frac2k$, we need some concentration inequality. Chebyshev's inequality should be sufficient, but in this case, we can use a Chernoff-type bound if we want to get tighter concentration, as well.
The random walk we got for analyzing the tree is slightly different: when we're at $0$, we don't have a $frac1k$ chance of moving to $-1$. However, we can argue that the same analysis applies: in both random walks, you only visit $0$ finitely many times, with probability $1$ (and in the random walk on the integers, with probability $1$ we eventually stay in the positive states forever). So the limit should be $1 - frac2k$ in your case as well.
$endgroup$
$begingroup$
I am having a hard time formally arguing that I get the same limit as the chain on the integers, can you elaborate on this a bit?
$endgroup$
– jackson5
Dec 2 '18 at 21:39
$begingroup$
Couple the two chains so that whatever the integer chain does, so does the tree chain unless it's at the root. If, in the first $n$ steps, the tree chain visits the root $r_n$ times, then its behavior differs from the integer chain's by at most $2r_n$. Since $r_n$ is bounded by a constant with probability $1$, $lim_{nto infty} frac{2r_n}{n} = 0$ (again, with probability $1$) and so you can ignore this effect.
$endgroup$
– Misha Lavrov
Dec 2 '18 at 21:48
$begingroup$
(To be more precise, "$r_n$ is bounded by a constant with probability $1$ is bad phrasing; I mean to say that $lim_{n to infty} r_n$ is finite with probability $1$. How this works out in practice is that every time you leave the root there's a probability depending on $k$ that you never return.)
$endgroup$
– Misha Lavrov
Dec 2 '18 at 22:37
$begingroup$
Yes, that makes sense!
$endgroup$
– jackson5
Dec 2 '18 at 22:39
add a comment |
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$begingroup$
Finding an exact expression for $d_n$ is invariably going to lead to a messy formula that's probably the one you discovered, but it's not necessary to know the exact value of $d_n$ to find the limit.
First, there is a way to simplify the random walk. For our purposes, all vertices of $G$ at distance $d$ from the root are functionally identical: they all have a $frac1k$ probability of going up to a vertex at distance $d-1$ from the root, and a $1-frac1k$ probability of going down to a vertex at distance $d+1$ from the root. So instead of considering a random walk on $G$, we can consider a biased random walk on the states ${0,1,2,dots}$ where each step is $+1$ with a probability of $1-frac1k$ and $-1$ with a probability of $frac1k$. (Except at $0$, which goes to $1$ with probability $1$.)
It's easier to solve for the behavior of a related Markov chain, which is the same random walk, but on the integers ${dots,-2,-1,0,1,2,dots}$, with no awkward boundary condition. Here, the expected state after $n$ steps is $frac nk cdot (-1) + n cdot(1-frac1k) cdot (+1) = n(1 - frac2k)$. To go from this to the statement $lim_{n to infty} frac{d_n}{n} = 1 -frac2k$, we need some concentration inequality. Chebyshev's inequality should be sufficient, but in this case, we can use a Chernoff-type bound if we want to get tighter concentration, as well.
The random walk we got for analyzing the tree is slightly different: when we're at $0$, we don't have a $frac1k$ chance of moving to $-1$. However, we can argue that the same analysis applies: in both random walks, you only visit $0$ finitely many times, with probability $1$ (and in the random walk on the integers, with probability $1$ we eventually stay in the positive states forever). So the limit should be $1 - frac2k$ in your case as well.
$endgroup$
$begingroup$
I am having a hard time formally arguing that I get the same limit as the chain on the integers, can you elaborate on this a bit?
$endgroup$
– jackson5
Dec 2 '18 at 21:39
$begingroup$
Couple the two chains so that whatever the integer chain does, so does the tree chain unless it's at the root. If, in the first $n$ steps, the tree chain visits the root $r_n$ times, then its behavior differs from the integer chain's by at most $2r_n$. Since $r_n$ is bounded by a constant with probability $1$, $lim_{nto infty} frac{2r_n}{n} = 0$ (again, with probability $1$) and so you can ignore this effect.
