System and method for predetermining the onset of impending oscillatory instabilities in practical devices

We claim: 1 . A system to determine impending oscillatory instabilities in a device, the system comprising: a measuring device ( 102 ) configured to generate at least one signal corresponding to dynamics in the device; an instability detection unit ( 104 ) provided in communication with the measuring device ( 102 ); and an amplitude estimation unit ( 130 ) provided in communication with the instability detection unit ( 104 ) and the measuring device ( 102 ), configured to estimate an amplitude of the impending oscillatory instabilities, wherein, the instability detection unit ( 104 ) is configured to diagnose the onset of the impending oscillatory instabilities in the device based on at least one of intermittent bursts in the signal generated by the measuring device ( 102 ) before the onset of oscillatory instabilities, or smooth variations in parameters as the device approaches the impending oscillatory instabilities, wherein the intermittent bursts are detected preceding a transition from a noisy or chaotic behavior to the oscillatory instabilities by detecting an increase in the amplitude of the impending oscillatory instabilities using the amplitude estimation unit ( 130 ). 2 . The system as claimed in claim 1 , wherein the system further includes a control unit ( 106 ) provided in communication with at least one of the measuring device ( 102 ), the instability detection unit ( 104 ) and the amplitude estimation unit ( 130 ), wherein the instability detection unit ( 104 ) is configured to generate control signal corresponding to onset of the impending oscillatory instabilities; and the control unit ( 106 ) is configured to control the oscillatory instabilities that proceed through the intermittent bursts based on the control signal. 3 . The system as claimed in claim 1 , wherein the system is used to detect the impending oscillatory instabilities that proceed through the intermittent bursts in at least one of a combustor, an industrial furnace, a burner, aeroacoustic systems, aero-elastic systems, aeromechanical systems, air-compression systems and any other device subjected to oscillatory instabilities. 4 . The system as claimed in claim 3 , wherein a digital to analog convertor ( 120 ) is integrated with the system to convert at least one digital signal obtained as an output from the instability detection unit ( 104 ) to at least one analog signal that could be processed by a control unit ( 106 ). 5 . The system as claimed in 1 , wherein the measuring device ( 102 ) includes a plurality of sensors that are configured to generate the signal corresponding to the dynamics of the device. 6 . The system as claimed in 5 , wherein the sensor is selected from at least one of an acoustic sensor, a photodiode and a photomultiplier. 7 . The system as claimed in 1 , wherein an analog to digital converter ( 128 ) is integrated with the system to convert at least one analog signal generated by the measuring device ( 102 ) to at least one digital signal that could be processed by the instability detection unit ( 104 ) and the amplitude estimation unit ( 130 ). 8 . The system as claimed in claim 1 , wherein the system determines the proximity of the device to the oscillatory instabilities that proceeds through the intermittent bursts by performing at least one of 0-1 test, Burst count test and Hurst exponent test. 9 . The system as claimed in claim 8 , wherein the system configured to detect and control the impending oscillatory instabilities in the device by performing the 0-1 test comprises: the measuring device ( 102 ) provided in communication with the device and configured to generate at least one signal (measured signal) corresponding to the dynamics in the device; a signal conditioner ( 108 ) in communication with the measuring device ( 102 ) and configured to amplify the measured signal generated in the measuring device ( 102 ); an analog to digital convertor ( 128 ) connected to the signal conditioner; the amplitude estimation unit ( 130 ) in communication with the instability detection unit ( 104 ) and configured to estimate the amplitude of the impending oscillatory instability; the instability detection unit ( 104 ) provided in communication with the analog to digital convertor ( 128 ) and the amplitude estimation unit ( 130 ), wherein the instability detection unit ( 104 ) is configured to generate a value between 0 and 1 based both on the amplitude of instability estimated by the amplitude estimation unit ( 130 ) and the proximity of the device to the oscillatory instabilities proceeding through the intermittent bursts in the device; at least one digital to analog convertor ( 120 ) provided in communication with the instability detection unit ( 104 ); and the control unit ( 106 ) provided in communication with the digital to analog convertor, wherein the instability detection unit ( 104 ) is configured to generate a value close to 1 for noisy/chaotic signals and close to 0 for oscillatory dynamics and values in between 0 and 1 for the intermittent bursts. 10 . The system as claimed in claim 8 , wherein the system configured to detect and control the impending oscillatory instabilities in the device that proceed through the intermittent bursts by performing the Burst count test comprises: a measuring device ( 202 ) provided in communication with the device and configured to generate at least one signal (measured signal) corresponding to the dynamics in the device; a threshold logic circuit ( 210 ) having a fixed threshold value for the signal; an amplitude estimation logic unit ( 232 ), provided in communication with the threshold logic unit ( 210 ) and configured to estimate the amplitude of the oscillations during instability, before instability is approached; an internal gating circuit ( 204 ) provided in communication with the threshold logic circuit ( 210 ) and configured to generate a gating signal; a comparator ( 212 ) provided in communication with the threshold logic circuit ( 210 ) and configured to compare measured signal with the fixed threshold value of the signal; a counter ( 216 ) provided in communication with the threshold logic circuit ( 210 ) and configured to count a number of peaks in the at least one signal above the fixed threshold value of the signal; and a controller ( 218 ) provided in communication with the counter ( 216 ) and configured to regulate the functioning of the device, wherein the gating signal controls a time duration of signal acquisition from the device. 11 . The system as claimed in claim 10 , wherein the system further includes a signal conditioner ( 208 ) provided in communication with the measuring device ( 202 ) and configured to amplify the measured signal. 12 . The system as claimed in claim 10 , wherein the controller ( 218 ) is configured to regulate the functioning of at least one of operating parameters of the device, such that the device is prevented from the oscillatory instabilities that happen through the intermittent bursts. 13 . The system as claimed in claim 8 , wherein the system configured to detect and control the impending oscillatory instabilities that proceeds through the intermittent bursts in the device by performing the Hurst exponent test comprises: the measuring device ( 302 ) provided in communication with the device and configured to generate at least one signal (measured signal) corresponding to the dynamics in the device; a signal conditioner ( 326 ) in communication with the measuring device ( 102 ); an analog to digital convertor ( 328 ) connected to the signal conditioner; the instability detection unit ( 304 ) attached to the analog to d