A high frequency filter includes: a multilayer substrate including a first substrate for which lands are provided, a second substrate for which lands are provided, and a third substrate for which lands are provided, the third substrate being sandwiched between the first substrate and the second substrate; a columnar conductor electrically connected to the lands in the multilayer substrate; and columnar conductors provided to surround the columnar conductor, electrically connected to a ground plane of the first substrate, and electrically connected to a ground plane of the second substrate. The spacing between the lands of the first substrate and the lands of the third substrate and the spacing between the lands of the second substrate and the lands of the third substrate are electrical lengths of 90 degrees or less at the cutoff frequency.

A contact height adjustment structure for a flexible circuit board is provided for making a plurality of conductive zones on a first surface of the flexible circuit board in tight contact engagement with corresponding contact points of a circuit device. The flexible circuit board is provided, on a second surface opposite to the first surface, with a plurality of height adjustment pads that are arranged at intervals and correspond, in a one-to-one manner, to the plurality of conductive zones. The plurality of height adjustment pads provide the plurality of conductive zones with a pushing force toward the corresponding contact points of the circuit device, so as to adjust a contact height of the conductive zones and to achieve an effect of setting the conductive zones in tight contact engagement with the corresponding contact points.

A substrate plate is provided for at least one MEMS device to be mounted thereon. The MEMS device has a certain footprint on the substrate plate, and the substrate plate has a pattern of electrically conductive leads to be connected to electric components of the MEMS device. The pattern forms contact pads within the footprint of the MEMS device and includes at least one lead structure that extends on the substrate plate outside of the footprint of the MEMS device and connects a number of the contact pads to an extra contact pad. The lead structure is a shunt bar that interconnects a plurality of contact pads of the MEMS device and is arranged to be removed by means of a dicing cut separating the substrate plate into a plurality of chip-sized units. At least a major part of the extra contact pad is formed within the footprint of one of the MEMS devices.

Some example forms relate to an electronic package. The electronic package includes a first dielectric layer that includes an electrical trace formed on a surface of the first dielectric layer and a second dielectric layer on the surface of the first dielectric layer. The second dielectric layer includes an opening. The electrical trace is within the opening. The electronic package includes an electrical interconnect that fills the opening and extends above an upper surface of the second dielectric layer such that the electrically interconnect is electrically connected to the electrical trace on the first dielectric layer.

The present disclosure describes a closely spaced array of penetrating electrodes. In some implementations, the electrodes of the array are spaced less than 50 m apart. The present disclosure also describes methods for manufacturing the closely spaced array of penetrating electrodes. In some implementations, each row of electrode of the array is manufactured in-plane and then coupled to other rows of electrodes to form an array.

Circuit having a first printed circuit board and a second printed circuit board. In the circuit, the printed circuit boards spaced apart from one another by means of an air gap are mechanically connected together by at least one power semiconductor.

A printed wiring board has thereon an electronic component having a heat radiation pad, and an electrolytic capacitor provided for the electronic component. The printed wiring board further has thereon another electronic component having another heat radiation pad and exhibiting a higher heat value than that of the electronic component, and another electrolytic capacitor provided for the other electronic component. The heat radiation pad of the electronic component, a ground terminal of the electrolytic capacitor, the other heat radiation pad for the other electronic component, and another ground terminal of the other electrolytic capacitor are connected by using a ground conductor. In the ground conductor, a thermal resistance between the other heat radiation pad and other ground terminal is lower than the thermal resistance between the heat radiation pad and the ground terminal.

A printed wiring board has thereon an electronic component having a heat radiation pad, and an electrolytic capacitor provided for the electronic component. The printed wiring board further has thereon another electronic component having another heat radiation pad and exhibiting a higher heat value than that of the electronic component, and another electrolytic capacitor provided for the other electronic component. The heat radiation pad of the electronic component, a ground terminal of the electrolytic capacitor, the other heat radiation pad for the other electronic component, and another ground terminal of the other electrolytic capacitor are connected by using a ground conductor. In the ground conductor, a thermal resistance between the other heat radiation pad and other ground terminal is lower than the thermal resistance between the heat radiation pad and the ground terminal.

Some example forms relate to an electronic package. The electronic package includes a first dielectric layer that includes an electrical trace formed on a surface of the first dielectric layer and a second dielectric layer on the surface of the first dielectric layer. The second dielectric layer includes an opening. The electrical trace is within the opening. The electronic package includes an electrical interconnect that fills the opening and extends above an upper surface of the second dielectric layer such that the electrically interconnect is electrically connected to the electrical trace on the first dielectric layer.

A circuit structure includes a first busbar, a second busbar, an insulating member including an insulating portion located between the first busbar and the second busbar, a first wiring board provided on one main surface of the first busbar, one main surface of the second busbar and the insulating portion, and a first electronic component provided on the first wiring board. The first electronic component has a first connection terminal electrically connected to the first busbar and bonded to the first wiring board, and a second connection terminal electrically connected to the second busbar and bonded to the first wiring board.