1. Introduction
In recent years, due to their great potential in weight saving, fiber reinforced laminated composites are becoming increasingly important in applications where low weight, high stiffness, and high strength are required, in particular in the aircraft industry. Composite structures can be damaged under mechanical and thermal loadings. The development of an effective technique to monitor and detect the size, location and orientation of any internal defects may serve to help to avoid composite failures.
Currently, new airplanes are manufactured with carbon fiber composite materials to be lighter and more fuel efficient. With the increased usage of fiber reinforced materials in structural materials, it has become all the more important for the NDT community to develop viable technique which can be used to test these materials while they are in service. Typical NDT techniques which have been used to try and reconstruct signals and / or images of defects inside the metals and composite materials are visual optical inspection, radiography, magnet particle inspection, eddy current testing, ultrasonic testing, acoustic emission testing, microwave testing, etc. [1-2]
The ultrasonic testing is based on the detection and the interpretation of the ultrasonic waves reflected by defects. Widely used methods at the present time are split spectrum processing [3-7], wavelet method [8-16], the high resolution pursuit (HRP) [17-18], and the chirplet transform [19-20]. The results are presented in various forms, so a direct comparison is very difficult.
In this paper, a new approach to the inspection problem of composite materials using ultrasonic signal processing is proposed in order to detect delamination defects and thicknesses measurement. We consider two main steps for interpreting ultrasonic data: the pre-processing technique necessary to enhance the SNR, this step is realized by SSP algorithm. The second step was carried out by using matching pursuit signal decomposition (MPSD), this technique is necessary for the estimation of the time-of-arrival (TOA) and/or time-of-flight (TOF) of the ultrasonic echoes.
This paper is organized as follows: Section 2 describes the proposed method for flaw detection using SSP-MPSD system structure. In section 3, the performance of the algorithm is tested and compared using simulated ultrasonic echoes. In section 4 the performance of the method is experimentally verified using ultrasonic traces acquired from three specimens of carbon fibre reinforced polymer multi-layered composite materials (CFRP) provided by an aircraft manufacturer company. Finally, conclusions are given in Section 5.
2. Proposed Method for Flaw Detection
In this work, a new approach is presented for ultrasonic flaw detection applications. This approach is based on split-spectrum processing (SSP) combined with matching pursuit signal decomposition (MPSD).
2.1 Ultrasound signal formulation
The main aim of the analysis of the signal received by ultrasonic receiver in an NDT process is to obtain information about the material integrity.
We therefore need to detect a possible reflection induced by a defect in the structure in a signal that is corrupted by the structural noise generated mainly by the reinforcement, such as carbon fibers, in the matrix material. From a mathematical point of view, we can define the problem as follows:
In this equation, x(t) represents the observed noisy signal, y(t) is the model-based noiseless signal and n(t) represents the electrical and structural noise. The parameter vector Θm is defined as Θm = [α1m α2m βm fcm φm τm] which contains all the unknown parameters of the problem, the bandwidth factor α1m, the chirp rate α2m, the amplitude βm, the center frequency fcm, the phase φm, and the arrival time τm.
2.2 The structure of SSP-MPSD
The overall system diagram of SSP-MPSD is given in Fig. 1, including a pre-process (i.e., SSP) and post-process (i.e., MPSD). SSP technique [4] splits the received wide band signal into a group of diverse frequency narrow band signals exhibiting different SNR, and subsequently recombine those using non linear techniques in order to increase this SNR. The principle of this technique is illustrated in Fig. 1. The performance of the SSP is sensitive to four parameters which are the number of filters used for splitting spectrum, the filter band width, the step frequency between filters and the position of passband filter (the frequency center of the first and the last filter) [21].
Fig. 1.The structure of SSP-MPSD
The reconstruction stage of SSP output may be achieved by several non linear algorithms to improve SNR of the input signal. In this work, we use the arithmetic mean [22] defined as:
Where xi(t) i=1,2,…,N represent the narrowband output signals. The arithmetic mean essentially acts as a band pass filter since it linearly combines the sampled waveforms from different frequency regions of the input wide band signal.
In this work, we use the constant-Q decomposition. SSP algorithm gives better results when the decomposition is achieved by constant-Q filters as shown in [23] (see Fig. 2).
Fig. 2.Frequency response of the constant-Q filter bank Q is the quality factor defined as Q=fi/bi , with fi the center frequency and bi the band width of filters.
