73results about How to "Uniform sensitivity" patented technology

A touch sensor panels having segmented electrodes for both the drive and sense lines. The touch sensor panel may include a number of columns of sense electrodes and a number of rows of drive electrodes. Each of the drive and sense electrodes are connected to one of the metal bus lines using a connecting trace. Pixels on the touch sensor panel are formed by the unique pairings of individual drive electrodes and their adjacent sense electrodes. Electrically, the mutual capacitance of one touch-sensing pixel can be distinguished from the mutual capacitance of another touch sensing pixel because the two mutual capacitances are formed with combinations of different drive electrodes and sense electrodes. In one embodiment, the drive electrodes and sense electrodes in adjacent columns are staggered horizontally with respect to each other by half a Y-pitch of the electrodes.

A photosensor is disposed in each pixel, and the brightness is adjusted for each pixel depending on the light quantity of an organic EL element. The adjustment of brightness is realized by making the current amount of a pixel with a high brightness small in accordance with a pixel with a small light emission amount. Thus, low power consumption can be achieved, and the unevenness of brightness can be corrected. By disposing the photosensor to configure a photoreceptor circuit in each pixel, the unevenness of brightness is corrected. Further, it becomes possible to correct brightness in a brightness half-life. Hence, a longer lifetime can be achieved.

An exemplary touch panel device includes a substrate, an insulating layer form on a surface of the substrate, a plurality of first electrode groups and a plurality of second electrode groups. Each first electrode group includes a plurality of first electrodes and a plurality of first connecting wires each electrically connecting two adjacent first electrodes. Each second electrode group includes a plurality of second electrodes and a plurality of bridge connecting wires each electrically connecting two adjacent second electrodes. The first electrode groups and the second electrodes of the second electrode groups are alternately formed on a surface of the insulating layer away from the substrate. The bridge connecting wires are formed on the surface of the substrate contacting with the insulating layer.

In one exemplary embodiment, a touch panel device includes a substrate, an insulating layer, a number of first electrode groups and a number of second electrode groups. The first electrode groups are formed on the first surface of the insulating layer. Each of the first electrode groups includes a number of first electrodes and a number of first leads. The first electrodes are spaced with each other. The first leads electrically connect each two adjacent first electrodes. Each of the second electrode groups includes a number of second electrodes and a number of bridge conductors electrically connecting each two adjacent second electrodes. The second electrodes are spaced with each other and are arranged on the first surface of the insulating layer. The first electrodes and the second electrodes are arranged in a staggered manner. The bridge conductors are formed on the second surface of the insulating layer.

A photosensor and a display unit are fabricated on the same substrate. Input coordinates are identified by comparing the light quantities at positions (pixels) which is and is not touched by a finger or the like by use of a comparison circuit. Thus, TFTs to form the photosensor can be fabricated on the same substrate in the same process, and also reductions in manufacturing cost and the number of parts can be realized. A region required for disposing a sensor in the circumference becomes unnecessary, thus realizing the miniaturization of the device. Moreover, since a region to be a blind spot is eliminated in the display unit, it is possible to utilize the display unit effectively. It is possible to improve the precision of an input recognition and to uniformly perform detection all over the display unit. Furthermore, since the photosensor is constituted of a photoreceptor circuit which is capable of adjusting the sensitivity of receiving light, it is possible to make the sensitivity of receiving light (detection) uniform in the display unit.

A touch panel includes a substrate comprising divided regions; first electrodes, each of the first electrodes comprising first rhombus patterns spaced apart a predetermined distance from each other in a predetermined first direction and first connection patterns configured to connect the first rhombus patterns second electrodes, each of the second electrodes comprising second rhombus patterns spaced apart a predetermined distance from each other in the second direction and second connection patterns configured to connect the second rhombus patterns; third electrodes formed in border areas between the divided regions and outer areas of the divided regions; a touch controller formed in each of the divided regions correspondingly; and pad electrodes connected with the touch controller.

Systems and methods for inspecting a surface of a specimen such as a semiconductor wafer are provided. A system may include an illumination system configured to direct a first beam of light to a surface of the specimen at an oblique angle of incidence and to direct a second beam of light to a surface of the specimen at a substantially normal angle. The system may also include a collection system configured to collect at least a portion of the first and second beams of light returned from the surface of the specimen. In addition, the system may include a detection system. The detection system may be configured to process the collected portions of the first and second beams of light. In this manner, a presence of defects on the specimen may be detected from the collected portions of the first and second beams of light.

