Abstract: A force sensing device comprises a first electrode and a second electrode and a substrate comprising at least one groove. The force sensing device further comprises an active material between the first and second electrodes. The at least one groove comprises a first face and a second face inclined to the first face. The first face and second face are arranged a distance apart from each other. The first electrode is deposited on the first face and the second electrode is deposited on the second face. The distance changes on application of an applied force to deform the active material and provide a change in an electrical property, such as resistance, capacitance or a combination, of the active material.

Abstract: A microarrayer for dispensing reagent onto a substrate, comprising a dispensing print head adapted to load reagent and provided with a plurality of nozzles to dispense said at least reagent on the substrate, wherein the print head is mounted in the microarrayer to allow the print head to move with respect to the substrate in subsequent, essentially, parallel print passes, wherein the print head moves during a first print pass between a first end of the substrate toward a second end of the substrate and during a subsequent printpass in the opposite direction, the microarrayer being characterised in that the microarrayer comprises a first camera adapted to move behind the print head during a print pass and a second camera adapted to move ahead of the print head during said print pass, the first and second camera being adapted to obtain images of the substrate.

Abstract: Method for manufacturing a microarray and verifying the quality of said microarray, wherein the method comprises: —providing at least one reagent, —loading said at least one reagent in a dispensing print head, in a predetermined arrangement, —moving the print head with respect to a substrate and dispensing said at least one reagent on the substrate, during a print pass, to obtain a microarray, —illuminating the substrate using illumination means and obtaining an image of the printed microarray on the substrate, using a camera, —processing the obtained image to verify the quality of the microarray, wherein the step of obtaining an image of the printed microarray comprises: —illuminating the substrate and obtaining an image of the microarray by means of illumination means and a camera which are connected to and move together with the print head with respect to the substrate, the illumination means and the camera being adapted to move behind the print head.

Abstract: Method for manufacturing microarrays and verifying the quality of said microarrays, wherein the method comprises: a) providing at least one reagent, b) loading said at least one reagent in a dispensing print head, in a predetermined arrangement, c) in a first print pass, generating instructions for the print head and moving said print head with respect to a substrate to print said at least one reagent on the substrate to obtain microarrays, d) obtaining an image of the printed microarrays by means of a camera, e) processing the obtained images of the printed microarrays, to calculate parameters indicative for the quality of the printed microarrays, f) comparing, at the end of the first print pass, the calculated parameters for the printed microarrays with predetermined criteria for the microarrays, to identify possible printing defects, g) comparing, for the printed microarrays, the identified printing defects of step f), h) using the outcome of the comparison of step g) to select a corrective action to impro

Abstract: A microarrayer for dispensing reagent onto a substrate, comprising a dispensing print head adapted to load reagent and provided with a plurality of nozzles to dispense said at least reagent on the substrate, wherein the print head is mounted in the microarrayer to allow the print head to move with respect to the substrate in subsequent, essentially, parallel print passes, wherein the print head moves during a first print pass between a first end of the substrate toward a second end of the substrate and during a subsequent printpass in the opposite direction, the microarrayer being characterised in that the microarrayer comprises a first camera adapted to move behind the print head during a print pass and a second camera adapted to move ahead of the print head during said print pass, the first and second camera being adapted to obtain images of the substrate.

Abstract: Method for manufacturing a microarray and verifying the quality of said microarray, wherein the method comprises: —providing at least one reagent, —loading said at least one reagent in a dispensing print head, in a predetermined arrangement, —moving the print head with respect to a substrate and dispensing said at least one reagent on the substrate, during a print pass, to obtain a microarray, —illuminating the substrate using illumination means and obtaining an image of the printed microarray on the substrate, using a camera, —processing the obtained image to verify the quality of the microarray, wherein the step of obtaining an image of the printed microarray comprises: —illuminating the substrate and obtaining an image of the microarray by means of illumination means and a camera which are connected to and move together with the print head with respect to the substrate, the illumination means and the camera being adapted to move behind the print head.

Abstract: Method for manufacturing microarrays and verifying the quality of said microarrays, wherein the method comprises: a) providing at least one reagent, b) loading said at least one reagent in a dispensing print head, in a predetermined arrangement, c) in a first print pass, generating instructions for the print head and moving said print head with respect to a substrate to print said at least one reagent on the substrate to obtain microarrays, d) obtaining an image of the printed microarrays by means of a camera, e) processing the obtained images of the printed microarrays, to calculate parameters indicative for the quality of the printed microarrays, f) comparing, at the end of the first print pass, the calculated parameters for the printed microarrays with predetermined criteria for the microarrays, to identify possible printing defects, g) comparing, for the printed microarrays, the identified printing defects of step f), h) using the outcome of the comparison of step g) to select a corrective action to impro

Abstract: Systems and methods for distinguishing between user mobile device location data indicating user locations within an area of interest or merely near an area of interest are disclosed. User geospatial location data is obtained at user mobile devices (e.g., smartphones) upon the triggering event of a user action (e.g., visiting a web site or using an application on the user mobile device). The location data is stored and compared against polygonal map data accurately and precisely defining a map area of the area of interest. A map view may be generated by generating markers having different styles for user location data within or near the area of interest, which markers may then be overlaid on a map including a polygon representation of the area of interest. Such map view may be augmented by additional data and presented as a report including location and additional data for a plurality of users.