$endgroup$
– Misha Lavrov
Dec 2 '18 at 21:48
$begingroup$
(To be more precise, "$r_n$ is bounded by a constant with probability $1$ is bad phrasing; I mean to say that $lim_{n to infty} r_n$ is finite with probability $1$. How this works out in practice is that every time you leave the root there's a probability depending on $k$ that you never return.)
$endgroup$
– Misha Lavrov
Dec 2 '18 at 22:37
$begingroup$
Yes, that makes sense!
$endgroup$
– jackson5
Dec 2 '18 at 22:39
add a comment |
$begingroup$
Finding an exact expression for $d_n$ is invariably going to lead to a messy formula that's probably the one you discovered, but it's not necessary to know the exact value of $d_n$ to find the limit.
First, there is a way to simplify the random walk. For our purposes, all vertices of $G$ at distance $d$ from the root are functionally identical: they all have a $frac1k$ probability of going up to a vertex at distance $d-1$ from the root, and a $1-frac1k$ probability of going down to a vertex at distance $d+1$ from the root. So instead of considering a random walk on $G$, we can consider a biased random walk on the states ${0,1,2,dots}$ where each step is $+1$ with a probability of $1-frac1k$ and $-1$ with a probability of $frac1k$. (Except at $0$, which goes to $1$ with probability $1$.)
It's easier to solve for the behavior of a related Markov chain, which is the same random walk, but on the integers ${dots,-2,-1,0,1,2,dots}$, with no awkward boundary condition. Here, the expected state after $n$ steps is $frac nk cdot (-1) + n cdot(1-frac1k) cdot (+1) = n(1 - frac2k)$. To go from this to the statement $lim_{n to infty} frac{d_n}{n} = 1 -frac2k$, we need some concentration inequality. Chebyshev's inequality should be sufficient, but in this case, we can use a Chernoff-type bound if we want to get tighter concentration, as well.
The random walk we got for analyzing the tree is slightly different: when we're at $0$, we don't have a $frac1k$ chance of moving to $-1$. However, we can argue that the same analysis applies: in both random walks, you only visit $0$ finitely many times, with probability $1$ (and in the random walk on the integers, with probability $1$ we eventually stay in the positive states forever). So the limit should be $1 - frac2k$ in your case as well.
$endgroup$
$begingroup$
I am having a hard time formally arguing that I get the same limit as the chain on the integers, can you elaborate on this a bit?
$endgroup$
– jackson5
Dec 2 '18 at 21:39
$begingroup$
Couple the two chains so that whatever the integer chain does, so does the tree chain unless it's at the root. If, in the first $n$ steps, the tree chain visits the root $r_n$ times, then its behavior differs from the integer chain's by at most $2r_n$. Since $r_n$ is bounded by a constant with probability $1$, $lim_{nto infty} frac{2r_n}{n} = 0$ (again, with probability $1$) and so you can ignore this effect.
$endgroup$
– Misha Lavrov
Dec 2 '18 at 21:48
$begingroup$
(To be more precise, "$r_n$ is bounded by a constant with probability $1$ is bad phrasing; I mean to say that $lim_{n to infty} r_n$ is finite with probability $1$. How this works out in practice is that every time you leave the root there's a probability depending on $k$ that you never return.)
$endgroup$
– Misha Lavrov
Dec 2 '18 at 22:37
$begingroup$
Yes, that makes sense!
$endgroup$
– jackson5
Dec 2 '18 at 22:39
add a comment |
$begingroup$
Finding an exact expression for $d_n$ is invariably going to lead to a messy formula that's probably the one you discovered, but it's not necessary to know the exact value of $d_n$ to find the limit.
First, there is a way to simplify the random walk. For our purposes, all vertices of $G$ at distance $d$ from the root are functionally identical: they all have a $frac1k$ probability of going up to a vertex at distance $d-1$ from the root, and a $1-frac1k$ probability of going down to a vertex at distance $d+1$ from the root. So instead of considering a random walk on $G$, we can consider a biased random walk on the states ${0,1,2,dots}$ where each step is $+1$ with a probability of $1-frac1k$ and $-1$ with a probability of $frac1k$. (Except at $0$, which goes to $1$ with probability $1$.)
