# Interviewstreet puzzle. How many edges needed for a random graph to become connected

This is Interviewstreet puzzle:

We have a country containing N cities. Each day we choose 2 cities such that there is no road between them and build a road between them. We choose each pair of nonadjacent cities with equal probability. Let X be the number of days before we obtain a connected country. What is the expected value of X? Output the integer part of answer.

What they are really asking is what number of edges m is needed (on average) for a random graph G(n, m) to become connected.

After writing a program that actually performed the experiment, I came up with this 'solution' that passes 9/10 tests

``````\$f = fopen('php://stdin', 'r');
\$n = intval(fgets(\$f));
echo round(1.25 * \$n * log(\$n, 10));
``````

So can it be solved with a single formula? What is the right way of finding likelihood of connectedness of random graph?

-
how should I interpret this: "we choose 2 cities such that there is no road between them"? Let's say that there is a road between A-B, and B-C, is it possible for the algorithm to choose a road A-C?? – Gevorg Feb 4 '12 at 19:10
Yes, if there are only 3 cities (A, B and C), the only remaining pair without a road is A-C. But the country will be already connected with just 2 roads. – Eugene Xa Feb 4 '12 at 19:15
That's a special case: if there are only three cities, no one road will result in a connected country, but any two roads will. For four cities, the chance that the third road connects the country is 80%, and otherwise the fourth road always will, so the estimated number of days is 3.2 (to be truncated to 3). Is that a correct interpretation of the question? – hvd Feb 4 '12 at 19:43
Actually, I'm not sure anymore. What does nonadjacent mean in this context? Is it meant as "cities that don't have a road between them"? Because that's not what the word usually means. The question also doesn't address how a road can be built between A and C, if A is completely surrounded by B. If that's not possible -- it physically isn't -- then the answer doesn't depend solely on N. – hvd Feb 4 '12 at 19:53
@hvd, you first interpretation is absolutely correct. – Eugene Xa Feb 4 '12 at 20:06

You should check out the classic paper of Erdos and Renyi from 1960 entitled "On the evolution of random graphs". It contains complete probabilistic bounds for number of components, size of the largest components, etc.

Here's a bit of the math set-up to get you started.

Let `G(n,m)` be the simple random graph on `n` vertices with `m` edges. Let `X_k` be the number of edges added while there are `k` connected components until there are `k-1` connected components. For example, initially there are `n` connected components, so adding the first edge results in `n-1` connected components so `X_n = 1`. Similarly, the second edge also removes a component (though this happens in one of two ways) so `X_n-1 = 1` as well. Define

``````X = X_n + X_n-1 + ... + X_2
``````

The goal is to compute `E(X)`, the expected value of `X`. By additivity, we have

``````E(X) = E(X_n) + E(X_n-1) + ... + E(X_2)
``````

It's not too hard to show that the probability that an edge added while there are `k` components reduces the number of components has a lower bound of `(k-1)/(n-1)`. Since `X_k` is the random variable with probability of success given by this amount, the lower bound gives an upper bound for the expectation of `X_k`:

``````E(X_k) <= (n-1)/(k-1)
``````

Combining this, we get an asymptotic upper bound for `E(X)` by `n log n`.

With a bit more work and some hints from the Erdos-Renyi paper, you can probably deduce an exact formula.

-
I'm not sure what you mean by "initially there are n connected components". Isn't the whole point that we don't know how many vertices are connected. How does adding an edge result in fewer connected components. Am I confusing what you mean by connected components. I assume it means connected vertices. – Scott Jun 11 '12 at 23:44

OP's is a great solution and with a slight modification to the formula, it will always pass.

``````\$f = fopen('php://stdin', 'r');
\$n = intval(fgets(\$f));
echo round(1.249 * \$n * log(\$n, 10));// constant factor is changed
``````
-