A sensing device includes a printed circuit board (PCB) having a conductive trace. A micro-controller is attached to the conductive trace and data transmission means is connected to the micro-controller. A sensor is embedded within the PCB and is connected to the micro-controller via the conductive trace. The sensor is configured to sense at least one physiological parameter in a patient.

A pin assembly is provided for a plated via of a circuit board. The pin assembly includes a pin sized for insertion into the plated via, and a plurality of expandable elements affixed to the pin. A conductive coating is disposed over the pin and over the plurality of expandable elements. With the pin assembly inserted into the plated via, one or more expandable elements of the plurality of expandable elements can be expanded within the plated via to enhance contact of the pin assembly to a wall of the plated via.

A printed circuit board (PCB) includes an insulating layer, a first solder resist layer disposed on an upper surface of the insulating layer, a first conductive pattern disposed on the insulating layer and providing a conductive post protruding from an upper surface of the first solder resist layer, and a second conductive pattern buried in the insulating layer and having an upper surface positioned to be lower than the upper surface of the insulating layer.

The electronic device includes a printed circuit board having a first main surface, an electronic part mounted on the first main surface, and a first connection member connecting the printed circuit board and the electronic part. The printed circuit board includes at least one projection formed on the first main surface so as to project in a direction crossing the first main surface. The projection is formed outside the bottom surface of the electronic part which is located at the side of the first main surface. The first connection member is in contact with at least part of the projection, at least part of the bottom surface of the electronic part, and at least part of a lateral surface of the electronic part intersecting the bottom surface.

A circuit module comprises a substrate module, an electronic component, and a first conductive joining member. The substrate module includes a circuit substrate having an upper main surface and a lower main surface, an insulating member covering the upper main surface of the circuit substrate, an insulating member covering the upper main surface of the circuit substrate, and a first metal pin that passes through the insulating member parallel to a vertical axis and is electrically connected to the circuit substrate. The first metal pin has a first exposed portion. The first exposed portion is exposed from the insulating member to face a right direction. A first outer electrode has a left projecting portion projecting in a left direction from the left surface. A first conductive joining member joins the first exposed portion and the left projecting portion to each other.

A compact solid state relay (7) is provided. Solid state devices (74, 75), such as Triacs or Thyristors are used to implement the relay functionality. The device is at least partially enclosed in a housing that has pins for mounting on an electronics board. A number of U shaped jumpers (72) or other jumpers or wires are provided in the housing to act as heat sinks. A sub-miniature fan (70) is positioned to create an air flow over the heat sinks and dissipate heat from the device.

The invention relates to a control device having a casing, control electronics located in the casing, and at least one electrical feedthrough. By means of the electrical feedthrough, current can be provided for a load which is located outside the casing of the control device. The electrical feedthrough is located on the casing. The casing is fluid-tight at least in part, and the electrical feedthrough is located in a fluid-tight region of the casing. The electrical feedthrough has a metal core and an insulator surrounding the metal core. The metal core has an end face. A first bond is provided between the end face of the metal core and the control electronics, the first bond being laser-bonded at the end face.

A sensor for sensing ions, comprising a circuit board assembly, and a core assembly connected to the circuit board assembly, the core including a first electrical conductor and a second electrical conductor.

A multilayer bus board comprising a multilayer stacked assembly including a plurality of electrically conductive first layers, and at least one second dielectric layer disposed between adjacent first layers; and a frame formed of a dielectric material, the frame encapsulating at least a portion of the multilayer stacked assembly and mechanically maintaining the first and second layers in secure aligned abutting relation.

A circuit board assembly in an electronic is disclosed. To conserve space in the electronic device, the circuit board assembly includes stacked circuit boards in electrical communication with each other, such as a first circuit board stacked over a second circuit board. Each circuit board may include multiple surfaces that carry operational components. Moreover, the first circuit board may include a first surface and the second circuit board may include a second surface facing the first surface. The first and second surfaces may include operational components in corresponding locations. Also, the operational components may include corresponding shapes such that one component is positioned in another component. The components may electrically connect to each other. Also, the circuit board assembly may include EMI shields around an outer perimeter in order to shield the operational components form EMI and to components in the electronic device from EMI emanating from the operational components.