Abstract: Systems and methods for distinguishing between user mobile device location data indicating user locations within an area of interest or merely near an area of interest are disclosed. User geospatial location data is obtained at user mobile devices (e.g., smartphones) upon the triggering event of a user action (e.g., visiting a web site or using an application on the user mobile device). The location data is stored and compared against polygonal map data accurately and precisely defining a map area of the area of interest. A map view may be generated by generating markers having different styles for user location data within or near the area of interest, which markers may then be overlaid on a map including a polygon representation of the area of interest. Such map view may be augmented by additional data and presented as a report including location and additional data for a plurality of users.

Abstract: A system and method for high-availability inverse synthetic aperture radar (ISAR). In one embodiment a set of quadratic phase vectors, each corresponding to a different acceleration, is multiplied, one at a time, in a Hadamard product, with a 3-dimensional data cube, and a fast Fourier transform (FFT) is taken of the result, to form a 2-dimensional array. The two-dimensional array is made sparse by setting to zero elements that fall below a threshold based on a coherency metric, and the sparse arrays are stacked to form a sparse 3-dimensional image. Projections of the sparse 3-dimensional image are formed for presentation to an operator or an image exploitation system.

Abstract: Systems and methods for distinguishing between user mobile device location data indicating user locations within an area of interest or merely near an area of interest are disclosed. User geospatial location data is obtained at user mobile devices (e.g., smartphones) upon the triggering event of a user action (e.g., visiting a web site or using an application on the user mobile device). The location data is stored and compared against polygonal map data accurately and precisely defining a map area of the area of interest. A map view may be generated by generating markers having different styles for user location data within or near the area of interest, which markers may then be overlaid on a map including a polygon representation of the area of interest. Such map view may be augmented by additional data and presented as a report including location and additional data for a plurality of users.

Abstract: An adaptive electronically steerable array (AESA) system comprises a plurality of arrays, each comprising a plurality of radiating elements, each array configured for placement on a forward-facing surface of a different one of a plurality of aerodynamic control surfaces on an interceptor. A plurality of radio frequency (RF) transmissive radome elements, each having an aerodynamic shape complementary to the aerodynamic control surface, are placed over one of the arrays. Control circuitry configures the arrays, independently or in concert, for RF target engagement and communication. Additional arrays may be positioned on side or aft-facing surfaces of the aerodynamic control surfaces for RF communication. The AESA system may be paired with an IR system for dual-mode operation.

Abstract: An AESA system comprises a plurality of arrays, each comprising a plurality of radiating elements, each array configured for placement on a forward-facing surface of a different one of a plurality of aerodynamic control surfaces on an interceptor. A plurality of RF transmissive radome elements, each having an aerodynamic shape complementary to the aerodynamic control surface, are placed over one of the arrays. Control circuitry configures the arrays, independently or in concert, for RF target engagement and communication. Additional arrays may be positioned on side or aft-facing surfaces of the aerodynamic control surfaces for RF communication. The AESA system may be paired with an ER system for dual-mode operation.

Abstract: A system and method for high-availability inverse synthetic aperture radar (ISAR). In one embodiment a set of quadratic phase vectors, each corresponding to a different acceleration, is multiplied, one at a time, in a Hadamard product, with a 3-dimensional data cube, and a fast Fourier transform (FFT) is taken of the result, to form a 2-dimensional array. The two-dimensional array is made sparse by setting to zero elements that fall below a threshold based on a coherency metric, and the sparse arrays are stacked to form a sparse 3-dimensional image. Projections of the sparse 3-dimensional image are formed for presentation to an operator or an image exploitation system.

Abstract: A method and apparatus for depth imaging by triangulation in which a pattern is projected on to an object scene and the scene, and the pattern, imaged, the projection and the imaging being spatially offset, in which the pattern has a characteristic dimension x and depth changes in the object scene cause deformations in the image of the pattern having a maximum dimension ?x, characterised in that ?x<x.

Abstract: A printing method and apparatus is disclosed wherein the printhead has a linear array of nozzles oriented in an axis, and drops of a liquid are printed at a particular location from first and second nozzles of the printhead at a first location. In an embodiment, the nozzles are arranged in groups, each group of nozzles being used to superpose spots of a particular liquid at a different location. A further method is described wherein the printhead is triggered by transferring printing triggers from a processing module to a printhead at print intervals representative of a plurality of fixed units of spatial displacement of the printhead. The present invention is particularly advantageous for the cycling of print nozzles, superposition of spots in linear arrays and fine control of spot positioning. The invention has particular application in the field of printing DNA microarrays.