An electronic device includes an electromagnetic interference shield having a layer of conductive material covering at least a portion of the electronic device and having a skin depth of less than 2 μm for electromagnetic signals having frequencies in a kilohertz range.

A noise filter includes a metallic bottom plate, a case main body integrally formed with a terminal strip and attached to the bottom plate, and a capacitor including a terminal configured to be connected in the terminal strip. The noise filter further includes a capacitor housing part formed inside the terminal strip in the case main body, the capacitor housing part being configured to house the capacitor, and an inductor disposed on a top surface side of the case main body, the inductor comprising a terminal configured to be connected in the terminal strip. The capacitor housing part houses the capacitor, in a state where the capacitor is inclined with respect to the bottom plate, so that a lead part of the terminal of the capacitor is positioned on an upper end side of the capacitor in an inclination direction.

A connector including a first body, a second body, a dielectric film and one or more conductive traces. The first body has first and second opposite sides and includes an elastomeric absorber material with ferrite or iron powder dispersed therein. The second body includes the elastomeric absorber material with ferrite or iron powder dispersed therein. The dielectric film is disposed on surfaces of the first body to extend along and between the first and second opposite sides. The one or more conductive traces are sandwiched between the second body and the dielectric film to extend along and between the first and second opposite sides. The connector can be installed into a conductive aperture, to channel RF energy through it and thus effecting an absorptive RF filter for a signal.

Inductor designs and methods are provided. An inductor can include a first core and a second core. The first core can be larger than the second core and the second core can be seated within the inner diameter of the first core. A first and a second wire can be provided that each wrap around the first core and the second core. The first core can have less windings than the second core.

A filter circuit and an electronic equipment are provided. The filter circuit, electrically connected between a power module and an integrated circuit control module, includes a capacitor unit, a ferrite bead component, and a filter capacitor. The capacitor unit is electrically connected to a first node of the power module. The ferrite bead component is electrically connected to a second node of the integrated circuit control module and the first node of the power module. The filter capacitor is electrically connected to the second node of the integrated circuit control module. The ferrite bead component has a zero resistance. This reduces the ripple of the power signal, outputted by the power module, after the power signal passes through the ferrite bead component, solving the above-mentioned EMI issue, and improving the performance of the IC.

Provided is a noise filter device that is capable of suppressing electrical interference between an input-side conductive line and an output-side conductive line. A noise filter device (10) includes: a noise filter (50) connected to a distal end of an input-side conductive line (41) and a distal end of an output-side conductive line (42); and a holding member (60) that holds the input-side conductive line (41) and the output-side conductive line (42). The holding member (60) includes: a body (61) attached to a wire harness (WH) so as to surround an outer circumference thereof; and a pair of hooks (62) that are respectively formed at two ends of the body (61) in a circumferential direction thereof, and are hooked on the input-side conductive line (41) and the output-side conductive line (42) to restrict the input-side conductive line (41) and the output-side conductive line (42) from approaching each other.

A Communication System includes a first power supply channel including a first impedance and a second impedance, and configured to transfer electrical power from a first power source to a first load. The first power supply channel is configured to electrically couple to the first power source via a first common mode choke. The communication system also includes a second power supply channel comprising a third impedance and a fourth impedance, and configured to transfer electrical power from a second power source to a second load. The second power supply channel is configured to electrically couple to the second power source via a second common mode choke. The communication system further includes a first transceiver comprising a first output pin electrically coupled to the first power supply channel and a second output pin electrically coupled to the second power supply channel at a first end of the communication system.

This application relates to an independent active electromagnetic interference filter module. In one aspect, the filter module includes a first element group including a noise sensing unit provided to sense electromagnetic noise, and a second element group including a compensating unit provided to generate a compensation signal for the electromagnetic noise. The first group and the second group may be respectively mounted on different substrates. According to some embodiments, the filter module can reduce a volume of each element constituting an electromagnetic interference filter module, implement a single modularization of a compact structure. The filter module can also improve electromagnetic interference noise reduction performance and a manufacturing method thereof.

A hermetically sealed feedthrough assembly for an active implantable medical device having an oxide-resistant electrical attachment for connection to an ENI filter, an EMI filter circuit board, an AIMD circuit board, or AIMD electronics. The oxide-resistant electrical attachment, including an oxide-resistant coating layer that is disposed on the device side surface of the hermetic seal ferrule over which an optional ECA stripe may be provided. The optional ECA stripe may comprise one of a thermal-setting electrically conductive adhesive, an electrically conductive polymer, an electrically conductive epoxy, an electrically conductive silicone, an electrically conductive polyamide, or an electrically conductive polyimide, such as those manufactured by Ablestick Corporation. The oxide-free coating layer may comprise one of gold, platinum, palladium, silver, iridium, rhenium, rhodium, tantalum, tungsten, niobium, zirconium, vanadium, and combinations or alloys thereof. As used herein, the oxide-free coating layer is not limiting and as will be taught, in addition to sputtering, there are many other methods of applying a proud oxide-free surface on either an AIMD ferrule or am AIMD housing.

A differential mode electromagnetic noise injection network includes an injection piece and a differential mode loop. The injection piece includes a semiconductor transistor or a winding differential mode inductor. The injection piece is at least provided with a first injection end, a second injection end, and a differential mode electromagnetic noise component input end. The differential mode electromagnetic noise component input end is configured to input a differential mode electromagnetic noise component. The first injection end and the second injection end are connected to any two points that are connected in series in the differential mode loop in a one-to-one correspondence, and are configured to inject the differential mode electromagnetic noise component. An active electromagnetic interference filter including the differential mode electromagnetic noise injection network mentioned above is provided.