A ring electrode design that produces a uniform mass sensitivity distribution across a TSM device is presented. A new technique and apparatus to measure this mass sensitivity distribution is also presented. Novel electrode geometries on thickness shear mode (TSM) quartz resonators achieve radial uniformity of mass sensitivity, how receptive the device is to mass loadings, and high frequency stability across the active sensing area of the sensor device. The device allows for absolute mass measurement down to the nanogram level. Fabricated devices utilizing model predictions were tested using this apparatus, and good agreement between theory and experiment is found.

In order to realize a surface inspection apparatus capable of inspecting a contaminant particle and a defect with a uniform sensitivity without depending on a rotation angle in a primary scan direction even in the case where intensity of scattered light, which is generated derived from the contaminant particle and the defect existing on the surface of a semiconductor wafer or adjacent to the surface, has anisotropy which depends on an illumination direction; light from a light source 11 becomes two illumination beams 21 and 22 by a beam splitter 12, the beams being irradiated onto a semiconductor wafer 100 from two mutually substantially orthogonal azimuthal angles having substantially equal elevation angles to form illumination spots 3 and 4. When the sum of scattered, diffracted, and reflected lights due to the illumination beams 21 and 22 is detected; influence of the anisotropy which a contaminant particle and a defect existing in the wafer 100 itself or thereon have with respect to an illumination direction, can be eliminated. This makes it possible to inspect a contaminant particle, defect, and the like with a uniform sensitivity without depending on a rotation angle in a primary scan direction even in the case where intensity of the scattered light generated derived from the contaminant particle, defect, and the like depends on the illumination direction.

A controller includes an operating member operable by user's depression, and a touch detection device constructed to detect a depressing touch on the operating member. The touch detection device includes a movable contact pattern provided on the lower surface of the operating member, and a fixed contact pattern disposed underneath the operating member. One of the fixed and movable contact patterns is a coil-shaped contact pattern while the other of the fixed and movable contact patterns is a uniform surface pattern, at least one of the fixed and movable contact patterns has flexibility, and at least one of the fixed and movable contact patterns has a surface slanted from the center of the coil toward the outer peripheral edge of the coil. The coil-shaped contact pattern comprises first and second contact elements constituting a dual coil pattern.

The invention relates to a touch control panel device, which comprises a base material layer, an insulating layer, a plurality of first electrode groups and a plurality of second electrode groups. The insulating layer is formed on the base material layer and comprises a first surface adjacent to the base material layer and a second surface away from the base material layer. A plurality of first electrode groups are positioned on the first surface of the insulating layer; and each first electrode group comprises a plurality of first electrode pieces which are arranged on the first surface of the insulating layer at intervals and a plurality of first leads which are electrically connected with the adjacent first electrode pieces. Each second electrode group comprises a plurality of second electrode pieces and a plurality of bridging leads which are electrically connected with the adjacent second electrode pieces; a plurality of second electrode pieces are arranged on the first surface of the insulating layer at intervals and are staggered between the first electrode pieces; and the bridging leads are formed on the second surface of the insulating layer. The touch control panel device has a simple structure so as to simplify a manufacturing process and obtain evener sensing sensitivity.

A structure of a rectangular panel-form loudspeaker is provided. The structure includes a radiating panel, a transducer, a frame and a suspending unit. The radiating panel includes a rectangular laminated composite plate with length b and width a, and the laminated composite plate includes an intermediate core layer sandwiched between two fiber-reinforced polymeric layers. The transducer is used for exciting the radiating panel to produce flexural vibration. The transducer includes a voice coil assembly and a magnet assembly, wherein the voice coil assembly is coupled to a first side of the laminated composite plate at a first specified location. The frame is used for positioning the laminated composite plate and the magnet assembly. The suspending unit is made of a soft material and disposed between peripheral edges of the laminated composite plate and the frame.

