A magnetic sensor according to an embodiment includes: a magneto-resistive film including a laminate structure, the laminate structure including a first magnetic layer, a second magnetic layer, and an intermediate layer arranged between the first magnetic layer and the second magnetic layer; and a pair of electrodes for supplying current in a first direction perpendicular to a laminate direction of the magneto-resistive film, wherein the second magnetic layer includes an amorphous magnetic layer, and a crystalline magnetic layer arranged between the amorphous magnetic layer and the intermediate layer, and a length of a current path of the magneto-resistive film is 10 m or more.

A magnetic sensor of an embodiment includes: a magnetic field detector including a magnetic layer in which a length in a first direction is 10 times or more of a length in a second direction perpendicular to the first direction and a length in a third direction perpendicular to the first direction and the second direction is or less of the length in the second direction; a first magnetic material member arranged along the first direction, and in which a length in the third direction is longer than the length in the third direction of the magnetic layer; a first nonmagnetic insulating layer arranged between the magnetic field detector and the first magnetic material member, and in which a length in the second direction is or less of the length in the second direction of the magnetic layer; and a circuit supplying current to the magnetic layer.

A production method of a gas cell includes: forming a coating layer on a surface of a plate material; assembling a plurality of the plate materials having the coating layer formed thereon so as to form a cell surrounded by the surface having the coating layer formed thereon; and filling the formed cell with an alkali metal gas.

A cryocooler superconducting quantum interference (SQUID) system includes a cryocooler including a cold head, a cold head chamber in which the cold head is disposed, a sensor chamber including a SQUID sensor cooled to a low temperature by the cryocooler; and a connection block connecting the cold head and a thermal anchor disposed in the sensor chamber to each other to cool the SQUID sensor in the sensor chamber.

Provided are a biomagnetic measuring device and a control method for a biomagnetic measuring device that can measure biomagnetism more accurately. A biomagnetic measuring device according to the present invention includes: a first magnetic sensor and a second magnetic sensor that each include a cell having an internal space, and detect biomagnetism utilizing an optical pumping action by plasma generated in the cell; a plasma generator that supplies electric power for generating plasma in the internal space of each of the cells included in the first magnetic sensor and the second magnetic sensor; and a power supply controller that controls the plasma generator to generate plasma in the first magnetic sensor from a first start time to a first end time and generate plasma in the second magnetic sensor from a second start time after the first start time to a second end time after the first end time.

A treatment system includes a magnetic sensor configured to detect a biomagnetic field generated by a living body to be treated, a catheter configured to be inserted into the living body, an image information processor programmed to generate a combined image including a first image expressing a strength of the biomagnetic field and a second image expressing a position of the catheter, by using biomagnetic field information output from the magnetic sensor and position information of the catheter inserted into the living body, and a display configured to display the combined image.

The use of machine learning for pattern recognition in magnetocardiography (MCG) that measures magnetic fields emitted by the electrophysiological activity of the heart is disclosed herein. Direct kernel methods are used to separate abnormal MCG heart patterns from normal ones. For unsupervised learning, Direct Kernel based Self-Organizing Maps are introduced. For supervised learning Direct Kernel Partial Least Squares and (Direct) Kernel Ridge Regression are used. These results are then compared with classical Support Vector Machines and Kernel Partial Least Squares. The hyper-parameters for these methods are tuned on a validation subset of the training data before testing. Also investigated is the most effective pre-processing, using local, vertical, horizontal and two-dimensional (global) Mahanalobis scaling, wavelet transforms, and variable selection by filtering.

A magnetic field measuring apparatus includes a cell array which includes plural cells different in size of detection surface through which a magnetic flux passes when the cells are arranged in a magnetic field of a measurement object, a medium which is enclosed inside each of the plural cells and rotates a light polarization plane according to an intensity of the magnetic field, an irradiator to irradiate a light to the detection surface of each of the cells, and a detector to detect a rotation angle of a polarization plane of the light passing through each of the cells.

The gradiometers of the present invention are developed by applying GSR sensors to have the detectability of magnetic field same to that of SQUID without a cryogenic temperature retainer. Plural GSR elements are fitted on two parallel convex line guides of the gradiometer board using two parallel concave line guides of the GSR element board to keep the parallel among wires direction of GSR elements perfectly and to cancel the outside magnetic field noise without a magnetic shield room.

Some embodiments described herein relate to a method that includes defining an electro-anatomical model of a heart. The electro-anatomical model can include conduction patterns for multiple patterns or phases identified by a measurement instrument. The electro-anatomical model can also include a voltage map of the heart. A portion of the heart containing a rotor can be identified based on circulation in one phase of the model. The rotor can be determined to be stable based on that portion of the heart having circulation in another phase of the model. The rotor can be characterized as a substrate rotor based on the rotor being stable and based on the voltage or a change in voltage at the portion of the heart containing the rotor. The rotor can be treated or ablated when the rotor is determined to be a substrate rotor.