Method and apparatus for magnetic resonance imaging

I claim as my invention: 1. A method for magnetic resonance imaging, comprising: operating a magnetic resonance scanner to acquire magnetic resonance data from an examination region of an examination subject situated in the magnetic resonance scanner, by executing a magnetic resonance data acquisition sequence comprising a plurality of repetition intervals and refocusing of nuclear spins in the examination region at an end of each repetition interval, said magnetic resonance data acquisition sequence being executed while an interference object produces a magnetic interference field in said examination region that disrupts said refocusing, said magnetic interference field having an amplitude; operating said magnetic resonance scanner to counteract said disruption of said focusing caused by said magnetic interference field by activating, during an entirety of a duration of acquisition of said magnetic resonance raw data, a magnetic compensation gradient that is opposed to said magnetic interference field and that has a compensation gradient moment that at least partially compensates a time integral of the amplitude of said magnetic interference field; and compiling the magnetic resonance raw data in a memory and, via a computer, making the compiled magnetic resonance raw data available from said memory as a data file in electronic form. 2. A method as claimed in claim 1 comprising operating said magnetic resonance scanner with a steady-state free-precession (SSFP) magnetic resonance sequence as said magnetic resonance data acquisition sequence. 3. A method as claimed in claim 1 comprising operating said magnetic resonance scanner with a quantitative magnetic resonance method embodying said magnetic resonance data acquisition sequence. 4. A method as claimed in claim 1 comprising activating said compensation gradient during the refocusing of the nuclear spins in the examination region at each end of each of repetition interval. 5. A method for magnetic resonance imaging, comprising: operating a magnetic resonance scanner to acquire magnetic resonance data from an examination region of an examination subject situated in the magnetic resonance scanner, by executing a magnetic resonance data acquisition sequence comprising a plurality of repetition intervals and refocusing of nuclear spins in the examination region at an end of each repetition interval by activating a refocusing gradient that produces a phase development of the nuclear spins in the examination region, said magnetic resonance data acquisition sequence being executed while an interference object produces a magnetic interference field in said examination region that disrupts said refocusing, said magnetic interference field having an amplitude: operating said magnetic resonance scanner to counteract said disruption of said focusing caused by said magnetic interference field by activating, during said refocusing gradient in addition to said refocusing gradient, a magnetic compensation gradient that is opposed to said magnetic interference field and that has a compensation gradient moment that at least partially compensates a time integral of the amplitude of said magnetic interference field: and compiling the magnetic resonance raw data in a memory and, via a computer, making the compiled magnetic resonance raw data available from said memory as a data file in electronic form. 6. A method as claimed in claim 5 comprising activating said compensation gradient with compensation gradient parameters that are determined dependent on parameters of said refocusing gradient. 7. A method as claimed in claim 3 comprising operating said magnetic resonance scanner with a magnetic resonance fingerprinting method, as said quantitative magnetic resonance method, wherein, during each repetition interval, magnetic resonance raw data for an individual magnetic resonance image are acquired and, in said computer, determining a magnetic resonance signal characteristic from each magnetic resonance image for each respective repetition interval, and making a signal comparison of said signal characteristic with a plurality of database signal characteristics stored in a database that is accessible by said computer, to identify tissue represented in each individual magnetic resonance image as a result of the comparison. 8. A method as claimed in claim 1 comprising operating said magnetic resonance scanner, before acquiring said magnetic resonance raw data, to acquire adjustment data, and setting parameters of said magnetic compensation gradient dependent on said adjustment data. 9. A method as claimed in claim 1 comprising operating said magnetic resonance scanner in said magnetic data acquisition sequence to emit radiofrequency excitation pulses that excite said nuclear spins with an excitation frequency, and selecting said excitation frequency to match a resonance frequency of nuclear spins in a vicinity of said interference object. 10. A magnetic resonance apparatus comprising: a magnetic resonance data acquisition scanner; a computer configured to operate said magnetic resonance data acquisition scanner to acquire magnetic resonance data from an examination region of an examination subject situated in the magnetic resonance scanner, by executing a magnetic resonance data acquisition sequence comprising a plurality of repetition intervals and refocusing of nuclear' spins in the examination region at an end of each repetition interval, said magnetic resonance data acquisition sequence being executed while an interference object produces a magnetic interference field in said examination region that disrupts said refocusing, said magnetic interference field having an amplitude; said computer being configured to operate said magnetic resonance data acquisition scanner to counteract said disruption of said focusing caused by said magnetic interference field by activating, during an entirety of a duration of acquisition of said magnetic resonance raw data, a magnetic compensation gradient that is opposed to said magnetic interference field and that has a compensation gradient moment that at least partially compensates a time integral of the amplitude of said magnetic interference field; and said computer being configured to compile the magnetic resonance raw data in a memory, and to make the compiled magnetic resonance raw data available from said memory as a data file in electronic form. 11. A non-transitory, computer-readable data storage medium encoded with programming instructions, said storage medium being loaded into a control computer of a magnetic resonance apparatus that comprising a magnetic resonance data acquisition scanner, said programming instructions causing said control computer to: operate said magnetic resonance data acquisition scanner to acquire magnetic resonance data from an examination region of an examination subject situated in the magnetic resonance scanner, by executing a magnetic resonance data acquisition sequence comprising a plurality of repetition intervals and refocusing of nuclear spins in the examination region at an end of each repetition interval, said magnetic resonance data acquisition sequence being executed while an interference object produces a magnetic interference field in said examination region that disrupts said refocusing, said magnetic interference field having an amplitude; operate said magnetic resonance data acquisition scanner to counteract said disruption of said focusing caused by said magnetic interference field by activating, an entirety of a duration of acquisition of said magnetic resonance raw data, a magnetic compensation gradient that is opposed to said magnetic interference field and that has a compensation