The invention provides a capturing method of Beidou second-generation B1 signals and a system thereof. The capturing method comprises steps of 1: changing processed a B1 signal received by an antenna into a digital intermediate frequency signal; 2: receiving the digital intermediate frequency signal, peeling carrier waves, extracting and then storing data; 2: interpolating the data; 3: searching the data and peeling the carrier waves; 4: performing DFT for the data on 4 points; 5: peeling carrier waves for the data, performing FFT, then performing IFFT, obtaining related peak results, and then processing all data so as to related peak results; and 6: sequencing the related peak results, wherein if the biggest peak value is larger than a captured threshold, it shows that the B1 signal has been captured, and otherwise, the B1 signal has not been captured. The invention also provides a capturing system of the Beidou second-generation B1 signals. According to the invention, 4ms coherent integration of the B1 signals can be achieved, capturing sensitivity of the B1 signals is increased and balance between computation amount and capturing sensitivity can be obtained.

A touch screen including a plurality of first sensing electrode columns having a plurality of first sensing electrodes, the plurality of first sensing electrode columns extending in one direction, and a plurality of second sensing electrode columns alternately disposed with the first sensing electrode columns, the plurality of second sensing electrode columns including a plurality of second sensing electrodes having a plurality of sub-electrodes. Sub-electrodes of one of adjacent second sensing electrodes are electrically connected to sub-electrodes of another of the adjacent second sensing electrodes. At least some of the first sensing electrodes include a first region and a second region electrically separated from the first region.

The invention relates to the technical field of an optical fiber induction layer. The optical fiber induction layer provided by the invention comprises an upper pressure-sensitive component thin film and a lower pressure-sensitive component thin film which are superposed, and at least one soft smooth thin film by which a space between the two layers of the pressure-sensitive component thin films is divided into at least two compartments; at least one optical fiber moving segment, which extends in a first direction and comprises a plurality of sections which are subjected to S-shaped serial wiring, is arranged in the same compartment, and wiring elbows of upper and lower adjacent optical fiber moving segments are superposed in a staggered mode. The optical fiber moving segments are uniformly distributed on the pressure-sensitive component thin films of the optical fiber induction layer, so that optical fiber induction regions are formed, and since the wiring elbows of the upper and lower optical fiber moving segments are superposed in a staggered mode, an induction blind area can be mutually filled up by the various optical fiber induction regions, so that the optical fiber induction layer, breaking through the characteristic that an optical fiber is easily broken, can be used for rapidly and accurately detecting breath, heartbeats, sleep, temperature and humidity; and the optical fiber induction layer has the characteristics of being high and adjustable in sensitivity, high in resolution, anti-electromagnetic-interference and uniform in sensitivity. The invention also provides a monitoring system, and the monitoring system comprises the optical fiber induction layer, a light source, a light detection component, an optical fiber transmission loop and a processing circuit.

A method for determining the effects of the wind on a blind (1) or the like that is provided with a sensor means (231) for measuring the effects of the wind in a first measurement direction (X1) and in a second measurement direction (Y1), the two directions being different, the method comprising the following steps:collecting, from the sensor means, a first signal representative of the effects of the wind on the blind or the like, in the first measurement direction;collecting, from the sensor means, a second signal representative of the effects of the wind on the blind or the like, in the second measurement direction;which comprises the step of:processing these signals so as to provide a secondary signal representative of the effects of the wind and independent of the orientation of the sensor means in a plane defined by the two directions, in order to obtain uniform sensor detection sensitivity irrespective of the orientation of the sensor.

The method for calibrating an inspection instrument coupled with acoustic transducers disposed at circumferential positions distributed around a surface of an elongated object to inspect generally has the steps of: for each one of the circumferential positions, measuring a first and a second received signal using two acoustic transducers disposed at two axial positions along the object, the received signals resulting from the propagation of an acoustic guided wave signal along the object; identifying an acoustic mode according to the first received and the second received signals using a known period of time associated with the propagation of the acoustic guided wave signal between the two axial positions along the object; and determining a coupling coefficient associated with the acoustic mode, the coupling coefficient being indicative of the coupling of the acoustic transducers on the object; and calibrating the inspection instrument coupled to the object based on the coupling coefficients.