It's easier to solve for the behavior of a related Markov chain, which is the same random walk, but on the integers ${dots,-2,-1,0,1,2,dots}$, with no awkward boundary condition. Here, the expected state after $n$ steps is $frac nk cdot (-1) + n cdot(1-frac1k) cdot (+1) = n(1 - frac2k)$. To go from this to the statement $lim_{n to infty} frac{d_n}{n} = 1 -frac2k$, we need some concentration inequality. Chebyshev's inequality should be sufficient, but in this case, we can use a Chernoff-type bound if we want to get tighter concentration, as well.
The random walk we got for analyzing the tree is slightly different: when we're at $0$, we don't have a $frac1k$ chance of moving to $-1$. However, we can argue that the same analysis applies: in both random walks, you only visit $0$ finitely many times, with probability $1$ (and in the random walk on the integers, with probability $1$ we eventually stay in the positive states forever). So the limit should be $1 - frac2k$ in your case as well.
$endgroup$
Finding an exact expression for $d_n$ is invariably going to lead to a messy formula that's probably the one you discovered, but it's not necessary to know the exact value of $d_n$ to find the limit.
First, there is a way to simplify the random walk. For our purposes, all vertices of $G$ at distance $d$ from the root are functionally identical: they all have a $frac1k$ probability of going up to a vertex at distance $d-1$ from the root, and a $1-frac1k$ probability of going down to a vertex at distance $d+1$ from the root. So instead of considering a random walk on $G$, we can consider a biased random walk on the states ${0,1,2,dots}$ where each step is $+1$ with a probability of $1-frac1k$ and $-1$ with a probability of $frac1k$. (Except at $0$, which goes to $1$ with probability $1$.)
It's easier to solve for the behavior of a related Markov chain, which is the same random walk, but on the integers ${dots,-2,-1,0,1,2,dots}$, with no awkward boundary condition. Here, the expected state after $n$ steps is $frac nk cdot (-1) + n cdot(1-frac1k) cdot (+1) = n(1 - frac2k)$. To go from this to the statement $lim_{n to infty} frac{d_n}{n} = 1 -frac2k$, we need some concentration inequality. Chebyshev's inequality should be sufficient, but in this case, we can use a Chernoff-type bound if we want to get tighter concentration, as well.
The random walk we got for analyzing the tree is slightly different: when we're at $0$, we don't have a $frac1k$ chance of moving to $-1$. However, we can argue that the same analysis applies: in both random walks, you only visit $0$ finitely many times, with probability $1$ (and in the random walk on the integers, with probability $1$ we eventually stay in the positive states forever). So the limit should be $1 - frac2k$ in your case as well.
answered Dec 2 '18 at 19:34
Misha LavrovMisha Lavrov
44.9k556107
44.9k556107
$begingroup$
I am having a hard time formally arguing that I get the same limit as the chain on the integers, can you elaborate on this a bit?
$endgroup$
– jackson5
Dec 2 '18 at 21:39
$begingroup$
Couple the two chains so that whatever the integer chain does, so does the tree chain unless it's at the root. If, in the first $n$ steps, the tree chain visits the root $r_n$ times, then its behavior differs from the integer chain's by at most $2r_n$. Since $r_n$ is bounded by a constant with probability $1$, $lim_{nto infty} frac{2r_n}{n} = 0$ (again, with probability $1$) and so you can ignore this effect.
$endgroup$
– Misha Lavrov
Dec 2 '18 at 21:48
$begingroup$
(To be more precise, "$r_n$ is bounded by a constant with probability $1$ is bad phrasing; I mean to say that $lim_{n to infty} r_n$ is finite with probability $1$. How this works out in practice is that every time you leave the root there's a probability depending on $k$ that you never return.)
