A method for fabricating a fluidic device includes depositing a sacrificial material on a pillar array arranged on a substrate. The method also includes removing a portion of the sacrificial material. The method further includes depositing a sealing layer on the pillar array to form a sealed fluidic cavity.

A microphone package and an electronic apparatus including the same are provided. The microphone package includes a substrate in which an acoustic hole and a via hole are formed; an acoustic sensor attached to a front surface of the substrate and covering the acoustic hole; a first electrode pad provided on the front surface of the substrate; a second electrode pad provided on a rear surface of the substrate and electrically connected to the first electrode pad through the via hole; and a third electrode pad on a side surface of the substrate and electrically connected to the second electrode pad.

An alternate venting path can be employed in a sensor device for pressure equalization. A sensor component of the device can comprise a diaphragm component and/or backplate component disposed over an acoustic port of the device. The diaphragm component can be formed with no holes to prevent liquid or particles from entering a back cavity of the device, or gap between the diaphragm component and backplate component. A venting port can be formed in the device to create an alternate venting path to the back cavity for pressure equalization for the diaphragm component. A venting component, comprising a filter, membrane, and/or hydrophobic coating, can be associated with the venting port to inhibit liquid and particles from entering the back cavity via the venting port, without degrading performance of the device. The venting component can be designed to achieve a desired low frequency corner of the sensor frequency response.

A semiconductor device includes a substrate. A first semiconductor die including a microelectromechanical system (MEMS) is disposed over the substrate. A lid is disposed on the substrate around the first semiconductor die. A first encapsulant is deposited over the substrate and lid. A second encapsulant is deposited into the lid.

A microphone device comprises a microphone die including a first microphone motor and a second microphone motor, an acoustic integrated circuit structured to process signals produced by the first microphone motor and the second microphone motor, and a sensor die stacked on top of the acoustic integrated circuit, wherein the sensor die comprises a pressure sensor. Another microphone comprises a microphone die including a first microphone motor and a second microphone motor and an integrated circuit die. The integrated circuit die comprises an acoustic integrated circuit structured to process signals produced by the first microphone motor and the second microphone motor, a pressure sensor, and a pressure integrated circuit structured to press signals produced by the pressure sensor.

In an example implementation, a reagent storage system for a microfluidic device includes a microfluidic chamber formed in a microfluidic device. A blister pack to store a reagent includes an electrically conductive membrane barrier adjacent to the chamber. A thinned region is formed in the membrane barrier, and a conductive trace is to supply electric current to heat and melt the thinned region. Melting the thinned region is to cause the membrane barrier to open and release the reagent into the chamber.

A method of fabricating a plurality of MEMS microphone modules by providing a first substrate wafer 62 on which are mounted a plurality of sets comprising an LED 102, an IC chip 22 and a MEM microphone device 24, where the LED 102 and IC chip 22 are surrounded and separated by first spacers 104, 64A, 64, the spacer 104 being much taller, attaching a second substrate on top of the first spacer elements above the IC chip 22, mounting a MEMS microphone device 24 to the second substrate 60, the second substrate not extending over the LED 102, surrounding the MEMS microphone device by second spacers 32A, 32, attaching a cover wafer 28 across the whole first substrate wafer 62 covering all the plurality of sets, forming openings 30 to the MEMS cavities, dividing the substrate wafer 62 into individual MEMS microphone modules through the width of the separating spacers 104, 32, 64. Conductive traces may extend through the spacers. Also defined are MEMS modules without LED's, without stacking, on a single substrate, or on either side of a single substrate.

A micromechanical component having a substrate which includes a micro-electromechanical microphone structure, the micro-electromechanical microphone structure encompassing at least one piezoelectric layer and at least one polymer mass as at least part of a packaging of the substrate fitted with the micro-electromechanical microphone structure, which is in contact with at least a partial outer surface of the substrate fitted with the micro-electromechanical microphone structure. A method is also described for packaging a substrate having a micro-electromechanical microphone structure encompassing at least one piezoelectric layer by developing at least a portion of a packaging of the substrate fitted with the micro-electromechanical microphone structure from at least one polymer mass, and the at least one polymer mass being applied directly on at least a partial outer surface of the substrate fitted with the micro-electromechanical microphone structure.

A micromechanical device that includes a silicon substrate with an overlying oxide layer and with a micromechanical functional layer lying above same, which extend in parallel to a main extension plane, a cavity being formed at least in the micromechanical functional layer and in the oxide layer. An access channel is formed in the oxide layer and/or in the micromechanical functional layer which, starting from the cavity, extends in parallel to the main extension plane and in the process extends in a projection direction, as viewed perpendicularly to the main extension plane, all the way into an access area outside the cavity. A method for manufacturing a micromechanical device is also described.

A transducer module, comprising: a supporting substrate, having a first side and a second side; a cap, which extends over the first side of the supporting substrate and defines therewith a first chamber and a second chamber internally isolated from one another; a first transducer in the first chamber; a second transducer in the second chamber; and a control chip, which extends at least partially in the first chamber and/or in the second chamber and is functionally coupled to the first and second transducers for receiving, in use, the signals transduced by the first and second transducers.