A magnetic particle imaging apparatus includes magnets [106,107] that produce a gradient magnetic field having a field free region (FFR), excitation field electromagnets [102,114] that produce a radiofrequency magnetic field within the field free region, high-Q receiving coils [112] that detect a response of magnetic particles in the field free region to the excitation field. Field translation electromagnets create a homogeneous magnetic field displacing the field-free region through the field of view (FOV) allowing the imaging region to be scamled to optimize scan time, scanning power, amplifier heating, SAR, dB/dt, and/or slew rate. Efficient multi-resolution scanning techniques are also provided. Intermodulated low and radio-frequency excitation signals are processed to produce an image of a distribution of the magnetic nanoparticles within the imaging region. A single composite image is computed using deconvolution of multiple signals at different harmonics.

The invention relates to a measuring arrangement comprising: a coil arrangement for creating a magnetic field to measure a sample to be arranged in connection with it including at least one flat coil, the coil geometry of which is arranged to be changed in the direction of the plane defined by the coil arrangement, in order to create a spatially changing magnetic field having a known distance dependence for measuring the sample; and electronics connected to the coil arrangement for creating a magnetic field using the coil arrangement; and means for changing the position of the sample and the coil arrangement relative to each other in order to change the magnetic field affecting the sample and having the known distance dependence. In addition, the invention also relates to a method for measuring a sample.

Example embodiments of the present invention provide a magnetic relaxometry measurement apparatus, comprising: a magnetizing system configured to supply a pulsed magnetic fields to a sample; a sensor system configured to detect magnetic fields produced by induced magnetization of the sample after a magnetic field pulse from the magnetizing system; one or more compensating coils configured to suppress generation of eddy currents in an environment surrounding the apparatus due to the pulsed magnetic fields.

A magnetic biosensor includes a fluidic channel, a magnetic sensor and an acoustic wave emitter. The disposition of the magnetic sensor corresponds to the fluidic channel. The acoustic wave emitter includes two wave generating units, and the fluidic channel is disposed between the two wave generating units.

A component sensitive to an electromagnetic field, which includes a first absorbent material, able to partially absorb energy of a given electromagnetic field and converting the absorbed energy into heat. The sensitive component includes a second fluorescent and thermosensitive material, placed in contact with the first material in order to store the heat converted by the first material. The second material is able to re-emit, under the action of a predetermined excitation light, a light by fluorescence with light intensity dependent on the stored heat.

A Magnetic Particle Imaging (MPI) system with a magnet configured to generate a magnetic field having a field free line, the system including at least one shim magnet configured to modify the magnetic field in a manner to maintain desired magnetic flux distributions during imaging.

Methods, apparatuses, and computer program products for optimizing utilization of a wireless position sensor are disclosed. In a particular embodiment, a controller of the wireless position sensor receives output from a magnetic-field-dependent sensor of the wireless position sensor. The magnetic-field-dependent sensor is configured to register the strength of a magnetic field of a magnet attached to a mechanical component. In this example, the registered strength corresponds to a position of the mechanical component along a directional path. According to this embodiment, the controller generates a comparison of the output to one or more predefined movement signatures and based on the comparison, determines whether to change an operating state of one or more components of the wireless position sensor.

A magnetic biosensor includes a fluidic channel, a magnetic sensor and an acoustic wave emitter. The disposition of the magnetic sensor corresponds to the fluidic channel. The acoustic wave emitter includes two wave generating units, and the fluidic channel is disposed between the two wave generating units.

Methods, apparatuses, and computer program products for optimizing utilization of a wireless position sensor are disclosed. In a particular embodiment, a controller of the wireless position sensor receives output from a magnetic-field-dependent sensor of the wireless position sensor. The magnetic-field-dependent sensor is configured to register the strength of a magnetic field of a magnet attached to a mechanical component. In this example, the registered strength corresponds to a position of the mechanical component along a directional path. According to this embodiment, the controller generates a comparison of the output to one or more predefined movement signatures and based on the comparison, determines whether to change an operating state of one or more components of the wireless position sensor.

Aspects of this disclosure relate to one or more particles that move within a container in response to a magnetic field. A measurement circuit is configured to output an indication of the magnetic field based on position of the one or more particles.