Embodiments described herein can include multi-layer circuits within a liquid crystal polymer (LCP) material to define a 3-D interconnect structure that connects the microelectronics features, devices, components and electrical interfaces. In addition, mechanical functions can be embedded in a fashion and proximity such that the embedded electronics can interface and interact with each other as well as introduced conditions relevant to the function of the device and the outside world or environment it is exposed to.

A wiring board, comprising: wiring patterns that are buried with the wiring board, in which at least one of thickness regions to a thickness position of 7 μm toward a direction away from the wiring patterns with each of one surface and the other surface of the wiring pattern in a thickness direction as a reference has an elastic modulus at 240° C. equal to or greater than 300 MPa, and a dielectric loss tangent is equal to or less than 0.006.

A wiring board, comprising: wiring patterns that are buried in the wiring board, in which a region positioned between wiring patterns disposed in an in-plane direction of the same plane has an elastic modulus at 140° C. equal to or less than 0.1 MPa, and a dielectric loss tangent is equal to or less than 0.006.

A polymer film is provided, the polymer film comprises a liquid crystal polymer, comprising a soluble liquid crystal polymer and an insoluble liquid crystal polymer; and a polyimide polymer, accounting for 5 wt % or more of the polymer film. A method for manufacturing the polymer film is also provided, the method for manufacturing the polymer film comprises steps: providing a liquid crystal polymer powder, a particle size of the liquid crystal polymer powder is 0.1 um to 20 um; providing a liquid crystal polymer glue, a solid content of which is greater than 3 wt %; providing a polyamic acid glue; mixing the liquid crystal polymer powder, the liquid crystal polymer glue and the polyamic acid glue into a mixed solution, the mixed solution is made into a gel film, and the gel film is baked at a temperature of 300° C. to form a polymer film.

A wiring circuit board includes a porous insulating layer, and a first conductive layer sequentially toward one side in the thickness direction. The first conductive layer includes a first signal wire and first ground wires. Each of the first ground wires is thicker than the first signal wire.

A multilayer substrate includes a base body including a first main surface, a first external electrode provided on the first main surface and made of metal foil, a first interlayer connection conductor, and a second interlayer connection conductor having higher conductivity than the first interlayer connection conductor. The base body includes insulating base material layers that are stacked on one another. The first interlayer connection conductor is provided at least in an insulating base material layer on which the first external electrode is provided, and is connected to the first external electrode. The second interlayer connection conductor is disposed inside the base body, and is connected to the first external electrode through the first interlayer connection conductor.

A substrate according to an embodiment includes an insulating layer having a grain formed therein extending in a first direction; and a circuit pattern disposed on the insulating layer; wherein the insulating layer includes an upper surface and a plurality of outer side surfaces; wherein the plurality of outer side surfaces includes: a first outer side surface extending in the same first direction as the first direction having the grain formed in the insulating layer; and a second outer side surface extending in a second direction different from the first direction and excluding the first outer side surface, wherein the first outer side surface has a first surface roughness; and wherein the second outer side surface has a second surface roughness different from the first surface roughness.

An inductor bridge includes a flexible substrate and a coil defined by a conductor pattern provided on or in the flexible substrate, and connects a plurality of circuit portions. The flexible substrate includes a rigid portion and a flexible portion, the rigid portion being wider than the flexible portion. The rigid portion includes the coil and a joining portion connected to another circuit. The coil includes two coil portions located at different positions in plan view, a flexible portion is located adjacent to one side of the rigid portion, and at least two coil portions of the plurality of coil portions are located on the one side when viewed from the joining portion.

A manufacturing method includes stacking, between two endless belts, a first sheet of metal foil, a plurality of insulating films, and a second sheet of metal foil in this order one on top of another and hot-press molding these sheets and films together to form an insulating layer out of the plurality of insulating films. Each of the plurality of insulating films has a first surface and a second surface. The second surface has a larger ten-point mean roughness (Rzjis) than the first surface. The absolute value of difference between a ten-point mean roughness (Rzjis) of a surface, in contact with the first sheet of metal foil, of the insulating layer and a ten-point mean roughness (Rzjis) of another surface, in contact with the second sheet of metal foil, of the insulating layer is equal to or less than 0.35 μm.

A multilayer circuit board includes a board body including insulator layers stacked upon each other, a first land pattern at the board body to mount a passive component, a second land pattern at the board body to mount an active component, and a heat-dissipation layer between the insulator layers and extending along main surfaces of the insulator layers. The heat-dissipation layer includes a hole extending therethrough in a stacking direction of the insulator layers. In a plan view from the stacking direction, an outer edge of the hole of the heat-dissipation layer is on an outer side of the first land pattern, or overlaps the first land pattern.