Abstract: An atomic force microscope includes a cantilever operating in amplitude modulation mode. A controller determines the amplitude of the cantilever oscillation by processing a signal representative of the cantilever motion by square-rooting a signal having a value substantially equal to a sum of a square of the received signal and a squared and phase-shifted version of the received signal. The aforementioned processing, in some implementations is implemented using analog circuit components.

Abstract: An atomic force microscope includes a cantilever operating in amplitude modulation mode. A controller determines the amplitude of the cantilever oscillation by processing a signal representative of the cantilever motion by square-rooting a signal having a value substantially equal to a sum of a square of the received signal and a squared and phase-shifted version of the received signal. The aforementioned processing, in some implementations is implemented using analog circuit components.

Abstract: An atomic force microscope includes a cantilever operating in amplitude modulation mode. A controller determines the amplitude of the cantilever oscillation by processing a signal representative of the cantilever motion by square-rooting a signal having a value substantially equal to a sum of a square of the received signal and a squared and phase-shifted version of the received signal. The aforementioned processing, in some implementations is implemented using analog circuit components.

Abstract: An atomic force microscope includes a cantilever operating in amplitude modulation mode. A controller determines the amplitude of the cantilever oscillation by processing a signal representative of the cantilever motion by square-rooting a signal having a value substantially equal to a sum of a square of the received signal and a squared and phase-shifted version of the received signal. The aforementioned processing, in some implementations is implemented using analog circuit components.

Abstract: A method of operating an atomic force microscope, comprising a probe, the probe being moved forth and back during respective trace and retrace times of a scan line, the method comprising: a) during trace time, oscillating the probe, b) generating a z feedback signal to keep an amplitude of oscillation of the probe constant at a setpoint value, the z feedback signal being generated by a first feedback loop, c) during retrace time, placing the probe in a drift compensation state by changing the setpoint value to a different value so that the z feedback signal being generated by the first feedback loop causes the probe to move away from the sample and oscillate free, d) detecting an amplitude of free oscillation of the probe and adjusting with a second feedback loop its excitation signal to maintain the amplitude of free oscillation of the probe close to a set value.

Abstract: A method, apparatus and computer program are provided for automatically compensating a drift of a force applied by an Atomic Force Microscope during contact mode. The method makes it possible to automatically control and correct force drift in contact mode Atomic Force Microscopy. In a preferred embodiment, the present method includes steps measuring independently lateral and vertical vibration signals, analyzing theses signals and finally comparing theses signals to reference vibration signals. In a second embodiment, the vibration signals may be combined by means of an index, called force index.