Abstract: An integrated circuit package for an integrated circuit having one or more sensor elements in a sensor element area of the circuit. An encapsulation covers bond wires but leaves an opening over the sensor element area. A protection layer is provided over the integrated circuit over which the encapsulation extends, and it has a channel around the sensor element area to act as a trap for any encapsulation material which has crept into the opening area.

Abstract: A sensor package comprises a sensor chip bonded to an intermediate carrier, with the sensor element over an opening in the carrier. The package is for soldering to a board, during which the intermediate carrier protects the sensor part of the sensor chip.

Abstract: Disclosed is an integrated circuit comprising a substrate (10) including at least one light sensor (12); an interconnect structure (20) over the substrate; at least one passivation layer (30) over the interconnect structure, said passivation layer including a first area over the at least one light sensor; and a gas sensor such as a moisture sensor (50) at least partially on a further area of the at least one passivation layer, wherein the gas sensor comprises a gas sensitive layer (46?) in between a first electrode (42) and a second electrode (44), the gas sensitive layer further comprising a portion (46?) over the first area. A method of manufacturing such an IC is also disclosed.

Abstract: An integrated heat sink array is introduced in SOI power devices having multiple unit cells, which can be used to reduce the temperature rise in obtaining more uniform temperature peaks for all the unit cells across the device area, so that the hot spot which is prone to breakdown can be avoided, thus the safe operating area of the device can be improved. Also the array sacrifice less area of the device, therefore results in low Rdson.

Abstract: An integrated heat sink array is introduced in SOI power devices having multiple unit cells, which can be used to reduce the temperature rise in obtaining more uniform temperature peaks for all the unit cells across the device area, so that the hot spot which is prone to breakdown can be avoided, thus the safe operating area of the device can be improved. Also the array sacrifice less area of the device, therefore results in low Rdson.

Abstract: A micro-device includes a substrate with a cavity. The cavity is covered with a porous layer that is permeable to vapor hydrofluoric acid (HF) etchant. The micro-device comprises a Microelectromechanical Systems (MEMS) device with a component that is moveable in operational use of the MEMS device. The component is arranged within the cavity.

Abstract: Disclosed is a liquid immersion sensor comprising a substrate (10) carrying a conductive sensing element (20) and a corrosive agent (30) for corroding the conductive sensing element, said corrosive agent being immobilized in the vicinity of the conductive sensing element and being soluble in said liquid.

Abstract: A capacitive sensor for detecting the presence of a substance includes a plurality of upstanding conductive pillars arranged within a first layer of the sensor, a first electrode connected to a first group of the pillars, a second electrode connected to a second, different group of the pillars, and a dielectric material arranged adjacent the pillars, for altering the capacitance of the sensor in response to the presence of said substance.

Abstract: Disclosed is an integrated circuit comprising a substrate (10) including at least one light sensor (12); an interconnect structure (20) over the substrate; at least one passivation layer (30) over the interconnect structure, said passivation layer including a first area over the at least one light sensor; and a gas sensor such as a moisture sensor (50) at least partially on a further area of the at least one passivation layer, wherein the gas sensor comprises a gas sensitive layer (46?) in between a first electrode (42) and a second electrode (44), the gas sensitive layer further comprising a portion (46?) over the first area. A method of manufacturing such an IC is also disclosed.

Abstract: A sensor (2) for sensing a first substance and a second substance, the sensor comprising first (3) and second (5) sensor components each comprising a first material (20), the first material being sensitive to both the first substance and the second substance, the sensor further comprising a barrier (18) for preventing the second substance from passing into the second sensor component (5).

Abstract: The invention relates to a micro-device with a cavity, the micro-device comprising a substrate, the method comprising steps of: A) providing the substrate, having a surface and comprising a sacrificial oxide region at the surface; B) covering the sacrificial oxide region with a porous layer being permeable to a vapor HF etchant, and C) selectively etching the sacrificial oxide region through the porous layer using the vapor HF etchant to obtain the cavity. This method may be used in the manufacture of various micro-devices with a cavity, i.e. MEMS devices, and in particular in the encapsulation part thereof, and semiconductor devices, and in particular the BEOL-part thereof.

