Abstract
Although the ultrasonic technique for measuring temperature distributions has drawn much attention in recent years, most studies that adopt this technique focus on two-dimensional (2D) systems. Mathematically, extending from 2D to 3D requires higher construction-performing algorithms, as well as more complicated, but extremely crucial, designs of ultrasonic transducer layouts. Otherwise the ill condition of governing-equation matrices will become more serious. Here, we aim at constructing 3D temperature distributions by using a network of properly-installed ultrasonic transducers that can be controlled to transmit and receive ultrasound. In addition, the proposed method is capable of performing this construction procedure in real time, thus monitoring transient temperature distributions and guarantee the safety of operations related to heating or burning. Numerical simulations include constructions for four kinds of temperature distributions, as well as corresponding qualitative and quantitative analyses. Finally, our study offers a guide in developing non-intrusive experimental methods that measure 3D temperature distributions in real time.
Similar content being viewed by others
Introduction
Ultrasonic techniques for non-intrusive measurements have been used in both the academia and the industry1,2,3,4,5,6,7,8,9,10,11,12,13,14,15,16,17,18,19. Particularly, in reference3, a method of ultrasonic scattering measurement is presented for nondestructive testing of additively manufactured material, which can avoid both missed detections and false positives. Due to temperatures’ characteristics of spatial distributing and time-varying, the ultrasonic method has drawn much attention in areas of heat transfer and thermometry in recent years6,7,8,9,10,11. Particularly, by ultrasonic pulse-echo measurements, the inverse ultrasonic technique raised in reference8 can be used for high-accurately determining internal transient temperature distributions in heat materials. According to references9,10,11,12, the ultrasound velocity varies dependently on temperature. Particularly, a one-to-one relationship exists between the ultrasound velocity and the temperature, allowing the temperature to be computed after the ultrasound velocity is acquired13,14. Conversely, within a given 3D space, the temperature distribution may be constructed if the distribution of ultrasound velocity is acquired by some means15.
In the proposed study, we focus on constructing 3D temperature distributions using a network of properly-installed ultrasonic transducers that can be controlled to transmit and receive ultrasounds in different times. Under such circumstances, ultrasound signals will propagate among ultrasonic transducers and will be distributed within the 3D space. In fact, constructing temperature distributions based on ultrasound signals constitutes an inversion process generally accompanied by ill-conditioned matrices9. Therefore, mathematical methods of Multi-quadric radial basis approximation and singular-value decomposition are adopted, incorporating advantages of fitting sparse data and solving inversion problems16. To validate the constructing performance, we carry out a series of numerical simulations in which temperature-distribution models with different complexity levels are designed. Qualitative and quantitative analyses of simulations theoretically indicate that this ultrasonic method can construct 3D temperature distributions with adequate accuracy, strong anti-interference and satisfactory real-time capability.
Description of Temperature Distribution Construction
As mentioned above, the ultrasound velocity changes depending on temperatures. In gases, the relationship between ultrasound velocity and temperatures is described as6,17,18
where v denotes the ultrasound velocity; T the absolute temperature; R the universal gas constant; κ and Mg respectively the adiabatic exponent and the average molecular weight of the gas. As constants, κ, Mg and R can be grouped and replaced by another constant B.
For situations with uniform temperatures, the simplest device illustrated in Fig. 1 will meet most demands. This device is composed of an ultrasonic transmitter and an ultrasonic receiver. Since distance L between the transmitter and the receiver is fixed, we can compute the uniform temperature by
if t is measured.
However, in various realistic situations with non-uniform temperatures, average temperatures no longer suffice. For constructing 3D temperature distributions, numerous ultrasonic transducers should be installed spatially to ensure adequate precision.
A network of 32 ultrasonic transducers is represented by black dots and installed uniformly on each edge of the cube (Fig. 2). These transducers can be regarded as transceivers due to their ability of working as transmitters and receivers, which are controlled to transmit and detect ultrasonic signals in different times16. Ultrasound signals propagate from one transducer to another transducer and generate ultrasound paths, which are represented by blue lines. Theoretically, ultrasound paths exist between every two transducers17. However, since ultrasound paths on edges or surfaces contribute little to the construction of internal temperatures, they are non-essential and have been eliminated from Fig. 2. Totally, these 32 ultrasonic transducers generate 172 effective ultrasound paths. We obtain
where lk denotes the kth ultrasound path, tk travelling time of the ultrasound path lk, and f(x, y, z) the reciprocal of v.
