Method and apparatus for acquiring magnetic resonance data

The invention claimed is: 1. A method for acquiring magnetic resonance (MR) data, comprising: placing an object in MR data acquisition scanner, said object comprising a volume containing a first excitable nuclear spin type and a second excitable nuclear spin type, each of said first and second excitable spin types having a respective Larmor frequency, and the respective Larmor frequencies differing by a chemical shift, said MR data acquisition scanner having a basic magnetic field (B0) therein in which said volume is situated; in a computer, obtaining a B0 map that describes a distribution of said basic magnetic field at least in a region of interest within said volume; in said computer, deriving, from said B0 map, a first item of distribution information that describes a spectral distribution of Larmor frequencies that indicates how frequently a Larmor frequency of the first spin type that is associated with the object is found within a frequency range, and a second item of distribution information that describes a spatial distribution of Larmor frequencies that indicates how frequently a Larmor frequency of the second spin type that is associated with the object is found within the frequency range; in said computer, for a radio-frequency (RF) pulse sequence that will be radiated in said MR data acquisition scanner in order to (i) selectively excite magnetic resonance signals of said first spin type and not excite magnetic resonance signals of said second spin type, or (ii) selectively suppress magnetic resonance signals of said second spin type and not suppress magnetic resonance signals of said first spin type, and optimize, based on said first and second items of distribution information, at least one pulse sequence parameter that describes an excitation spectrum of said RF pulse sequence, with regard to at least one quality criterion that optimizes at least one of the selective excitation or suppression, and thereby producing an optimized RF pulse sequence; and from said computer, producing and emitting, in electronic form, a control sequence, which includes said optimized RF pulse sequence, in a format for operating said MR data acquisition scanner in order to acquire MR data from said region of interest. 2. A method as claimed in claim 1 comprising, in said computer, using at least one extremization criterion as said at least one quality criterion, said at least one extremization criterion being at least one of a minimum excitation or suppression of the respective first and second spin types, and a maximum excitation or suppression of the respective first and second spin types. 3. A method as claimed in claim 1 comprising, in said computer, using, as said at least one quality criterion, extremization criteria with respective weightings, which describe a maximum excitation or suppression of the respective first and second spin types, and a minimum excitation or suppression of the respective first and second spin types. 4. A method as claimed in claim 1 comprising, in said computer, using at least one constraint as said at least one quality criterion, said at least one constraint including at least one of a maximum permitted excitation or suppression of the respective first and second spin types, and a minimum desired excitation or suppression of the respective first and second spin types. 5. A method as claimed in claim 1 comprising producing said first item of distribution information as a first histogram and producing said second item of distribution information as a second histogram. 6. A method as claimed in claim 1 comprising, in said computer, producing one of said first or second items of distribution information for one of said first or second spin types by shifting the distribution of the Larmor frequencies of the other of said first or second spin types by the chemical shift. 7. A method as claimed in claim 6 comprising producing said B0 map based on said other of said first or second spin types, as a reference spin type. 8. A method as claimed in claim 1 , wherein said B0 map is comprised of voxels, and wherein said method further comprises, in said computer, producing a spin type distribution map that assigns spin type proportions to respective voxels in said spin type distribution map, at least in said region of interest, and using said B0 map to derive said first and second items of distribution information with a contribution of each voxel of said B0 map to said first and second items of distribution information being dependent on a spin type proportion in a corresponding voxel of said spin type distribution map. 9. A method as claimed in claim 8 comprising producing said spin type distribution map so as to describe a dominant spin type for each voxel. 10. A method as claimed in claim 8 comprising producing said spin type distribution map so as to describe relative proportions of the respective first and second spin types in each voxel. 11. A method as claimed in claim 10 comprising using a voxel of said B0 map to contribute to deriving said first and second items of distribution information only when a relative proportion of the respective first and second spin types in the corresponding voxel of said spin type distribution map exceeds a threshold value. 12. A method as claimed in claim 1 wherein said object is a patient comprising tissue, wherein said B0 map is comprised of voxels, and wherein said method further comprises producing a tissue mask in said computer that designates, for each voxel of said tissue map, whether or how strongly a corresponding voxel of said B0 distribution map should be used when deriving said first and second items of distribution information. 13. A method as claimed in claim 12 comprising producing said tissue mask in said computer by a procedure including at least one of automatic production of said tissue map, production of said tissue map in response to a user entry, production of said tissue map by segmentation of boundaries of said object, production of said tissue map by segmentation of an organ in said B0 map, and production of said tissue map by segmentation of the object or an organ in previously acquired MR data from the object. 14. A method as claimed in claim 1 , wherein said volume of said object comprises a plurality of further second spin types, deriving a second item of distribution information respectively for each of said plurality of further second spin types, and optimizing said at least one pulse sequence parameter based on said first item of distribution information and said plurality of further second items of distribution information. 15. A method as claimed in claim 14 comprising deriving a single second spin type distribution from each of the plurality of second spin type distributions, based on reference information established from the B0 map based on reference spin type. 16. A method as claimed in claim 15 comprising deriving said plurality of further second items of distribution information by weighting the reference information with a relative frequency and making a spectral shift of the chemical shift relative to the reference spin type. 17. A method as claimed in claim 16 comprising deriving the further second items of distribution information for the respective further spin types by re-summing. 18. A method as claimed in claim 16 comprising deriving said plurality of further second items of distribution information by establishing the relative frequencies dependent on an item of tissue information with respect to said volume or said region of interest. 19