Question

By applying the rules for natural logarithms, how could 2ln|x| be expressed so that the absolute value symbol is not required? Help?!

Answer 1

`ln(x^2)`

Explanation:

Apply the power rule for logarithms

`2ln|x|=ln(|x|^2)`

As we know, the square of a positive or negative number is always positive, so

`|x|^2=x^2`

and the answer becomes `ln(x^2)`.

Answer 2

`2ln|x| = ln(x^2); x!=0`

Explanation:

A property of logarithms is:

`cln(a) = ln(a^c)`

If we do this to the given logarithm

`2ln|x| = ln|x^2|`

We can drop the absolute value symbol:

`2ln|x| = ln(x^2)`

Please understand that the absolute value symbol is there

`2ln|x| = ln(x^2)`

to prevent a negative number from being entered into the logarithm. No logarithm can take a negative number. Try this on your calculator:

`ln(-1)`

or any negative number.

You receive an error message.

We can drop the absolute value, because `x^2` can never be negative.

There is still something missing, in either case, `x !=0`

No logarithm can take 0 as an argument. Try it.

`ln(0) = **ERROR**`

Therefore, we must always stipulate that `x != 0` with or without the absolute value symbol.

`2ln|x| = ln(x^2); x!=0`