If f(x) = O(g(x)) as x -> infinity, then
A. g is the upper bound of f
B. f is the upper bound of g.
C. g is the lower bound of f.
D. f is the lower bound of g.
Can someone please tell me when they think it is and why?
If f(x) = O(g(x)) as x -> infinity, then
A. g is the upper bound of f
B. f is the upper bound of g.
C. g is the lower bound of f.
D. f is the lower bound of g.
Can someone please tell me when they think it is and why?
The real answer is that none of these is correct.
The definition of big-O notation is that:
|f(x)| <= k|g(x)|
for all x > x0
, for some x0
and k
.
In specific cases, |k|
might be less than or equal to 1, in which case it would be correct to say that "|g| is the upper bound of |f|". But in general, that's not true.
Answer
g is the upper bound of f
When x goes towards infinity, worst case scenario is O(g(x))
. That means actual exec time can be lower than g(x)
, but never worse than g(x)
.
EDIT:
As Oli Charlesworth pointed out, that is only true with arbitrary constant k <= 1 and not in general. Please look at his answer for the general case.
k.g
is the upper bound of f
" would be correct.
Apr 30, 2011 at 15:25
|f(n)| <= k|g(n)|
for all n > n0
, where n0
and k
are constants to be found. Your answer assumes that k=1
.
Apr 30, 2011 at 15:54
The question checks your understanding of the basics of asymptotic algebra, or big-oh notation. In
f(x) = O(g(x))
asx
approaches infinity
the question says that when you feed the function f
a value x
, the value which f
computes from x
is then in the order of that returned from another function, g(x)
. As an example, suppose
f(x) = 2x
g(x) = x
then the value g(x)
returns when fed x
is of the same order as that f(x)
returns for x
. Specifically, the two functions return a value that is in the order of x
; the functions are both linear. It doesn't matter whether f(x)
is 2x
or ½x
; for any constant factor at all f(x)
will return a value that is in the order of x
. This is because big-oh notation is about ignoring constant factors. Constant factors don't grow as x
grows and so we assume they don't matter nearly as much as x
does.
We restrict g(x)
to a specific set of functions. g(x)
can be x
, or ln(x)
, or log(x)
and so on and so forth. It may look as if when
f(x) = 2x
g(x) = x
f(x)
yields values higher than g(x)
and therefore is the upper bound of g(x)
. But once again, we ignore the constant factor, and we say that the order-of upper bound, which is what big-oh is all about, is that of g(x)
.