|
|
|
|
|
|
Classification and Identification of Real or Fake Blood Based on OPO Pulsed Laser Induced Photoacoustic Spectroscopy |
REN Zhong1, 2*, LIU Tao1, LIU Guo-dong1, 2 |
1. Key Laboratory of Optic-Electronics and Communication, Jiangxi Science and Technology Normal University, Nanchang 330038, China
2. Key Laboratory of Optic-Electronic Detection and Information Processing of Nanchang City, Jiangxi Science and Technology Normal University, Nanchang 330038, China |
|
|
Abstract In order to rapidly and accurately achieve the identification of the real or fake blood, as well as recycled usage of blood, the photoacoustic spectroscopy was used in this work to establish a set of blood photoacoustic detection systems and to capture the photoacoustic signal of blood samples. Three kinds of animal blood (horse blood, cow blood, and rabbit blood), two kinds of fake blood (props blood and red ink), the total number of blood samples are 125 groups, were used as the experimental samples. The photoacoustic signals and photoacoustic peak-to-peak spectral of all blood samples at 700~1 064 nm were obtained. Photoacoustic experimental results show that the amplitude, profile, peak-point time, and peak-to-peak values of real and fake blood samples are different. To achieve the classification and identification of the real and fake blood with high precision, we used the wavelet neural network optimized by a genetic algorithm (WNN-GA) to train the 100 groups of samples for five kinds of blood in full wavelengths. Moreover, a kind of Morlet-like wavelet basis function was built. Then, 25 groups of blood samples were tested. Meanwhile, the GA algorithm was used to optimize the weights and thresholds of WNN network and the shift factor and stretch factor of wavelet basis function, and two learn factors can be adjusted. Compared with WNN, the correction rate of classification and identification for real and fake blood based on WNN-GA improved by 24%. Then, the principle components analysis (PCA) algorithm was used to extract the characteristic information of real or fake blood from the photoacoustic peak-to-peak full spectral. After that, the chosen principle components were trained and test by the WNN-GA algorithm. Results show that under 6 principle components, the algorithm of PCA-WNN-GA algorithm improves the correction rate of classification and identification for real and fake blood to 100%. Finally, compared with other the six algorithms, the correction rate of classification and identification for PCA-WNN-GA was superior to others. Therefore, the classification and identification of the real and fake blood can be well achieved via photoacoustic spectroscopy combined with the PCA-WNN-GA algorithm.
|
Received: 2020-09-25
Accepted: 2021-01-20
|
|
Corresponding Authors:
REN Zhong
E-mail: renzhong0921@163.com
|
|
[1] Archana N A N, Rita C, Manjunath N, et al. Clinica Chimica Acta, 2018, 485: 305.
[2] Xu G., Hu B., Chen G., et al. Biological Trace Element Research, 2015, 164(2): 192.
[3] Mclaughlin G, Doty K C, Lednev I K. Forensicence International, 2014, 238(5): 91.
[4] BAI Peng-li, WANG Jun, YIN Huan-cai, et al(白鹏利, 王 均, 尹焕才, 等). The Journal of Light Scattering(光散射学报), 2016, 28(2): 163.
[5] Ren Z, Liu G D, Huang Z, et al. International Journal of Optomechatronics, 2015, 9(3): 221.
[6] LÜ Peng-fei, LU Zhi-qian, HE Qiao-zhi, et al(吕鹏飞, 陆志谦, 何巧芝, 等). Optics and Precision Engineering(光学精密工程), 2019, 27(6): 1301.
[7] Mohamed F, Ali H. Discrete & Continuous Dynamical Systems, 2017, 22(2): 491.
[8] Ren Z, Liu G D, Huang Z, et al. Chinese Optics Letters, 2013, 11(S21701): 1.
[9] Juarez-Guerra E, Alarcon-Aquino V, Gomez-Gil P, et al. Journal of VLSI Signal Processing Systems for Signal, Image, and Video Technology, 2020, 92(2): 187.
[10] Yu W B, Zhao F Y. International Journal of Green Energy, 2019, 16(12): 938.
[11] CHEN Ming(陈 明). Matlabneural Network Principle and Example Precise Soulution (Matlab)(神经网络原理与实例精解). Beijing:Tsinghua University Press(北京:清华大学出版社), 2012. 164.
