Method and magnetic resonance apparatus to acquire a magnetic resonance data set by radial scanning

We claim as our invention: 1. A method to acquire a magnetic resonance data set of an acquisition area of a subject, comprising: operating a magnetic resonance data acquisition unit to acquire raw magnetic resonance data from a subject situated in the magnetic resonance data acquisition unit; via a processor supplied with said raw magnetic resonance data, entering said raw magnetic resonance data into an electronic memory organized as k-space comprising a plurality of data entry points, by radially entering said raw magnetic resonance data along respective data points in a fixed number of spokes in k-space, with each of said spokes being described by a first angle in k-space, and wherein said acquisition area in said subject deviates from a circular shape and has a shape that is described collectively by said respective first angles; entering said raw magnetic resonance data into respective spokes according to an acquisition order of respective positions of said spokes, said acquisition order defining said respective positions by comparison of said first angle with a data set of a fixed number of second angles for successive acquisition positions that differ by a golden angle, so as to cause, for each first angle of each acquisition position, respective spatially adjacent first angles thereto to have the same acquisition positions as the respective second angles that are spatially adjacent to the second angle of the respective acquisition position; and making the raw magnetic resonance data entered into k-space available from said electronic memory in an electronic form for reconstructing a magnetic resonance image of said acquisition area therefrom. 2. A method as claimed in claim 1 comprising, in said processor, sorting said fixed number of first angles and said fixed number of second angles according to respective sizes thereof and transferring an acquisition position of a second angle to a first angle that coincides in size order therewith. 3. A method as claimed in claim 1 wherein the shape of the acquisition area is described by an angle-dependent target density of said spokes and, in said processor, determining a proximity relationship in which a second angle situated at a defined acquisition position in said acquisition order has two spatially adjacent second angles acquired at defined other positions of said acquisition order, and determining said first angles from said second angles while maintaining said acquisition order and said proximity relationship, to produce said target density by respective spokes in which said raw magnetic resonance data are entered according to said first angle. 4. A method as claimed in claim 1 comprising, in said processor, reconstructing a magnetic resonance image from said raw magnetic resonance data entered into respective spokes within a respective time interval. 5. A method as claimed in claim 1 comprising, in said processor, using the large golden angle for 180° as said golden angle. 6. A magnetic resonance apparatus comprising: a magnetic resonance data acquisition unit; an electronic memory comprising a plurality of data entry points therein organized as k-space; a control unit configured to operate the magnetic resonance data acquisition unit to acquire raw magnetic resonance data from a subject situated in the magnetic resonance data acquisition unit; a processor supplied with said raw magnetic resonance data, said processor being configured to enter said raw magnetic resonance data into said electronic memory by radially entering said raw magnetic resonance data along respective data points in a fixed number of spokes in k-space, with each of said spokes being described by a first angle in k-space, and wherein said acquisition area in said subject deviates from a circular shape and has a shape that is described collectively by said respective first angles; said processor being configured to enter said raw magnetic resonance data into respective spokes according to an acquisition order of respective positions of said spokes, said acquisition order defining said respective positions by comparison of said first angle with a data set of a fixed number of second angles for successive acquisition positions that differ by a golden angle, so as to cause, for each first angle of each acquisition position, respective spatially adjacent first angles thereto to have the same acquisition positions as the respective second angles that are spatially adjacent to the second angle of the respective acquisition position; and said processor being configured to make the raw magnetic resonance data entered into k-space available from said electronic memory in an electronic form for reconstructing a magnetic resonance image of said acquisition area therefrom.