Abstract: A method of performing a medical imaging process, including: dividing a computing task of a medical imaging system unit into a set of sub-tasks, wherein the computing task is related to a generation of medical image data based on measurement data; selecting at least one sub-task of the set of sub-tasks for external execution; exchanging a sequence of signals including task delegation signals with a plurality of remote computing units, whereby the sequence of signals comprises at least one request signal sent by the medical imaging system unit; outsourcing the at least one selected sub-task to the selected remote computing unit for remotely generating a computing result of the at least one selected sub-task; receiving the generated computing result from the selected remote computing unit; and completing the computing task with the computing result received from the selected remote computing unit.

Abstract: A local control device for a medical imaging system includes a measurement control unit for dividing a computing task into a sequence of consecutive sub-tasks. The computing task is related to a generation of image data based on measurement data. The local control device includes an execution unit for executing the computing task. The local control device includes a selection unit for selecting a sub-task of the consecutive sub-tasks for external execution. The local control device includes an outsourcing unit for outsourcing the selected sub-task to a remote computing source for remotely generating a partial computing result and for receiving the generated partial computing result. The execution unit is arranged to execute the computing task based on the received generated partial computing result.

Abstract: A magnet arrangement for a magnetic resonance apparatus for capturing magnetic resonance data from an object may include gradient coils and gradient amplifiers. The gradient amplifiers may be configured to variably set a current flow in the gradient coils. Each gradient coil of the gradient arrangement may be electrically connected to a gradient amplifier of the plurality of gradient amplifiers. The magnet arrangement may provide, by the gradient amplifiers, in an alternating manner, a substantially homogeneous magnetic field and a magnetic gradient field.

Abstract: A method for storing MR implant information data, comprises: receiving a request for storing MR implant information data for an implant; determining a hash for the MR implant information data; generating a block for a blockchain, wherein the block includes the hash and a reference to a previous block in the blockchain; storing the MR implant information data in a memory; and registering the block in the blockchain.

Abstract: A trustworthy component for a control path of a magnetic resonance apparatus and a magnetic resonance apparatus with at least one trustworthy component are provided. The trustworthy component is configured to be arranged in a control path of a safety-relevant function of a magnetic resonance apparatus, so that when the trustworthy component is arranged in the control path, the control path is, at least in parts, non-trustworthy.

Abstract: The disclosure relates to a method for operating a medical device, (e.g., an imaging apparatus such as an X-ray device or magnetic resonance tomography unit), and a fault monitoring apparatus for carrying out the method. The fault monitoring apparatus is connected to the medical device via a signal connection. In the method, the fault monitoring apparatus receives an item of status information from the medical device and stores the item of status information in a system state. Further, the fault monitoring apparatus compares the stored system state with a predetermined target state, and, depending on the comparison, releases a function of the medical device, wherein the predetermined target state has a successfully executed function test.

Abstract: Techniques are described for controlling a fleet of MR-scanner systems by means of a user interface. Each MR scanner system in the fleet of MR scanner systems comprises a hardware layer having a plurality of electronically controllable components and mechanical components to perform an MR measurement and capture MR-scanner raw data, a Measurement And Reconstruction System (MARS) computing unit configured to implement a measurement framework using a sequence to calculate real-time instructions and transmit these instructions to the components of the hardware layer for controlling the MR-scanner system, and a communication interface for communicating with an external device. Each MR scanner system has system attributes, which are transmitted to the external device via the communication interface.

Abstract: One or more peripheral components are attached to a medical imaging system. One or more devices are attached to the one or more peripheral components and configured to communicate data with a controller of the medical imaging system.

Abstract: The disclosure relates to a method for operating a medical device, (e.g., an imaging apparatus such as an X-ray device or magnetic resonance tomography unit), and a fault monitoring apparatus for carrying out the method. The fault monitoring apparatus is connected to the medical device via a signal connection. In the method, the fault monitoring apparatus receives an item of status information from the medical device and stores the item of status information in a system state. Further, the fault monitoring apparatus compares the stored system state with a predetermined target state, and, depending on the comparison, releases a function of the medical device, wherein the predetermined target state has a successfully executed function test.

Abstract: Techniques are described for controlling a fleet of MR-scanner systems by means of a user interface. Each MR scanner system in the fleet of MR scanner systems comprises a hardware layer having a plurality of electronically controllable components and mechanical components to perform an MR measurement and capture MR-scanner raw data, a Measurement And Reconstruction System (MARS) computing unit configured to implement a measurement framework using a sequence to calculate real-time instructions and transmit these instructions to the components of the hardware layer for controlling the MR-scanner system, and a communication interface for communicating with an external device. Each MR scanner system has system attributes, which are transmitted to the external device via the communication interface.

