I feel like your notations are not accurate enough to write what you would like to write.
Let $\Sigma(S;K,T)$ denote the implied volatility of a European vanilla of strike $K$ and maturity $T$ now that the underlying spot price is worth $S$.
Sticky strike translates to
$$ \Sigma(S+\delta S;K,T) = \Sigma(S;K,T) \iff \color{blue}{\frac{\partial \Sigma}{\partial S}(S; K, T) = 0} $$
Sticky moneyness would require re-expressing the IV in the moneyness rather than absolute strike space by defining the function $$ \hat{\Sigma}(S;m,T) = \Sigma(S;K=S m, T)$$ and then write that
$$ \hat{\Sigma}(S+\delta S; m, T) = \hat{\Sigma}(S; m ,T) \iff \color{blue}{\frac{\partial \hat{\Sigma}}{\partial S}(S; m, T) = 0} $$
One can show that this stickiness assumption is the one embedded in space homogeneous diffusion models since
\begin{align}
\frac{\partial \hat{\Sigma}}{\partial S}(S; m, T) &= \frac{\partial \Sigma}{\partial S}(S; K, T) + m \frac{\partial \Sigma}{\partial K}(S; K, T) \\
&= \frac{\partial \Sigma}{\partial S}(S; K, T) + \frac{K}{S} \frac{\partial \Sigma}{\partial K}(S; K, T)
\end{align}
which is zero under a space homogeneous diffusion model because the following holds (would require a separate question to show that)
$$ S \frac{\partial \Sigma}{\partial S}(S; K, T) = - K \frac{\partial \Sigma}{\partial K}(S; K, T) $$
The other definitions you mention are actually equivalent to the sticky moneyness, in the sense that it amounts to considering not $\Sigma(S; K, T)$ but rather a re-expression of the IV in a spatial dimension $\theta$ such that
$$\hat{\Sigma}(S; \theta, T) = \Sigma(S; K = S f(\theta), T) $$
For instance in a sticky delta you would have
$$ \frac{\partial \hat{\Sigma}(S; \Delta, T)}{\partial S} = 0 $$
Intuitively, it's equivalent to sticky moneyness because for the $\Delta$ to remain constant, everything else being equal, it's the same as for $K/S$ (or $\ln(K/S)$) to remain constant. More formally, you can re-use the same argument as the one I just hinted above.
