Abstract: An energy-resolving photon counting detector pixel. The energy-resolving photon counting detector may include a plurality of such pixels. In an embodiment, the detector pixel is operable in a calibration mode, in which mode an offset unit determines a correction signal to be provided to the detecting unit and/or to the comparing unit for correcting an offset in the detecting unit and/or comparing unit.

Abstract: Aspects of the present disclosure relate to an energy-resolving photon counting detector pixel. Further aspects of the present disclosure relate to an energy-resolving photon counting detector comprising a plurality of such pixels, and to an energy-resolving photon counting system comprising the same. In accordance with an aspect of the present disclosure, a CSA base level shift detector is used for determining a shift in the CSA base level over time relative to a first level. The pixel is configured to reset the CSA in dependence of the determined CSA base level shift.

Abstract: The present disclosure relates to a detector pixel for an energy-resolving photon counting detector, and to a photon counting detector comprising the same. The pixel comprises: a photodetector configured to convert an incident photon into a first signal indicative of an energy of the incident photon; a charge sensitive amplifier (CSA) configured to convert the first signal at an input of the CSA into a CSA output signal at an output of the CSA; and a dark current compensation unit (DCCU) for compensating a dark current of the photodetector.

Abstract: The present disclosure relates to an X-ray system for multi-spectrum imaging. The system comprises an X-ray source configured to be sequentially operable in a plurality of spectral modes in dependence of at least one synchronization signal, the plurality of modes including a first mode, in which the X-ray source is configured to emit first X-rays having a first spectrum, and a second mode, in which the X-ray source is configured to emit second X-rays having a second spectrum different from the first spectrum; and an X-ray detector comprising a pixel controller, a readout unit, and an active pixel including a first storage element and a second storage element. The pixel controller is configured to control the active pixel in dependence of the at least one synchronization signal to record a first signal associated with the first X-rays in the first storage element and record a second signal associated with the second X-rays in the second storage element.

Abstract: The invention relates to a method for producing control data for correcting the refraction of an eye (2) by corneal modification, comprising the steps of receiving data about a refraction correction need for the eye (2), determining, on the basis of the refraction correction need, an additive refraction alteration value by an implant (26) to be inserted into the cornea (17), determining a subtractive refraction alteration value by a lenticule (21) to be removed from the cornea (17), the additive refraction alteration value and the subtractive refraction alteration value together yielding the refraction correction need, calculating a lenticule (21) to be isolated in the cornea (17), the calculation being implemented in such a way on the basis of the subtractive refraction alteration value that the lenticule (21) is embodied to bring about the subtractive refraction alteration value as a result of being removed from the cornea (17).

Abstract: A microelectromechanical system (MEMS) device includes a substrate, a suspended element and a damping structure connected to the suspended element and one or more fluid confinement structures. The suspended element is connected to a fixed part of the substrate by one or more flexures configured to permit movement of the suspended element relative to a fixed part of the substrate. The damping structure extends into a gap between the suspended element and the fixed part of the substrate. The damping structure includes one or more winglets that protrude over a recessed portion of the fixed part of the substrate. The fluid confinement structures are formed by the recessed portion of the fixed substrate and are configured to permit movement of the damping structure over the recessed portion of the substrate and confine a viscoelastic fluid to the limited portion of the gap underneath the winglets.

Abstract: A microelectromechanical system (MEMS) device comprising a wafer including a MEMS device in a substrate of the wafer is mounted to a fluid dispenser stage. The MEMS device has a damping structure coupled to a suspended element and one or more fluid confinement structures. The suspended element is connected to a fixed part of the substrate by one or more flexures configured to permit movement of the suspended element relative to the fixed part of the substrate. The damping structure extends into a gap between the suspended element and fixed part of the substrate. The fluid confinement structures permit movement of the damping structure within a limited portion of the gap and confine a viscoelastic fluid to the limited portion of the gap. A viscoelastic fluid is deposited onto the wafer in an area of the wafer configured to communicate the viscoelastic fluid into the limited portion of the gap.

Abstract: MEMS devices include a suspended element connected to a fixed part of a substrate by one or more flexures, wherein the one or more flexures are configured to permit movement of the suspended element relative to a fixed part of the substrate. A sensor coupled to the suspended element and a damping structure coupled to the suspended element extends into a gap between the suspended element and the fixed part of the substrate. One or more fluid confinement structures are configured to permit movement of the damping structure within a limited portion of the gap and to confine a viscoelastic fluid to the limited portion of the gap.

Abstract: A microelectromechanical system (MEMS) device comprising a wafer including a MEMS device in a substrate of the wafer is mounted to a fluid dispenser stage. The MEMS device has a damping structure coupled to a suspended element and one or more fluid confinement structures. The suspended element is connected to a fixed part of the substrate by one or more flexures configured to permit movement of the suspended element relative to the fixed part of the substrate. The damping structure extends into a gap between the suspended element and fixed part of the substrate. The fluid confinement structures permit movement of the damping structure within a limited portion of the gap and confine a viscoelastic fluid to the limited portion of the gap. A viscoelastic fluid is deposited onto the wafer in an area of the wafer configured to communicate the viscoelastic fluid into the limited portion of the gap.

