Systems and methods of grounded neutral fault detection by single frequency excitation and leakage spectral analysis

What is claimed is: 1. A grounded neutral fault detector, comprising: induction circuits configured to: generate a leakage signal corresponding to a current imbalance between a line conductor and a neutral conductor for a load; and a controller configured to: determine a frequency of a test signal by: measuring load noise based on a first leakage signal without the test signal being injected, the first leakage signal corresponding to a first current imbalance between the line conductor and the neutral conductor for the load when the test signal is not being injected into the neutral conductor; analyzing a frequency spectrum of the load noise; and selecting the frequency of the test signal based on the frequency spectrum of the load noise; inject the test signal at the selected frequency to the neutral conductor; measure impedance of a current loop formed by a potential grounded neutral fault based on a second leakage signal corresponding to a second current imbalance with the test signal being injected; and determine a grounded neutral fault based on the measured impedance. 2. The detector of claim 1 , wherein the controller is further configured to select the frequency of the test signal corresponding to a frequency at which the load noise has the lowest magnitude. 3. The detector of claim 1 , wherein the controller is further configured to: perform a Fourier transform of the load noise to derive a frequency spectrum of the load noise; measure magnitudes of the load noise at a plurality of frequencies based on the frequency spectrum of the load noise; and select the frequency corresponding to a frequency having the lowest magnitude among the plurality of frequencies. 4. The detector of claim 1 , wherein the controller is further configured to: determine a current response at the selected frequency to the test signal; and determine the impedance of the current loop as being inversely proportional to a magnitude of the current response. 5. The detector of claim 4 , wherein the controller is further configured to: between two adjacent samples of a second leakage signal, multiply an earlier sample of the two adjacent samples with a corresponding point in a reference cosine waveform to derive a cosine product, the reference cosine waveform having the selected frequency; multiply the earlier sample with a corresponding point in a reference sine waveform to derive a sine product, the reference sine waveform having the selected frequency; add the cosine product to a first accumulator; and add the sine product to a second accumulator; multiply a last sample with the corresponding point in the reference cosine waveform to derive a last cosine product; multiply the last sample with the corresponding point in the reference sine waveform to derive a last sine product; add the last cosine product to the first accumulator; add the last sine product to the second accumulator; and determine the magnitude of the current response as a square root over a sum of a square of an average of cosine products and a square of an average of sine products. 6. The detector of claim 5 , wherein the reference cosine waveform and the reference sine waveform are prestored at the same location. 7. The detector of claim 5 , wherein a full cycle of the reference cosine waveform and the reference sine waveform are prestored. 8. The detector of claim 1 , wherein the controller is further configured to repeat determining a frequency, injecting the test signal, measuring impedance, and determining the grounded neutral fault. 9. The detector of claim 8 , wherein a sampling rate of the first leakage signal and the second leakage signal remains the same, and a sampling duration of the first leakage signal and the second leakage signal remains the same. 10. The detector of claim 1 , wherein samples of the second leakage signal have an integer number of cycles of the test signal. 11. A method of detecting a grounded neutral fault, comprising: determining a frequency of a test signal by: measuring load noise based on a first leakage signal without the test signal being injected, the first leakage signal corresponding to a first current imbalance between a line conductor and a neutral conductor for a load when the test signal is not being injected into the neutral conductor; analyzing a frequency spectrum of the load noise; and selecting the frequency of the test signal based on the frequency spectrum of the load noise; injecting the test signal at the selected frequency to the neutral conductor; measuring impedance of a current loop formed by a potential grounded neutral fault based on a second leakage signal corresponding to a second current imbalance with the test signal injected; and determining a grounded neutral fault based on the measured impedance. 12. The method of claim 11 , wherein selecting the frequency further comprises selecting the frequency of the test signal corresponding to a frequency at which the load noise has the lowest magnitude. 13. The method of claim 11 , wherein: analyzing a frequency spectrum further comprises performing a Fourier transform of the load noise to derive the frequency spectrum of the load noise; and selecting the frequency further comprises: measuring magnitudes of the load noise at a plurality of frequencies based on the frequency spectrum of the load noise; and selecting the frequency corresponding to a frequency having the lowest magnitude among the plurality of frequencies. 14. The method of claim 11 , wherein measuring impedance further comprises: determining a current response at the selected frequency; and determining the impedance of the current loop as being inversely proportional to a magnitude of the current response. 15. The method of claim 14 , wherein determining a current response further comprises: between two adjacent samples of a second leakage signal, multiplying an earlier sample of the two adjacent samples with a corresponding point in a reference cosine waveform to derive a cosine product, the reference cosine waveform having the selected frequency; multiplying the earlier sample with a corresponding point in a reference sine waveform to derive a sine product, the reference sine waveform having the selected frequency; adding the cosine product to a first accumulator; and adding the sine product to a second accumulator; multiplying a last sample with the corresponding point in the reference cosine waveform to derive a last cosine product; multiplying the last sample with the corresponding point in the reference sine waveform to derive a last sine product; adding the last cosine product to the first accumulator; adding the last sine product to the second accumulator; and determining the magnitude of the current response as a square root over a sum of a square of an average of cosine products and a square of an average of sine products. 16. The method of claim 15 , wherein the reference cosine waveform and the reference sine waveform are prestored at the same location. 17. The method of claim 15 , wherein a full cycle of the reference cosine waveform and the reference sine waveform are prestored. 18. The method of claim 11 , further comprising repeating determining a frequency, injecting the test signal, measuring impedance, and determining the grounded neutral fault. 19. The method of claim 18 , wherein a sampling rate of the first leakage signal and the second leakage signal remains the same, and a sampling duration of the first leakage s