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Could somebody tell me the definition of a "characteristic time"? For example, what is the characteristic time for a function $f(t)=\operatorname{tanh}(t)$ to reach 1? I tried looking up a definition, but  there seems not to be a universal definition. Is there a preferred definition?

Many thanks!

Context:

I have a vector $\begin{pmatrix}a \operatorname{sech} t\\ b\operatorname{tanh}t\\ c\operatorname{sech} t \end{pmatrix}$

I am asked what the "characteristic time" for the vector to align with $\begin{pmatrix} 0\\1\\0 \end{pmatrix}$

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    @AndréNicolas: Oh foo, I had it confused with hyperbolic sine. Could the OP be looking for something like the limiting subtangent relative to the asymptote, i.e. $\lim_{x\to\infty} \frac{1}{1-\tanh x}\frac{d}{dx}\tanh x$ (which ought to exist)?2012-07-16

2 Answers 2

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What is meant in this particular context is almost certainly that for large $t$, we can approximate $\begin{pmatrix} a \operatorname{sech} t \\ b\tanh t \\ c \operatorname{sech} t \end{pmatrix} \sim \begin{pmatrix}0 \\ b \\ 0\end{pmatrix} + e^{-t/k} \begin{pmatrix}p \\ q \\ r\end{pmatrix} + o(e^{-t/k})$ for appropriate constants $k$, $p$, $q$, $r$. The characteristic time of the approach to $(0,b,0)$ is then $k$.

(And your $b$ had better be $1$ for the question to make sense).


Hmm ... alternatively, "align with $(0,1,0)$" could mean the process of the direction of the vector approaching the direction of the positive $y$ axis. In that case the relevant approximation would be something like $ \frac{ \sqrt{a^2+c^2} \operatorname{sech} t }{ b \tanh t } \sim e^{-t/k} s + o(e^{-t/k}) $ for constants $k$ and $s$. Again $k$ is the characteristic time.

Here the left-hand side of this represents the angle between the vector and $(0,1,0)$ as seen from the origin, rather than the distance between your vector and $(0,1,0)$. Strictly speaking the left-hand side should arguably be $\tan^{-1}\left(\frac{\sqrt{a^2+c^2}\operatorname{sech}t}{b\tanh t}\right)$, but since $\tan^{-1}(x)\sim x$ for small $x$ anyway, it doesn't matter for the result.

(So much for "almost certainly").

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    ... _direction_ of the vector $(e^{-t}, 1+e^{-t/10})$ for large $t$, so the _direction_ it approaches "due up" with characteristic time $1$.2012-07-16
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The characteristic time is usually defined to be the time in which a quantity, in this case the deviation from $(0,b,0)$, decreases by $1/\mathrm e$. In the present case the functions don't decay exactly exponentially, but it still makes sense to speak of the characteristic time with respect to the leading terms for $t\to\infty$. These are

$\operatorname{sech} t=\frac2{\mathrm e^t-\mathrm e^{-t}}\approx2\mathrm e^{-t}$

and

$\operatorname{tanh} t-1=\frac{\mathrm e^t+\mathrm e^{-t}}{\mathrm e^t-\mathrm e^{-t}}-1=\frac{2\mathrm e^{-t}}{\mathrm e^t-\mathrm e^{-t}}\approx2\mathrm e^{-2t}\;.$

Thus the $y$ component decays twice as quickly as the other two, and the characteristic time of the approach could be said to be that of $\mathrm e^{-t}$, which is $1$.

(This is basically the same answer as Henning's, just with less rigour and more numbers.)

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    Also with a better explanation of the underlying concept (+1). (Except that I now think the operative limit is that of the _direction_ rather than the vector itself).2012-07-16