Disclosed embodiments include a two-dimensional scale with a simple arrangement capable of omitting setting of an origin mark in the Y-axis direction. In a linear scale, a reference origin mark array and a tilting origin mark array that is a tilting marker array are provided in an origin mark region. Since the reference origin mark array is parallel to X-coordinates, an X-direction origin signal is correctly generated. On the other hand, for the Y direction in which no origin mark is provided, the distance between a reference origin mark and a tilting origin mark is detected. A Y-direction absolute position is decided in accordance with the distance.

The present invention relates to a system and method for modelling the physical characteristics of a building. Models of buildings, such as floor plans, are often produced when renovation work or other work is planned. Manual measurements maybe taken (e.g. using a tape measure or an optical distance meter), and these measurements are subsequently used by a draftsman to construct a model of the measured space. This is time consuming. The present invention provides a system and method Which includes a measurement and modelling process which assigns a unique identifier to openings that are shared by adjoining rooms when plotting measurements. These room associations are then used to determine the layout of the rooms within a building model. There is significantly less time and cost involved in generating a computer model of the measured space, using the present system and method.

The invention relates to a sensor device and method for detecting measurement data relating to the absolute position of a linearly or rotationally moveable body, comprising an optical sensor system, wherein the optical sensor system uses exclusively zero-order rejections for the position measuring, and a magnetic sensor system which emits a second sensor output signal depending on the position to be determined of the moveable body, wherein the gauge of the optical sensor system and the gauge of the magnetic sensor system are integrated in a common gauge body, and a computer unit which is provided to obtain the first sensor output signal and the second sensor output signal and to generate a common sensor output signal from the first sensor output signal and the second sensor output signal, wherein the current period of the second sensor system can be deduced from the first sensor output signal at every time, in order to calculate clear absolute position information based on the first and second sensor output signal.

By configuring an encoder scale as an angled or inclined magnet or pair of oppositely arranged, adjacent magnets, a magnetic field sensor in a travel path of the scale can detect an absolute position of the scale for use in an industrial control system. Due to the angle or incline, when a first side of the scale is proximal to the sensor, the sensor can detect an angle of 180. As the scale moves to center with respect to the sensor, the sensor can detect an increasing angle to 0. Then, as a second side of the scale becomes proximal to the sensor, the sensor can detect an increasing angle to +180. The angle changes linearly with position. In one aspect, the pair of oppositely arranged magnets can be rotated with respect to the travel path to provide the angle. In another aspect, the pair of oppositely arranged magnets can be magnetized diagonally to provide the angle.

The present invention provides a position detection apparatus that is provided with a scale and a detector and includes a processing unit configured to perform processing for setting a number of light receiving elements that are consecutive in a direction of relative movement and whose outputs are to be added for the light receiving elements so that, in a first resolution mode, a phase of a component of a fourth spatial frequency lower than a spatial frequency corresponding to a frequency offset amount is detected and, in a second resolution mode for which a resolution is lower than the first resolution mode, a phase of a component of a spatial frequency of an interference image of a second grating pattern is detected.

The invention relates to a detector device having pixels in a two-dimensional arrangement, the detector device comprising row pixels, a row readout wiring for each row of said row pixels and a column select wiring for each column of said row pixels, as well as column pixels, a column readout wiring for each column of said column pixels and a row select wiring for each row of said column pixels. Analog-to-digital converters adapted for row-parallel and column-parallel operation are connected to the readout wirings, and simultaneously one or more columns of row pixels for row parallel readout and one or more rows of column pixels for column parallel readout can be selected. The invention further relates to a positioning code and to a position detecting method.

The present disclosure may be embodied as an optical encoder system comprising a first optical sensor, a second optical sensor, a first up-down counter, a second up-down counter, and an I/O expander. The optical encoder system may further include a buffer. The present disclosure may also be embodied as an optical encoder system comprising an optical encoder, and a monostable multivibrator. The present disclosure may also be embodied as a method for encoding optical data comprising generating a first optical sensor signal and a second optical sensor signal, converting the first optical sensor signal and second optical sensor signal into four first counter signals, generating a borrow output signal and a carry output signal, converting the borrow output signal and the carry output signal into four second counter signals, and converting the first counter signals and second counter signals into a serial data signal and a serial clock signal.

An absolute position detection apparatus includes a calculator configured to generate, based on a detection signal, a first signal, and a second signal. A relative movement range of the scale and the sensor includes a boundary between adjacent detection units in the first signal such that at least one of the boundary is included in each of a plurality of areas in the relative movement range. The calculator is configured to specify a detection unit, to be used to calculate the absolute position, in the first signal based on a code of each detection unit of the second signal in an area that includes the boundary of the plurality of areas.

A code plate including a pattern thereon is provided. The pattern includes a first set of codes and a second set of codes. The first set of codes is associated with a first waveform. The second set of codes is associated with a second waveform.

An optical sensor for a delivery device having a piston that displaces a substance, such as a fluid, from a reservoir. The optical sensor has a light source and a detector array for imaging encoding features disposed along a plunger rod coupled to the piston. By virtue of the pattern of encoding features, an absolute position of the plunger rod relative to a fiducial position may be determined uniquely. Thus, the volume of fluid remaining in the reservoir, the rate of fluid delivery, and proper loading of the reservoir may be accurately ascertained. Additionally, the encoding may serve to uniquely identify a version of the reservoir which may be supplied in various versions corresponding, for example, to differing concentrations of a therapeutic agent to be dispensed.