Wind turbine and method for detecting low-frequency oscillations in an electrical supply grid

The invention claimed is: 1. A method for detecting low-frequency oscillations in an electrical supply grid having a line voltage and associated with a rated line frequency, comprising: recording at least one series of measurements having a plurality of measurement points of a grid variable over a measurement time period for performing a frequency analysis on the at least one series of measurements; multiplying each measurement point of the at least one series of measurements by a time-dependent sinusoidal test function for the measurement time period to obtain a product for each measurement point, wherein the test function has a test frequency and a test angle as phase angle; summing a plurality of products of the plurality of measurement points to produce a product sum, wherein summing the plurality of products includes retaining a plurality of signs of the plurality of products, respectively; and determining, based on the product sum, whether the at least one series of measurements has a low-frequency oscillation having an oscillation frequency in a region of the test frequency and a phase angle in a region of the test angle, wherein the oscillation frequency is below the rated line frequency. 2. The method as claimed in claim 1 , comprising: repeating multiplying each measurement point of the at least one series of measurements by the test function and summing the plurality of products while varying the test frequency and/or varying the test angle to obtain a plurality of product sums; and determining whether the at least one series of measurements has the low-frequency oscillation depending on the plurality of product sums. 3. The method as claimed in claim 1 , wherein: repeating multiplying each measurement point of the at least one series of measurements by the test function and summing the plurality of products while varying the test frequency and varying the test angle to obtain a product sum as each test pair is formed by a test frequency value and a test angle value. 4. The method as claimed in claim 1 , comprising: detecting the low-frequency oscillation based on the product sum by determining whether the product sum reaches at least a predetermined test amplitude. 5. The method as claimed in claim 1 , comprising: repeating multiplying each measurement point of the at least one series of measurements by the test function and summing the plurality of products while varying the test frequency in a first test loop, wherein: the test frequency is varied within a first frequency range in the first test loop to detect the low-frequency oscillation having the oscillation frequency, and the oscillation frequency is detected with a first accuracy; and repeating multiplying each measurement point of the at least one series of measurements by the test function and adding the plurality of products while varying the test frequency in a second test loop, wherein: the test frequency is varied within a second frequency range in the second test loop; and the second frequency range is selected depending on the oscillation frequency detected in the first test loop to detect the oscillation frequency with a higher accuracy than in the first test loop. 6. The method as claimed in claim 1 , comprising: recording a plurality of series of measurements of the grid variable, wherein: each series of measurements of the plurality of series of measurements is recorded for analyzing a respective frequency range, for each series of measurements of the plurality of series of measurements, a respective measurement time period is selected depending on the respective frequency range, for each series of measurements of the plurality of series of measurements, multiplying each measurement point of the series of measurements by the test function and summing the plurality products to produce the product sum is repeated while varying the test frequency and/or varying the test angle to obtain a respective plurality of product sums for each series of measurements, and for each series of measurements, the respective plurality of product sums are evaluated for detecting the low-frequency oscillation. 7. The method as claimed in claim 1 , wherein: repeating multiplying each measurement point of the at least one series of measurements by the test function and summing the plurality of products to give the product sum while varying the test frequency, wherein: the test frequency is varied within at least one frequency range having an upper frequency value and a lower frequency value and using a frequency increment, and the frequency increment is set depending on the frequency range. 8. The method as claimed in claim 1 , wherein the low-frequency oscillations are sub synchronous resonances. 9. The method as claimed in claim 1 , wherein the oscillation frequency is 1 hertz (Hz) or less. 10. The method as claimed in claim 1 , wherein the grid variable is the line voltage, an input current or a line frequency of the electrical supply grid. 11. The method as claimed in claim 2 , comprising: when a first product sum has a maximum amplitude in relation to the plurality of product sums, detecting the low-frequency oscillation in the first product sum having an associated first frequency and an associated first phase of a first test frequency and a first test angle, and/or in response to detecting the low-frequency oscillation, detecting an amplitude of the low-frequency oscillation. 12. The method as claimed in claim 3 , comprising: obtaining a curved area in three-dimensional space depending on test frequency values and test angle values for test pairs; and identifying the test frequency and phase angle of the low-frequency oscillation as a first test frequency value and a first test angle of the test pairs at which in relation the product sum has a maximum in relation to remaining product sums. 13. The method as claimed in claim 5 , comprising: repeating multiplying each measurement point of the at least one series of measurements by the test function and summing the plurality of products while varying the test angle in the first test loop, wherein: the test angle is varied within a first angle range, and the test angle is varied with a first angle increment; and repeating multiplying each measurement point of the at least one series of measurements by the test function and summing the plurality of products while varying the test angle in the second test loop, wherein: the test angle is varied within a second angle range, and the second angle range is selected depending on the phase angle of the low-frequency oscillation detected in the first test loop to detect the phase angle of the low-frequency oscillation with a higher accuracy than in the first loop. 14. The method as claimed in claim 5 , wherein: in the first test loop, the test frequency is varied with larger frequency steps than in the second test loop, and/or in the first test loop, the test angle is varied with larger angle steps than in the second test loop. 15. The method as claimed in claim 7 , wherein the frequency increment is set depending on the frequency range such that: the frequency increment is less than the lower frequency value; and/or the frequency increment is less than a predetermined percentage value of the upper frequency value. 16. The method as claimed in claim 7 , wherein: the test frequency is varied within a plurality of frequency ranges, and frequency increments of different frequency ranges are different than each other, and each frequency increment is greater than a predetermined percentag