Let $E/F$ be a quadratic extension of nonarchimedean local field, and let $G$ be a reductive group over $E$, and $G(E)$ the $E$-points of $G$. (For my question, one may just assume $G=\operatorname{GL}_n$.) Now $G(E)$ can be viewed in two different way: the $F$ points of the restriction of scalar $G_1:=\operatorname{Res}_{E/F}G$, and the $E$-points of just $G_2:=G$. Their Langlands $L$-groups are respectively $$ ^LG_1=(G^\vee(\mathbb{C})\times G^\vee(\mathbb{C}))\rtimes W_F\qquad\text{and}\qquad ^LG_2=G^\vee(\mathbb{C})\times W_E, $$$$ {^LG_1}=(G^\vee(\mathbb{C})\times G^\vee(\mathbb{C}))\rtimes W_F\qquad\text{and}\qquad{^LG_2}=G^\vee(\mathbb{C})\times W_E, $$ where $G^\vee$ is the dual group of $G$ and for the semidirect product the nontrivial element in $W_F/ W_E$ acts by switching the two factors.
Now,assuming assuming the local Langlands correspondence, for each irreducible admissible representation of $G(E)$, one can associate local Langlands parameters $$ \varphi_1:WD_F\longrightarrow{^LG_1}\qquad\text{and}\qquad \varphi_2:WD_E\longrightarrow{^LG_2}, $$$$ \varphi_1:\operatorname{WD}_F\longrightarrow{^LG_1}\qquad\text{and}\qquad \varphi_2:\operatorname{WD}_E\longrightarrow{^LG_2}, $$ where $WD_F$$\operatorname{WD}_F$ and $WF_E$$\operatorname{WD}_E$ are the Weil-Deligne groups.
I believe there must be a way to pass from $\varphi_1$ to $\varphi_2$. But how?
