eulerbooks/notebooks/problem0015.ipynb

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    "# [Lattice Paths](https://projecteuler.net/problem=15)\n",
    "\n",
    "Let $f(m, n)$ equal the number of routes in an $m \\times n$ grid. Intuitively, if you start at the top left corner, you immediately have two choices - you can go down or right. If you go down, there are $f(m-1,n)$ routes in the $(m - 1) \\times n$ subgrid; if you go right, there are $f(m,n-1)$ routes in the $m \\times (n-1)$ subgrid. Therefore\n",
    "$$f(m,n) = f(m-1,n) + f(m,n-1)$$\n",
    "\n",
    "There are two trivial base cases: $f(m,0) = 1$ for any $m$ and $f(0,n) = 1$ for any $n$. From these facts, you can write a simple [memoized](https://en.wikipedia.org/wiki/Memoization) recursive function to solve this problem."
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    "from functools import cache\n",
    "\n",
    "@cache\n",
    "def f(m, n):\n",
    "    if m == 0:\n",
    "        return 1\n",
    "    if n == 0:\n",
    "        return 1\n",
    "    \n",
    "    return f(m - 1, n) + f(m, n - 1)"
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    "Then the answer is given by"
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   "source": [
    "f(20,20)"
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    "However, we can do better and give a non-recursive formula for $f$. It turns out, for an $m \\times n$ grid, there are $\\binom{m+n}{m}$ possible routes. Here's an outline of how you can prove this [inductively](https://en.wikipedia.org/wiki/Mathematical_induction):\n",
    "\n",
    "1. Prove $f(m, 0) = \\binom{m+0}{m} = 1$ for all $m$\n",
    "    1. Prove $f(0, 0) = \\binom{0 + 0}{0} = 1$\n",
    "    2. Assuming $f(j, 0) = \\binom{j+0}{j} = 1$ for some $j$, prove $f(j+1,0) = \\binom{j+1+0}{j+1} = 1$\n",
    "2. Assuming there exists some $k$ such that for all $m$, $f(m, k) = \\binom{m + k}{m}$, prove $f(m, k+1) = \\binom{m + k + 1}{m}$ for all $m$\n",
    "    1. Prove $f(0, k+1) = \\binom{0+k+1}{0} = 1$\n",
    "    2. Assuming $f(j, k+1) = \\binom{j+k+1}{j}$ for some $j$, prove $f(j+1,k+1) = \\binom{j+k+2}{j+1}$\n",
    "\n",
    "Note that there are *three* inductive proofs here - an overall induction on $m$ and nested inductions in both the base case and the induction step (yo dawg, I heard you like induction...).\n",
    "\n",
    "One useful identity for proving this, particularly in step 2, comes from [Pascal's triangle](https://en.wikipedia.org/wiki/Pascal%27s_triangle):\n",
    "$$\\binom{n}{k} = \\binom{n-1}{k} + \\binom{n-1}{k-1}$$"
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    "## Relevant sequences\n",
    "* Central binomial coefficients: [A000984](https://oeis.org/A000984)\n",
    "* General formula: [A046899](https://oeis.org/A046899)"
   ]
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