The process of constructing temperature distributions involves Multi-quadric radial basis approximation. To proceed, we divide the measured area into N elements, and then establish N radial basis functions whose centers correspond to centers of those elements (Fig. 3, N = 512 = 8 × 8 × 8).
The Multi-quadric radial basis function is established as
where ||·|| denotes the standard Euclidean norm; (xi, yi, zi) the center of Multi-quadric radial basis, or the midpoint of the ith element; and γ the smooth factor related to the specific area as well as the network of transducers16.
Next, f(x, y, z) is expressed as a linear combination of N Multi-quadric radial basis functions:
where εi is an undetermined coefficient describing the distribution of ultrasound velocity’s reciprocal.
Define aki as:
To compute coefficient εi, we can merge Eqs (3)–(6) to obtain
With definitions given as
we can rewrite Eq. (7) into a matrix form as
Considering A as an ill-conditioned matrix, we adopt the singular-value decomposition to achieve regularization estimation. According to matrix theory20, any real matrix \(A\in {R}^{M\times N}\) can be decomposed as
where \(U\in {R}^{M\times M}\) and \(V\in {R}^{N\times N}\) denote two orthogonal matrices; r the rank of matrix A; and \({\sigma }_{1}\ge {\sigma }_{2}\ge \cdots \ge {\sigma }_{r} > 0\) the r singular values of matrix A. Let us further define
then the generalized inverse matrix of A, i.e.\({A}^{+}\in {R}^{N\times M}\) is obtained as
Thus, the undetermined coefficient ε can be rewritten as
Since parameter γ is determined appropriately via the numerical method, elements of matrix A can be computed in advance to predetermine A+. When matrix of travelling times t are measured, undetermined coefficients ε will be obtained. Thus, the reciprocal of ultrasound velocity f(x, y, z) and then ultrasound velocity v(x, y, z) can be eventually determined. Finally, the temperature distribution T(x, y, z) is constructed as
By the expression T(x, y, z), not only the temperature of any position with exact coordinates, but also the temperature distribution of the whole measured area can be constructed.
Numerical Simulations and Analysis
To validate the temperature distribution construction performance of this ultrasonic method, we carry out a series of numerical simulations. As shown in Figs 2 and 3, the measured area is a cube of 8m × 8m × 8m, with 32 ultrasonic transducers generating 172 effective ultrasound paths. The cube is divided into 512 uniform elements to establish 512 Multi-quadric radial basis functions. In addition, constant coefficient B in gaseous environment is 20.0318,19, and parameters γ is predetermined as 0.1. In simulations, four temperature distribution models with different complexity levels are set up to serve as references to constructions below.
One-peak symmetrical temperature distribution:
One-peak asymmetrical temperature distribution:
Two-peak temperature distribution:
Four-peak temperature distribution:
Known from practical experiences, travelling times of ultrasound paths obtained via actual measurements may be influenced by various interferences21,22,23. Thus, to investigate the anti-interference of this ultrasonic method, we implement experiments respectively in both ideal condition and non-ideal condition. In the former, travelling times are theoretically computed from Eq. (19). In the latter, travelling times are assumed to be theoretical values over laid with Gaussian noise, whose mean deviation and standard deviation are 0 and 0.001 respectively.
To make comprehensive evaluations, we analyze simulations qualitatively and quantitatively. The former includes slice maps and scatter plots of temperature distributions, the latter consists of temperature mean relative error Em, temperature root-mean-square percent error Er, as well as average construction time. Here, Em and Er are respectively defined as:
and
where n denotes the number of computed points; TRj and TMj temperatures of point (xj, yj, zj) respectively of the construction and its model; and TMm the mean temperature of model.
Figures 4–7 display the slice map and scatter plot of temperature distributions, respectively of models and their constructions. As figures show, these constructions resemble, and almost look identical to, their corresponding models. Even for the most complex four-peak temperature distribution and under the influence of noise, it is difficult to distinguish constructions from the model via the visual inspection.
Quantitative temperature errors and construction times are computed and respectively displayed in Tables 1 and 2, which can further evaluate the construction performance. Considering impact of random factors, simulations that construct a certain temperature distribution model are repeatedly done 1000 times. Thus, these quantitative temperature errors and construction times are average values.
Observing from Table 1, we find out that errors in constructions of complex two-peak and four-peak temperature distributions are relatively larger than those of simple ones. And for a specific temperature distribution, errors under influence of noise are slightly larger than those without influence of noise. On the whole, constructions in various situations are accurate enough, as Em and Er are respectively within 8.7% and 4.3%.
