Randomization of crosstalk probing signals

The invention claimed is: 1. A vectoring controller for controlling a vectoring processor that mitigates crosstalk between communication lines of a vectoring group, the vectoring controller comprising: a memory storing computer-readable instructions; and a processor configured to execute the computer-readable instructions to, iterate through successive crosstalk acquisition cycles, successively configure sequences of crosstalk probing symbols within respective successive crosstalk acquisition cycles for transmission over respective communication lines, receive sequences of error samples as successively measured by respective receivers coupled to the respective communication lines while the successively configured sequences of crosstalk probing symbols are being transmitted, successively determine crosstalk estimates between the respective communication lines based on the sequences of error samples, randomize the successively configured sequences of crosstalk probing symbols between the respective successive crosstalk acquisition cycles, to mitigate bias in the successively determined crosstalk estimates due to non-linear effects including one or more of quantization artifacts, signal clipping, and demapping errors, by at least one of reshuffling the sequences of crosstalk probing symbols assigned to the respective communication lines between the respective successive crosstalk acquisition cycles, and varying at least one of a phase and an amplitude of the sequences of crosstalk probing symbols assigned to the respective communication lines between the respective successive crosstalk acquisition cycles, and iteratively configure the vectoring processor to mitigate crosstalk between the respective communication lines by adjusting vectoring parameters based on the successively determined crosstalk estimates. 2. The vectoring controller according to claim 1 , wherein the successively configured sequences of crosstalk probing symbols are randomized by successive arbitrary selection of crosstalk probing sequences within a set of mutually orthogonal sequences for modulation of respective sequences of crosstalk probing symbols. 3. The vectoring controller according to claim 1 , wherein the successively configured sequences of crosstalk probing symbols are randomized by successive arbitrary rotation in the frequency domain of some or all of the sequences of crosstalk probing symbols. 4. The vectoring controller according to claim 3 , wherein rotated transmit frequency samples of the successively configured sequences of crosstalk probing symbols coincide with constellation points of a reference constellation grid used for modulation of crosstalk probing symbols, thereby yielding a limited set of allowed rotation values. 5. The vectoring controller according to claim 4 , wherein the processor is further configured to execute the computer-readable instructions to evenly distribute the allowed rotation values across the respective communication lines of the vectoring group for rotation of the sequences of crosstalk probing symbols. 6. The vectoring controller according to claim 4 , wherein the reference constellation grid is a Binary Phase Shift Keying (BPSK) constellation grid, and the allowed rotation values are multiples of 180°. 7. The vectoring controller according to claim 4 , wherein the reference constellation grid is a 4-QAM constellation grid, and the allowed rotation values are multiples of 90°. 8. The vectoring controller according to claim 3 , wherein an amount of applied rotation is arbitrarily selected between 0° and 360°, and the processor is further configured to execute the computer-readable instructions to send successive rotation information to the respective receivers indicative of successive rotation values to be applied to receive frequency samples of respective sequences of crosstalk probing symbols. 9. The vectoring controller according to claim 1 , wherein the successively configured sequences of crosstalk probing symbols are randomized by successive arbitrary scaling of some or all of the sequences of crosstalk probing symbols, and the processor is further configured to execute the computer-readable instructions to send successive scaling information to the respective receivers indicative of successive scaling values to be applied to receive frequency samples of respective sequences of crosstalk probing symbols. 10. The vectoring controller according to claim 1 , wherein the sequences of error samples are indicative of error vectors between receive frequency samples of respective sequences of crosstalk probing symbols and respective selected constellation points onto which the receive frequency samples are demapped. 11. An access node for providing broadband communication services to subscribers, and comprising the vectoring controller according to claim 1 . 12. The access node according to claim 11 , wherein the access node is a Digital Subscriber Line Access Multiplexer (DSLAM). 13. A method for controlling a vectoring processor that mitigates crosstalk between communication lines of a vectoring group, the method comprising: iterating through successive crosstalk acquisition cycles; successively configuring sequences of crosstalk probing symbols within respective successive crosstalk acquisition cycles for transmission over respective communication lines; receiving sequences of error samples as successively measured by respective receivers coupled to the respective communication lines while the successively configured sequences of crosstalk probing symbols are being transmitted; successively determining crosstalk estimates between the respective communication lines based on the sequences of error samples; randomizing the successively configured sequences of crosstalk probing symbols between the respective successive crosstalk acquisition cycles, to mitigate bias in the successively determined crosstalk estimates due to non-linear effects including one or more of quantization artifacts, signal clipping, and demapping errors, by at least one of reshuffling the sequences of crosstalk probing symbols assigned to the respective communication lines between the respective successive crosstalk acquisition cycles, and varying at least one of a phase and an amplitude of the sequences of crosstalk probing symbols assigned to the respective communication lines between the respective successive crosstalk acquisition cycles; and iteratively configuring the vectoring processor to mitigate crosstalk between the respective communication lines by adjusting vectoring parameters based on the successively determined crosstalk estimates.