In this work the SSP described above presents only signal features and can be viewed as an initial stage of signal processing. While SSP can provide signal features, we still need another algorithm to detect the echoes, so the MPSD has been introduced for this aim. MPSD algorithm has been developed based on the matching pursuit signal decomposition and the Maximum Likelihood Estimation [20]. The matching pursuit (MP) algorithm is an adaptive signal decomposition technique that is energy conservative [24]. The MP algorithm first matches a function to the original signal. Then, this best matching function is subtracted from the signal to obtain the signal residue. At each iteration a new function is matched to the current signal residue. When the energy of signal residue is a fraction of the energy of the original signal the decomposition is completed. The final decomposition is a linear expansion of all chosen matching functions. In the original matching pursuit algorithm, the best match criterion uses correlation criteria to determine the best matching function. The real challenge of matching pursuit signal decomposition is that different matching criteria can produce different decomposition results [24-25]. In the optimization stage of the matching pursuit signal decomposition (MPSD) algorithm, the signal residue is represented by a chirplet function and the remaining signal (i.e. next residue),
Here, Rns is the current signal residue z(t) , Rn+1s is the next signal residue and g(t;Θ) is a chirplet echo
Where Θ = [α1 α2 β fc φ τ] denotes the parameter vector of g(t;Θ) . If we assume Rn+1s has white Gaussian noise characteristics, the MLE of the parameter vector Θ can be obtained by minimizing:
In summary, the iterative MPSD algorithm can be briefly stated as follows [20]:
(1) Initialization: Set iteration index n=0 and first signal residue Rns = z(t) . (2) Find the best parameter vector of the chirplet function: ΘMLE=argΘmin‖Rns−gΘ(t)‖2, and set gn=g(t; Θn). (3) Update: Compute the next residue Rn+1s = Rns − gn (4) Check convergence: If≤Threshold , stop the iterative procedure; else; n = n +1and go to Step 2. Jump to step 2 and go on.
In the next section we applied both simulated and experimental ultrasonic signals to test SSP-MPSD algorithm, and show its performance.
3. Simulation Study
In this section we evaluate the robustness of the proposed SSP-MPSD algorithm compared to our previous work [7]. For easy comparison with previous published results, we have used the same ultrasonic synthetic signal with different levels of signal to noise ratio. We simulated ultrasonic signal with two echoes. The frequency is supposed to be centered at 2.25Mhz. The parameter Δτ or the time difference of arrival (TDOA) of ultrasonic echoes has then been modified, varying from 0.1㎲ to 1㎲. The SSP-MPSD, SSP-PT and deconvolution by EM algorithm have been applied for estimating Δτ and the backscattered signal has been reconstructed. Fig. 3 shows the error (in %), between the simulated and the reconstructed signal, as a function of the distance Δτ.
Fig. 3.(a) Error Δτ measurement with noise less signal; (b) Error Δτ measurement with SNR=20dB
In Figs. 3(a) and Fig. 3(b), we can note that the noise level does not have a large influence on the SSP-PT, but this method does not give a good detection. The results obtained by the deconvolution method are very similar to the SSP-MPSD method in the case of noiseless signal. In the case of noisy signal the detection efficiency of SSP-MPSD is better than that of the deconvolution and the SSP-PT. Based on these simulations; the best results were obtained with the SSP-MPSD method.
4. Experimental Results and Discussion
Experimental tests were performed on three specimens of carbon fiber reinforced polymer multi-layered composite materials (CFRP), provided by an aircraft manufacturer company. Typically, delaminations in thin composite laminates are detectable by an immersion transducer operating in pulse-echo mode. Fig. 4 shows schematic diagram of the experimental system. The three samples contain three different types of delamination defects. Multiple signals are reflected from the surfaces of the specimen as well as from delaminations, as shown in Fig. 4.
Fig. 4.Schematic diagram of the experimental system
The thickness and the delamination depth in the material can be given using the equation:
where, Vsample is the velocity of ultrasound in the material; τFS represents the time location of the ultrasonic front surface echo; τB represents the time location of the ultrasonic first back wall echo of the sample; τd represents the defect echo location of the delamination zone; (τd,B - τFS) represents the pulse-echo time delay between a front surface and back wall echoes or delamination echoes.
The signals are obtained using tow transducers centered at frequency 2.25Mhz and 5Mhz, with quality factor 1.8 and 1.92, respectively. Longitudinal waves are used, the sound velocity in this material is Vsample=2830m/s.
The specimen (A) is made of eight layers joined with epoxy, one layer on the other altering the orientation from (0°, 45°). This specimen is divided in two zones (Fig. 5):
- The 1st zone is an undamaged zone with 2.7mm thickness. - The 2nd zone is a damaged zone. The delamination defect is a Teflon blade, with 0.6mm thickness, situated before the end of the last layer (i.e. between layers 7 and 8).
