3D reconstruction of temperature field using Gaussian Radial Basis Functions (GRBF)

3D temperature field reconstruction is of practical interest to the power, transportation and aviation industries and it also opens up opportunities for real time control or optimization of high temperature fluid or combustion process. In this paper, a new algorithm for the reconstruction of 3D temperature field is proposed based on Gaussian Radial Basis Functions (GRBF). A 3D temperature field is a space distribution profile evolving over time which is infinite dimensional in nature, the proposed GRBF-based approach can approximate the temperature field as a finite summation of space-dependent basis functions and time-dependent coefficients. According to the acoustic pyrometry principle, these Gaussian functions are integrated along a number of paths which are determined by the number and distribution of sensors. This inversion problem to estimate the unknown parameters of the Gaussian functions can be solved with the measured times-of-flight (TOF) of acoustic waves and the length of propagation paths using the recursive least square method (RLS). Compared with polynomial interpolation and functions parameterization, GRBF provides better approximation capability for most nonlinear functions over irregular regions. It is also superior in scalability and more efficient when extended to higher dimensional space. The simulation result shows an error less than 2% between the reconstructed temperature field and the ideal one. It demonstrates the availability and efficiency of GRBF framework for temperature field reconstruction.

[1]  Dario Pompili,et al.  A CDMA-based Medium Access Control for UnderWater Acoustic Sensor Networks , 2009, IEEE Transactions on Wireless Communications.

[2]  A. A. Anosov,et al.  Experimental reconstruction of temperature distribution at a depth through thermal acoustic radiation , 1999 .

[3]  Nan Wu,et al.  Cutting temperature in rotary ultrasonic machining of titanium: experimental study using novel Fabry-Perot fibre optic sensors , 2013, Int. J. Manuf. Res..

[4]  Carsten Franke,et al.  Solving partial differential equations by collocation using radial basis functions , 1998, Appl. Math. Comput..

[5]  Tobin A. Driscoll,et al.  Eigenvalue stability of radial basis function discretizations for time-dependent problems , 2006, Comput. Math. Appl..

[6]  Upul P. Desilva,et al.  Novel Gas Turbine Exhaust Temperature Measurement System , 2013 .

[7]  E. Salerno,et al.  An acoustic pyrometer system for tomographic thermal imaging in power plant boilers , 1996 .

[8]  H. Booth An acoustic pyrometer , 1916 .

[9]  C. Niezrecki,et al.  Optical pressure/acoustic sensor with precise Fabry-Perot cavity length control using angle polished fiber. , 2009, Optics express.

[10]  Wang Lin-lin A STUDY ON COMPLEX TEMPERATURE FIELD RECONSTRUCTION ALGORITHM BASED ON COMBINATION OF GAUSSIAN FUNCTIONS WITH REGULARIZATION METHOD , 2004 .

[11]  Jiang Gen-shan Reconstruction of Temperature Fields of Furnace on the Basis of Few Acoustic Data , 2007 .

[12]  Robert Schaback,et al.  Improved error bounds for scattered data interpolation by radial basis functions , 1999, Math. Comput..

[13]  Xiaotian Zou,et al.  Fiber-optic ultrasound generator using periodic gold nanopores fabricated by a focused ion beam , 2013 .

[14]  Christopher Niezrecki,et al.  Ultrafast Fabry-Perot fiber-optic pressure sensors for multimedia blast event measurements. , 2013, Applied optics.

[15]  Tobin A. Driscoll,et al.  Polynomials and Potential Theory for Gaussian Radial Basis Function Interpolation , 2005, SIAM J. Numer. Anal..