A wireless communication module includes: a wireless circuit configured to transmit/receive a wireless signal; a first inter-board connector; a first board on which the wireless circuit and the first connector are mounted; a signal processing circuit configured to process the wireless signal transmitted/received by the wireless circuit; a second inter-board connector configured to be connected to the first connector; and a second board on which the signal processing circuit and the second connector are mounted. The first board overlaps at least partially with the second board under a condition where the first connector and the second connector are interconnected.

A flexible electronics assembly includes a single-piece substrate having two regions of rigidity separated by a localized region of flexibility. The localized region of flexibility has a lower rigidity than the two regions of rigidity. The two regions of rigidity are angularly deflectable from a planar configuration of the single-piece substrate to a non-planar configuration of the single-piece substrate by hinging action of the localized region of flexibility. At least one electronic component is mounted on at least one of the two regions of rigidity.

A multilayer structure (200) including a preferably flexible substrate film (102) capable of accommodating electronics (106, 108), such as conductive traces and optionally electronic components such as SMDs (surface-mount device), on a first side thereof, the film having the first side and a second side, and a plastic layer (204) molded onto the first side of the substrate and protruding at one or more locations (114, 114B) through the substrate onto the second side, forming one or more protrusions (218) on the second side having a predetermined function. A corresponding method of manufacture is presented.

A wireless communication module includes: a wireless circuit configured to transmit/receive a wireless signal; a first inter-board connector; a first board on which the wireless circuit and the first connector are mounted; a signal processing circuit configured to process the wireless signal transmitted/received by the wireless circuit; a second inter-board connector configured to be connected to the first connector; and a second board on which the signal processing circuit and the second connector are mounted. The first board overlaps at least partially with the second board under a condition where the first connector and the second connector are interconnected.

A wireless communication module includes: a wireless circuit configured to transmit/receive a wireless signal; a first inter-board connector; a first board on which the wireless circuit and the first connector are mounted; a signal processing circuit configured to process the wireless signal transmitted/received by the wireless circuit; a second inter-board connector configured to be connected to the first connector; and a second board on which the signal processing circuit and the second connector are mounted. The first board overlaps at least partially with the second board under a condition where the first connector and the second connector are interconnected.

Aspects relate to a system and a method of manufacturing an integrated device. The method includes providing a circuit board, configuring an upper surface of the circuit board as a substrate, integrally depositing photovoltaic device layers that include at least a semi-conductor absorber layer, a buffer layer, and a top electrode layer on the upper surface of the circuit board to form a photovoltaic device using the upper surface of the circuit board as a photovoltaic device substrate, wherein the buffer layer is integrally deposited between the semi-conductor absorber layer and the top electrode, and electrically connecting the photovoltaic device to one or more on-board electronic components.

Aspects relate to a system and a method of operating an integrated device is provided. The method includes providing a circuit board that includes one or more on-board electronic components and an upper surface configured as a substrate, providing photovoltaic device layers that include at least a semi-conductor absorber layer, a buffer layer, and a top electrode layer on the upper surface of the circuit board that form a photovoltaic device using the upper surface of the circuit board as a photovoltaic device substrate, wherein the buffer layer is integrally deposited between the semi-conductor absorber layer and the top electrode, generating electricity using the photovoltaic device, and powering one or more of the on-board electronic components using the electricity from the photovoltaic device.

Provided are: a conductive base for forming a wiring pattern of a collector sheet for solar cells, which has good rust inhibiting properties and solderability without using an organic rust inhibitor that may harm a solar cell element; and a method for producing a collector sheet for solar cells, said method using the conductive base. A conductive base for forming a wiring pattern of a collector sheet for solar cells, which is a conductive base (30) wherein a zinc layer (320) composed of zinc is formed on the surface of a copper foil (310), is used. The conductive base for forming a wiring pattern of a collector sheet for solar cells is characterized in that the zinc layer (320) does not contain chromium and the amount of zinc therein is more than 20 mg/m.sup.2 but 40 mg/m.sup.2 or less.

A multilayer structure (200) including a preferably flexible substrate film (102) capable of accommodating electronics (106, 108), such as conductive traces and optionally electronic components such as SMDs (surface-mount device), on a first side thereof, the film having the first side and a second side, and a plastic layer (204) molded onto the first side of the substrate and protruding at one or more locations (114, 114B) through the substrate onto the second side, forming one or more protrusions (218) on the second side having a predetermined function. A corresponding method of manufacture is presented.

A multilayer printed circuit as well as printed passive and active electronic components using additive printing technology is provided. The fabrication process includes a substrate and a first conductive layer that is printed with conductive ink on the substrate. An insulation layer that has uniform thickness is printed on the first conductive layer and the substrate, less via cavities, test point cavities, and a surface mount component contact point and mounting cavities. The insulation layer is replaceable with resistive layer or semi-conductive layer to fabricate electronic components. The vias are printed with conductive ink inside of the via cavities. Additionally, a second conductive layer is printed on the vias and over the insulation layer. The insulation, resistive, or semi-conducting layer, the vias, and the conductive layers are repeatedly printed in sequence to thus form the multilayer printed circuit.