Provided is a semiconductor package having a package housing in an engraved surface form and a method of manufacturing the same, wherein the semiconductor package includes: at least one substrate on which at least one semiconductor chip is installed; at least one terminal lead electrically connected to the substrates; electrical connectors for connecting the semiconductor chips to the substrates or the terminal leads; a package housing covering the semiconductor chips, the electrical connectors, and the at least one substrate; at least one stopper which is formed of a material same as that of the package housing, is higher by a certain height than exposed surfaces of the substrates, is disposed on the exposed surfaces of the substrates, or covers at least a part of the exposed surfaces; and at least one heat sink transmitting heat from the semiconductor chips and radiating heat, wherein the at least a part of the exposed surfaces of the at least one substrate is formed on the upper surface, the lower surface, or the upper and lower surfaces of the package housing and the exposed surfaces of the at least one substrate are joined to the heat sinks by using heat transfer connectors interposed therebetween. Accordingly, the full thickness of the heat transfer connectors may be uniformly maintained.

A package structure includes a semiconductor device and an adhesive pattern. The adhesive pattern surrounds the semiconductor device, wherein an angle θ is formed between a sidewall of the semiconductor device and a sidewall of the adhesive pattern, 0°<θ<90° wherein the adhesive layer has a first opening misaligned with a corner of the semiconductor device closest to the first opening.

The present invention relates to a molded air-cavity package. In addition, the present invention is related to a device comprising the same. The present invention is particularly related to molded air-cavity packages for radio-frequency ‘RF’ applications including but not limited to RF power amplifiers. Instead of using hard-stop features that are arranged around the entire perimeter of the package in a continuous manner, the present invention proposes to use spaced apart pillars formed by first and second cover supporting elements. By using only a limited amount of pillars, e.g. three or four, the position of the cover relative to the body can be defined in a more predictable manner. This particularly holds if the pillars are arranged in the outer corners of the package.

A module includes a substrate including a first surface, at least one first component mounted on the first surface, a shield member mounted on the first surface to cover the first component, and a first sealing resin arranged at least between the shield member and the first surface. The shield member includes a top surface portion in a form of a plate and a plurality of leg portions that extend from the top surface portion toward the first surface.

A semiconductor package and a method of forming the same are provided. The semiconductor package includes a package substrate and a semiconductor device mounted on the surface of the package substrate. A first ring is disposed over the surface of the package substrate and surrounds the semiconductor device. A second ring is disposed over the top surface of the first ring. Also, a protruding part and a matching recessed part are formed on the top surface of the first ring and the bottom surface of the second ring, respectively. The protruding part extends into and engages with the recessed part to connect the first ring and the second ring. An adhesive layer is disposed between the surface of the package substrate and the bottom surface of the first ring for attaching the first ring and the overlying second ring to the package substrate.

A semiconductor device includes a substrate, an electronic component, a cover and a liquid metal. The electronic component is disposed on the substrate. The cover is disposed on the substrate and covers the electronic component. The liquid metal is formed between the cover and the electronic component.

A package structure includes a substrate, a semiconductor device and an adhesive layer. The semiconductor device is disposed on the substrate, wherein an angle θ is formed between one sidewall of the semiconductor device and one of sides of the substrate, 0°<θ<90°. The adhesive layer surrounds the semiconductor device on the substrate and at least continuously disposed at two of the sides of the substrate, wherein the adhesive layer has a first opening misaligned with a corner of the semiconductor device closest to the first opening.

A high-frequency package includes a radio wave shielding portion that shields radio waves radiated from a high-frequency component, a radio wave absorber that is arranged facing the high-frequency component and that absorbs the radio waves, and an adjusting means that enables adjustment of distance from the radio wave absorber to the high-frequency component by adjusting a position of the radio wave absorber with respect to the radio wave shielding portion.

A light emitting device includes a body having a cavity and a step difference structure around the cavity, a plurality of electrodes in the cavity, a light emitting chip in the cavity, a transparent window having an outer portion provided on the step difference structure to cover the cavity, and an adhesive member between the transparent window and the body. The adhesive member includes a first adhesive member between an outer bottom surface of the transparent window and a bottom of the step difference structure and a second adhesive member between the outer portion of the transparent window and the body.

A method of manufacturing an electronic package is provided, in which a package module including a routing structure is stacked on a carrier structure via a plurality of conductive elements, a heat dissipation member covers a part of a surface of the routing structure, and an electronic module is disposed on another part of the surface of the routing structure, so that the routing structure is formed with at least one heat dissipation pad bonded to the heat dissipation member, such that the heat energy of the electronic module and the package module can be dissipated via the heat dissipation pad and the heat dissipation member.