MR imaging using a multi-point dixon technique

The invention claimed is: 1. A method of MR imaging of at least a portion of a body of a patient positioned in an examination volume of a MR device, the method comprising: with an MR controller, controlling at least one RF coil and gradient field coils in order to implement a multi-point Dixon imaging technique that generates calibration MR data for the portion of the body in the examination volume at a first image resolution; with one or more computer processors: reconstructing the calibration MR data into a B 0 field map, a water map, and a fat map, identifying fat and water regions of the portion of the body in the image volume from the water and fat maps, and selecting a frequency and bandwidth for each of a plurality of fat suppression pulses, with the MR controller, controlling the at least one RF coil and the gradient field coils that generate RF pulses including the plurality of fat suppression pulses and the switched magnetic field gradients in order to generate diagnostic image data at a second image resolution which is higher than the first image resolution; with the one or more processors: reconstructing a diagnostic MR image from the generated diagnostic image data at the second image resolution which is higher than the first image resolution, and having the one or more processors, identify pixels or voxels of the reconstructed diagnostic MR image in which the fat suppression is incomplete or has failed, by using the reconstructed B 0 field map and the reconstructed fat map along with the frequency and bandwidth of the plurality of fat suppression pulses. 2. The method of claim 1 , wherein fat suppression RF pulses effect a spectrally selective suppression of fat signals in the diagnostic image data. 3. The method of claim 2 , further including with the one or more computer processors, determining shim settings from the B 0 field map and at least one of the water and fat maps in order to control a plurality of shim coils and thereby improve linearity of the existing B 0 field occurring in at least one of water and fat regions within the portion of the body that is in the examination volume. 4. The method of claim 3 , wherein the frequency and bandwidth of the one or more fat suppression RF pulses is determined from the improved linearity of the B 0 field whereby a number of pixels or voxels within a given region of interest having a B 0 field strength outside of a pre-determined range of spectral selectivity, of the one or more fat suppression RF pulses is minimized. 5. The method of claim 2 , wherein one or more computer processors generates a prediction derived from the calibration MR data about the pixels or voxels within the reconstructed diagnostic MR image, in which the spectrally selective suppression of fat signals is incomplete or has failed. 6. The method of claim 5 , wherein the diagnostic MR image is corrected in a post-processing according to the prediction by regenerating the calibration MR data using a higher order multi-point Dixon imaging technique. 7. The method of claim 1 , further comprising: determining shim settings that maximize magnetic field homogeneity in the water region and/or in the fat region. 8. The method of claim 7 , wherein the shim settings are computed with the one or more processors by optimizing a cost function depending on the B 0 field deviation within the water region and the fat region. 9. A magnetic resonance (MR) device that images at least a portion of a body of a patient positioned in an examination volume comprising: at least one main magnet coil configured to generate a uniform, steady magnetic field B 0 within an examination volume; a number of gradient coils configured to generate switched magnetic field gradients in different spatial directions within the examination volume; at least one body RF coil configured to generate RF pulses within the examination volume and/or configured for receiving MR signals from a portion of a body of a patient positioned in the examination volume; shimming coils configured to adjust the homogeneity of the a steady magnetic field B 0 ; a MR controller configured to control the at least one RF body coil and the number of gradient coils in order to generate the temporal succession of RF pulses and switched magnetic field gradients which then subject the portion of the body of the patient positioned in the examination volume to a multi-point Dixon imaging technique in order to generate calibration data at a first image resolution; one or more computer processors configured to: segment the generated calibration data into a water region and a fat region select B 0 shim settings that maximize B 0 homogeneity in each of the water region and the fat region, cause the MR controller to subject the portion of the body to a multi-point Dixon magnetic resonance imaging sequence comprising RF pulses and switched magnetic field gradients controlled in such a manner that diagnostic MR image data is acquired at a second image resolution which is higher than the first image resolution, and reconstruct a diagnostic MR image from the diagnostic MR image data, wherein the MR device is operated according to the derived calibration parameters during acquisition of the diagnostic MR data and/or during reconstruction of the diagnostic MR image. 10. A non-transitory computer-readable medium carrying software to control one or more computer processors in order to control a MR device and perform the method of claim 1 . 11. A magnetic resonance (MR) imaging apparatus configured for imaging a portion of a body in an examination volume, the MR imaging apparatus comprising: at least one main magnet coil configured to generate a uniform, steady B 0 magnetic field within the examination volume; gradient coils configured to generate magnetic field gradients within the examination volume; RF coil windings configured to generate RF pulses within the examination volume and receive MR signals from the portion of the body positioned in the examination volume; shim coils configured to shim the B 0 magnetic field; one or more computer processors configured to: control the RF coil windings and the gradient coils in order to implement a multi-point Dixon imaging sequence and generate calibration data at a first image resolution, reconstruct, from the generated calibration data, a B 0 field map, a water image, and a fat image at the first image resolution, identify water and fat regions within the portion of the body that is in the examination volume from the reconstructed water and fat images, determine a B 0 magnetic field homogeneity in each of the water regions and in each of the fat regions, determine settings for each of the shim coils in order to adjust the B 0 magnetic field homogeneity that is present in the water and fat regions, select a frequency and a bandwidth of one or more fat suppression RF pulses, based on the adjusted B 0 magnetic field homogeneity, the reconstructed water image, and the reconstructed fat image, whereby a number of pixels or voxels, located within a given region of interest of the portion of the body in the examination region, that have a B 0 magnetic field homogeneity outside of a pre-determined range of spectral selectivity, of the one or more fat suppression RF pulses, is minimized, control the gradient coils, the RF coil windings, and the shim coils in order to shim the B 0 magnetic field and adjust the B 0 magnetic field homogeneity and apply a magnetic resonance imaging sequence that uses the one or more fat suppression pulses of the selected frequency and bandwidth in order to generate diagnostic MR image data at a second image resolution, the second i