Condition monitoring and fault detection in induction motors

What is claimed is: 1. A method for condition monitoring of turn-to-turn faults (TTFs) of an induction motor in a drive system, the method comprising: receiving, by a processor, a signal of the induction motor, the signal comprising information on a radiated magnetic field of the induction motor; performing, by the processor, a mathematical morphology (Mat-Morph) technique on the signal of the induction motor, based on the information on the radiated magnetic field of the induction motor, the Mat-Morph technique being performed in the time domain; and determining, by the processor, whether a TTF exists in the induction motor and, if so, a location of the TTF, based on results of the Mat-Morph technique. 2. The method according to claim 1 , the induction motor being driven by direct torque control (DTC). 3. The method according to claim 1 , the drive system being an electric vehicle drive system. 4. The method according to claim 1 , the performing of the Mat-Morph technique comprising extracting relevant features of the signal based on interaction between the signal and a structuring element (SE) of the Mat-Morph technique. 5. The method according to claim 4 , the SE being 2 n , where n is a positive integer. 6. The method according to claim 5 , a length of the SE being 2 n times T s , where T s is a sampling time of the signal. 7. The method according to claim 5 , n being 4 such that the SE is 16. 8. The method according to claim 4 , the performing of the Mat-Morph technique comprising performing a dilation operation to produce a dilated signal, an erosion operation to produce an eroded signal, and a Mat-Morph Gradient (MMG) operation, the MMG operation comprising subtracting the erosion signal from the dilation signal. 9. The method according to claim 8 , the dilation operation comprising the following δ=( k⊕g )=max { k ( x+s )+ g ( s )|( x+s )∈ D k ,s∈D g }, where k represents the signal, g represents the SE, δ represents the dilated signal, ⊕ represents k dilated with g to produce the dilated signal, D k is a definition domain of k, D g is a definition domain of g, x is a sample of k, and s is a length of the SE, and the erosion operation comprising the following ε=( k⊖g )=min { k ( x+s )+ g ( s )|( x+s )∈ D k ,s∈D g }, where ε represents the eroded signal and ⊖ represents k eroded with g to produce the eroded signal. 10. The method according to claim 1 , the performing of the Mat-Morph technique comprising performing a dilation operation to produce a dilated signal, an erosion operation to produce an eroded signal, and a Mat-Morph Gradient (MMG) operation, the MMG operation comprising subtracting the erosion signal from the dilation signal. 11. The method according to claim 1 , the determining of whether a TTF exists in the induction motor comprising monitoring an energy end value of the induction motor after performing the Mat-Morph technique. 12. A system for condition monitoring of turn-to-turn faults (TTFs) of an induction motor in a drive system, the system comprising: a sensor configured to detect magnetic radiation; a processor; and a non-transitory machine-readable medium in operable communication with the processor and the sensor, and comprising instructions stored thereon that when executed cause the processor to: receive a signal of the induction motor, the signal comprising information on a radiated magnetic field of the induction motor; perform, a mathematical morphology (Mat-Morph) technique on the signal of the induction motor, based on the information on the radiated magnetic field of the induction motor, the Mat-Morph technique being performed in the time domain; and determine whether a TTF exists in the induction motor and, if so, a location of the TTF, based on results of the Mat-Morph technique. 13. The system according to claim 12 , the sensor being a loop antenna. 14. The system according to claim 12 , the induction motor being driven by direct torque control (DTC), and the drive system being an electric vehicle drive system. 15. The system according to claim 12 , the performing of the Mat-Morph technique comprising extracting relevant features of the signal based on interaction between the signal and a structuring element (SE) of the Mat-Morph technique. 16. The system according to claim 15 , the SE being 2 n , where n is a positive integer, and a length of the SE being 2 n times T s , where T s is a sampling time of the signal. 17. The system according to claim 15 , the performing of the Mat-Morph technique comprising performing a dilation operation to produce a dilated signal, an erosion operation to produce an eroded signal, and a Mat-Morph Gradient (MMG) operation, the MMG operation comprising subtracting the erosion signal from the dilation signal. 18. The system according to claim 17 , the dilation operation comprising the following δ=( k⊕g )=max { k ( x+s )+ g ( s )|( x+s )∈ D k ,s∈D g }, where k represents the signal, g represents the SE, δ represents the dilated signal, ⊕ represents k dilated with g to produce the dilated signal, D k is a definition domain of k, D g is a definition domain of g, x is a sample of k, and s is a length of the SE, and the erosion operation comprising the following ε=( k⊖g )=min { k ( x+s )+ g ( s )|( x+s )∈ D k ,s∈D g }, where ε represents the eroded signal and ⊕ represents k eroded with g to produce the eroded signal. 19. The system according to claim 12 , the determining of whether a TTF exists in the induction motor comprising monitoring an energy end value of the induction motor after performing the Mat-Morph technique. 20. A method for condition monitoring of turn-to-turn faults (TTFs) of an induction motor in a drive system, the method comprising: receiving, by a processor, a signal of the induction motor, the signal comprising information on a radiated magnetic field of the induction motor; performing, by the processor, a mathematical morphology (Mat-Morph) technique on the signal of the induction motor, based on the information on the radiated magnetic field of the induction motor, the Mat-Morph technique being performed in the time domain; and determining whether a TTF exists in the induction motor and, if so, a location of the TTF, based on results of the Mat-Morph technique, the induction motor being driving by direct torque control (DTC), the drive system being an electric vehicle drive system, the performing of the Mat-Morph technique comprising extracting relevant features of the signal based on interaction between the signal and a structuring element (SE) of the Mat-Morph technique, the SE being 2 n , where n is a positive integer, a length of the SE being 2 n times T s , where T s is a sampling time of the signal, n being 4 such that the SE is 16, the performing of the Mat-Morph technique comprising performing a dilation operation to produce a dilated signal, an erosion operation to produce an eroded signal, and a Mat-Morph Gradient (MMG) operation, the MMG operation comprising subtracting the erosion signal from the dilation signal, the dilation operation comprising the following δ=( k⊕g )=max { k ( x+s )+ g ( s )|( x+s )∈ D k ,s∈D g }, where k represents the signal, g represents the SE, δ represents the dilated signal, ⊕ represents k dilated with g to produce the dilated signal, D k is a definition domain of k, D g is a definition domain of g, x is a sample of k, and s is a length of the SE, the erosion operation comprising the fo