Optical fiber instrumented apparatus and methods of use thereof

What is claimed is: 1 . An instrumented temperature-control blanket comprising an insulative material; a temperature control structure integrated with the insulative material and configured to produce a heat or a cooling output in response to an input signal; and an optical sensor including an optical fiber integrated with the insulative material along the heating structure, wherein the optical sensor is configured to detect a change in an optical property measured from a plurality of intervals along a length of the optical fiber, the change in the optical property indicative of a temperature of the temperature-control blanket at a respective interval of the plurality of intervals. 2 . The blanket of claim 1 , wherein the optical sensor comprises a signal generator configured to propagate an optical signal through the optical fiber, and a receiver configured to detect returned light scattering, based on the optical signal, from each interval of the plurality of intervals of the optical fiber, and the optical sensor is coupled with a processing unit configured to analyze the returned light scattering to determine the change in the optical property from each interval of the plurality of intervals along the length of the optical fiber, and determine the temperature of the temperature-control blanket for each interval of the plurality of intervals by comparing the change in the optical property for each respective interval with a baseline optical property. 3 . The blanket of claim 2 , wherein the processing unit may be configured to analyze the returned light scattering using one or both of an optical time domain reflectometry or an optical frequency domain reflectometry. 4 . The blanket of claim 2 , wherein the optical property comprises a light frequency spectrum, and the processing unit associates changes of the light frequency spectrum with each respective interval of the plurality of intervals based on a detected time of the returned light scattering at the receiver. 5 . The blanket of claim 2 , wherein the insulative material is wrapped around a pipe or a vessel, and the processing unit is configured to generate a 3-D temperature map corresponding to a 3-D surface of the pipe or vessel engaged with the insulative material, the 3-D temperature map formed from the determined temperature of the temperature-control blanket at each respective interval. 6 . The blanket of claim 2 , wherein the processing unit is configured to compare the determined temperature of the temperature-control blanket to one or more set points, the blanket further comprises a controller operatively coupled with the temperature control structure and configured to deliver the input signal thereto, and the controller is configured to change a property of the input signal based on the determined temperature of the temperature-control blanket deviating from the one or more set points, the input signal comprises at least one of an electrical signal or a flow of a coolant medium. 7 . The blanket of claim 2 , wherein the temperature control structure comprises a heating structure and the blanket further comprises a first thermocouple assembly integrated with the insulative material along a first interval of the plurality of intervals of the optical fiber and configured to measure a first temperature of the temperature-control blanket at the first interval, and a second thermocouple assembly integrated with the insulative material along a interval of the plurality of intervals of the optical fiber and configured to measure a second temperature of the temperature-control blanket at the second interval, and the processing unit is configured to determine the baseline optical property by correlating the first measured temperature of the first thermocouple assembly and the second measured temperature of the second thermocouple assembly with the optical property measured by the optical sensor for said first and second temperatures. 8 . The blanket of claim 1 , wherein the optical sensor is a first optical sensor, and the blanket further comprises a second optical sensor including a second optical fiber integrated with the insulative material along the temperature control structure and the first optical sensor, wherein the second optical sensor is configured to detect a change in an optical property measured from a plurality of intervals along a length of the second optical fiber, the change in the optical property indicative of a temperature of the temperature-control blanket at a respective interval of the plurality of intervals of the second optical fiber. 9 . The blanket of claim 1 , wherein the insulative material comprises a high-temperature ceramic with formed channels therein configured to receive at least a portion of the temperature control structure and at least a portion of the optical fiber. 10 . The blanket of claim 9 , further comprising high-temperature ceramic threads engaged with the insulative material and the portion of the temperature control structure and/or the portion of the optical fiber to secure the portion of the temperature control structure and/or the portion of the optical fiber in the formed channels. 11 . The blanket of claim 9 , wherein the portion of the temperature control structure and the portion of the optical fiber are enclosed within the insulative material. 12 . The blanket of claim 11 , wherein the formed channels define a serpentine pattern. 13 . The blanket of claim 2 , wherein the temperature control structure comprises a heating structure and a cooling structure integrated with the insulative material. 14 . The blanket of claim 13 , wherein the processing unit is configured to compare the determined temperature of the temperature-control blanket to one or more set points, the blanket further comprises a controller operatively coupled with the temperature control structure configured to deliver the input signal to the heating structure and/or the cooling structure, and the controller is configured to change a property of the input signal based on the determined temperature of the temperature-control blanket deviating from the one or more set points. 15 . A system comprising the blanket of claim 1 ; and a pipe or a vessel having a fluid therein, wherein the blanket is engaged with the pipe or the vessel to provide the heat output of the heating structure to the fluid. 16 . The system of claim 15 , wherein the blanket further comprises a signal generator configured to propagate an optical signal through the optical fiber, and a receiver configured to detect returned light scattering, based on the optical signal, from each interval of the plurality of intervals of the optical fiber, and the system further comprises a processing unit configured to analyze the returned light scattering to determine the change in the optical property from each interval of the plurality of intervals along the length of the optical fiber, and determine the temperature of the temperature-control blanket for each interval of the plurality of intervals by comparing the change in the optical property for each respective interval with a baseline optical property. 17 . The system of claim 16 , wherein the fluid comprises a fissile molten salt fluid of a molten salt reactor system, the processing unit is further configured to compare the determined temperature of the temperature control blanket to one or more set points associated with a freezing temperature of the fissile molten salt fluid, the blanket furth