The disclosure is directed to an electronic package with an interposer between integrated circuit dies. At least one inner capacitor (e.g., single layer capacitor) is mounted to the interposer. The electronic package further includes an input passive circuit substrate and an output passive circuit substrate mechanically coupled to the metal base. Use of an interposer to be simultaneously solder attached with integrated circuit dies provides a configuration that improves linearity performance and/or wide video bandwidth of the electronic package (e.g., packages that use epoxy and laminate interposers). Further, such configuration facilitates efficient manufacturing of the electronic package at high volumes.

An air cavity package includes a flange and a pedestal extending upward from the flange. A dielectric frame is joined to the flange and surrounds the pedestal. The semiconductor die is placed on the pedestal, which reduces the length of the wires joining the die to the leads of the air cavity package.

A device includes: a surface mount device carrier configured to be mounted to a metal submount of a transistor package, said surface mount device carrier includes an insulating substrate includes a top surface and a bottom surface and a first pad and a second pad arranged on a top surface of said surface mount device carrier; at least one surface mount device includes a first terminal and a second terminal, said first terminal of said surface mount device mounted to said first pad and said second terminal mounted to said second pad; and at least one of the first terminal and the second terminal being configured to be isolated from the metal submount by said insulating substrate, where at least one of the first pad and the second pad are configured as wire bond pads.

An air cavity package with one or more dovetail recesses configured with a first recess and a coincident second recess. The first recess has a first depth and the second recess has a second depth. The first recess has a lower width and an upper width smaller than the first lower width creating a dovetail shape. Individual dovetail recesses are created by creating a first recess in the flange at a first width and depth. A second recess with a second width and second depth and coincident with the first recess is pressed into the flange. The second width is greater than the first width and the second depth is smaller than the first depth. Pressing the second recess causes the first width at an upper portion to decrease, causing the first recess to develop a dovetail shape.

Embodiments of semiconductor devices (e.g., RF devices) include a substrate, an isolation structure, an active device, a lead, and a circuit. The isolation structure is coupled to the substrate, and includes an opening. An active device area is defined by a portion of the substrate surface that is exposed through the opening. The active device is coupled to the substrate surface within the active device area. The circuit is electrically coupled between the active device and the lead. The circuit includes one or more elements positioned outside the active device area (e.g., physically coupled to the isolation structure and/or under the lead). The elements positioned outside the active device area may include elements of an envelope termination circuit and/or an impedance matching circuit. Embodiments also include method of manufacturing such semiconductor devices.

Embodiments of semiconductor devices (e.g., RF devices) include a substrate, an isolation structure, an active device, a lead, and a circuit. The isolation structure is coupled to the substrate, and includes an opening. An active device area is defined by a portion of the substrate surface that is exposed through the opening. The active device is coupled to the substrate surface within the active device area. The circuit is electrically coupled between the active device and the lead. The circuit includes one or more elements positioned outside the active device area (e.g., physically coupled to the isolation structure and/or under the lead). The elements positioned outside the active device area may include elements of an envelope termination circuit and/or an impedance matching circuit. Embodiments also include method of manufacturing such semiconductor devices.

A thermal packaging device for dissipating heat generated by electronic components comprising a copper base and a ceramic frame mounted to the base with a buffer comprising a nickel-cobalt ferrous alloy. Also disclosed is a thermal packaging device with a base comprised of a layer of copper molybdenum alloy sandwiched between two layers of copper and a ceramic frame mounted to the base. Further disclosed is a thermal packaging device with a base comprised of alternating layers of copper, molybdenum, and copper; and a ceramic frame mounted to the base.

An object is to provide a semiconductor device in which heat generated in a lead electrode when conducting a large current can be reduced and the bonding quality between the lead electrode and a semiconductor element can be inspected easily. A semiconductor device includes: a base portion; a semiconductor element mounted on the base portion; a metal part erect with respect to the semiconductor element and having one end bonded, with a bonding material, to a principal surface of the semiconductor element opposite to another principal surface of the semiconductor element mounted on the base portion; and a lead electrode connected to the semiconductor element through the metal part. The lead electrode includes a through hole extending in a thickness direction. The metal part connects the semiconductor element to the lead electrode, while inserted into the through hole of the lead electrode together with a part of the bonding material.

An object is to provide a semiconductor device in which heat generated in a lead electrode when conducting a large current can be reduced and the bonding quality between the lead electrode and a semiconductor element can be inspected easily. A semiconductor device includes: a base portion; a semiconductor element mounted on the base portion; a metal part erect with respect to the semiconductor element and having one end bonded, with a bonding material, to a principal surface of the semiconductor element opposite to another principal surface of the semiconductor element mounted on the base portion; and a lead electrode connected to the semiconductor element through the metal part. The lead electrode includes a through hole extending in a thickness direction. The metal part connects the semiconductor element to the lead electrode, while inserted into the through hole of the lead electrode together with a part of the bonding material.

A semiconductor packaging structure includes a copper heat-sink with a shim projection which provides a stress release structure. The heat-sink with the shim projection may be used in conjunction with a pedestal in order to further reduce the thermal stress produced from the mismatch of thermal properties between the copper heat-sink metal and the ceramic frame. The copper heat-sink with a shim projection may also be part of the semiconductor package along with a lead frame, the ceramic frame, a semiconductor device, a capacitor, a wire bond and a ceramic lid or an encapsulation. The copper heat-sink, the ceramic frame and the lead frame are all chosen to be cost effective, and chosen such that the packaging process for the semiconductor device is able to achieve a smaller size while maintaining high reliability, low cost, and suitability for volume manufacturing.