Abstract: A method is provided for forming an integrated circuit (IC) chip package structure. The method includes providing a substrate for an interposer, and forming a conductive interconnect structure in and on the substrate for connecting a group of selected IC dies. The method includes forming warpage-reducing trenches in non-routing regions of the interposer, wherein the warpage-reducing trenches are sized and positioned based on a warpage characteristic to reduce the warpage of the chip package structure. The method also includes depositing a warpage-relief material in the warpage-reducing trenches according to the warpage characteristic to reduce the warpage of the chip package structure, and bonding the group of selected IC dies to the interposer to form a chip package structure.

Abstract: A structure includes a first waveguide and a second waveguide. The first waveguide includes a first strip portion and a first tapered tip portion connected to the first strip portion. The second waveguide includes a second strip portion and a second tapered tip portion connected to the second strip portion, wherein the first tapered tip portion of the first waveguide is optically coupled to the second tapered tip portion of the second waveguide, and the first waveguide and the second waveguide are configured to guide a light. In a region where the light is coupled between the first tapered tip portion and the second tapered tip portion, an effective refractive index of the first waveguide with respect to the light is substantially equal to an effective refractive index of the second waveguide with respect to the light.

Abstract: A fastener is adapted for assembling a first housing to a second housing. The first housing is provided with a protruding portion and a buckling portion, and the second housing has a first surface, a second surface, and a through hole. The fastener includes a first portion, at least one connecting portion, at least two elastic portions, and a second portion. The first portion movably abuts against the first surface and has a first opening. The connecting portion is accommodated in the through hole. One end of the connecting portion is connected to the first portion. The connecting portion is spaced apart from an inner edge of the second housing by a gap. The two elastic portions inclinedly extend into the first opening. The second portion movably abuts against the second surface and is disposed at the another end of the connecting portion.

Abstract: A hybrid permanent magnet motor rotor rotates around a central axis, and includes: a rotor core provided with a plurality of magnet installation slots; and a plurality of magnet parts embedded inside a plurality of magnet installation slots respectively, wherein the rotor is provided with a plurality of first magnetic pole parts and a plurality of second magnetic pole parts, the magnetic poles of the first magnetic pole part and the second magnetic pole part are arranged in opposite and alternately in the circumferential direction, and the magnetic placement of the first magnetic pole part is different from that of the second magnetic pole part, the amount of magnets used in the second magnetic pole part is greater than that used in the first magnetic pole part.

Abstract: A composition for preparing a foam, a foam, and a shoe employing the foam are provided. The composition for preparing a foam includes 3-30 parts by weight of a first polymer and at least one of a second polymer and a third polymer. The first polymer is cyclic olefin polymer (COP), cyclic olefin copolymer (COC), metallocene based cyclic olefin copolymer (mCOC), fully hydrogenated conjugated diene-vinyl aromatic copolymer, or a combination thereof. The total weight of the second polymer and the third polymer is 70-97 parts by weight. The second polymer is polyolefin, olefin copolymer, or a combination thereof. The third polymer is conjugated diene-vinyl aromatic copolymer, partially hydrogenated conjugated diene-vinyl aromatic copolymer, or a combination thereof. The total weight of the first polymer and at least one of the second polymer and the third polymer is 100 parts by weight.

Abstract: A reticle enclosure includes a base including a first surface, a cover including a second surface and coupled to the base with the first surface facing the second surface. The base and the cover form an internal space that includes a reticle. The reticle enclosure includes restraining mechanisms arranged in the internal space and for securing the reticle, and structures disposed adjacent the reticle in the internal space. The structures enclose the reticle at least partially, and limit passage of contaminants between the internal space and an external environment of the reticle enclosure. The structures include barriers disposed on the first and second surfaces. In other examples, a padding is installed in gaps between the barriers and the first and second surfaces. In other examples, the structures include wall structures disposed on the first and second surfaces and between the restraining mechanisms.

Abstract: An electronic device includes a substrate, a plurality of first retaining walls, a second retaining wall, and a light emitting element. The first retaining walls are arranged on the substrate. The second retaining wall is arranged on the substrate and disposed within one of the first retaining walls. The light emitting element is arranged on the substrate and disposed between the second retaining wall and one of the first retaining walls adjacent to the second retaining wall. In a cross section, there are a first distance between the light emitting element and the one of the first retaining walls, and a second distance between the light emitting element and the second retaining wall, wherein the second distance is smaller than the first distance.

Abstract: A mouse includes a lower shell, an upper shell covered on the lower shell, a first elastic element, a second elastic element and a circuit board. The upper shell has a first button and a second button. A bottom surface of the first button extends downward to form a first pressing portion. A bottom surface of the second button extends downward to form a second pressing portion and a third pressing portion. One end of the first elastic element abuts against the first pressing portion to generate a first downward force. One end of the second elastic element abuts against the second pressing portion to form a second downward force. The other end of the second elastic element abuts against the third pressing portion to generate a resilience force. The first downward force is equal to a sum of the second downward force and the resilience force.

Abstract: A semiconductor device is provided. The semiconductor device includes a waveguide over a first dielectric layer. A first portion of the waveguide has a first width and a second portion of the waveguide has a second width larger than the first width. The semiconductor device includes a first doped semiconductor structure and a second doped semiconductor structure. The second portion of the waveguide is between the first doped semiconductor structure and the second doped semiconductor structure.

