Fast crosstalk limitation between modems

The invention claimed is: 1. A method for limiting crosstalk between vectoring modems connected to a group of communication lines interconnecting the vectoring modems with a data network accessing device, the method comprising: obtaining, by the data network accessing device, information indicating a division of the group of communication lines into subgroups, wherein each subgroup includes two or more lines experiencing cross-talk from other lines in the same subgroup above a cross-talk level threshold; assigning, based on the information indicating the division of the group of communication lines into subgroups, a set of operational pilot sequences to the group of communication lines according to the division of the group of communication lines into subgroups, wherein the set of operational pilot sequences comprises a number of subsets, one for each subgroup, and wherein the lengths of the pilot sequences in a subset are set to correspond to the minimum length required for being mutually orthogonal; transmitting said set of operational pilot sequences on the communication lines between the vectoring modems and said data network accessing device, said pilot sequences being mutually orthogonal to each other at least within each subgroup, wherein each communication line receives a corresponding operational pilot sequence; obtaining a set of cross-talk measurement sequences related to the transmitted set of operational pilot sequences; and determining, for each subgroup, crosstalk and a corrective action based on measurements made for a number of sequence symbols, said number corresponding to the minimum number required for obtaining mutually orthogonal pilot sequences within the subgroup. 2. The method according to claim 1 , wherein the information comprises cross-talk measurements corresponding to the measurement results from a set of mutually orthogonal investigation pilot sequences, the method further comprising comparing these measurements with said cross-talk level threshold and determining said subgroups of communication lines based on the comparison. 3. The method according to claim 2 , further comprising: transmitting said set of mutually orthogonal investigation pilot sequences on the communication lines between the vectoring modems and said data network accessing device, wherein each communication line receives a corresponding investigation pilot sequence. 4. The method according to claim 2 , wherein the length of the operational pilot sequences is longer than or equal to that of the set of investigation pilot sequences. 5. The method according to claim 4 , wherein the step of determining corrective action is performed for a subgroup before all cross-talk measurements of the cross-talk measurement sequences have been received. 6. The method according to claim 5 , wherein the operational pilot sequences each comprise a segment, and wherein the segment lengths of operational pilot sequences assigned to a subgroup is equal to or higher than the minimum number of elements for obtaining mutual orthogonality within the subgroup and lower than the minimum number required for obtaining mutual orthogonality within the whole group of communication lines. 7. The method according to claim 1 , wherein the step of determining a corrective action for a subgroup comprises finalising the determining of a corrective action as soon as measurement results for the operational pilot sequences of this subgroup have been obtained. 8. The method according to claim 1 , wherein the lengths of operational pilot sequences of a subset is equal to or higher than the minimum number of elements for obtaining mutual orthogonality within the subset and lower than the minimum number required for mutual orthogonality within the whole set of operational pilot sequences. 9. The method according to claim 1 , wherein the number of sequence symbols for which cross-talk is determined and corrective action is performed with regard to one subgroup (i) is L i =4*┌N i /4┐, wherein Ni is the number of lines in the subgroup and ┌N i /4┐ means that N i /4 is rounded up to the nearest higher integer. 10. The method according to claim 1 , wherein the number of sequence symbols for which cross-talk is determined and corrective action is performed with regard to one subgroup (i) is L i =2 ┌log 2 N i ┐ ,and wherein Ni is the number of lines in the subgroup and┌log 2 N i ┐ means that log 2 N i is rounded up towards the nearest higher integer. 11. The method according to claim 1 , wherein the step of determining corrective action comprises finalising the determining of a corrective action for a subgroup as soon as a number of cross-talk measurements of the corresponding cross-talk measurement sequence have been received, said number being equal to or larger than a minimum number for obtaining mutual orthogonality within the pilot sequence symbols used for the subgroup and smaller than a minimum number for obtaining mutual orthogonality within the pilot sequence symbols used for the whole group. 12. A data network accessing device for limiting crosstalk between vectoring modems connected to a group of communication lines interconnecting the vectoring modems with a data network accessing device, the data network accessing device for limiting crosstalk comprising: a processor and memory including instructions executable by the processor, whereby the device is operative to: obtain, by the data network accessing device, information indicating a division of the group of communication lines into subgroups, wherein each subgroup includes two or more lines experiencing cross-talk from other lines in the same subgroup above a cross-talk level threshold; assign, based on the information indicating the division of the group of communication lines into subgroups, a set of operational pilot sequences to the group of communication lines according to the division of the group of communication lines into subgroups, wherein the set of operational pilot sequences comprises a number of subsets, one for each subgroup, and wherein the lengths of the pilot sequences in a subset are set to correspond to the minimum length required for being mutually orthogonal; transmit said set of operational pilot sequences on the communication lines between the vectoring modems and said data network accessing device, said pilot sequences being mutually orthogonal to each other at least within each subgroup, wherein each communication line receives a corresponding operational pilot sequence; obtain a set of cross-talk measurement sequences related to the transmitted set of operational pilot sequences; and determine, for each subgroup, cross-talk and a corrective action based on measurements made for a number of sequence symbols, said number corresponding to the minimum number required for obtaining mutually orthogonal pilot sequences within the subgroup. 13. The device according to claim 12 , wherein the information comprises cross-talk measurements corresponding to the measurement results from a set of mutually orthogonal investigation pilot sequences, the device being further operative to compare these measurements with said cross-talk level threshold and determine said subgroups of communication lines based on the comparison. 14. The device according to claim 13 , wherein the device is further operative to provide the transmission of the set of mutually orthogonal investigation pilot sequences on the communication lines between the vectoring modems and said data network accessing device, wherein each communication line receives a corresponding pilot sequence. 15. The device for limiting