Let's take a look at the definition of big-O notation.
f ∈ O(g) <=> (∃ x) (∃ c > 0) (∀ y > x) (|f(y)| <= c*|g(y)|)
The right hand side can be formulated "the quotient
f/g is bounded for sufficiently large
So to prove that
f ∈ O(g), look at the quotient, choose a (largish)
x and try to find a bound.
For the first case, the quotient is
x^7 / x^10 = 1/x^3
A bound for
x >= 1 is obvious.
f ∈ O(g), look at the quotient and prove that it assumes values of arbitrarily large modulus on each interval
[x, ∞). Assume an arbitrary
c > 0, and prove that for any
x, there is an
y > x with
|f(y)/g(y)| > c.
That should give enough of a hint.
x^3> c for
x >= c+1.