Magnetic resonance system with pulsed compensation magnetic field gradients

I claim as my invention: 1. A method for acquiring magnetic resonance (MR) data in an examination region of an examination subject situated in a measurement region of an MR data acquisition unit, said MR data acquisition unit comprising a basic field magnet, a radio-frequency (RF) system, and a gradient coil system, said method comprising: operating said basic field magnet of said MR data acquisition unit, with said examination region situated in said measurement region, to produce a polarization field in said measurement region that gives nuclear spins in the examination region a magnetization, said polarization field having a first field inhomogeneity across said measurement region; operating said MR data acquisition unit according to an MR imaging sequence having a sequence duration and, in said MR imaging sequence, operating said RF system to radiate at least one RF pulse into the examination region that deflects said magnetization and thereby causes said nuclear spins to emit an MR signal; in said MR imaging sequence, operating said gradient coil system of said MR data acquisition unit to activate a spatially encoding magnetic field gradient that spatially codes said MR signal; operating said gradient coil system of said MR data acquisition unit to activate at least one pulsed compensation magnetic field gradient during a compensation time interval in said MR imaging sequence that is shorter than said sequence duration and that occurs relative to the radiation of the at least one RF pulse so as to make said compensation field gradient effective during said at least one RF pulse, by supplying a temporally variable current, that is varying over said sequence duration, to said gradient coil system, and configuring said at least one pulsed compensation magnetic field gradient to reduce said first field inhomogeneity during said compensation time period to a second field inhomogeneity across said measurement region that is less than said first field inhomogeneity; operating said MR data acquisition unit to detect said MR signal at least in said compensation time period; and converting the detected MR signal into an electrical signal representing raw MR data and entering said raw MR data into an electronic memory, to produce a raw data set in a form that is accessible from said electronic memory for conversion into an image of the examination region. 2. A method as claimed in claim 1 comprising operating said basic field magnet of said MR data acquisition unit to generate said polarization field with said first field inhomogeneity being larger than one mT. 3. A method as claimed in claim 1 comprising configuring said at least one pulsed compensation magnetic field gradient to reduce said first field inhomogeneity by a factor of at least 100. 4. A method as claimed in claim 1 comprising configuring said at least one pulsed compensation magnetic field gradient to reduce said first field inhomogeneity by a factor of 1,000. 5. A method as claimed in claim 1 comprising operating said gradient coil system of said MR data acquisition unit to activate said at least one spatially encoding magnetic field gradient and to activate said at least one pulsed compensation magnetic field gradient, respectively, as a weighted linear combination of linear gradients and gradients of an order higher than said linear gradients. 6. A method as claimed in claim 5 wherein said gradient field system comprises a plurality of gradient coils and activating each of said at least one spatially encoding magnetic field gradient and said at least one pulsed compensation magnetic field gradient using multiple coils among said plurality of coils. 7. A method as claimed in claim 6 comprising simultaneously activating said at least one spatially encoding magnetic field gradient and said at least one pulsed compensation magnetic field gradient, and supplying respective currents to said multiple coils having respective amperages for which weighting coefficients of the weighted linear combination are calculated individually, for the respective gradient coils, and are added together. 8. A method as claimed in claim 5 wherein said at least one pulsed compensation magnetic field gradient is configured to produce said second field inhomogeneity across the measurement field with a value that is less than 10 μT. 9. A method as claimed in claim 1 comprising operating said RF system of said MR data acquisition unit to radiate said at least one RF pulse during an RF radiation period, and operating said gradient coil system of said MR data acquisition unit to activate said at least one pulsed compensation magnetic field gradient with said compensation time period substantially corresponding to said RF radiation period. 10. A method as claimed in claim 1 comprising operating said MR data acquisition unit to only activate said spatially encoding magnetic field gradient or said pulsed compensation magnetic field gradient in said sequence duration. 11. A method as claimed in claim 1 comprising: operating said MR data acquisition unit to detect said first field inhomogeneity, as detected field inhomogeneity information, and supplying said detected field inhomogeneity infonnation to a processor and, in said processor, calculating a field map of said polarization field from the detected inhomogeneity information, said polarization field not representing a spatial dependency of said first field inhomogeneity; and configuring said at least one pulsed compensation magnetic field gradient to reduce said first field inhomogeneity to said second field inhomogeneity by calculating, in said processor, a configuration of said variable current from the spatial dependency of the first field inhomogeneity in order to cause said at least one pulsed compensation magnetic field gradient to have a spatial dependency that reduces said first field inhomogeneity to said second field inhomogeneity. 12. A method as claimed in claim 1 comprising configuring said MR image sequence to cause said MR signal to be detected as a spin echo by operating said RF system to radiate a 90° RF pulse in said examination region during a first time period and to radiate a 180° RF pulse into said examination region in a second time period, and operating said gradient coil system to activate said at least one pulsed compensation magnetic field gradient with said compensation time period set to correspond to a sum of said first time period and said second time period. 13. A method as claimed in claim 1 comprising operating said MR data acquisition unit with said pulse sequence configured to detect said MR signal as a gradient echo by operating said RF system to radiate said at least one RF pulse as an α pulse during an α pulse time period, wherein α≦90°, and operating said gradient coil system to activate said compensation magnetic field gradient with said compensation time period corresponding to said α pulse time period. 14. A method as claimed in claim 1 wherein said RF system comprises multiple RF transmission channels, and operating said RF system in said MR imaging sequence to radiate RF pulses simultaneously via said multiple RF transmission channels to selectively deflect said magnetization. 15. A method as claimed in claim 1 comprising operating said gradient coil system to radiate said spatially encoding magnetic field gradient as a slice selection gradient or a readout gradient that is a weighted linear combination of linear gradients and gradients of a higher order than said linear gradients. 16. A method as claimed in claim 1 comprising operating said basic field magnet to genera