Fault detection in a power transmission system

The invention claimed is: 1. A method for fault detection during power swing in a power transmission system, the method comprising: obtaining voltage measurements and current measurements for each phase at a terminal of the power transmission system, wherein the voltage measurements and the current measurements are obtained with one or more measurement equipment associated with the terminal of the power transmission system, wherein the voltage measurements and the current measurements comprise sampled values of voltage and current obtained at the terminal; calculating, for each sampled value of the voltage and current, a value of change in an impedance angle for each phase-to-ground loop and each phase-to-phase loop, wherein the value of change in the impedance angle is a difference between impedance angles of two samples separated by a predetermined interval; calculating average values for change in impedance angle for a predetermined number of values of the change in the impedance angle, for each phase-to-ground loop and each phase-to-phase loop; comparing the average values calculated for each phase-to-ground loop and each phase-to-phase loop with a threshold range of change in impedance angle; and detecting a fault in one or more of the phase-to-ground loops or phase-to-phase loops when the average value calculated for the one or more phase-to-ground loops or phase-to-phase loops is within the threshold range. 2. The method as claimed in claim 1 , wherein the method comprises releasing the corresponding loop for distance protection on detecting the fault in one or more of the phase-to-ground loops or phase-to-phase loops. 3. The method as claimed in claim 1 , wherein the predetermined interval is a duration of one measurement cycle, wherein one measurement cycle comprises a predetermined number of samples based on a sampling frequency. 4. The method as claimed in claim 1 , wherein the calculating the average values comprises applying a moving window average filter to calculate values of the change in impedance angle for the samples, wherein the predetermined number of values of the change in impedance angle is a size of the moving window. 5. The method as claimed in claim 4 , wherein the size of the moving window is equal to a number of samples in one measurement cycle. 6. The method as claimed in claim 1 , comprising detecting the fault in one or more of the phase-to-ground loops or phase-to-phase loops at a swing center voltage. 7. The method as claimed in claim 1 , wherein the threshold range is 1 to 3 degrees. 8. The method as claimed in claim 1 , comprising classifying the fault detected as a phase-to-ground fault, a phase-to-phase fault, or a double phase-to-ground fault based on a loop in which the fault is detected. 9. The method as claimed in claim 1 , wherein the method comprises calculating voltage phasors and current phasors for each phase-to-ground loop and each phase-to-phase loop respectively based on a full cycle Discrete Fourier Transform of the voltage measurements and the current measurements. 10. An intelligent electronic device (IED) to detect a fault during a power swing in a power transmission line, the IED comprising: a processor; and a fault detection module executable by the processor to: obtain voltage measurements and current measurements from each phase at a terminal of the power transmission system, wherein the voltage measurements and the current measurements are obtained with one or more measurement equipment associated with the terminal of the power transmission system, wherein the voltage measurements and the current measurements comprise samples of voltage and current values obtained at the terminal; calculate, for each sample of the voltage and current values, a value of change in an impedance angle for each phase-to-ground loop and each phase-to-phase loop, wherein the value of change in the impedance angle is a difference between impedance angles of two samples separated by a predetermined interval; calculate average values for change in impedance angle for a predetermined number of values of the change in the impedance angles, for each phase-to-ground loop and each phase-to-phase loop; compare the average values calculated for each phase-to-ground loop and each phase-to-phase loop with a threshold range of change in impedance angle; and detect a fault in one or more of the phase-to-ground loops or phase-to-phase loops when the average value calculated for the one or more phase-to-ground loops or phase-to-phase loops is within the threshold range. 11. The device as claimed in claim 10 , wherein the threshold range of change in impedance angle is −ε to +ε, wherein ε is in range of 1-3 degrees. 12. The device as claimed in claim 10 , wherein the device is configured to release the corresponding loop for distance protection on detecting the fault in one or more of the phase-to-ground loops or phase-to-phase loops. 13. The device as claimed in claim 10 , wherein the predetermined interval between the two samples for determining the value of change in impedance angle is a duration of one measurement cycle, wherein one measurement cycle comprises a predetermined number of samples based on a sampling frequency. 14. The device as claimed in claim 10 , wherein, to calculate the average values, the fault detection module is configured to apply a moving window average filter to calculate values of the change in the impedance angle for the samples, wherein the predetermined number of values of the change in the impedance angle is a size of the moving window. 15. The device as claimed in claim 14 , wherein the size of the moving window is equal to a number of samples in one measurement cycle. 16. The device as claimed in claim 10 , wherein the fault detection module is configured to classify the fault detected as a phase-to-ground fault, a phase-to-phase fault, or a double phase-to-ground fault based on a loop in which the fault is detected. 17. A non-transient computer readable medium containing program instructions which when executed cause an intelligent electronic device (IED) to detect a fault during a power swing in a power transmission line, wherein the program instructions comprise instructions to: obtain voltage measurements and current measurements from each phase at a terminal of the power transmission system, wherein the voltage measurements and the current measurements are obtained with one or more measurement equipment associated with the terminal of the power transmission system, wherein the voltage measurements and the current measurements comprise samples of voltage and current values obtained at the terminal; calculate, for each sample of the voltage and current values, a value of change in an impedance angle for each phase-to-ground loop and each phase-to-phase loop, wherein the value of change in the impedance angle is a difference between impedance angles of two samples separated by a predetermined interval; calculate average values for change in impedance angle for a predetermined number of values of the change in the impedance angles, for each phase-to-ground loop and each phase-to-phase loop; compare the average values calculated for each phase-to-ground loop and each phase-to-phase loop with a threshold range of change in impedance angle, wherein the threshold range is −ε to +ε, wherein ε is in a range of 1-3 degrees; and detect a fault in one or more of the phase-to-ground loops or phase-to-phase loops when an average value of the change in impedance angle lies within the threshold range. 18. The