A metal-laminated structure is provided. The metal-laminated structure includes a substrate, a compressive stress layer disposed on the substrate, and at least one metal layer disposed on the compressive stress layer, wherein the thickness ratio of the metal layer to the compressive stress layer is in a range from 1 to 30. A high-frequency device including the metal-laminated structure is also provided.

The transmission line substrate includes a first transmission line of a first line length on a substrate made of a dielectric material and connects a first integrated circuit and a second integrated circuit, a first dielectric layer having a first dielectric constant covering the first integrated circuit, the second integrated circuit and the first transmission line, a second dielectric layer having a second dielectric constant formed on the first dielectric layer, a first columnar via connected to the first integrated circuit, a second columnar via connected to the second integrated circuit, and a second transmission line having a second line length in the second dielectric layer and connected to the first via and the second via. A first dielectric constant and a second dielectric constant are set so that the signal transmission times in each of the first transmission line and the second transmission line are equal.

Various embodiments disclosed relate to a circuit. The circuit includes a transceiver adapted to generate a signal. A stranded transmission line is connected to the transceiver. The signal is then transmitted through the first pair of conductive strands.

An electro-magnetic transmission line system having very low loss, which includes a low dielectric material proximate to a conductor on one side, a conductor on the opposite side and a substrate to which at least one of the conductors are attached. Also an antenna is provided, which incorporate the electro-magnetic transmission line system to transmit the radiation energy.

Embodiments of the invention include a packaged device with transmission lines that have an extended thickness, and methods of making such device. According to an embodiment, the packaged device may include a first dielectric layer and a first transmission line formed over the first dielectric layer. Embodiments may then include a second dielectric layer formed over the transmission line and the first dielectric layer. According to an embodiment, a first line via may be formed through the second dielectric layer and electrically coupled to the first transmission line. In some embodiments, the first line via extends substantially along the length of the first transmission line.

A feeder circuit includes: a first line 103 having first and second ends; a second line 104 having first and second ends; a third line 105 having first and second ends; a first combiner 101 configured to combine signals output from the second ends of the first and second lines 103 and 104; a first coupling portion 115 configured to electrically couple portions of the first and third lines to each other; and a second coupling portion 116 configured to electrically couple portions of the second and third lines to each other in a manner that allows a signal reaching the first combiner from the first end of the third line through the first coupling portion and a signal reaching the first combiner from the first end of the third line through the second coupling portion, to be cancelled out.

A multilayer substrate includes an element assembly including stacked insulating layers and including at least a first insulating layer with a first principal surface and a second principal surface and a second insulating layer with a third principal surface and a fourth principal surface, a first conductor layer, and a second conductor layer. The second principal surface and the third principal surface are in contact with each other, and no planar or linear conductors are located on the second principal surface and the third principal surface. The first conductor layer is located on the first principal surface, and the second conductor layer is located on the fourth principal surface.

The invention discloses a three-dimensional complementary-conducting-strip (CCS) structure. Some two-dimensional mesh metal layers are stacked vertically and connected mutually via numerous vias to form a three-dimensional network structure, and one or more signal lines with three-dimensional trace style(s) are positioned inside and separated away the three-dimensional network structure. Moreover, each two-dimensional mesh metal layer is a planar metal layer with one or more empty areas. The three-dimensional network structure is grounded, the signal lines(s) is electrically connected to the device(s) and/or terminal(s) respectively, and the dielectric material(s) is used to electrically insulate the signal line(s) from the three-dimensional network structure.

Described herein are integrated circuit structures having a package substrate with microstrip architecture as the uppermost layers and a surface conductive layer that is electrically connected to a ground plane internal to the package substrate, as well as related devices and methods. In one aspect of the present disclosure, an integrated circuit package substrate may have an internal ground plane, a dielectric layer, a microstrip signal layer as the top transmission line layer, a solder resist layer, and a surface conductive layer that is electrically connected to the internal ground plane in the package substrate. In another aspect of the present disclosure, an integrated circuit package substrate may include altering thicknesses of the dielectric and/or solder resist layers to optimize electrical performance by having the microstrip signal layer closer in proximity to the internal ground layer as compared to the surface conductive layer.

A transmission line impedance transformer including at least two different dielectric media having different dielectric properties, each of the dielectric media being configured to taper in thickness along the length of the impedance transformer in an inverse relationship with respect to each other so as to form a combined dielectric medium having an effective dielectric property that is graded along the transmission path. The two or more dielectric media may be disposed between two conductors to provide an impedance transformer in which a characteristic impedance of the transmission line varies along its length in response to the gradation of the effective dielectric property of the combined dielectric medium.