A magnetic transmitting antenna has a beam member having a first end and a second end, wherein the beam member comprising: an elastic member; at least one magnetoelastic member disposed on a first surface of the elastic member; and an actuator disposed on a second surface of the elastic member, wherein the actuator is configured to apply stress to the elastic member thereby applying a bending stress thereto for changing the magnetic permeability of the at least one magnetoelastic member, which in turn, changes an external magnetic field. At least one magnet is disposed adjacent to the magnetoelastic member such that magnetization is induced in the magnetoelastic member.

A power generation element and an actuator for vibration power generation is provided that can be mass-produced at low cost while achieving increase in electromotive force. A power generation element includes a main series magnetic circuit having a frame yoke made of magnetic material and provided with a fixed portion that is one end and a free portion that is the other end across a U-shaped bent portion, a main magnet that applies a magnetic bias to the frame yoke, and a first gap formed at a position in contact with the free portion; and an auxiliary series magnetic circuit having an auxiliary yoke made of magnetic material and attached to the frame yoke, an auxiliary magnet that gives a magnetic bias to the auxiliary yoke, a second gap formed at a position facing the first gap across the free portion, the frame yoke, the main magnet, and the first gap. The amount of change in a main magnetic flux passing in a coil wound around the frame yoke increases when the free portion vibrates due to application of an external force and a magnetic resistance of the first gap and a magnetic resistance of the second gap increase or decrease reciprocally.

There is provided a magnetic deformable member that is deformable upon application of magnetism, and that has a front surface that projects toward the side opposite to a magnet when such a magnet is placed. The front surface provides variations in tactile feel or viewability for humans by providing a soft tactile feel. A magnetic deformable member includes: a flexible sheet; a back plate made of a hard material and stacked on the flexible sheet; a gel charged inside a space between the flexible sheet and the back plate; and a magnetic member having an annular shape as viewed in plan in a direction that is perpendicular to a front surface of the flexible sheet and having a length in the perpendicular direction. The magnetic member is secured to the flexible sheet, and disposed in the gel.

A magnetic sensor includes a piezomagnetic component which includes a first piezomagnetic element and a second piezomagnetic element that are arranged opposite to each other, a magnetostrictive component which includes a first magnetostrictive element and a second magnetostrictive element arranged opposite to each other on the same side of the first piezomagnetic element and the second piezomagnetic element, respectively, and a piezoelectric component which includes a first piezoelectric element deposited underneath the first piezomagnetic element, a second piezoelectric element deposited underneath the second piezomagnetic element, a third piezoelectric element deposited underneath the first magnetostrictive element, and a fourth piezoelectric element deposited underneath the second magnetostrictive element. The first piezoelectric element and the second piezoelectric element are electrically connected to a power supply circuit, and produce first deformation, which is applied to the first piezomagnetic element and the second piezomagnetic element to produce an alternating magnetic field.

Active-mode sensors are provided, and may be used to detect air, water, and sediment interfaces. Systems and methods for sensing air, water, and sediment are also provided. The sensors are robust and withstand forces due to moving or shifting water and sediment.

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.

The invention relates generally to electroactive material actuators (and combined sensor-actuators) having embedded magnetic particles (42) for facilitating enhanced actuation and/or sensing effects.

A power generation element includes a first magnetostrictive plate and a second magnetostrictive plate each including a magnetostrictive material, a magnet unit including a magnet fixed to at least one of the first magnetostrictive plate or the second magnetostrictive plate, and a coil containing at least part of the first magnetostrictive plate and the second magnetostrictive plate therein, wherein the first magnetostrictive plate and the second magnetostrictive plate are laid out in such a manner that stresses applied to the first magnetostrictive plate and the second magnetostrictive plate are in opposite directions to each other, and the magnet unit is disposed in such a manner that magnetic fields applied to the first magnetostrictive plate and the second magnetostrictive plate are in opposite directions to each other.

A power generating element according to an aspect of the present disclosure includes at least one magnetostrictive portion containing a magnetostrictive material, at least one magnetic portion containing a magnetic material, part of a surface of the magnetic portion being fixed to the magnetostrictive portion, a coil housing part of one of the magnetostrictive portion and the magnetic portion, and a magnet portion including a magnet and fixed to the magnetostrictive portion, wherein the magnetic portion is magnetically connected in parallel to the magnetostrictive portion and is fixed to the magnetostrictive portion so as to have an interval between the magnetostrictive portion and the magnetic portion, the interval being magnetically connected in series to the magnetic portion.

A gap compensated stress sensing system and methods for using the same are provided. The system can include a sensor head in communication with a controller. The sensor head can contain a stress sensor configured to generate a stress signal representing stress applied to a target based upon measurement of generated magnetic fluxes passing through the target. The system can also include a drive circuit configured to provide a current for generation of the magnetic fluxes, and to measure signals characterizing a gap between the sensor head and the target. The controller can analyze these signals to determine a gap-dependent reference signal that is relatively insensitive to electrical runout. The controller can further adjust the stress signal based upon the gap-dependent reference signal to determine an improved stress signal that has reduced sensitivity to gap changes.