The present invention provides a measurement apparatus for measuring a velocity of a measurement object in a moving direction, including an optical system configured to divide each of lights emitted from a light source unit into first light and second light and irradiate the measurement object with the lights such that the first light and the second light overlap to form an interference fringe at different positions in a direction orthogonal to the moving direction in correspondence with wavelengths of the lights, wherein a first wavelength of the first light is different from a second wavelength of the second light, a first detection unit configured to detect the light from the measurement object, and a processing unit configured to obtain the velocity based on a change in an intensity of the light detected by the first detection unit.

The invention relates to a method and system for monitoring at least one parameter of an object. There is provided an imaging system for monitoring at least one parameter of movement of a moving object, the system comprises at least one imaging unit comprising an optical transformer configured and operable for applying spatial image space transformation of at least one parameter of movement into geometric relation, by translating different components of six degrees of freedom of movement in a three-dimensional space into a lateral translation; wherein the imaging unit is configured and operable for imaging the moving object on an image plane and generating image data indicative of the moving object in an x-y plane; the imaging system generating motion data indicative of the six degrees of freedom of movement.

The present invention relates to systems and methods of monitoring velocity or flow in channels, especially in microfluidic channels. In some embodiments, the present invention relates to systems and methods of monitoring velocity or flow rate in systems and methods for performing a real-time polymerase chain reaction (PCR) in a continuous-flow microfluidic system.

The invention relates to a method and a corresponding apparatus for measuring distance and optionally speed, in particular for multiscale distance measurement. The method comprises generating a first and a second frequency comb signal (201, 202), wherein the first and second frequency comb signals (201, 202) have different line spacings; a reference measurement comprising superimposing the at least one part of the first frequency comb signal (201) and at least one part of the second frequency comb signal (202) in a reference beam path (103) and detecting the superimposition signal propagated by the reference beam path; a first measurement comprising superimposing at least one part of the second frequency comb signal (202) on the at least one part of the first frequency comb signal (201), injecting the superimposition signal into a measurement beam path (104) and detecting the superimposition signal propagated by the measurement beam path; and determining the path difference between the reference beam path (103) and the measurement beam path (104) from the detected superimposition signals.

The present invention relates to a method for measuring the diameter and/or the geometry of the diameter of a cylindrical object. The cylindrical object has a longitudinal axis and a cylindrical shell. The method comprises measuring in a contactless manner at a specific point in the direction of the longitudinal axis the momentary circumferential velocity of the cylindrical shell at specific time or the distance which the circumference of the cylindrical shell rotates, measuring revolutions of the cylindrical shell or the angle of rotation of the cylindrical shell simultaneously with the measuring of the momentary circumferential velocity at specific time or the distance which the circumference of the cylindrical shell rotates, and calculating the diameter of the cylindrical shell and/or the geometry of the diameter of the cylindrical shell at the specific point in the direction of the longitudinal axis. The present invention also relates to a measurement system for measuring the diameter and/or the geometry of the diameter of a cylindrical object and the use of the measurement system.

The invention is related to a laser diode based multiple beam laser spot imaging system for characterization of vehicle dynamics. A laser diode based, preferably VCSEL based laser imaging system is utilized to characterize the vehicle dynamics. One or more laser beams are directed to the road surface. A compact imaging system including an imaging matrix sensor such as a CCD or CMOS camera measures locations or separations of individual laser spots. Loading status of vehicles and vehicles' pitch and roll angle can be characterized by analyzing the change of laser spot locations or separations.

There is provided a scattered light signal measurement apparatus and an information processing apparatus that are capable of performing accurate measurement while preventing noise due to changes in relative velocity and relative position caused between a sensor and an observation target. The scattered light signal measurement apparatus includes a light receiving element and an incident angle limiting unit. The light receiving element receives scattered light obtained when coherent light emitted to a measurement target is scattered by the measurement target. The incident angle limiting unit limits an incident angle of the scattered light that is incident on a single point of the light receiving element to be equal to or smaller than a predetermined angle and controls the single light receiving element to increase an aperture ratio.

A velocimeter configured to detect light modulated by a moving object with a Doppler effect and measure a velocity of the object includes a detector configured to detect the light, and a processor configured to perform binarization of a signal obtained by the detector, and measure a time duration over a predetermined number of pulse intervals in the signal obtained by the binarization to obtain a measurement value of the velocity. The processor is configured to determine the measurement value as an error based on a change in an index relating to the time duration.

Disclosed herein are electronic devices having touch input surfaces. A user's touch input or press on the touch input surface is detected using a set of lasers, such as vertical-cavity surface-emitting lasers (VCSELs) that emit beams of light toward the touch input surface. The user's touch causes changes in the self-mixing interference within the VCSEL of the emitted light with reflected light, such as from the touch input surface. Deflection and movement (e.g., drag motion) of the user's touch is determined from detected changes in the VCSELs' operation due to the self-mixing interference.

Disclosed herein are electronic devices having touch input surfaces. A user's touch input or press on the touch input surface is detected using a set of lasers, such as vertical-cavity surface-emitting lasers (VCSELs) that emit beams of light toward the touch input surface. The user's touch causes changes in the self-mixing interference within the VCSEL of the emitted light with reflected light, such as from the touch input surface. Deflection and movement (e.g., drag motion) of the user's touch is determined from detected changes in the VCSELs' operation due to the self-mixing interference.