Conclusions can be drawn from qualitative error figures and quantitative errors. First, although constructions may be accompanied by some errors, they can accurately describe how temperatures distribute over the whole area, especially for hot peaks. Second, construction errors have tendency to increase with complexity of temperature distributions and influences of noise.
To some extent, average construction times demonstrate the real-time capability of this ultrasonic method (Table 2). Clearly, the proposed method can construct various temperature distributions within about 0.089s–0.102s and provide real-time temperature distributions in most situations.
Conclusion
Based on the one-to-one relationship between the ultrasound velocity and the temperature, we have developed a non-intrusive and real-time ultrasonic technique that can compute 3D temperature distributions using a network of properly-installed ultrasonic transducers. Due to the ill-posed condition in the process, multi-quadric radial basis approximation and singular value decomposition are adopted, incorporating advantages of fitting sparse data and solving inversions. To validate the constructing performance, we further carry out a series of numerical simulations in which temperature distribution models with different complexity levels are designed.
This paper performed numerical simulations but not experimental validation is in three considerations. First, this study focuses on the theoretical feasibility of constructing 3D temperature distributions using ultrasonic technique, and numerical simulations are convincing enough. Second, the experimental validation requires absolutely accurate realistic temperature distributions for references, but it is difficult and even impossible to accurately measure realistic temperature distributions using existing thermometry techniques. Third, inaccurate travelling times of ultrasound paths may cause unsatisfactory constructed temperature distributions, whether the construction algorithm is excellent enough or not. Therefore, in realistic situations, the measured travelling times of ultrasound paths frequently affected by uncertain interferences may lead to an incorrect assessment of the ultrasonic technique in temperature distribution constructions.
Since this paper has demonstrated the theoretical feasibility of the ultrasonic technique in constructing 3D temperature distributions, our future studies will focus on its experimental validation and engineering application, including the selection of hardware components, the design and establishment of experimental platform, the performance optimization of ultrasonic transducers, the processing, extraction and transformation of ultrasonic signals, etc. The main factors affect the accuracy of realistic temperature distribution constructions may lie in the uniformity of the measured media, the flow of gas, the size and layout of ultrasonic transducers, and the time delay in transmitting and receiving of ultrasound signals, etc., and these therefore must be emphases in our future studies.
Data Availability
The datasets generated and analyzed during the current study are available from the corresponding author on reasonable request.
References
Zhu, X. Y. et al. Ultrasonic detection based on polarization-dependent optical reflection. Opt. Lett. 42, 439–441 (2017).
Chen, Y., Chang, Z. Q., Yu, X. C., Song, R. X. & Huang, W. M. Use of ultrasonic device in cervical and thoracic laminectomy: a retrospective comparative study and technical note. Sci. Rep. 8, Article ID 4006 (2018).
Song, Y. F. et al. Nondestructive testing of additively manufactured material based on ultrasonic scattering measurement. Measurement 118, 105–112 (2018).
Alzebda, S. & Kalashnikov, A. N. Ultrasonic sensing of temperature of liquids using inexpensive narrowband piezoelectric transducers. IEEE Trans. Ultrason., Ferroelectr., Freq. Control 57, 2704–2711 (2010).
Fang, J. & Tsui, P.-H. Evaluation of thrombolysis by using ultrasonic imaging: an in vitro study. Sci. Rep. 5, Article ID 11669 (2015).
Bramanti, M., Salerno, E. A., Tonazzini, A., Pasini, S. & Gray, A. An acoustic pyrometer system for tomographic thermal imaging in power plant boilers. IEEE Trans. Instrum. Meas. 45, 159–167 (1996).
Blachowski, B., Swiercz, A., Gutkiewicz, P., Szelazek, J. & Gutkowski, W. Structural damage detectability using modal and ultrasonic approaches. Measurement 85, 210–221 (2016).
Dong, W. et al. Reconstruction of internal temperature distributions in heat materials by ultrasonic measurements. Appl. Therm. Eng. 112, 38–44 (2010).
Fan, W., Chen, C. T. A. & Chen, Y. Calibration of an acoustic system for measuring 2-D temperature distribution around hydrothermal vents. Ultrasonics 53, 897–906 (2013).
Srinivasan, K., Sundararajan, T., Narayanan, S., Jothi, T. J. S. & RohitSarma, C. S. L. V. Acoustic pyrometry in flames. Measurement 46, 315–323 (2013).
