In a method for manufacturing a semiconductor sensor, an upper mold has a pair of projections on a wall surface opposing to side surfaces of a semiconductor chip in a first cavity and at positions closest to a second cavity. The projections project so as to reduce the space between the side surfaces of the semiconductor chip and the upper mold, so that a flow of a resin material from a first cavity to a second cavity is delayed. The resin material is filled in the first cavity prior to the second cavity. After a portion of a film corresponding to the first cavity is entirely brought into close contact with the upper mold, the resin material is filled in the second cavity.

A computer-implement method for forming a flow insert for an ultrasonic flow meter. The method includes positioning one or more reflectors in a flow insert cavity configured to receive plastic by injection molding and configured to define an ultrasonic signal path based on machined surfaces of the mold and fixing the one or more reflectors in position along the ultrasonic signal path extending into the flow insert cavity. The method further includes forming a flow insert body by injection molding and configured to define an ultrasonic signal path within a flow conduit that includes one or more reflectors integrated within the flow insert body during the injection molding and providing ultrasonic signal reflection along the ultrasonic signal path.

A joint structure comprises a light-absorbable member having at least one opening portion and a light-permeable member superposed on the light-absorbable member so as to cover the opening portion, wherein an annular weld part is formed so as to enclose the opening portion and join the light-absorbable member and the light-permeable member, and the light-permeable member is formed into a thin sheet adhering to the light-absorbable member by deforming at a depressurized state of an interior of the opening portion before the formation of the annular weld part.

A second stacked product is configured with a flexible wiring sheet, and a stacked-element array supported by the flexible wiring sheet. To a biological-body side of the stacked-element array, a ground film is bonded, whereby a structurally reinforced third stacked product is produced. Then, the third stacked product is bent, whereby a curved stacked product is produced. In the bending procedure, in the ground film, a plurality of extension parts arranged along the direction are automatically formed.

Ultrasound transducer assemblies and methods include a kerf fill material that substantially fills kerfs between adjacent transducer elements. In at least one embodiment, an ultrasound transducer assembly includes a plurality of transducer elements and a plurality of kerfs. Each of the kerfs is disposed between adjacent ones of the transducer elements. A kerf fill material is disposed in the plurality of kerfs. The kerf fill material includes a first material having a first viscosity and a solvent that reduces the first viscosity of the kerf fill material to a second viscosity that is less than the first viscosity. The kerf fill material may include a mixture of a silicone and a volatile methylsiloxane (VMS) fluid.

A microfluidic package may include a fluid passage, a substrate having a substrate surface adjacent an interior of the fluid passage and components inset in the substrate, the components having component surfaces adjacent the fluid passage and substantially flush with the substrate surface.

Methods and systems suitable for fabricating multi-layer elastic electronic devices, and elastic electronic devices formed thereby. A method of fabricating an elastomer-based electronic device includes printing a first liquid material and then a second liquid material on a fabric substrate that comprises fibers. The first and second liquid materials are sequentially printed with a three-dimensional printer that directly prints the first liquid material onto the fabric substrate so that the first liquid material wicks through some of the fibers of the fabric substrate and forms a solid matrix of an elastomer-based composite that comprises the matrix and the fabric substrate, after which the three-dimensional printer directly prints the second liquid material on the elastomer-based composite to form a film thereon. The elastomer-based composite and film are electrical components of the elastomer-based electronic device.

The wafer-level method for applying N2 first elements to a first side of a substrate, wherein the substrate has at the first side a first surface including the steps of providing the substrate, wherein at least N barrier members are present at the first side, and wherein each barrier member is associated with one of the first elements. For each of the first elements, the method includes bringing a first amount of a hardenable material in a flowable state in contact with the first surface, the first amount of hardenable material being associated with the first element; controlling a flow of the first amount of hardenable material on the first surface with the associated barrier member; and hardening the first amount of hardenable material to interconnect the first surface and the respective element.

A testing method is disclosed. The testing method includes: providing a mixture solution of a gelling agent and a microbe to a gelling device; solidifying the mixture solution to form a solid thin film in which the microbe is immobilized; supplying a bioactive agent to the solid thin film and allowing the bioactive agent to diffuse into the solid thin film; and imaging the individual responses of the single microbial cells to the bioactive agent, and determining the minimum inhibitory concentration (MIC) of the bioactive agent based on the analysis of the images to obtain AST results.

A system and method for 3D microfabrication projects light capable of initiating photopolymerization toward a spatial light modulator that modulates light responsive to digital masks corresponding to layers of the structure. Projection optics focus the modulated light onto an optical plane within a photopolymerizable material supported on a stage. A computer controller causes the spatial light modulator to project a sequences of images corresponding to the digital masks while coordinating movement of the stage to move a position of the optical plane within the photopolymerizable material to sequentially project each image of the sequence to generate the structure by progressively photopolymerizing the photopolymerizable material.