Abstract: A system may include a magnetic shape memory (MSM) element having a longitudinal axis that extends from a first end of the MSM element to a second end of the MSM element. The system may further include a rotatable permanent magnet configured to rotate around an axis of rotation and positioned proximate to the MSM element. The system may also include a first solenoid having a first solenoid axis directed at the rotatable permanent magnet. The system may include a second solenoid having a second solenoid axis directed at the rotatable permanent magnet. A method may include applying a first alternating current (AC) signal to the first solenoid and a second AC signal to the second solenoid to cause the rotatable permanent magnet to rotate.

Abstract: A system may include a magnetic shape memory (MSM) element having a long axis that extends from a first end of the MSM element to a second end of the MSM element. The system may further include a first solenoid, where a longitudinal axis of the first solenoid is positioned at a first angle relative to the long axis of the MSM element. The system may also include a second solenoid, where a longitudinal axis of the second solenoid is positioned at a second angle relative to the long axis of the MSM element and at a third angle relative to the longitudinal axis of the first solenoid, where the longitudinal axis of the first solenoid and the longitudinal axis of the second solenoid are not parallel.

Abstract: A system may include a magnetic shape memory (MSM) element having a longitudinal axis that extends from a first end of the MSM element to a second end of the MSM element. The system may further include a rotatable permanent magnet configured to rotate around an axis of rotation and positioned proximate to the MSM element. The system may also include a first solenoid having a first solenoid axis directed at the rotatable permanent magnet. The system may include a second solenoid having a second solenoid axis directed at the rotatable permanent magnet. A method may include applying a first alternating current (AC) signal to the first solenoid and a second AC signal to the second solenoid to cause the rotatable permanent magnet to rotate.

Abstract: An apparatus may include a rotatable permanent magnet exhibiting a magnetic field. Alternatively, the actuation apparatus may include a set of coils configured to generate a rotatable magnetic field. The apparatus may further include a magnetic shape memory (MSM) element including MSM material and having a long axis, where the MSM element is configured to contract locally in a first part in response to local exposure to a first component of the magnetic field that is substantially perpendicular to the long axis and to not contract locally in a second part that is exposed to a second component of the magnetic field that is not substantially perpendicular to the long axis. The apparatus may include a first fixed magnet positioned at a first end of the MSM element and a second fixed magnet positioned at a second end of the MSM element.

Abstract: A system may include a magnetic shape memory (MSM) element having a first end and a second end, where a longitudinal axis of the MSM element extends from the first end to the second end. The system may further include a permanent magnet having a first pole and a second pole, where the first pole and the second pole are aligned perpendicularly to the longitudinal axis of the MSM element. The system may also include a first electromagnet directed to the first end of the MSM element and a second electromagnet directed to the second end of the MSM element.

Abstract: An apparatus may include a rotatable permanent magnet exhibiting a magnetic field. Alternatively, the actuation apparatus may include a set of coils configured to generate a rotatable magnetic field. The apparatus may further include a magnetic shape memory (MSM) element including MSM material and having a long axis, where the MSM element is configured to contract locally in a first part in response to local exposure to a first component of the magnetic field that is substantially perpendicular to the long axis and to not contract locally in a second part that is exposed to a second component of the magnetic field that is not substantially perpendicular to the long axis. The apparatus may include a first fixed magnet positioned at a first end of the MSM element and a second fixed magnet positioned at a second end of the MSM element.

Abstract: A system may include a magnetic shape memory (MSM) element having a long axis that extends from a first end of the MSM element to a second end of the MSM element. The system may further include a first solenoid, where a longitudinal axis of the first solenoid is positioned at a first angle relative to the long axis of the MSM element. The system may also include a second solenoid, where a longitudinal axis of the second solenoid is positioned at a second angle relative to the long axis of the MSM element and at a third angle relative to the longitudinal axis of the first solenoid, where the longitudinal axis of the first solenoid and the longitudinal axis of the second solenoid are not parallel.

Abstract: An actuation apparatus may include a magnetic shape memory (MSM) element configured to contract locally at a portion of the MSM element in response to local exposure to a magnetic field distribution component that is substantially perpendicular to a longitudinal axis of the MSM element. The apparatus may further include a plurality of conductive coils laterally offset from the MSM element. Central axes of each conductive coil of the plurality of conductive coils may be substantially parallel to a longitudinal axis of the MSM element.

Abstract: An actuation apparatus may include a magnetic shape memory (MSM) element configured to contract locally at a portion of the MSM element in response to local exposure to a magnetic field distribution component that is substantially perpendicular to a longitudinal axis of the MSM element. The apparatus may further include a plurality of conductive coils laterally offset from the MSM element. Central axes of each conductive coil of the plurality of conductive coils may be substantially parallel to a longitudinal axis of the MSM element.

Abstract: An apparatus for sensing strain or stress includes a body including magnetic shape-memory alloy (MSMA) material, having a first axis. A first drive coil and first sensor coil are wound around the body about the first axis. The drive coil is coupled to a power source and configured to generate an alternating magnetic field on the body. The first sensor coil is configured to detect changes in inductance of the body due to changes in magnetic permeability of the body with deformation thereof.

Abstract: A data storage method includes writing data to a ferromagnetic shape-memory material in its ferromagnetic state, the material exhibiting more than two stable states. A data storage device includes a non-volatile memory element containing a ferromagnetic shape-memory alloy in a martensite state, the shape-memory alloy being ferromagnetic in a plurality of stable states of the memory element.

Abstract: A data storage method includes writing data to a ferromagnetic shape-memory material in its ferromagnetic state, the material exhibiting more than two stable states. A data storage device includes a non-volatile memory element containing a ferromagnetic shape-memory alloy in a martensite state, the shape-memory alloy being ferromagnetic in a plurality of stable states of the memory element.