Abstract: In example implementations, a computing device is provided. The computing device includes a system management bus, a controller communicatively coupled to the system management bus, a noise generating component communicatively coupled to the controller, a noise cancellation codec communicatively coupled to the system management bus, and a speaker communicatively coupled to the noise cancellation codec. The operating parameters of the noise generating component are provided to the controller. The noise cancellation codec is to receive the operating parameters of the noise generating component from the controller via the system management bus and to generate a noise cancellation signal based on the operating parameters. The speaker outputs the noise cancellation signal to cancel noise generated by the noise generating component.

Abstract: A semiconductor structure includes a semiconductor substrate, a semiconductor device and a heating structure. The semiconductor substrate includes a device region and a heating region surrounding the device region. The semiconductor device is located on the device region. The heating structure is located on the heating region and includes an intrinsic semiconductor area, at least one heating element and at least one heating pad. The intrinsic semiconductor area is surrounding the semiconductor device. The at least one heating element is located at a periphery of the intrinsic semiconductor area. The at least one heating pad is joined with the at least one heating element, wherein the at least one heating pad includes a plurality of contact structures, and a voltage is supplied from the plurality of contact structures to control a temperature of the at least one heating element.

Abstract: A semiconductor structure includes a substrate, a grating coupler structure over the substrate, a multi-layers film structure over the grating coupler structure. The multi-layers film structure include a first layer including a first refractive index, a second layer over the first layer and including a second refractive index and a third layer over the second layer and including a third refractive index. The second refractive index is greater than the first refractive index and is greater than the third refractive index of the third layer, and a thickness of each layer of the multi-layers film structure is within a range from ?/4 to ?2, ? is a wavelength of light.

Abstract: An optical waveguide structure of a semiconductor photonic device includes a first semiconductor waveguide, a second semiconductor waveguide, and an air seam between the first and second semiconductor waveguides. The semiconductor waveguides extend in a first direction, and a plurality of air seams extend in a second direction. Each of the air seams is disposed between two adjacent semiconductor waveguides. A distance between the two adjacent semiconductor waveguides is less than a width of each semiconductor waveguide.

Abstract: A method includes receiving a silicon substrate; forming a first doped region and a second doped region in the silicon substrate; forming a third doped region and fourth doped region on upper portions of the first doped region and the second doped region, respectively; and patterning the silicon substrate to form an optical modulator. The optical modulator includes: a first section; a second section and a third section at least formed from the first and second doped regions, respectively; a fourth section, including a first height less than that of the first section and the second section and arranged between the first section and the second section, the fourth section being an undoped region; and a fifth section immediately adjacent to the fourth section, the fifth section including a height less than that of the first section and the second section and different from the first height.

Abstract: A photodetection device and a manufacturing method are provided. The photodetection device includes an absorption structure, a cathode, a charge multiplication region and an anode. The absorption structure is formed in a recess at a surface region of a semiconductor substrate, and configured to receive an incident light. The cathode is formed on a top surface of the absorption structure, and has a first conductive type. The charge multiplication layer is in lateral contact with the absorption structure, and is an intrinsic portion of the semiconductor substrate extending into the semiconductor substrate from a topmost surface of the semiconductor substrate. The anode is in lateral contact with the charge multiplication layer from a side of the charge multiplication region away from the absorption structure, and is a doped region in the semiconductor substrate having a second conductive type complementary to the first conductive type.

Abstract: An edge coupler, a waveguide structure and a method for forming a waveguide structure are provided. The edge coupler includes a substrate, a first cladding layer, a core layer and a first anti-reflection coating layer. The first cladding layer has a second sidewall aligned with a first sidewall of the substrate. The core layer has a third sidewall aligned with the second sidewall. The anti-reflection coating layer lines the first sidewall, the second sidewall and the third sidewall. A thickness of the anti-reflection coating layer varies along the first sidewall, the second sidewall and the third sidewall.

Abstract: Some implementations described herein include a photonics integrated circuit device including a photonics structure. The photonics structure includes a waveguide structure and an optical attenuator structure. In some implementation, the optical attenuator structure is formed on an end region of the waveguide structure and includes a metal material or a doped material. In some implementations, the optical attenuator structure includes a gaussian doping profile within a portion of the waveguide structure. The optical attenuator structure may absorb electromagnetic waves at the end of the waveguide structure with an efficiency that is improved relative to a spiral optical attenuator structure or metal cap optical attenuator structure.

Abstract: A semiconductor device is provided. The semiconductor device includes a waveguide over a first dielectric layer. A first portion of the waveguide has a first width and a second portion of the waveguide has a second width larger than the first width. The semiconductor device includes a first doped semiconductor structure and a second doped semiconductor structure. The second portion of the waveguide is between the first doped semiconductor structure and the second doped semiconductor structure.

Abstract: A semiconductor structure includes a waveguide and an optical attenuator. The waveguide is disposed over an insulating layer and configured to guide light. The optical attenuator is connected to the waveguide. The optical attenuator has a first surface and a second surface opposite the first surface, and a cross-sectional width of the optical attenuator decreases from the first surface to the second surface.

Abstract: A method for manufacturing an integrated circuit device is provided. The method includes: providing a photonic structure including an insulating structure and an optical coupler embedded in the insulating structure; and removing a portion of the insulating structure to expose a coupling surface of the optical coupler and form a light reflective structure corresponding to the coupling surface.