Fig. 5.Geometry and dimension of the CFRP specimen (A) (delamination defect is a Teflon blade situated between layers 7 and 8)
Fig. 6 (a) shows the measured echoes reflected from the front and back surfaces of CFRP specimen (A) in the undamaged zone with 2.25Mhz transducer. Three echoes can be found in the signal: The first echo represents the front surface echo, the second echo represents the first back wall echo and the third echo represents the second back wall echo. The results obtained by the three methods are shown in Fig. 6 (b). The time difference of arrival (TDOA) obtained by deconvolution Δτdeconv=1.89㎲, by SSP-PT method ΔτSSP-PT=1.87㎲ and by SSP-MPSD method ΔτSSP-MPSD=1.91㎲, corresponding to the detection error 1.1%, 2.2% and 0%, respectively. The average error is about 1%.
Fig. 6 (c) shows the measured ultrasonic signal on specimen (A) in the undamaged zone with 5 Mhz transducer. Fig. 6 (d) shows the TDOA results obtained by deconvolution Δτdeconv=1.89㎲, by SSP-PT method ΔτSSP-PT=1.68㎲ and by SSP-MPSD method ΔτSSP-MPSD=1.89㎲, corresponding to the detection error 1.1%, 12% and 1%, respectively. The average error is about 4.7%. It is important to note that here (i.e., in the case of 5Mhz transducer) the SSP-PT gives a high error compared to the deconvolution and SSP-MPSD.
Fig. 6.Experimental signals of specimen(A) in undamaged zone, (a) with 2.25Mhz transducer frequency, (b) Results obtained by deconvolution, SSP-PT and SSP-MPSD (Q =5, filters number=10 and f1 =0.9 Mhz), (c) with 5Mhz transducer frequency, (d) Results obtained by deconvolution, SSP-PT and SSP-MPSD (Q =5, filters number = 10 and f1 = 2.45 Mhz)
Fig. 7 (a) shows the measured echoes of the CFRP specimen (A) in damaged zone with 2.25Mhz transducer. Three echoes can be found in the signal: The first echo represents the front surface echo; the second echo represents the defect echo location of the delamination zone and the third echo represents the first back wall echo. After estimation by all methods (see Fig. 7 (b)), the delamination defect is detected by deconvolution method at a depth of τd-deconv=1.55㎲, by SSP-PT method at a depth of τd-SSP-PT=1.59㎲ and by SSP-MPSD method at a depth of τd-SSP-MPSD=1.67㎲.
Fig. 7 (c) shows the measured ultrasonic signal on specimen (A) in damaged zone with 5Mhz transducer. Fig. 7 (d) shows the results, the delamination defect is detected by deconvolution method at a depth of τd-deconv=1.41㎲, by SSP-PT method at a depth of τd-SSP-PT=1.37㎲ and by SSP-MPSD method at a depth of τd-SSP-MPSD=1.39㎲.
Fig. 7.Experimental signals of specimen (A) in damaged zone, (a) with 2.25Mhz transducer frequency, (b) Results of (a) obtained by deconvolution, SSP-PT and SSP-MPSD (Q =5, filters number =9 and f1 = 1.4Mhz), (c) with 5Mhz transducer frequency, (d) Results of (c) obtained by deconvolution, SSP-PT and SSP-MPSD (Q = 5, filters number = 10 and f1 = 2.45Mhz)
In the case of delamination defect with 2.25Mhz transducer, the average error is about 3% compared to the average error of 10% in the case of 5Mhz transducer.
The obtained results on CFRP Specimen (A) with the three methods are tabulated in Table 1 in terms of the time difference of arrival (TDOA), the thickness of the specimen, the position of the delamination, and the error in %.
Table 1.Thickness of the specimen (A) and depth of defect with error in %
We can note that the SSP-MPSD gives an average error of 1% in the case of thickness measurement. This result provides evidence of the good performance of SSP-MPSD method which has improved accuracy in the estimation of echo arrival time.
The specimen (B) is made of eight layers joined with epoxy, one layer on the other altering the orientation from (0°, 45°). This specimen is divided in two zones (see Fig. 8):
- The 1st zone is an undamaged zone with 2.9mm thickness. - The 2nd zone is a damaged zone. The delamination defect is a zone without epoxy situated in the middle of the specimen (i.e. between layers 4 and 5).
Fig. 8.Geometry and dimension of the CFRP specimen (B)
Fig. 9 (a) shows the measured echoes of the CFRP specimen (B) in damaged zone with 2.25Mhz transducer. After estimation by all methods (see Fig. 9(b)), the delamination defect is detected by deconvolution method at a depth of τd-deconv=1.19㎲, by SSP-PT method at a depth of τd-SSP-PT=1.46㎲ and by SSP-MPSD method at a depth of τd-SSP-MPSD=1.1㎲, corresponding to the detection error 12%, 37% and 3%, respectively.
Fig. 9 (c) shows the measured ultrasonic signal on specimen (B) in damaged zone with 5Mhz transducer. Fig. 9d shows the results, the delamination defect is detected by deconvolution method at a depth of τd-deconv=1.05㎲, by SSP-PT method at a depth of τd-SSP-PT=1.03㎲ and by SSPMPSD method at a depth of τd-SSP-MPSD=1.07㎲, corresponding to the detection error 1.3%, 3% and 0.6%, respectively.
