Analysis of component having engineered internal space for fluid flow

The invention claimed is: 1. A method for analyzing an internal characteristic of a component, the component having an engineered internal space, a fluid entrance and a fluid exit to allow fluid flow through the internal space past a portion of the component for which the internal characteristic is determined, the method comprising: operating the component using a process control parameter; receiving, by a processor, operational time-dependent acoustic data signals produced by the component during the fluid flow through the internal space at one or more controlled flow rates in response to operating the component using the process control parameter, wherein the one or more controlled flow rates are based on a type of the component; converting, by the processor, the operational time-dependent acoustic data signals to an operational frequency-dependent spectrum; extracting, by the processor, operational frequency and acoustic intensity values from the operational frequency-dependent spectrum; identifying, by the processor, an operational frequency in the operational frequency-dependent spectrum that corresponds to the internal characteristic of the component by identifying the frequency that corresponds to a maximum operational acoustic intensity value in the extracted operational acoustic intensity values; predicting, by the processor, based on the identified operational frequency, based on the maximum operational acoustic intensity value associated with the identified operational frequency, and based on the one or more controlled flow rates, at least one of an operational state or an operational source of the component by comparing the extracted operational frequency and acoustic intensity values in the operational frequency-dependent spectrum to a predetermined set of reference frequency and acoustic intensity values for the one or more controlled flow rates, wherein each of the set of reference frequency and acoustic intensity values is associated with a maximum reference acoustic intensity value for a sample component of a reference state or source; and updating the process control parameter, based on the at least one of the operational state or the operational source of the component, in response to predicting the at least one of the operational state or the operational source of the component. 2. The method of claim 1 , further comprising identifying, by the processor, a maximum operational acoustic intensity value in the extracted acoustic intensity values and determining a portion of the operational frequency-dependent spectrum that corresponds to the maximum operational acoustic intensity value. 3. The method of claim 2 , further comprising using the identified portion of the operational frequency-dependent spectrum to analyze the internal characteristic of the component. 4. The method of claim 3 , further comprising identifying, by the processor, a portion of the operational frequency spectrum that corresponds to flow phenomena comprising one or more of vortical flow, jet screech, or shock cell generation. 5. The method of claim 1 , further comprising receiving, by the processor, acoustic data signals that are detectable by a microphone and performing the method using the acoustic data signals that are detectable by a microphone. 6. The method of claim 1 , further comprising receiving, by the processor, acoustic data signals that are not detectable by a human ear and performing the method using the acoustic data signals that are not detectable by a human ear. 7. The method of claim 1 , further comprising calculating, by the processor, based on at least one of the identified operational frequency or the maximum operational acoustic intensity value, a probability that the state of the component is worn. 8. The method of claim 1 , further comprising: generating, by the processor, a fit model as a function of frequency and intensity based on the predetermined set of reference frequency and acoustic intensity values for the one or more controlled flow rates, wherein each of the set of reference frequency and acoustic intensity values is associated with a sample component of reference state, wherein the state of each sample component comprises new or worn, and predicting, by the processor, a likelihood that the state of the component is worn using the fit model. 9. The method of claim 1 , further comprising calculating, by the processor, based on at least one of the identified operational frequency or the maximum operational acoustic intensity value, a probability that the source of the component is a particular manufacturer. 10. The method of claim 1 , further comprising generating, by the processor, a fit model as a function of frequency and source, and predicting a likelihood that the component is made by a particular source using the fit model. 11. The method of claim 1 , further comprising, by the processor: generating a plurality of spectrograms of the extracted frequency values and the corresponding flow rates, analyzing the differences in the spectrograms, and predicting, based on the differences in the spectrograms, at least one of the state and the source of the component. 12. The method of claim 1 , wherein the component comprises one of a thermal spray nozzle and an electrode of a thermal spray device. 13. A computing device comprising a processor and memory having stored therein a plurality of instructions that when executed by the processor cause the computing device to perform the method of claim 1 . 14. An apparatus comprising: a fluid supply to supply fluid to the fluid entrance of a component having an engineered internal space, a fluid entrance and a fluid exit to allow fluid flow through the internal space past a portion of the component for which an internal characteristic is determined, a flow regulator to control the flow rate through the internal space of the component, an attachment apparatus to attach the fluid supply to the component, a microphone configured to capture acoustic data signals associated with the flow of the fluid through the component, and a processor configured to: (i) receive operational time-dependent acoustic data signals produced by the component during the fluid flow through the internal space at one or more controlled flow rates, wherein the one or more controlled flow rates are based on a type of the component, (ii) convert the operational time-dependent acoustic data signals to operational frequency-dependent spectrum, (iii) extract operational frequency and acoustic intensity values from the operational frequency-dependent spectrum, (iv) identify an operational frequency in the operational frequency-dependent spectrum that corresponds to the internal characteristic of the component by identifying the frequency that corresponds to a maximum operational acoustic intensity value in the extracted operational acoustic intensity values, (v) predict at least one of an operational state or an operational source of the component, based on the identified operational frequency, based on the maximum operational acoustic intensity value associated with the identified operational frequency, and based on the one or more controlled flow rates, by comparing the extracted operational frequency and acoustic intensity values in the operational frequency-dependent spectrum to a predetermined set of reference frequency and acoustic intensity values for the one or more controlled flow rates, wherein each of the set of reference frequency and acoustic intensity values is associated with a maximum reference acoustic intensity value for a sample component of a reference state or source, and (v