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jBillou edited figures/InferedPhaseCircadian/caption.tex
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\textbf{A.} Illustration of the relationship between the phase and the data. The slow down of the phase $\theta(t)$ (blue) corresponds to visible a deformation in the data (black) compared to the waveform for a linear phase (dashed gray).
\textbf{B.} The trajectory shown in panel A is plotted in the $(\theta,\phi)$ plane. Here $\phi(t)$ is linear ($\phi(t) = 2\pi/T_2 \times t$ ). The color scale shows the velocity of the trajectory in the $\theta$ direction (centered around the mean velocity) computed by taking the finite differences of $\theta(t)$. A similar plot for the data is shown in
Supplementary Figure \ref{fig:dataVelocity}.
\textbf{C.}
Mean and standard deviation of the circadian phase $\theta_t/2\pi$ (blue) inferred from the \revalphaYFP signal (black). The model is shown in red and the inferred amplitude $A_t$ (top) and background variables $B_t$ (bottom) in dashed gray. Divisions are indicated by red vertical lines, note that the typical dip in the signal due to nuclear breakdown was masked to avoid spurious deformation of the phase.