Abstract: Disclosed is an integrated circuit comprising a substrate including at least one light sensor; an interconnect structure over the substrate; at least one passivation layer over the interconnect structure, said passivation layer including a first area over the at least one light sensor; and a gas sensor such as a moisture sensor at least partially on a further area of the at least one passivation layer, wherein the gas sensor comprises a gas sensitive layer in between a first electrode and a second electrode, the gas sensitive layer further comprising a portion over the first area. A method of manufacturing such an IC is also disclosed.

Abstract: An isolated semiconductor circuit comprising: a first sub-circuit and a second sub-circuit; a backend that includes an electrically isolating connector between the first and second sub-circuits; a lateral isolating trench between the semiconductor portions of the first and second sub-circuits, wherein the lateral isolating trench extends along the width of the semiconductor portions of the first and second sub-circuits, wherein one end of the isolating trench is adjacent the backend, and wherein the isolating trench is filled with an electrically isolating material.

Abstract: A lateral test flow arrangement for a test molecule is disclosed, comprising: a test strip for transporting an analyte away from a sampling region and towards an absorbing region, the test strip having therein and remote from the sampling region, a test region for functionalization with a molecule which binds to the test molecule or to a conjugate of the test molecule; a sensing test capacitor having electrodes extending across the test strip at least partially aligned with the test region and being physically isolated therefrom; a reference test capacitor having electrodes extending across the test strip and being physically isolated therefrom; and an electronic circuit configured to measure a time-dependant capacitance difference between the sensing test capacitor and the reference test capacitor.

Abstract: An isolated semiconductor circuit comprising: a first sub-circuit and a second sub-circuit; a backend that includes an electrically isolating connector between the first and second sub-circuits; a lateral isolating trench between the semiconductor portions of the first and second sub-circuits, wherein the lateral isolating trench extends along the width of the semiconductor portions of the first and second sub-circuits, wherein one end of the isolating trench is adjacent the backend, and wherein the isolating trench is filled with an electrically isolating material.

Abstract: A sensor for sensing an analyte includes capacitive elements, each having a pair of electrodes separated by a dielectric wherein the dielectric constant of the dielectric of at least one of the capacitive elements is sensitive to the analyte, the sensor further including a comparator adapted to compare a selected set of capacitive elements against a reference signal and to generate a comparison result signal, and a controller for iteratively selecting the set in response to the comparison result signal, wherein the sensor is arranged to produce a digitized output signal indicative of the sensed level of the analyte of interest. An IC comprising such a sensor, an electronic device comprising such an IC and a method of determining a level of an analyte of interest using such a sensor are also disclosed.

Abstract: Disclosed is an integrated circuit (IC) comprising a substrate (10) including a plurality of circuit elements and a metallization stack (20) covering said substrate for providing interconnections between the circuit elements, wherein the top metallization layer of said stack carries a plurality of metal portions (30) embedded in an exposed porous material (40) for retaining a liquid, said porous material laterally separating said plurality of metal portions. An electronic device comprising such an IC and a method of manufacturing such an IC are also disclosed.

Abstract: Disclosed is an integrated circuit comprising a substrate (10); and an optical CO2 sensor comprising: first and second light sensors (12, 12?) on said substrate, said second light sensor being spatially separated from the first light sensor; and a layer portion (14) including an organic compound comprising at least one amine or amidine functional group over the first light sensor; wherein said integrated circuit further comprises a signal processor (16) coupled to the first and second light sensor for determining a difference in the respective outputs of the first and second light sensor. An electronic device comprising such a sensor and a method of manufacturing such an IC are also disclosed.

Abstract: A method of manufacturing a module for a biosensor is disclosed. The method includes providing a substrate. The substrate includes a trench and a bond pad. The trench is filled with an electrically conductive material and the bond pad is arranged within the substrate. The method also includes removing a part of the electrically conductive material from the trench such that a recess is formed in a surface of the substrate, forming a biocompatible electrode in the recess, and removing a part of the substrate such that the bond pad is accessible through the surface of the substrate.

Abstract: An isolated semiconductor circuit comprising: a first sub-circuit and a second sub-circuit; a backend that includes an electrically isolating connector between the first and second sub-circuits; a lateral isolating trench between the semiconductor portions of the first and second sub-circuits, wherein the lateral isolating trench extends along the width of the semiconductor portions of the first and second sub-circuits, wherein one end of the isolating trench is adjacent the backend, and wherein the isolating trench is filled with an electrically isolating material.