Disclosed is an electronic device including a camera module enabling a movable member (e.g., a circuit board) having an image sensor disposed thereon to move for an image stabilization function and including a connecting member that provides electrical connection of the image sensor, and an electronic device including the camera module.

An apparatus and method wherein the method comprises: a deformable substrate; a curved support structure configured to support at least a portion of a resistive sensor wherein the resistive sensor comprises a first electrode, a second electrode and a resistive sensor material provided between the electrodes; at least one support configured to space the curved support structure from the deformable substrate so that when the deformable substrate is deformed the curved support structure is not deformed in the same way; wherein the resistive sensor is positioned on the curved support structure so as to limit deformation of the resistive sensor when the deformable substrate is deformed.

A flexible electronic circuit includes a plurality of leaves having a proximal section, a distal section, and an intermediate section. The plurality of leaves are bonded to each other within the distal section and loose within the intermediate section. The intermediate section also includes conductive connector pads for a wiring harness. A plurality of test connector pads are disposed on the plurality of leaves within the proximal section. The leaves within the proximal section may also be bonded to each other, for example in a ribbon or stepped configuration, in order to facilitate connection to testing apparatus. Once the circuit is tested, the proximal section can be severed from the intermediate section prior to installation of the circuit into a medical device, such as an intracardiac echocardiography catheter.

The pocket connector of the invention has been manufactured of a substrate, which is preferably flexible in at least one direction, of which three parts have been prepared, which are bent or assembled from three parts and joined together superimposed so that at least two opposite sides of the pocket connector have coupling apertures. Two flat cables or a connector for a flexible circuit board is connectable to these coupling apertures.

A planar multi-layer assembly method fabricates a dual frequency, dual polarization phased-array antenna. A plurality of vias make up an array of double-walled wells which are connected to a ground plane. A shorted annular ring patch antenna (SARPA) is deposited at the top of each double-walled well. Fabricated coaxially and parallel to each SARPA, is an array of circular patch antennas (CPA). The inner wall of each double-walled well improves isolation of the CPA signals from the SARPA signals. Each SARPA of the array is connected to a pair of first frequency band signal vias and the CPA is coupled to a pair of second frequency band signal vias. Within each frequency band, a plurality of signal phases enable steerable polarized antenna beams.

The invention relates to a carrier arrangement (100; 500; 600; 700; 800; 900; 1000), and a method for producing a carrier arrangement. The method comprises: producing a layer (130; 530; 630; 730; 830; 930; 1030) on a surface (120; 520; 620; 720; 820; 920; 1020) of a carrier (110; 510; 610; 710; 810; 910; 1010), the layer comprising a first region (131; 531; 631; 731; 831; 931; 1031) and a second region (132; 532; 632; 732; 832; 932; 1032) connected to the first region, the first region covering a first surface region (121; 521; 621; 721; 821; 921; 1021) of the carrier and the second region covering a second surface region (122; 722; 922) of the carrier, detaching the second region of the layer from the carrier, the first region of the layer remaining on the first surface region of the carrier and not being separated from the second region, the layer being flexible in the detached second region.

A planar multi-layer assembly method fabricates a dual frequency, dual polarization phased-array antenna. A plurality of vias make up an array of double-walled wells which are connected to a ground plane. A shorted annular ring patch antenna (SARPA) is deposited at the top of each double-walled well. Fabricated coaxially and parallel to each SARPA, is an array of circular patch antennas (CPA). The inner wall of each double-walled well improves isolation of the CPA signals from the SARPA signals. Each SARPA of the array is connected to a pair of first frequency band signal vias and the CPA is coupled to a pair of second frequency band signal vias. Within each frequency band, a plurality of signal phases enable steerable polarized antenna beams.

Tamper-respondent assemblies and methods of fabrication are provided which include at least one tamper-respondent sensor having unexposed circuit lines forming, at least in part, one or more tamper-detect network(s), and the tamper-respondent sensor having at least one external bond region. The tamper-respondent assembly further includes at least one conductive trace and an adhesive. The conductive trace(s) forms, at least in part, the one or more tamper-detect network(s), and is exposed, at least in part, on the tamper-respondent sensor(s) within the external bond region(s). The adhesive contacts the conductive trace(s) within the external bond region(s) of the tamper-respondent sensor(s), and the adhesive, in part, facilitates securing the at least one tamper-respondent sensor within the tamper-respondent assembly. In enhanced embodiments, the conductive trace(s) is a chemically compromisable conductor susceptible to damage during a chemical attack on the adhesive within the external bond region(s).

The pocket connector of the invention has been manufactured of a substrate, which is preferably flexible in at least one direction, of which three parts have been prepared, which are bent or assembled from three parts and joined together superimposed so that at least two opposite sides of the pocket connector have coupling apertures. Two flat cables or a connector for a flexible circuit board is connectable to these coupling apertures.

A flexible electronic circuit includes a plurality of leaves having a proximal section, a distal section, and an intermediate section. The plurality of leaves are bonded to each other within the distal section and loose within the intermediate section. The intermediate section also includes conductive connector pads for a wiring harness. A plurality of test connector pads are disposed on the plurality of leaves within the proximal section. The leaves within the proximal section may also be bonded to each other, for example in a ribbon or stepped configuration, in order to facilitate connection to testing apparatus. Once the circuit is tested, the proximal section can be severed from the intermediate section prior to installation of the circuit into a medical device, such as an intracardiac echocardiography catheter.