[12] Teymoori F, Asghari G, Mirmiran P, et al. Scientific Reports, 2017, 7(1): 16838. |
[1] |
ZHENG Hong-quan, DAI Jing-min*. Research Development of the Application of Photoacoustic Spectroscopy in Measurement of Trace Gas Concentration[J]. SPECTROSCOPY AND SPECTRAL ANALYSIS, 2024, 44(01): 1-14. |
[2] |
XU Qiu-yi1, 3, 4, ZHU Wen-yue3, 4, CHEN Jie2, 3, 4, LIU Qiang3, 4 *, ZHENG Jian-jie3, 4, YANG Tao2, 3, 4, YANG Teng-fei2, 3, 4. Calibration Method of Aerosol Absorption Coefficient Based on
Photoacoustic Spectroscopy[J]. SPECTROSCOPY AND SPECTRAL ANALYSIS, 2024, 44(01): 88-94. |
[3] |
FU Wen-xiang, DONG Li-qiang, YANG Liu*. Research Progress on Detection of Chemical Warfare Agent Simulants and Toxic Gases by Photoacoustic Spectroscopy[J]. SPECTROSCOPY AND SPECTRAL ANALYSIS, 2023, 43(12): 3653-3658. |
[4] |
CHENG Gang1, CAO Ya-nan1, TIAN Xing1, CAO Yuan2, LIU Kun2. Simulation of Airflow Performance and Parameter Optimization of
Photoacoustic Cell Based on Orthogonal Test[J]. SPECTROSCOPY AND SPECTRAL ANALYSIS, 2023, 43(12): 3899-3905. |
[5] |
CHEN Tu-nan1, 2, LI Kang1, QIU Zong-jia1, HAN Dong1, 2, ZHANG Guo-qiang1, 2*. Simulation Analysis and Experiment Verification of Insulating Material-Based Photoacoustic Cell[J]. SPECTROSCOPY AND SPECTRAL ANALYSIS, 2023, 43(09): 2922-2927. |
[6] |
JIN Hua-wei1, 2, 3, WANG Hao-wei1, 2, LUO Ping1, 2, FANG Lei1, 2. Simulation Design and Performance Analysis of Two-Stage Buffer
Photoacoustic Cell[J]. SPECTROSCOPY AND SPECTRAL ANALYSIS, 2023, 43(08): 2375-2380. |
[7] |
ZHENG Zhi-jie1, LIN Zhen-heng1, 2*, XIE Hai-he2, NIE Yong-zhong3. The Method of Terahertz Spectral Classification and Identification for Engineering Plastics Based on Convolutional Neural Network[J]. SPECTROSCOPY AND SPECTRAL ANALYSIS, 2023, 43(05): 1387-1393. |
[8] |
GUO Feng1, ZHAO Dong-e1*, YANG Xue-feng1, CHU Wen-bo2, ZHANG Bin1, ZHANG Da-shun3MENG Fan-jun3. Research on Hyperspectral Image Recognition of Iron Fragments[J]. SPECTROSCOPY AND SPECTRAL ANALYSIS, 2023, 43(04): 997-1003. |
[9] |
LIU Xin-yu1, SHAO Wen-wu2*, ZHOU Shi-rui3. Spectral Pattern Recognition of Cardiac Tissue in Electric Shock Death and Post-Mortem Electric Shock[J]. SPECTROSCOPY AND SPECTRAL ANALYSIS, 2023, 43(04): 1126-1133. |
[10] |
LI Zhen-gang1, 2, SI Gan-shang1, 2, NING Zhi-qiang1, 2, LIU Jia-xiang1, FANG Yong-hua1, 2*, CHENG Zhen1, 2, SI Bei-bei1, 2, YANG Chang-ping1, 2. Research on Long Optical Path and Resonant Carbon Dioxide Gas
Photoacoustic Sensor[J]. SPECTROSCOPY AND SPECTRAL ANALYSIS, 2023, 43(01): 43-49. |
[11] |
HU Yi-bin1, BAO Ni-sha1, 2*, LIU Shan-jun1, 2, MAO Ya-chun1, 2, SONG Liang3. Research on Hyperspectral Features and Recognition Methods of Typical Camouflage Materials[J]. SPECTROSCOPY AND SPECTRAL ANALYSIS, 2023, 43(01): 297-302. |
[12] |
CHEN Si-ying1, JIA Yi-wen1, JIANG Yu-rong1*, CHEN He1, YANG Wen-hui2, LUO Yu-peng1, LI Zhong-shi1, ZHANG Yin-chao1, GUO Pan1. Classification and Recognition of Adulterated Manuka Honey by
Multi-Wavelength Laser-Induced Fluorescence[J]. SPECTROSCOPY AND SPECTRAL ANALYSIS, 2022, 42(09): 2807-2812. |
[13] |
YANG Jie-kai1, GUO Zhi-qiang1, HUANG Yuan2, 3*, GAO Hong-sheng1, JIN Ke1, WU Xiang-shuai2, YANG Jie1. Early Classification and Detection of Melon Graft Healing State Based on Hyperspectral Imaging[J]. SPECTROSCOPY AND SPECTRAL ANALYSIS, 2022, 42(07): 2218-2224. |
[14] |
ZHENG Yi1, 2, 3, WANG Yao1, 2, LIU Yan1, 2*. Study on Classification and Recognition of Mountain Meadow Vegetation Based on Seasonal Characteristics of Hyperspectral Data[J]. SPECTROSCOPY AND SPECTRAL ANALYSIS, 2022, 42(06): 1939-1947. |
[15] |
WANG Qi, WANG Shi-chao, LIU Tai-yu, CHEN Zi-qiang. Research Progress of Multi-Component Gas Detection by Photoacoustic Spectroscopy[J]. SPECTROSCOPY AND SPECTRAL ANALYSIS, 2022, 42(01): 1-8. |
|
|
|
|