\begin{document}$ \delta G_F $\end{document}, and eight-parameter flavor-universal one. We discuss the amounts of tensions between different \begin{document}$ m_W $\end{document} measurements reflected in these fits and the corresponding shifts in central values of these parameters. With these electroweak fit pictures in hand, we present a few different classes of models and discuss their compatibility with these results. We find that while explaining the \begin{document}$ m_W $\end{document} discrepancy, the single gauge boson extensions face strong LHC direct search constraints unless the \begin{document}$ Z' $\end{document} is fermiophobic (leptophobic), which can be realized if extra vector fermions (leptons) mix with the SM fermions (leptons). Vector-like top partners can partially generate the needed shift to the electroweak observables. The compatibility with the top squark is also studied in detail. We find that the non-degenerate top squark soft masses enhance the needed operator coefficients, enabling an allowed explanation compatible with current LHC measurements. Overall, more theoretical and experimental developments are highly in demand to reveal the physics behind this discrepancy."> Speculations on the <i>W</i>-mass measurement at CDF -
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