Answer: true
The graph is connected => m >= n-1
=> m = n-1+k
where k >= 0
.
But m <= n(n-1)/2
because you don't need more edges if you have an edge between every 2 nodes. => n-1+k <= n(n-1)/2
=> k <= (n-1)(n/2-1)
=> k <= (n-1)(n-2)/2
.
So, we have m = n - 1 + k
where 0 <= k <= (n-1)(n-2)/2
; k
represents the number of edges which exceed the minimum number necessary for connectivity.
O(m+n) = O(n-1+k+n) = O(2n-1+k) = O(2n+k) = a
O(m) = O(n-1+k) = O(n+k) = b
Now, let's take 3 situations:
lim(n->inf) n/k = 0
a = O(k(2n/k + 1)) = O(k)
b = O(k(n/k + 1)) = O(k)
lim(n->inf) n/k = constant
a = O(2*constant*k + k) = O(another_constant * k) = O(k)
b = O(constant*k + k) = O(another_constant2 * k) = O(k)
lim(n->inf) n/k = inf
=> lim(n->inf) k/n = 0
a = O(n(2 + k/n)) = O(2n) = O(n)
b = O(n(1 + k/n)) = O(n)
So, in every case this is true.