Method and magnetic resonance apparatus to generate an artifact-free magnetic resonance image data set

We claim as our invention: 1. A method for generating an artifact-free magnetic resonance image data set comprising: acquiring magnetic resonance measurement data from an examination subject located in a measurement volume of a magnetic resonance data acquisition unit by operating the data acquisition unit according to a magnetic resonance data acquisition pulse sequence in which magnetic field gradients, which spatially encode said measurement data, are ramped continuously over time to a predetermined gradient strength for acquiring said measurement data, with no abrupt changes in said gradient strength; measuring actual magnetic field gradients that are present in said measurement volume of said data acquisition unit with a field mapping device located in said measurement volume; in a processor supplied with the measured actual magnetic field gradients, automatically calculating, based on the measured actual magnetic field gradients, trajectories along which said measurement data are entered into k-space during acquisition of said measurement data; in said processor, reconstructing an artifact-free magnetic resonance image data set from the acquired measurement data, dependent on the calculated trajectories; and making the artifact-free magnetic resonance image data set available at an output of said processor in electronic form as at least one data file. 2. A method as claimed in claim 1 comprising ramping said magnetic field gradients to said gradient strength after acquisition of said measurement data. 3. A method as claimed in claim 1 comprising activating said gradient magnetic fields non-constantly during an entirety of acquisition of said measurement data. 4. A method as claimed in claim 1 comprising activating said magnetic field gradients simultaneously with acquisition of said measurement data. 5. A method as claimed in claim 1 comprising measuring the actual magnetic field gradients that are present in said measurement volume in a measurement procedure that is separate from operating said data acquisition unit according to said pulse sequence. 6. A method as claimed in claim 1 comprising ramping said magnetic field gradients without abrupt changes in said gradient strength by making changes in said gradient strength over time are small enough to avoid mechanical oscillations in said data acquisition unit due to said changes in said gradient strength. 7. A magnetic resonance apparatus comprising: a magnetic resonance data acquisition unit comprising a measurement volume; a control unit configured to operate said data acquisition unit to acquire magnetic resonance measurement data from an examination subject located in the measurement volume of the magnetic resonance data acquisition unit, according to a magnetic resonance data acquisition pulse sequence in which magnetic field gradients, which spatially encode said measurement data, are ramped continuously over time to a predetermined gradient strength for acquiring said measurement data, with no abrupt changes in said gradient strength; a field mapping device located in said measurement volume that measures actual magnetic field gradients that are present in said measurement volume of said data acquisition unit; a processor supplied with the measured actual magnetic field gradients, configured to automatically calculate, based on the measured actual magnetic field gradients, trajectories along which said measurement data are entered into k-space during acquisition of said measurement data; said processor being configured to reconstruct an artifact-free magnetic resonance image data set from the acquired measurement data, dependent on the calculated trajectories; and said processor being configured to make the artifact-free magnetic resonance image data set available at an output of said processor in electronic form as at least one data file. 8. A non-transitory, computer-readable data storage medium encoded with programming instructions, said storage medium being loaded into a computerized control and evaluation system of a magnetic resonance apparatus that also comprises a magnetic resonance data acquisition unit that comprises a measurement volume, said programming instructions causing said control and evaluation system to: operate the data acquisition unit to acquire magnetic resonance measurement data from an examination subject located in the measurement volume of the magnetic resonance data acquisition unit, according to a magnetic resonance data acquisition pulse sequence in which magnetic field gradients, which spatially encode said measurement data, are ramped continuously over time to a predetermined gradient strength for acquiring said measurement data, with no abrupt changes in said gradient strength; operate a field mapping device located in said measurement volume to measure actual magnetic field gradients that are present in said measurement volume of said data acquisition unit; calculate, based on the measured actual magnetic field gradients, trajectories along which said measurement data are entered into k-space during acquisition of said measurement data; reconstruct an artifact-free magnetic resonance image data set from the acquired measurement data, dependent on the calculated trajectories; and make the artifact-free magnetic resonance image data set available at an output of said control and evaluation system in electronic form as at least one data file.