Embodiments of a magnetic field sensor of the present disclosure includes magnetoelectric nanowires suspended above a substrate across electrodes without substrate clamping. This results in enhanced magnetoelectric coupling by reducing substrate clamping when compared to layered thin-film architectures. Accordingly, the magnetoelectric nanowires of the magnetic field sensor generate a voltage response in the presence of a magnetic field.

A power generation element uses an inverse magnetostrictive effect and includes: a frame yoke made of a magnetic material and having a bent part for forming a closed magnetic circuit, a magnetic part formed in a part of the frame yoke, a magnetostrictive plate made of a magnetostrictive material, a coil, and magnets. The magnetic part has rigidity and geometry for applying a uniform compressive force or tensile force to the magnetostrictive plate and is magnetically saturated by magnetic biases of the magnets. The magnetostrictive plate is attached to the frame yoke so as to be parallel to the magnetic part. The coil is wound around a parallel beam part including the magnetostrictive plate and the magnetic part and/or around the frame yoke. An application of an external force causes the magnetostrictive plate to be extended and compressed and causes the generation of electricity.

Embodiments of the invention include a current sensing device for sensing current in an organic substrate. The current sensing device includes a released base structure that is positioned in proximity to a cavity of the organic substrate and a piezoelectric film stack that is positioned in proximity to the released base structure. The piezoelectric film stack includes a piezoelectric material in contact with first and second electrodes. A magnetic field is applied to the current sensing device and this causes movement of the released base structure and the piezoelectric stack which induces a voltage (potential difference) between the first and second electrodes.

An electrical generator comprises a converter including two electrical terminals for converting a variation in a magnetic field into a potential difference between the terminals. The generator includes a stack of a first layer comprising an anisotropic magnetostrictive material defining a reference plane and a second layer comprising a piezoelectric material. The first layer has at least one preferential axis of deformation in the reference plane and the second layer has a polarization axis parallel to the reference plane, the preferential axis of deformation of the first layer being aligned to within 15 with the polarization axis of the second layer. The generator includes a source that generates the magnetic field, the strength of which is insufficient to magnetically saturate the material of the first layer. The source and converter are able to rotate with respect to each other so as to vary the orientation of the magnetic field.

A magnetic field sensor includes a magnetic sense element and a shield structure formed on a substrate. The shield structure fully encircles the magnetic sense element for suppressing stray magnetic fields along a first axis and a second axis, both of which are parallel to a surface of the substrate and perpendicular to one another. A magnetic field is oriented along a third axis perpendicular to the surface of the substrate, and the magnetic sense element is configured to sense a magnetic field along the first axis. A magnetic field deflection element, formed on the substrate proximate the magnetic sense element, redirects the magnetic field from the third axis into the first axis to be sensed as a measurement magnetic field by the magnetic sense element. At least two magnetic field sensors, each fully encircled by a shield structure, form a gradient unit for determining a magnetic field gradient.

A power generation element of inverse magnetostrictive type has: a first power generation part including a first magnetostrictive rod made of magnetostrictive material, a first coil wound around the first magnetostrictive rod, and a first magnetic rod having appropriate rigidity and a shape to apply a uniform compressive force or tensile force to the first magnetostrictive rod and being placed in parallel with the first magnetostrictive rod; a frame made of magnetic material bent in a substantially U shape, whose one end and other end across the bent location constitute a fixed end and free end, respectively; and a magnet. The power generation element can suppress the loss of kinetic energy while vibrating so that vibration will last long. The power generation element can be used in an actuator.

According to one embodiment, a sensor includes a film portion, and a first sensor portion. The film portion includes a first film including a plurality of holes. The film portion is deformable. The first sensor portion is fixed to a portion of the film portion. The first sensor portion includes a first magnetic layer, a second magnetic layer, and a first intermediate layer. The second magnetic layer is provided between the first film and the first magnetic layer. The first intermediate layer is provided between the first magnetic layer and the second magnetic layer. A direction from at least a portion of the plurality of holes toward the first sensor portion is aligned with a first direction. The first direction is from the first film toward the first sensor portion.

A compact magnetic-based battery device that offers energy, a large number of cycles, a long storage time, and a short charging time is provided. The rechargeable battery device can include a first magnetic layer, a second magnetic layer, a dielectric layer disposed between the first magnetic layer and the second magnetic layer, and a plurality of high anisotropic magnetic nanoparticles embedded into the dielectric layer.

A magnetostrictive sensor, including a tubular or columnar substrate extending along an axis, and a magnetostrictive portion disposed on an outer peripheral surface of the substrate and including a plurality of magnetostrictive lines. The plurality of magnetostrictive lines include adjacent first and second magnetostrictive lines that extend along an extension direction, and that are disposed on the outer peripheral surface of the substrate via respectively first and second contact areas. In a cross sectional view of the magnetostrictive portion taken orthogonally to the extension direction, a first length, which is a width of a widest portion of the first magnetostrictive line in a width direction parallel to the outer peripheral surface of the substrate, is larger than a width of the first contact area in the width direction, and than a shortest distance between the first and second contact areas in the width direction.

A converter including a first transducer that can lengthen inside at least a first deformation zone and simultaneously shrink inside at least a different second deformation zone. Inner faces of second and third electromechanical transducers are secured respectively, with no degree of freedom, substantially to the first and second deformation zones of the layer of the first transducer. The third transducer differs from the second transducer by the polarization of its layer of piezoelectric material in a different direction to polarization of the layer of piezoelectric material of the second transducer and/or by existence of a separation that mechanically and electrically insulates a first electrode of the third transducer from a first electrode of the second transducer located on a same side of the layer of piezoelectric material.