Abstract: A microelectromechanical system (MEMS) device includes a substrate, a suspended element and a damping structure connected to the suspended element and one or more fluid confinement structures. The suspended element is connected to a fixed part of the substrate by one or more flexures configured to permit movement of the suspended element relative to a fixed part of the substrate. The damping structure extends into a gap between the suspended element and the fixed part of the substrate. The damping structure includes one or more winglets that protrude over a recessed portion of the fixed part of the substrate. The fluid confinement structures are formed by the recessed portion of the fixed substrate and are configured to permit movement of the damping structure over the recessed portion of the substrate and confine a viscoelastic fluid to the limited portion of the gap underneath the winglets.

Abstract: MEMS devices include a suspended element connected to a fixed part of a substrate by one or more flexures, wherein the one or more flexures are configured to permit movement of the suspended element relative to a fixed part of the substrate. A sensor coupled to the suspended element and a damping structure coupled to the suspended element extends into a gap between the suspended element and the fixed part of the substrate. One or more fluid confinement structures are configured to permit movement of the damping structure within a limited portion of the gap and to confine a viscoelastic fluid to the limited portion of the gap.

Abstract: Aspects of the present disclosure relate to a photon counting detector and to a read-out integrated circuit to be used in such detector. Aspects of the present disclosure particularly relate to X-ray applications. According to an aspect of the present disclosure, the detector comprises an electrical ground plane arranged at or near an interface between the carrier and at least one ROIC die. Each ROIC die comprises an extension region that laterally extends beyond the photon conversion assembly, wherein peripheral circuitry for a given ROIC die is arranged in the extension region of that ROIC die. The detector comprises at least one electrical connection that connects the power supply line that is arranged on the carrier to the peripheral circuitry of the at least one ROIC die.

Abstract: Aspects of the present disclosure relate to a photon counting detector and to a read-out integrated circuit to be used in such detector. Aspects of the present disclosure particularly relate to X-ray applications. According to an aspect of the present disclosure, the detector comprises an electrical ground plane arranged at or near an interface between the carrier and at least one ROIC die. Each ROIC die comprises an extension region that laterally extends beyond the photon conversion assembly, wherein peripheral circuitry for a given ROIC die is arranged in the extension region of that ROIC die. The detector comprises at least one electrical connection that connects the power supply line that is arranged on the carrier to the peripheral circuitry of the at least one ROIC die.

Abstract: MEMS devices include a suspended element connected to a fixed part of a substrate by one or more flexures, wherein the one or more flexures are configured to permit movement of the suspended element relative to a fixed part of the substrate. An actuator coupled to the suspended element and a damping structure coupled to the suspended element extends into a gap between the suspended element and the fixed part of the substrate. One or more fluid confinement structures are configured to permit movement of the damping structure within a limited portion of the gap and to confine a viscoelastic fluid to the limited portion of the gap.

Abstract: Aspects of the present disclosure relate to an energy-resolving photon counting detector pixel. Further aspects of the present disclosure relate to an energy-resolving photon counting detector comprising a plurality of such pixels, and to an energy-resolving photon counting system comprising the same. In accordance with an aspect of the present disclosure, a CSA base level shift detector is used for determining a shift in the CSA base level over time relative to a first level. The pixel is configured to reset the CSA in dependence of the determined CSA base level shift.

Abstract: Aspects of the present disclosure relate to an energy-resolving photon counting detector pixel. Further aspects of the present disclosure relate to an energy-resolving photon counting detector comprising a plurality of such pixels. In an embodiment of the present disclosure, the detector pixel is operable in a calibration mode, in which mode an offset unit determines a correction signal to be provided to the detecting unit and/or to the comparing unit for correcting an offset in the detecting unit and/or comparing unit.

Abstract: MEMS devices include a suspended element connected to a fixed part of a substrate by one or more flexures, wherein the one or more flexures are configured to permit movement of the suspended element relative to a fixed part of the substrate. An actuator coupled to the suspended element and a damping structure coupled to the suspended element extends into a gap between the suspended element and the fixed part of the substrate. One or more fluid confinement structures are configured to permit movement of the damping structure within a limited portion of the gap and to confine a viscoelastic fluid to the limited portion of the gap.

Abstract: MEMS devices include fluid confinement structures on either a fixed part of a substrate and/or on a suspended element. The fluid confinement structures may be configured to confine a viscoelastic fluid in a limited part of a gap between one or more vertical sidewalls of both the fixed part of the substrate and either the suspended element or the drive beam or both the suspended element and drive beam such that one part of the gap is bridged by the fluid and another part of the gap is not, The structures may be configured to prevent flow of the fluid to other parts of the gap.

Abstract: A device and a method, by means of which energy can be supplied to a retinal implant (12) via infrared radiation, are provided. To this end, infrared light is coupled in from an infrared light source (14), for example into a spectacle lens (13), and coupled out toward an eye (10) by way of an output coupling device (17) in order to illuminate the retinal implant (12).

Abstract: A planning device for generating control data for a treatment apparatus which by means of a laser device produces at least one incision surface in the cornea, and to a treatment apparatus having such a planning device. The invention further relates to a method for generating control data for a treatment apparatus which by using a laser device produces at least one incision surface in the cornea, and to a corresponding ophthalmic surgery method. The planning device is thereby provided with calculation means for defining the corneal incision surfaces, wherein the calculation means determine the corneal incision surfaces on the basis of data of a LIRIC structure and/or a refractive correction, and generate for the corneal incision surfaces a control data set for controlling the laser device, wherein the calculation means determine the corneal incision surfaces in such a manner that the LIRIC structure is enclosed by the incision surfaces.