The problem is just showing that the Hausdorff outer measure scales as follows:
$$\mathcal{H}^{s,*} (cA) = c^s \mathcal{H}^{s,*}(A)$$
For some covering $\{E_k\}$ of $A$, we get that
$$cA \subset \cup_i (c E_i)$$
$$\mathrm{diam} (cE_i) < c \delta$$
where $\mathrm{diam} (S)$ is the diameter of the set $S$.
Therefore,
$$H_\delta^{s,*}(cA) \leq \sum_{i=1}^\infty (\mathrm{diam} (cE_i))^s = c^s \sum_{i=1}^\infty (\mathrm{diam}(E_i))^s$$
Take $\inf$ on both sides over the countable coverings of $A$
$$H_\delta^{s,*}(cA) \leq c^s H_\delta^{s,*}(A) \xrightarrow[]{\delta \to0} H^{s,*}(cA) \leq c^s H^{s,*}(A)$$
I am suposed to use $\frac{1}{c}A$ to obtain the remaining inequality, but since I have to go through the same procedure, I end up with
$$H^{s,*}(\frac{1}{c}A) \leq \frac{1}{c^s}H^{s,*}(A)$$
From here, I can't get
$$H^{s,*}(cA)\geq c^s H^{s,*}(A)$$
$H(A)=H(c^{-1}\cdot c\cdot A)\leq c^{-s}H(c\cdot A)$, so $c^{s}H(A)\leq H(c\cdot A)$.