may the point is *nonlinearity*. my approach is from chaos theory ( fractals , multifractals,... ) and the range of input and parameter values of a nonlinear dynamical system have strong influence on the system behavior. this is because of the nonlinearity, in case of `tanh`

the type of nonlinearity in the interval [-1,+1] is different than in other intervals, i.e. in the range [10,*infinity*) it is approx. a constant.

any nonlinear dynamical system is only valid in a specific range for both parameters and initial value, see i.e. the *logistic map*. Depending on the range of parameter values and initial values the behavior of the logistic map is **completely different**, this is the *sensitivity to initial conditions*
RNNs can be regarded as nonlinear self-referential systems.

in general there are some remarkable similarities between nonlinear dynamical systems and neural networks, i.e. the **fading memory** property of Volterra series models in Nonlinear Systems Identification and the **vanishing gradient** in recurrent neural networks

strongly chaotic systems have the *sensitivity to initial conditions* property and it is not possible to reproduce this heavily nonlinear behavior neither by Volterra series nor by RNNs because of the fading memory, resp. the vanishing gradient

so the mathematical background could be that a nonlinearity is more 'active' in the range of a specific intervall while linearity is equally active anywhere ( it is linear or approx constant )

in the context of RNNs and monofractality / multifractality **scaling** has two different meanings. This is especially confusing because RNNs and nonlinear, self-referential systems are deeply linked

in the context of RNNs *scaling* means a **limiting of the range** of
input or output values in the sense of an *affine transformation*

in context of monofractality / multifractality *scaling* means that
the output of the nonlinear system has a *specific structure* that is
scale invariant in case of monofractals, self-affine in case of self-affine fractals ... where the *scale* is equivalent to a 'zoom level'

The link between RNNs and nonlinear self-referential systems is that they are both exactly that, nonlinear and self-referential.

in general *sensitivity to initial conditions* ( which is related to the **sensitivity to scaling** in RNNs ) and *scale invariance* in the resulting structures ( output ) only appears in **nonlinear** self-referential systems

the following paper is a good summary for multifractal and monofractal scaling in the output of a nonlinear self-referential system ( not to be confused with the scaling of input and output of RNNs ) : http://www.physics.mcgill.ca/~gang/eprints/eprintLovejoy/neweprint/Aegean.final.pdf

in this paper is a direct link between nonlinear systems and RNN : https://www.ncbi.nlm.nih.gov/pmc/articles/PMC4107715/ - *Nonlinear System Modeling with Random Matrices: Echo State Networks Revisited*