The invention discloses a method and a device for capturing GPS satellite signals, which comprises the following steps that: a GPS receiver carries out acquisition and re-sampling operations for the GPS satellite signals; the GPS receiver carries out boundary and message prediction for the acquired GPS satellite signal data; the GPS receiver carries out grouping and setting of non-coherent integration according to the predicted boundary position and message; the GPS receiver carries out computing operations of the non-coherent integration according to the finished setting mode of the non-coherent integration grouping respectively; and the GPS receiver judges the capturing result of the GPS satellite signals according to the computing results of the grouped non-coherent integration till finishing capture. Through the operation of the method, the method can effectively improve the signal integration length during GPS satellite capture, can operate across GPS navigation data, and greatly enhances the capturing sensitivity of the GPS signal receiver and the detection capacity of the weak signals. In addition, the invention also provides a corresponding realization device according to the method.

The invention discloses a method for preparing a surface-enhanced Raman scattering (SERS) matrix. According to the method, precious-metal inorganic salt liquid is filled in a molecular sieve template, the template is removed by using high-concentration corrosive acid or alkaline liquid after calcination or reduction, and a precious-metal mesoporous material with uniformly distributed particle size and gaps is finally obtained. The method has the advantages that the particle diameter and gap size can be effectively controlled; the particle size and the gaps are uniformly distributed, so that the quantitative research on electromagnetic coupling among particles is facilitated; and meanwhile, the repeatability of SERS detection can be improved due to the uniformity of hotspot distribution. The low-concentration molecule detection capability can be effectively increased due to high density and small gaps, so that the SERS matrix has a broad application prospect in fields of biology, chemistry, medicine, environment and the like.

The invention discloses a sensor and a gas / solid two-phase flow concentration detection device and method. The sensor comprises a measurement pipe and a plurality of ultrasonic measurement assemblies; at least two detection cross sections are arranged on the measurement pipe in the axial direction, the multiple ultrasonic measurement assemblies are arranged on the detection cross sections, and each ultrasonic measurement assembly comprises at least one transmitting device and at least one receiving device. The gas / solid two-phase flow concentration detection device comprises an information processing device and the sensor; the information processing device comprises a signal analysis module used for receiving and analyzing signals transmitted by the sensor, an information fusion module used for calculating the information obtained after analysis, an output module used for outputting the signals, a control module used for controlling signal transmission between the modules and a power module used for supplying power to control movement. By means of the sensor and the gas / solid two-phase flow concentration detection device and method, the technical problems of discontinuous measurement, high radioactivity, poor adaptability and flowing hinders can be solved.

The invention relates to a multi-component part transducer assembly for determining the pressure of a fluid of interest. One part of the assembly comprises a reusable transducer, another part a disposable component comprising a flexible membrane which is in pressure connection with the fluid of interest, and another part comprises a locking component for securing the reusable and disposable parts together.

A sensitivity compensation method of a touch input device sensing a touch pressure may be provided. The sensitivity compensation method includes: defining a plurality of reference points spaced apart from each other on a touch sensor panel; generating a reference data corresponding to a capacitance change amount sensed by applying a predetermined pressure to the plurality of reference points; generating, on the basis of the reference data, an interpolated data corresponding to a capacitance change amount for a random point present between the plurality of reference points; calculating, on the basis of the generated reference data and interpolated data, with respect to the reference point and random point respectively, a compensation factor for compensating a sensitivity of the touch input device to a target value; and compensating uniformly for the sensitivity of the touch input device by applying the calculated compensation factor to each corresponding points.

The invention relates to the field of schlieren edge accurate fixing technology, and particularly to an image-based schlieren blade accurate fixing device. The image-based schlieren blade accurate fixing device comprises a light source, a schlieren mirror, an edge, an axial translation platform, a cutting translation platform, a motion controller, a camera, a lens, a computer and a bracket. The light source performs imaging on a focal plane through the schlieren mirror. In mounting of the schlieren blade accurate fixing device, the edge is approximately mounted on the focal plane, and partiallight source image is cut. The lens 4 performs imaging of the schlieren image of a testing area on the camera. Operation software is installed in the computer for controlling the camera and the motioncontroller. The motion controller makes the axial translation platform and the cutting translation platform move through receiving an instruction of the operation software. According to the device ofthe invention, through combining schlieren image analysis with an electric translation platform, the edge of a schlieren instrument is automatically and accurately fixed in the focal plane and furthermore a cutting amount of the edge can be quantitatively controlled. Furthermore experiment quality and experiment efficiency are improved.