Gradient coil with correction windings and method for production thereof

We claim: 1. An actively shielded gradient coil system for use in a magnetic resonance device, the gradient coil system generating a main magnetic field oriented in a direction of a z-axis, wherein, when a current flows, the gradient coil system generates a gradient field in a measuring volume through which the z-axis extends, the gradient coil system comprising: a main coil, said main coil occupying a first radial partial area which extends in a radial direction with respect to the z-axis from r_min_1( z ) to r_max_1( z ), with r_min_1( z ) r_max_1( z ); a shielding coil, said shielding coil occupying a second radial partial area which extends in said radial direction with respect to the z-axis from r_min_2( z ) to r_max_2( z ), with r_max_1( z )≦r_min_2( z )≦r_max_2( z ), wherein active conductor elements of said main coil and of said shielding coil which contribute to the gradient field when a current flows, each take up spatial areas in a plane perpendicular to the z-axis and said first and second radial partial areas are occupied by active conductor elements in more than half of an azimuthal angle range with respect to the z-axis; and at least one correction coil, wherein active conductor elements of said correction coil lie outside of said first and said second radial partial areas in each plane perpendicular to the z-axis, said at least one correction coil being electrically connected in series with said main coil and with said shielding coil, active conductor elements of all correction coils together occupying maximally one quarter of an azimuthal angle range with respect to the z-axis, wherein, in comparison to a gradient coil system without correction coil, said at least one correction coil reduces a time duration of eddy currents, which are induced in a vicinity of the gradient coil system due to rapid changes in the current flowing in the gradient coil system. 2. The gradient coil system of claim 1 , further comprising additional correction coils, wherein active conductor elements of all correction coils together occupy maximally one quarter of said azimuthal angle range with respect to the z-axis. 3. The gradient coil system of claim 1 , wherein a coil cross-section of said at least one correction coil is smaller than a coil cross-section of said main coil. 4. The gradient coil system of claim 1 , wherein said at least one correction coil comprises individual serially connected windings at different z positions. 5. The gradient coil system of claim 1 , wherein said at least one correction coil comprises individual serially connected windings at different angle positions. 6. The gradient coil system of claim 1 , wherein individual windings of said at least one correction coil have different winding directions. 7. The gradient coil system of claim 1 , wherein said at least one correction coil is mounted to a coil carrier, said coil carrier having a cross-section perpendicular to the z direction which is round, elliptical or rectangular. 8. The gradient coil system of claim 1 , wherein said at least one correction coil is arranged in a space between said main field coil and said shielding coil. 9. The gradient coil system of claim 1 , wherein correction of a residual field having a component with m=1 is effected by connecting two correction coils at opposite angle positions which have opposite winding directions. 10. The gradient coil system of claim 9 , wherein said opposite angle positions oppose each other by 180 degrees. 11. The gradient coil system of claim 1 , wherein correction of a residual field having a component with m=0 is effected, thereby simultaneously suppressing generation of a residual field having a component with m=1 by connecting two correction coils at opposite angle positions which have a same winding direction. 12. The gradient coil system of claim 11 , wherein said opposite angle positions oppose each other by 180 degrees. 13. The gradient coil system of claim 1 , wherein the gradient coils are mounted to coil carriers which leave open a free space for receiving said at least one correction coil such that said at least one correction coil can be installed in the gradient coil system after assembly of the gradient coils without changing a mutual orientation of the gradient coils. 14. An arrangement of three electrically independent gradient coil systems of claim 1 , wherein said three gradient coil systems generate field gradients when a current flows, gradient directions of which being pair wise perpendicular to each other (=“XYZ gradient”). 15. An MRI arrangement with a main field magnet, an RF transmitting and receiving system and the gradient coil system of claim 1 . 16. A probe head for NMR spectroscopy with an RF transmitting and receiving system and the gradient coil system of claim 1 . 17. A method for producing the actively shielded gradient coil system of claim 1 , the method comprising the steps of: a) determining a coil arrangement for the gradient coils; b) calculating an induced voltage which is generated during switching of a current through the coil arrangement at a fixed radius which is larger than a largest radius of the gradient coil system at different positions along an axis of the gradient coil system; c) configuring a preliminary gradient coil system consisting of at least two gradient coils; d) measuring the induced voltage at points for which the induced voltage was calculated; e) determining a difference between the calculated induced voltage and the measured induced voltage; f) determining positions, winding numbers and winding directions for at least one correction coil such that the calculated difference between the induced voltages plus the induced voltages of the at least one correction coil has as many zero passages as possible; g) producing the at least one correction coil and installing that coil in the gradient coil system; and h) monitoring an improvement caused by the at least one correction coil based on the induced voltage and repeating steps e)-g) until a deviation between the voltages measured in step d) and the voltages calculated in step b) is as small as desired.