System for remote vibration detection on combustor basket and transition in gas turbines

What is claimed is: 1. A method for sensing combustion-induced vibration characteristics in a gas turbine engine combustor, comprising: providing an operating gas turbine engine, which includes a combustor having a combustor housing, which defines an interior including therein combustor basket and transition components that entrain combustion gasses, and an inspection port in communication with the housing interior that is accessible from outside the housing, the inspection port including therein at least one optical pipe or optical window for preventing combustion gas escape from the housing interior; providing a non-contact reflective optical vibration sensor in optical communication with the respective inspection port optical pipe or window and the respective combustor basket or transition components, the sensor having a photon source and photon detector oriented outside the combustor housing; providing a vibration analyzer coupled to the non-contact reflective optical vibration sensor that correlates photons received by the photon detector with vibration frequency and/or magnitude characteristics; providing a gas turbine engine monitoring system, coupled to the vibration analyzer, the monitoring system capable of associating vibration characteristics sensed by the sensor with operating engine vibration characteristics that are indicative of combustion gas flame front position or a flameout condition; reflecting photons off of an exterior circumferential surface of the combustor basket or the transition component within the operating combustor with the photon source; receiving reflected photons with the photon detector correlating, with the vibration analyzer and the monitoring system, photons received by the detector with vibration characteristics of the corresponding combustor basket or transition component and identifying operating engine combustion gas flame front position or a flameout condition therewith. 2. The method of claim 1 , comprising using component vibration characteristics as an operational parameter for operating the gas turbine. 3. The method of claim 1 , the vibration sensor comprising a laser intensity sensor. 4. The method of claim 1 , the vibration sensor comprising a laser interferometry sensor. 5. The method of claim 1 , the vibration sensor comprising a laser Doppler sensor. 6. The system method of claim 1 , the vibration sensor further comprising at least one fiber optic cable inserted within the inspection port, coupled to the photon source. 7. The method of claim 1 , the vibration sensor further comprising at least one fiber optic cable inserted within the inspection port, coupled to the detector. 8. The method of claim 1 , the vibration sensor further comprising an optical tube and optical window inserted within the inspection port.