A magnetic resonance unit with a housing unit and a patient accommodation area for the accommodation and/or holding of at least one part region of a patient is provided. The patient accommodation area is surrounded at least partially by the housing unit, a first and a second movement sensor unit for acquiring a first and a second item of movement information of a movement of the patient. The first movement sensor unit exhibits a first field of view for the acquisition of a first part region of the patient and/or of the patient accommodation area, and the second movement sensor unit exhibits a second field of view for the acquisition of a second part region of the patient and/or of the patient accommodation area, which is formed differently in relation to the first part region of the patient and/or of the patient accommodation area.

A distributed device and method for detecting groundwater based on nuclear magnetic resonance are provided. The device includes an excitation apparatus, multiple polarization apparatuses, an aerial reception apparatus, and a control apparatus. The aerial reception apparatus includes an array cooled coil sensor. For each of the multiple polarization apparatuses, a position analysis module determines, together with a second position analysis module of the polarization apparatus, a position of the array cooled coil sensor relative to a polarization coil in the polarization apparatus. A polarization transmitter in the polarization apparatus switches to a mode of waiting for output in a case that the array cooled coil sensor is in coverage of the polarization coil. The polarization transmitter in the polarization apparatus remains in a standby mode in a case that the array cooled coil sensor is beyond coverage of the polarization coil.

A magnetic resonance imaging antenna (114) comprising one or more coil elements (115) is disclosed. The magnetic resonance imaging antenna further comprises a radio frequency system (116) coupled to the one or more coil elements. The magnetic resonance imaging antenna further comprises a gas inlet (200) configured for receiving a pressurized gas. The magnetic resonance imaging antenna further comprises a gas outlet (202) configured for venting the pressurized gas. The magnetic resonance imaging antenna further comprises an electrical generator (117) configured for converting mechanical energy resulting from passing the pressurized gas from the gas inlet to the gas outlet into electricity while in the presence of an external magnetic field. The electrical generator is configured to power the radio frequency system using the electricity.

In one embodiment, an image processing apparatus includes processing circuitry. The processing circuitry acquires an image in which a coil is depicted. The processing circuitry acquires, from the image, information on disposition of the coil and information on a port to which the coil is connected.

The disclosure relates to a receiving unit configured for acquiring MR signals from an examination object in a magnetic resonance device. The receiving unit may include a detector unit comprising a light source and a first optical detector, a sensor unit comprising a first optical magnetometer, a first optical waveguide connecting the sensor unit to the light source, and a second optical waveguide connecting the sensor unit to the first optical detector.

A magnetic resonance (MR) receive device comprises a coil or coil array including at least one radiofrequency (RF) coil element wherein each RF coil element comprises a coil and a preamplifier connected to amplify an output of the RF coil element to generate an amplified RF signal. The MR receive device further includes an RF-over-Fiber module comprising an optical fiber, a photonic device optically coupled to send an optical signal into the optical fiber, and an RF modulator connected to modulate the optical signal by an MR signal comprising the amplified RF signal.

A portable nuclear magnetic resonance (NMR) system configured for semi-autonomous or autonomous operation, including a portable NMR device configured to obtain NMR or other sensor data from an environment; a wireless communications device configured to communicate with a remote computing device; and at least one local computing device in communication with the wireless communications device and the NMR/Multisensor device, the at least one local computing device configured to perform operations comprising: receiving the NMR and sensor data that is obtained from the environment by the NMR system; sending, by the wireless communications device, the NMR or sensor data to the remote computing device; receiving, through the wireless communications device, at least one control signal for operating the NMR system in the environment, and the control signal being based on processing by the remote computing device; and causing, based on the control signal, the NMR system to adjust a data collection parameter for obtaining additional NMR and sensor data.

Provided in the present invention are a power control apparatus for a radio-frequency power amplifier and a radio-frequency transmission system for a magnetic resonance imaging system. The power control apparatus comprises: a power control module used to receive a control voltage so as to control an output power of the radio-frequency power amplifier; a voltage detection module used to detect an operating voltage provided to the radio-frequency power amplifier and to output a detected voltage; and a voltage adjustment module used to adjust, on the basis of the detected voltage, the control voltage received by the power control module so as to adjust the output power of the radio-frequency power amplifier.

A dongle includes: a battery configured to provide direct current (DC) power to a device to which the dongle is electrically and mechanically connected. The battery is adapted to be removed and replaced by another battery. A heat sink configured to dissipate heat generated by the battery is adapted to be removed and replaced by another heat sink.

An MRI scanner and a method for operation of the MRI scanner are provided. The MRI scanner has a first receiving antenna for receiving a magnetic resonance signal from a patient in a patient tunnel, a second receiving antenna for receiving a signal having the Larmor frequency of the magnetic resonance signal, and a receiver. The second receiving antenna is located outside of the patient tunnel or near an opening thereof. The receiver has a signal connection to the first receiving antenna and the second receiving antenna and is configured to suppress an interference signal by the second receiving antenna in the magnetic resonance signal received by the first receiving antenna.