Continual trajectory correction in magnetic resonance imaging

The invention claimed is: 1. A correction method for reducing temperature-related deviations in a gradient response of a magnetic resonance (MR) pulse sequence in MR imaging, the correction method comprising: applying an MR pulse sequence that includes at least one nominal test gradient, wherein the MR pulse sequence includes the at least one nominal test gradient as an additional gradient pulse; repeatedly acquiring a gradient response to the at least one nominal test gradient using a magnetic field measurement in an examination region during an MR imaging process; determining a gradient characterization function based on the gradient response; and determining a corrected MR pulse sequence based on the gradient characterization function and the at least one nominal test gradient. 2. The correction method of claim 1 , wherein repeatedly acquiring the gradient response comprises acquiring the gradient response at least after every fifth repetition interval. 3. The correction method of claim 2 , wherein the repeatedly acquiring the gradient response comprises acquiring the gradient response in each repetition interval. 4. The correction method of claim 1 , wherein the at least one nominal test gradient has a shape of a rectangle or a trapezium. 5. The correction method of claim 4 , wherein the MR pulse sequence includes the at least one nominal test gradient as an integral component. 6. The correction method of claim 1 , wherein the MR pulse sequence does not include any rectangular- or trapezoid-shaped gradient pulses, such that the at least one nominal test gradient has a shape that differs from a rectangle or a trapezium. 7. The correction method of claim 6 , wherein the at least one nominal test gradient comprises at least one chirp pulse, and wherein determining the gradient characterization function comprises acquiring a gradient response of the at least one chirp pulse. 8. The correction method of claim 1 , wherein the MR pulse sequence includes at least one spiral-shaped gradient. 9. The correction method of claim 1 , wherein based on the gradient characterization function and the at least one nominal test gradient in a repetition interval, a gradient in the MR pulse sequence that has already been applied is corrected. 10. The correction method of claim 1 , wherein based on the gradient system transfer function and the at least one nominal test gradient of a repetition interval, a corrected gradient in the MR pulse sequence of a subsequent repetition interval is determined. 11. A method for recording magnetic resonance image data relating to an examination object, the method comprising: acquiring raw data that is generated by a gradient pulse sequence; determining a corrected gradient pulse sequence, the determining of the corrected gradient pulse sequence comprising: applying the gradient pulse sequence, which includes at least one nominal test gradient as an additional gradient pulse; repeatedly acquiring a gradient response to the at least one nominal test gradient using a magnetic field measurement in an examination region during an MR imaging process; determining a gradient characterization function based on the gradient response; and determining the corrected gradient pulse sequence based on the gradient characterization function and the at least one nominal test gradient; and reconstructing magnetic resonance (MR) image data based on the acquired raw data and the corrected gradient pulse sequence. 12. A correction facility comprising: an output interface configured to run a magnetic resonance (MR) pulse sequence that includes at least one nominal test gradient, wherein the MR pulse sequence includes the at least one nominal test gradient as an additional gradient pulse; an input interface configured to repeatedly acquire a gradient response to the at least one nominal test gradient using a magnetic field measurement in an examination region; a determination unit configured to determine a gradient characterization function based on the gradient response; and a correction unit configured to determine a corrected MR pulse sequence based on the gradient characterization function and the at least one nominal test gradient. 13. A magnetic resonance (MR) image reconstruction facility comprising: a correction facility comprising: an output interface configured to run a magnetic resonance (MR) pulse sequence that includes at least one nominal test gradient as an additional gradient pulse; a first input interface configured to repeatedly acquire a gradient response to the at least one nominal test gradient using a magnetic field measurement in an examination region; a determination unit configured to determine a gradient characterization function based on the gradient response; and a correction unit configured to determine a corrected MR pulse sequence based on the gradient characterization function and the at least one nominal test gradient a second input interface configured to acquire MR raw data from the examination region; and an image reconstruction unit configured to reconstruct image data based on the acquired MR raw data and the corrected MR pulse sequence. 14. A magnetic resonance installation comprising: a main field magnet system; a radio frequency (RF) transmission antenna system; a gradient system; an RF receive antenna system comprising a control facility for activating the main field magnet system, the RF transmission antenna system, the gradient system, and the RF receive antenna system; and a correction facility comprising: an output interface configured to run a magnetic resonance (MR) pulse sequence that includes at least one nominal test gradient as an additional gradient pulse; an input interface configured to repeatedly acquire a gradient response to the at least one nominal test gradient using a magnetic field measurement in an examination region; a determination unit configured to determine a gradient characterization function based on the gradient response; and a correction unit configured to determine a corrected MR pulse sequence based on the gradient characterization function and the at least one nominal test gradient. 15. In a non-transitory computer-readable storage medium that stores instructions executable by a computation unit to reduce temperature-related deviations in a gradient response of a magnetic resonance (MR) pulse sequence in MR imaging, the instructions comprising: applying an MR pulse sequence that includes at least one nominal test gradient, wherein the MR pulse sequence includes the at least one nominal test gradient as an additional gradient pulse; repeatedly acquiring a gradient response to the at least one nominal test gradient using a magnetic field measurement in an examination region during an MR imaging process; determining a gradient characterization function based on the gradient response; and determining a corrected MR pulse sequence based on the gradient characterization function and the at least one nominal test gradient.