I entered in "does $2ln(x)$ equal $ln(x^2)$" into Wolfram and it came out false. Purplemath.com says that $log_b(m^n) = n · log_b(m)$. Which is correct? And why is there a difference?
-
1Domains/quantification. – Git Gud Jun 25 '15 at 21:50
-
Instead try typing "solve 2*ln(x)=ln(x^2)." – J. W. Perry Jun 25 '15 at 21:59
-
1I am not certain that the domain issue that the various answers pointed out is the entire story. Otherwise, "does $2\ln|x|$ equal $\ln(x^2)$?" should return true, which it doesn't. – EuYu Jun 25 '15 at 22:01
-
@EuYu that is a good point. I guess we are all just trying to provide a justification for Wolfram Alpha's answer, when the question was if Wolfram Alpha is interpreting it correctly. Your comment suggests that it might not be. – Joel Jun 25 '15 at 22:57
-
1It seems that WA considers $\ln 0=-\infty$. Since both $\ln |0|$ and $\ln 0^2$ equal $-\infty$, it cautiously does not claim they are equal. – vadim123 Jun 25 '15 at 23:11
-
1@EuYu Inputting $ 2\ln|x|- \ln(x^2)$ gives a function defined on $\mathbb{R}^*$ which it claims is non-zero. This is incorrect, of course, and seems to come from an approximation error (an incorrect graph is provided at scale -10.4 to 10.4). WA claims the function is zero on $x>0$, so it seems to me mysterious as to where the approximation error comes from. Note that if one replaces $x^2$ by $|x|^2$ WA returns the correct result. I initially thought WA was looking at complex numbers, giving a possible explanation for the false flag, but the output I get shows this is not the case. – guest Jun 25 '15 at 23:34
-
solve 2 ln(x) = ln(x^2) will give the interval $(0, \infty)$ – Steven Alexis Gregory May 16 '19 at 01:24
4 Answers
For positive real $x$, $$2\ln(x) = \ln(x^2).$$
As others have pointed out, this does not hold for all reals.
The domain of $f(x)=\ln(x^2)$ is $(-\infty, 0)\cup (0,\infty)$, while the domain of $g(x)=2\ln(x)$ is $(0,\infty)$. Functions that have different domains are different functions.
- 16,256
No, it isn't.
When you say $f(x) = g(x)$, where $x$ is not a precise value, what is implied is that you are saying $f \equiv g$; that's, $f$ and $g$ are identical as mappings.
This is clearly false here, because $\ln(\cdot)$ is defined only on $(0, \infty)$, whereas $\ln(\cdot^2)$ is defined on $(-\infty, \infty) \setminus \{0\}$.
In brief, your input is not understood as an equality between two values, but as an identification of two functions.
Let $x=-1$. Then, $$2\ln(-1) \Rightarrow \;\; \text{undef}$$ and $$\ln[(-1)^2] = \ln(1) = 0$$
So not always.
- 4,522