$endgroup$
– Misha Lavrov
Dec 2 '18 at 22:37
$begingroup$
Yes, that makes sense!
$endgroup$
– jackson5
Dec 2 '18 at 22:39
add a comment |
$begingroup$
I am having a hard time formally arguing that I get the same limit as the chain on the integers, can you elaborate on this a bit?
$endgroup$
– jackson5
Dec 2 '18 at 21:39
$begingroup$
Couple the two chains so that whatever the integer chain does, so does the tree chain unless it's at the root. If, in the first $n$ steps, the tree chain visits the root $r_n$ times, then its behavior differs from the integer chain's by at most $2r_n$. Since $r_n$ is bounded by a constant with probability $1$, $lim_{nto infty} frac{2r_n}{n} = 0$ (again, with probability $1$) and so you can ignore this effect.
$endgroup$
– Misha Lavrov
Dec 2 '18 at 21:48
$begingroup$
(To be more precise, "$r_n$ is bounded by a constant with probability $1$ is bad phrasing; I mean to say that $lim_{n to infty} r_n$ is finite with probability $1$. How this works out in practice is that every time you leave the root there's a probability depending on $k$ that you never return.)
$endgroup$
– Misha Lavrov
Dec 2 '18 at 22:37
$begingroup$
Yes, that makes sense!
$endgroup$
– jackson5
Dec 2 '18 at 22:39
$begingroup$
I am having a hard time formally arguing that I get the same limit as the chain on the integers, can you elaborate on this a bit?
$endgroup$
– jackson5
Dec 2 '18 at 21:39
$begingroup$
I am having a hard time formally arguing that I get the same limit as the chain on the integers, can you elaborate on this a bit?
$endgroup$
– jackson5
Dec 2 '18 at 21:39
$begingroup$
Couple the two chains so that whatever the integer chain does, so does the tree chain unless it's at the root. If, in the first $n$ steps, the tree chain visits the root $r_n$ times, then its behavior differs from the integer chain's by at most $2r_n$. Since $r_n$ is bounded by a constant with probability $1$, $lim_{nto infty} frac{2r_n}{n} = 0$ (again, with probability $1$) and so you can ignore this effect.
$endgroup$
– Misha Lavrov
Dec 2 '18 at 21:48
$begingroup$
Couple the two chains so that whatever the integer chain does, so does the tree chain unless it's at the root. If, in the first $n$ steps, the tree chain visits the root $r_n$ times, then its behavior differs from the integer chain's by at most $2r_n$. Since $r_n$ is bounded by a constant with probability $1$, $lim_{nto infty} frac{2r_n}{n} = 0$ (again, with probability $1$) and so you can ignore this effect.
$endgroup$
– Misha Lavrov
Dec 2 '18 at 21:48
$begingroup$
(To be more precise, "$r_n$ is bounded by a constant with probability $1$ is bad phrasing; I mean to say that $lim_{n to infty} r_n$ is finite with probability $1$. How this works out in practice is that every time you leave the root there's a probability depending on $k$ that you never return.)
$endgroup$
– Misha Lavrov
Dec 2 '18 at 22:37
$begingroup$
(To be more precise, "$r_n$ is bounded by a constant with probability $1$ is bad phrasing; I mean to say that $lim_{n to infty} r_n$ is finite with probability $1$. How this works out in practice is that every time you leave the root there's a probability depending on $k$ that you never return.)
$endgroup$
– Misha Lavrov
Dec 2 '18 at 22:37
$begingroup$
Yes, that makes sense!
$endgroup$
– jackson5
Dec 2 '18 at 22:39
$begingroup$
Yes, that makes sense!
$endgroup$
– jackson5
Dec 2 '18 at 22:39
add a comment |
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What are the edge weights of $G$? You mention that you follow the transition probabilities they induce, but you never say what they are.
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– Misha Lavrov
Dec 2 '18 at 6:53
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Sorry. We can take all edge weights to be 1.
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– jackson5
Dec 2 '18 at 18:00