Schmidt, P. L., Greg Walker, D., Yuhas, D. J. & Mutton, M. M. Thermal measurements using ultrasonic acoustical pyrometry. Ultrasonics 54, 1029–1036 (2014).
Tsai, W. Y., Chen, H. C. & Liao, T. L. High accuracy ultrasonic air temperature measurement using multi-frequency continuous wave. Sens. Actuators A 132, 526–532 (2006).
Barth, M. & Raabe, A. Acoustic tomographic imaging of temperature and flow fields in air. Meas. Sci. Technol. 22, Article ID 035102 (2011).
Hanson, T. A., Yilmaz, N. & Drozda, P. Acoustic pyrometry using an off-the-shelf range finding system. J. Fire Sci. 26, 287–308 (2008).
Chen, Y., Xu, K. B. & Liu, S. S. Application study on multiple acoustic paths intersection in temperature field measurement. Adv. Mater. Res. 902, 167–172 (2014).
Shen, X. H. et al. Ultrasonic temperature distribution reconstruction for circular area based on Markov radial basis approximation and singular value decomposition. Ultrasonics 62, 174–185 (2015).
Lu, J., Wakai, Takahashi, S. & Shimizu, S. Acoustic computer tomographic pyromery for two-dimensional measurement of gases taking into account the effect of refraction of sound wave paths. Meas. Sci. Technol. 11, 692–697 (2000).
Zhang, S. P., Shen, G. Q., An, L. S. & Niu, Y. G. Online monitoring of the two-dimensional temperature field in a boiler furnace. Appl. Therm. Eng. 75, 958–966 (2015).
Liu, S., Liu, S. & Ren, T. Acoustic tomography reconstruction method for the temperature distribution measurement. IEEE Trans. Instrum. Meas. 66, 1936–1945 (2017).
Pedrini, B. et al. Model-independent particle species disentanglement by X-ray cross-correlation scattering. Sci. Rep. 7, Article ID 45618 (2017).
Kolouri, S., Azimi-Sadjadi, M. R. & Ziemann, A. A statistical-based approach for acoustic tomography of the atmosphere. J. Acoust. Soc. Am. 135, 104–114 (2014).
Avanesians, P. & Momayez, M. Wave separation: Application for arrival time detection in ultrasonic signals. Ultrasonics 55, 15–25 (2015).
Jia, R. X. et al. Study of ultrasonic thermometry based on ultrasonic time-of-flight measurement. AIP Adv. 6, 23–33 (2016).
Acknowledgements
This research work is supported by Major State Basic Research Development Program (973 Program, Grant Number: 2013CB328903), National Natural Science Foundation of China (Grant Number: 61975072), Natural Science Foundation of Fujian Province (Grant Number: 2018J05110), Program for Innovative Research Team in Science and Technology in Fujian Province University (Optoelectronic Materials and Device Application), The foundation of Fujian Province Great Teaching Reform (Grant Number: FBJG20180015).
Author information
Authors and Affiliations
Contributions
Xuehua Shen and Huanting Chen presented the construction algorithm, conceived and conducted numerical simulations. Xuehua Shen, Tien-Mo Shih and Qingyu Xiong performed analysis of numerical simulations and wrote the main manuscript text. Hualin Zhang prepared all figures in the manuscript. All authors reviewed the manuscript.
Corresponding authors
Ethics declarations
Competing Interests
The authors declare no competing interests.
Additional information
Publisher’s note: Springer Nature remains neutral with regard to jurisdictional claims in published maps and institutional affiliations.
Rights and permissions
Open Access This article is licensed under a Creative Commons Attribution 4.0 International License, which permits use, sharing, adaptation, distribution and reproduction in any medium or format, as long as you give appropriate credit to the original author(s) and the source, provide a link to the Creative Commons license, and indicate if changes were made. The images or other third party material in this article are included in the article’s Creative Commons license, unless indicated otherwise in a credit line to the material. If material is not included in the article’s Creative Commons license and your intended use is not permitted by statutory regulation or exceeds the permitted use, you will need to obtain permission directly from the copyright holder. To view a copy of this license, visit http://creativecommons.org/licenses/by/4.0/.
About this article
Cite this article
Shen, X., Chen, H., Shih, TM. et al. Construction of three-dimensional temperature distribution using a network of ultrasonic transducers. Sci Rep 9, 12726 (2019). https://doi.org/10.1038/s41598-019-49088-y
Received:
Accepted:
Published:
DOI: https://doi.org/10.1038/s41598-019-49088-y
- Springer Nature Limited