Fig. 9.Experimental signals of specimen (B) in damaged zone, (a) with 2.25 Mhz transducer frequency, (b) Results of (a) obtained by deconvolution, SSP-PT and SSP-MPSD (Q =5, filters number = 9 and f1 = 1 Mhz), (c) with 5Mhz transducer frequency, (d) Results obtained by deconvolution, SSP-PT and SSP-MPSD (Q =5, filters number = 9 and f1 = 2.4 Mhz).
We can note that the SSP-MPSD gives a better result, in the case of 2.25Mhz transducer the error is about 3% and 0.6% in the case of 5Mhz transducer.
The obtained results on CFRP Specimen (B) are recapitulated in Table 2.We can note that the SSP-MPSD gives an average error of 2% in the case of thickness measurement and detection of delamination.
Table 2.Thickness of the specimen (B) and depth of defect with error in %
The specimen (C) is made of eight layers joined with epoxy, one layer on the other altering the orientation from (0°, 90°). This specimen is divided in two zones (see Fig. 10):
- The 1st zone is an undamaged zone with 3.1mm thickness. - The 2nd zone is a damaged zone. The delamination defect is a nylon sheet, with 0.1mm thickness situated in the middle of the part (i.e. between layers 4 and 5).
Fig. 10.Geometry and dimension of the CFRP specimen (C) (delamination defect is a nylon sheet situated between layers 4 and 5).
Fig. 11(a) shows the measured echoes of the CFRP specimen (C) in damaged zone with 2.25Mhz transducer. After estimation from all methods (see Fig. 11(b)), the delamination defect is detected by deconvolution method at a depth of τd-deconv=1.17㎲, by SSP-PT method at a depth of τd-SSP-PT=1.27㎲ and by SSP-MPSD method at a depth of τd-SSP-MPSD=1.13㎲, corresponding to the detection error 6.4%, 15% and 2.5%, respectively.
Fig. 11.Experimental signals of specimen (C) in damaged zone, (a) with 2.25Mhz transducer frequency, (b) Results of (a) obtained by deconvolution, SSP-PT and SSP-MPSD (Q =5, filters number = 9 and f1 = 0.9Mhz), (c) with 5Mhz transducer frequency, (d) Results obtained by deconvolution, SSP-PT and SSP-MPSD (Q =5, filters number =9 and f1= 2.4 Mhz)
Fig. 11(c) shows the measured ultrasonic signal on specimen (C) in damaged zone with 5Mhz transducer. Fig. 11(d) shows the results, the delamination defect is detected by deconvolution method at a depth of τd-deconv=1.06㎲, by SSP-PT method at a depth of τd-SSP-PT=1.2㎲ and by SSPMPSD method at a depth of τd-SSP-MPSD=1.06㎲. corresponding to the detection error 3.8%, 9% and 3.8%, respectively.
We can note that the SSP-MPSD gives a better result, in the case of 2.25Mhz transducer, the error is about 2.5%.
The obtained results on CFRP Specimen (C) are recapitulated in Table 3.
Table 3.Thickness of the specimen (C) and depth of defect with error in %
5. Conclusions
In this work, three types of delamination defects (Teflon, Air and Nylon) were inserted into carbon fiber reinforced polymer multi-layered composite materials. The tests were carried out by two broad band ultrasonic transducer of frequencies 2.25Mhz and 5Mhz, with same quality factor. The aim of these tests is to check the performances of the algorithms (Deconvolution, SSP-PT and SSP-MPSD) in determining defects position and resolution of detected defect position.
In consideration of the obtained results (Tables 1,2 and 3); when the defect is close to the back face, increasing the frequency does not improve the resolution, since the error of localization by SSP-MPSD method passed from 7% to 10% for the frequencies of 2.25Mhz and 5Mhz, respectively. This is explained by the attenuation of the materials which altered the quality of the obtained signals.
The comparison of the three types of defects gave the following results:
- The presence of a Teflon layer is precisely detected by the deconvolution (0.4%). - As for the layers of air or nylon in material, it is recommended to use SSP-MPSD which gives a more precise localization around 3%. In the case of thickness measurement of the composite samples, we can note that SSP-PT method gives an average error of 7.76%, the deconvolution gives an average error of 2.77% and SSP-MPSD method gives an average error of 1.33%. The obtained results show that the error on the thickness measurement is lower with SSP-MPSD method. In conclusion, we can note that the SSPMPSD method can locate with accuracy the reflected echoes on CFRP composite materials.
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피인용 문헌
- Signal Quality Improvement Using a New TMSSE Algorithm: Application in Delamination Detection in Composite Materials vol.36, pp.1, 2017, https://doi.org/10.1007/s10921-017-0398-4