Abstract: In a magnetic resonance apparatus and a method for operation thereof, at least one electrical operating value of at least one predetermined component of the apparatus is captured and, as a function of the at least one operating value, at least one coil operating value of a transmitting coil arrangement of the magnetic resonance apparatus is controlled for the purpose of limiting a B1 value.

Abstract: A method is for inserting a further data block into a first ledger, the first ledger including data blocks. In an embodiment, the method includes receiving a further medical dataset via an interface; determining the further data block via a calculation unit. The further data block includes the further medical dataset and a further link information. The further link information includes a hash of at least one of the data blocks of the first ledger. Finally, in an embodiment the method includes inserting the further data block into the first ledger via the calculation unit.

Abstract: A control apparatus for a magnetic resonance device, a system, a control system and a magnetic resonance system are disclosed. The control apparatus includes a control module, including a central coordination component, embodied to receive sequence commands calculated according to a scan sequence; a radio-frequency-control component, embodied to actuate a radio-frequency transmission unit of the magnetic resonance device in accordance with the sequence commands; and a gradient-coil-control component, embodied to actuate a gradient-coil unit of the magnetic resonance device in accordance with the sequence commands.

Abstract: An MR system including a control computer and a digital control device is described. The control computer includes an external digital image data port for transmitting control data, including sequence data and encoded as image data, from the control computer to a digital control device; and the digital control device includes a port, compatible with the external digital image data port of the control computer, for receiving the control data, received from the external digital image data port and designed to extract the sequence data from the received control data, encoded as image data. A method for activating a digital control device via a control computer is also described.

Abstract: One or more peripheral components are attached to a medical imaging system. One or more devices are attached to the one or more peripheral components and configured to communicate data with a controller of the medical imaging system.

Abstract: A method for monitoring a temporal change in a magnetic field in a magnetic resonance device, as well as an evaluation unit, a magnetic resonance device, and a computer program product for performing the method are provided. The method provides that a position-dependent magnetic field distribution that is produced by the plurality of gradient coils is provided with a plurality of monitoring points. In addition, time-dependent gradient values of the plurality of gradient coils are ascertained. Based on position-dependent magnetic field distribution and the time-dependent gradient values, the temporal change in the magnetic field is ascertained. The temporal change in the magnetic field is monitored by comparing the temporal change in the magnetic field with at least one limit value.

Abstract: In a magnetic resonance (MR) apparatus and an operating method therefor, a sequence with which the MR data are to be recorded is created in or provided to a control computer of the MR apparatus. A maximum RF output and a maximum gradient performance of the scanner magnetic resonance apparatus during the performance of the sequence are determined by simulating or analyzing the performance of the sequence in the control computer, and it is verified whether the maximum RF output and/or the maximum gradient performance violate predetermined limit values. Execution of the sequence to record the MR data is performed only if the verification showed that the limit values are not violated.

Abstract: An MR system including a control computer and a digital control device is described. The control computer includes an external digital image data port for transmitting control data, including sequence data and encoded as image data, from the control computer to a digital control device; and the digital control device includes a port, compatible with the external digital image data port of the control computer, for receiving the control data, received from the external digital image data port and designed to extract the sequence data from the received control data, encoded as image data. A method for activating a digital control device via a control computer is also described.

Abstract: In a method for operating a medical imaging examination apparatus having multiple subsystems controlled by a control computer in a scan sequence, a control protocol for the scan is provided to the control computer, which determines sequence control data for the control protocol that define different functional subsequences of the scan, with different effective volumes assigned to each functional subsequence. Current ambient conditions of the apparatus are determined that are decisive for the determined relevant sequence control data and associated effective volumes. Control signals for the scan are determined from the sequence control data, the effective volumes and the current ambient conditions determined that optimize the functional subsequences of the scan.

Abstract: A control apparatus for a magnetic resonance device, a system, a control system and a magnetic resonance system are disclosed. The control apparatus includes a control module, including a central coordination component, embodied to receive sequence commands calculated according to a scan sequence; a radio-frequency-control component, embodied to actuate a radio-frequency transmission unit of the magnetic resonance device in accordance with the sequence commands; and a gradient-coil-control component, embodied to actuate a gradient-coil unit of the magnetic resonance device in accordance with the sequence commands.