-The system build by these authors is based on a Linnick
-interferometer~\cite{Sinclair:05}. It is illustrated in
-Figure~\ref{fig:AFM}. A laser diode is first split (by the splitter)
-into a reference beam and a sample beam that reaches the cantilever
-array. In order to be able to move the cantilever array, it is
-mounted on a translation and rotational hexapod stage with five
-degrees of freedom. The optical system is also fixed to the stage.
-Thus, the cantilever array is centered in the optical system which can
-be adjusted accurately. The beam illuminates the array by a
-microscope objective and the light reflects on the cantilevers.
-Likewise the reference beam reflects on a movable mirror. A CMOS
-camera chip records the reference and sample beams which are
-recombined in the beam splitter and the interferogram. At the
-beginning of each experiment, the movable mirror is fitted manually in
-order to align the interferometric fringes approximately parallel to
-the cantilevers. When cantilevers move due to the surface, the
-bending of cantilevers produce movements in the fringes that can be
-detected with the CMOS camera. Finally the fringes need to be
-analyzed. In~\cite{AFMCSEM11}, authors used a LabView program to
-compute the cantilevers' deflections from the fringes.
+The system built by these authors is based on a Linnick
+interferometer~\cite{Sinclair:05}. It is illustrated in Figure~\ref{fig:AFM}.
+A laser diode is first split (by the splitter) into a reference beam and a
+sample beam that reach the cantilever array. In order to be able to move the
+cantilever array, it is mounted on a translation and rotational hexapod stage
+with five degrees of freedom. The optical system is also fixed to the stage.
+Thus, the cantilever array is centered in the optical system which can be
+adjusted accurately. The beam illuminates the array by a microscope objective
+and the light reflects on the cantilevers. Likewise the reference beam reflects
+on a movable mirror. A CMOS camera chip records the reference and sample beams
+which are recombined in the beam splitter and the interferogram. At the
+beginning of each experiment, the movable mirror is fitted manually in order to
+align the interferometric fringes approximately parallel to the cantilevers.
+When cantilevers move due to the surface, the bending of cantilevers produce
+movements in the fringes that can be detected with the CMOS camera. Finally the
+fringes need to be analyzed. In~\cite{AFMCSEM11}, authors used a LabView program
+to compute the cantilevers' deflections from the fringes.