A semiconductor device includes: a first electrode terminal; a second electrode terminal; a semiconductor element having an electrode on one surface connected to one surface of the first electrode terminal; a wire that connects an electrode on the other surface of the semiconductor element and the second electrode terminal; and a resin portion formed of an insulator covering the semiconductor element, a part of the second electrode terminal, and the one surface of the first electrode terminal, wherein a chamfered portion is formed on at least one of end portions where the first electrode terminal and the second electrode terminal face each other.

This application provides a diode discrete device, a circuit with a bypass function, and a converter. The diode discrete device is used in a circuit with a bypass function, and the diode discrete device includes a discrete device package, a first diode, and a second diode. The first diode is a main circuit diode, the second diode is a bypass diode, first performance of the first diode is better than first performance of the second diode, and the first performance includes a reverse recovery charge and reverse recovery time. The first diode and the second diode are packaged into the discrete device package, and an anode of the first diode is connected to an anode of the second diode, or a cathode of the first diode is connected to a cathode of the second diode. The diode discrete device can improve integration and power density of the circuit.

Electrical device including a substrate having a surface and a radiofrequency field effect transistor (RF-FET) on the substrate surface. RF-FET includes a CNT layer on the substrate surface, the CNT layer including electrically conductive aligned carbon nanotubes, and pin-down anchor layers on the CNT layer. A first portion of the CNT layer, located in-between the pin-down anchor layers, is not covered by the pin-down anchor layers and is a channel region of the radiofrequency field effect transistor and second portions of the CNT layer are covered by the pin-down anchor layers. For cross-sections in a direction perpendicular to a common alignment direction of the aligned CNTs in the first portion of the CNT layer: the aligned CNTs have an average linear density in a range from 20 to 120 nanotubes per micron along the cross-section, and at least 40 percent of the aligned CNTs are discrete from any CNTs of the CNT layer.

A semiconductor device includes: a first electrode terminal; a second electrode terminal; a semiconductor element having an electrode on one surface connected to one surface of the first electrode terminal; a wire that connects an electrode on the other surface of the semiconductor element and the second electrode terminal; and a resin portion formed of an insulator covering the semiconductor element, a part of the second electrode terminal, and the one surface of the first electrode terminal, wherein a chamfered portion is formed on at least one of end portions where the first electrode terminal and the second electrode terminal face each other.

A semiconductor device includes: a first electrode terminal; a second electrode terminal; a semiconductor element having an electrode on one surface connected to one surface of the first electrode terminal; a wire that connects an electrode on the other surface of the semiconductor element and the second electrode terminal; and a resin portion formed of an insulator covering the semiconductor element, a part of the second electrode terminal, and the one surface of the first electrode terminal, wherein a chamfered portion is formed on at least one of end portions where the first electrode terminal and the second electrode terminal face each other.

A programmable circuit includes an array of printed groups of microscopic transistors or diodes. The devices are pre-formed and printed as an ink and cured. The devices in each group are connected in parallel so that each group acts as a single device. In one embodiment, about 10 devices are contained in each group so the redundancy makes each group very reliable. Each group has at least one electrical lead that terminates in a patch area on the substrate. An interconnection conductor pattern interconnects at least some of the leads of the groups in the patch area to create logic circuits for a customized application of the generic circuit. The groups may also be interconnected to be logic gates, and the gate leads terminate in the patch area. The interconnection conductor pattern then interconnects the gates for form complex logic circuits.

Manufacturing an electrical device including providing a substrate having a surface and forming a radiofrequency field effect transistor on the surface, including forming a CNT layer on the surface and depositing a pin-down layer on the CNT layer. The pin-down layer is patterned to form separate pin-down anchor layers. A first portion of the CNT layer, located in-between the pin-down anchor layers and second portions of the CNT layer are covered by the pin-down anchor layers. For cross-sections in a direction perpendicular to a common alignment direction of the electrically conductive aligned carbon nanotubes in the first portion of the CNT layer the electrically conductive aligned carbon nanotubes have an average linear density in a range from 20 to 120 nanotubes per micron along the cross-sections, and at least 40 percent of the electrically conductive aligned carbon nanotubes are discrete from any carbon nanotubes of the CNT layer. A radiofrequency field effect transistor having such a CNT layer and pin-down anchor layers is also disclosed.

A semiconductor device includes: a first electrode terminal; a second electrode terminal; a semiconductor element having an electrode on one surface connected to one surface of the first electrode terminal; a wire that connects an electrode on the other surface of the semiconductor element and the second electrode terminal; and a resin portion formed of an insulator covering the semiconductor element, a part of the second electrode terminal, and the one surface of the first electrode terminal, wherein a chamfered portion is formed on at least one of end portions where the first electrode terminal and the second electrode terminal face each other.

A programmable circuit includes an array of printed groups of microscopic transistors or diodes. The devices are pre-formed and printed as an ink and cured. A patterned hydrophobic layer defines the locations of the printed dots of the devices. The devices in each group are connected in parallel so that each group acts as a single device. Each group has at least one electrical lead that terminates in a patch area on the substrate. An interconnection conductor pattern interconnects at least some of the leads of the groups in the patch area to create logic circuits for a customized application of the generic circuit. The groups may also be interconnected to be logic gates, and the gate leads terminate in the patch area. The interconnection conductor pattern then interconnects the gates for form complex logic circuits.

A solution for packaging a two terminal device, such as a light emitting diode, is provided. In one embodiment, a method of packaging a two terminal device includes: patterning a metal sheet to include a plurality of openings; bonding at least one two terminal device to the metal sheet, wherein a first opening corresponds to a distance between a first contact and a second contact of the at least one two terminal device; and cutting the metal sheet around each of the least one two terminal device, wherein the metal sheet forms a first electrode to the first contact and a second electrode to the second contact.