A scanning probe microscope with a first actuator (3) configured to move a feature in the form of a tip (2) so that the feature follows a scanning motion. A vision system (10) is configured to collect light from a field of view to generate image data. The field of view includes the feature and the light from the field of view travels from the feature to the vision system via the steering element (13). A tracking control system (15)bis configured to generate one or more tracking drive signals in accordance with stored reference data. A second actuator (14) is configured to receive the one or more tracking drive signals and move the steering element on the basis of the one or more tracking drive signals so that the field of view follows a tracking motion which is synchronous with the scanning motion and the feature remains within the field of view. An image analysis system (20) is configured to analyse the image data from the vision system to identify the feature and measure an apparent motion of the feature relative to the field of view. A calibration system is configured to adjust the stored reference data based on the apparent motion measured by the image analysis system.

An atomic force microscope includes a raster scan control mechanism configured to perform a raster scan between a cantilever having a probe at a free end and a sample relative to each other across an XY plane in a fluid, an interaction control mechanism configured to vibrate the cantilever and to control an interaction generated between the probe and the sample, and a sample information acquisition circuit configured to acquire sample information including inclination information of a sample surface with respect to the XY plane based on a control result of the interaction control mechanism. The interaction control mechanism is configured to control the interaction generated between the probe and the sample in accordance with inclination of the sample surface with respect to the XY plane.

Provided is a scanning probe microscope, and in particular, a scanning probe microscope capable of scanning a large area using a probe including a plurality of conductive tips and capable of simply generating a surface image of a sample with high resolution by recognizing only two binary states of contact/non-contact between the conductive tips and a surface of the sample.

An active noise isolation apparatus and method for cancelling vibration noise from the probe signal of a scanning tunneling microscope by generating a correction signal by convolution based on the probe signal and the sensor signal, which is based on the ambient vibration that adds noise to the probe signal.

A method for commanding a tip of a probe is disclosed, wherein a command signal, representative of the force applied by said tip on the surface of a sample to be analyzed, includes at least one cycle successively defined by: a first step where the value of said command signal decreases from a maximum value (Smax) to a minimum value (Smin) so as to move said tip away from said surface at a predetermined distance called detachment height; a second step where the value of the command signal is maintained constant at said minimum value so as to maintain the tip at said detachment height; a third step where the value of the command signal increases from the minimum value up to said maximum value so as to bring the tip closer towards the surface to be analyzed until the tip comes into contact with the surface; and a fourth step where the value of the command signal is maintained constant at said maximum value to maintain the tip in contact with the surface to be analyzed under a constant force between the tip and the surface to be analyzed; the command signal being controlled between two successive steps to avoid any oscillation of the tip.

A measuring device for a scanning probe microscope including a sample receptacle configured to receive a sample; a measuring probe which is arranged on a probe holder and has a probe tip; a displacement device which moves the measuring probe and the sample receptacle relative to each other; a control device which is connected to the displacement device and controls the relative movement between the measuring probe and the sample receptacle; and a sensor device which is configured to detect, movement measurement signals during an absolute measurement for a movement of the measuring probe and/or a movement of the sample receptacle. The movement measurement signals are relayed to the control device. The control device is configured to control the relative movement. The invention also provides a scanning probe microscope, as well as a method for examining a sample.

An AFM that suppress parasitic deflection signals is described. In particular, the AFM may use a cantilever with a probe tip that is offset along a lateral direction from a longitudinal axis of torsion of the cantilever. During AFM measurements, an actuator may vary a distance between the sample and the probe tip along a direction approximately perpendicular to a plane of the sample stage in an intermittent contact mode. Then, a measurement circuit may measure a lateral signal associated with a torsional mode of the cantilever during the AFM measurements. This lateral signal may correspond to a force between the sample and the probe tip. Moreover, a feedback circuit may maintain, relative to a threshold value: the force between the sample and the probe tip; and/or a deflection of the cantilever corresponding to the force. Next, the AFM may determine information about the sample based on the lateral signal.

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.

To avoid applying overload on both a probe and a sample surface, and to reduce time for measuring irregular shapes on the sample surface in performing an intermittent measurement method, provided is a scanning probe microscope including: a cantilever having a probe attached thereto, the scanning probe microscope being configured to scan a sample surface by intermittently bringing the probe into contact with the sample surface; and a control device configured to perform a first operation of bringing the probe and the sample surface into contact with each other, and a second operation of separating the probe and the sample surface from each other after the first operation. The control device executes the second operation by thermally deforming the cantilever.

The invention relates to a measurement device (120), for example for testing, comprising a micromechanical positioning actuator (130) for causing movement of a sensor (150) with respect to a target (110), a positioning controller (145), the positioning controller (145) having an output coupled to the actuator (130) for controlling the movement, and the having an input coupled to the sensor (150) for receiving a sensor signal from the sensor (150) to the positioning controller (145), and the positioning controller (145) arranged to control the movement based on the sensor signal. The measurement device (120) may have memory for storing positioning control instructions (300). The positioning controller (145) may be arranged to control said movement based on said sensor signal and said positioning control instructions (300).