Method and magnetic resonance apparatus for acquiring a sensitivity map for at least one local coil in a magnetic resonance scanner

I claim as my invention: 1 . A method for acquiring a sensitivity map for a local coil in the magnetic resonance (MR) scanner, said MR scanner also comprising a whole body coil and a gradient coil system, said method comprising: operating said MR scanner to acquire MR data from a target object situated in the MR scanner while activating a phase-coding gradient in a phase-coding direction with said gradient coils system; via a processor in communication with said MR scanner, entering the acquired MR data into a memory representing k-space, wherein k-space comprises a plurality of points, organized dependent on said phase-coding direction, that are available for entering said acquired MR data thereat; in said processor, dividing k-space in said memory to a first part that is situated around a center of k-space and that encompasses the center of k-space, and a second part; operating said MR scanner to acquire said MR data from said target object as a three-dimensional first MR data set acquired with said whole body coil and a three-dimensional second MR data set acquired with said local coil, and entering each of said first and second MR data sets into k-space with said second part being undersampled in said phase-coding direction, so that not all of said available data points in said second part are filled with the acquired MR data, and with said first part being globally sampled so that all available data points in said first part are filled with the acquired MR data, thereby resulting in each of said first and second MR data sets in k-space having unfilled data points due to said undersampling; in said processor, combining said first and second MR data sets in k-space to obtain a combined data set and applying an accelerated parallel magnetic resonance imaging reconstruction algorithm to said combined data set, to obtain a reconstructed MR data set; in said processor, generating a supplemented first MR data set by adding reconstructed MR data from said reconstructed MR data set to fill said unfilled data points in said second region of said first MR data set that resulted from said undersampling, and generating a supplemented second MR data set by adding reconstructed MR data from said reconstructed MR data set to fill said unfilled data points in said second region of said second MR data set that resulted from said undersampling; and in said processor, generating a sensitivity map for said local coil by comparing the supplemented first and second MR data sets, and making said sensitivity map available in electronic from from said processor. 2 . A method as claimed in claim 1 comprising employing a multi-channel whole body coil as a whole body coil in said magnetic resonance scanner. 3 . A method as claimed in claim 1 comprising employing a plurality of local coils in said magnetic resonance scanner, and determining said sensitivity map for each of said local coils. 4 . A method as claimed in claim 1 wherein k-space comprises a plurality of k-space lines, and comprising acquiring said MR data that will be entered into a same k-space line in said first data set and said second data set alternatingly for the first data set and the second data set. 5 . A method as claimed in claim 1 comprising defining said first part of k-space to encompass at least three k-space lines. 6 . A method as claimed in claim 1 comprising defining said first part of k-space to encompass at least twelve k-space lines. 7 . A method as claimed in claim 1 comprising operating said gradient coil arrangement to generate a further phase coding gradient in a further phase coding direction that is perpendicular to said phase coding direction, and undersampling said second part of k-space in both of said phase-coding directions. 8 . A method as claimed in claim 1 comprising undersampling said first part of k-space by a factor of two. 9 . A method as claimed in claim 1 comprising acquiring said first and second magnetic resonance data sets by operating said magnetic resonance scanner with a sequence selected from the group consisting of a GRAPPA sequence and a CAIPIRINHA sequence. 10 . A method as claimed in claim 1 comprising using reconstruction parameters from the globally sampled magnetic resonance data in said first part of k-space when reconstructing the missing magnetic resonance data in said second part. 11 . A method as claimed in claim 1 comprising using more than two adjacent lines in k-space for reconstructing said missing magnetic resonance data. 12 . A method as claimed in claim 1 comprising, in said processor, using said sensitivity map to correct an intensity of magnetic resonance image data acquired by operating said magnetic resonance scanner after acquiring said first and second magnetic resonance data sets. 13 . A magnetic resonance apparatus comprising: a magnetic resonance scanner comprising a whole body coil and a local coil and a gradient coil arrangement; a control computer configured to operate said MR scanner to acquire MR data from a target object situated in the MR scanner while activating a phase-coding gradient in a phase-coding direction with said gradient coils system; a memory in communication with said control computer; said control computer being configured to enter the acquired MR data into said memory, representing k-space, wherein k-space comprises a plurality of points, organized dependent on said phase-coding direction, that are available for entering said acquired MR data thereat; said control computer being configured to divide k-space in said memory to a first part that is situated around a center of k-space and that encompasses the center of k-space, and a second part; said control computer being configured to operate said MR scanner to acquire said MR data from said target object as a three-dimensional first MR data set acquired with said whole body coil and a three-dimensional second MR data set acquired with said local coil, and entering each of said first and second MR data sets into k-space with said second part being undersampled in said phase-coding direction, so that not all of said available data points in said second part are filled with the acquired MR data, and with said first part being globally sampled so that all available data points in said first part are filled with the acquired MR data, thereby resulting in each of said first and second MR data sets in k-space having unfilled data points due to said undersampling; said control computer being configured to combine said first and second MR data sets in k-space to obtain a combined data set and apply an accelerated parallel magnetic resonance imaging reconstruction algorithm to said combined data set, to obtain a reconstructed MR data set; said control computer being configured to generate a supplemented first MR data set by adding reconstructed MR data from said reconstructed MR data set to fill said unfilled data points in said second region of said first MR data set that resulted from said undersampling, and generating a supplemented second MR data set by adding reconstructed MR data from said reconstructed MR data set to fill said unfilled data points in said second region of said second MR data set that resulted from said undersampling; and said control computer being configured to generate a sensitivity map for said local coil by comparing the supplemented first and second MR data sets, and making said sensitivity map available in electronic from from said control computer.