Restoration Method of Hadamard Coding Spectral Imager

Hadamard coding spectral imaging technology is a computational spectral imaging technology, which modulates the target’s spectral information and recovers the original spectrum by inverse transformation. Because it has the advantage of multichannel detection, it is being studied by more researchers. For the engineering realization of push-broom coding spectral imaging instrument, it will inevitably be subjected to push-broom error, template error and detection noise, the redundant sampling problem caused by detector. Therefore, three restoration methods are presented in this paper: firstly, the one is the least squares solution, the two is the zero-filling inverse solution by extending the coding matrix in the redundant coding state to a complete higher order Hadamard matrix, the three is sparse method. Secondly, the numerical and principle analysis shows that the inverse solution of zero-compensation has better robustness and is more suitable for engineering application; its conditional number, error expectation and covariance are better and more stable because it directly uses Hadamard matrix, which has good generalized orthogonality. Then, a real-time spectral reconstruction method is presented, which is based on inverse solution of zero-compensation. Finally, simulation analysis shows that spectral data could be destructed relative accuracy in the error condition; however, the effect of template noise and push error on reconstruction is much greater than that of detection error. Therefore, in addition to reducing the detection noise as much as possible, lower template noise and more accurate push controlling should be guaranteed specifically in engineering realization.

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Research on Heat Transfer Dynamic Characteristics of Composite Layer Based on Laplace Transform

10.20944/preprints201901.0272.v1 ◽

2019 ◽

Author(s):

Chunyu Xu ◽

Junhua Lin ◽

Wenhao Liu ◽

Yuanbiao Zhang

Keyword(s):

Heat Transfer ◽

Composite Materials ◽

Temperature Distribution ◽

Transfer Function ◽

Dynamic Characteristics ◽

Transfer Functions ◽

Composite Layer ◽

Engineering Application ◽

Second Order ◽

Inverse Transformation

This paper predict and effectively control the temperature distribution of the steady-state and transient states of anisotropic four-layer composite materials online, knowing the density, specific heat, heat conductivity and thickness of the composite materials. Based on the transfer function, a mathematical model was established to study the dynamic characteristics of heat transfer of the composite materials. First of all, the Fourier heat transfer law was used to establish a one-dimensional Fourier heat conduction differential equation for each composite layer, and the Laplace transformation was carried out to obtain the system function. Then the approximate second-order transfer function of the system was obtained by Taylor expansion, and the Laplace inverse transformation was carried out to obtain the transfer function of the whole system in the time domain. Finally, the accuracy of the simplified analytical solutions of the first, second and third order approximate transfer functions was compared with computer simulation. The results showed that the second order approximate transfer functions can describe the dynamic process of heat transfer better than others. The research on the dynamic characteristics of heat transfer in the composite layer and the dynamic model of heat transfer in composite layer proposed in this paper have a reference value for practical engineering application. It can effectively predict the temperature distribution of composite layer material and reduce the cost of experimental measurement of heat transfer performance of materials.

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Optimization of matching coded aperture with detector based on compressed sensing spectral imaging technology

Chinese Optics ◽

10.3788/co.20201302.0290 ◽

2020 ◽

Vol 13 (2) ◽

pp. 290-301

Author(s):

刘铭鑫 LIU Ming-xin ◽

张新 ZHANG Xin ◽

王灵杰 WANG Ling-jie ◽

史广维 SHI Guang-wei ◽

吴洪波 WU Hong-bo ◽

...

Keyword(s):

Compressed Sensing ◽

Spectral Imaging ◽

Coded Aperture ◽

Imaging Technology

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Research on classification and recognition system based on miniaturized portable spectral imaging technology

Infrared and Laser Engineering ◽

10.3788/irla201948.1023001 ◽

2019 ◽

Vol 48 (10) ◽

pp. 1023001

Author(s):

张晨 Zhang Chen ◽

刘舒扬 Liu Shuyang ◽

赵安娜 Zhao Anna ◽

王天鹤 Wang Tianhe ◽

贾晓东 Jia Xiaodong

Keyword(s):

Spectral Imaging ◽

Recognition System ◽

Imaging Technology

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Staring acousto-optic spectral imaging technology with area FPA and discussion on its application of unmanned aerial vehicle (UAV) platforms

Infrared and Laser Engineering ◽

10.3788/m0001820164502.203001 ◽

2016 ◽

Vol 45 (2) ◽

pp. 203001

Author(s):

何志平 He Zhiping ◽

秦侠格 Qin Xiage ◽

徐映宇 Xu Yingyu

Keyword(s):

Unmanned Aerial Vehicle ◽

Spectral Imaging ◽

Imaging Technology ◽

Aerial Vehicle

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Multi-Perspective Ultrasound Imaging Technology of the Breast with Cylindrical Motion of Linear Arrays

Applied Sciences ◽

10.3390/app9030419 ◽

2019 ◽

Vol 9 (3) ◽

pp. 419 ◽

Cited By ~ 3

Author(s):

Chang Liu ◽

Binzhen Zhang ◽

Chenyang Xue ◽

Wendong Zhang ◽

Guojun Zhang ◽

...

Keyword(s):

Chest Wall ◽

Ultrasound Imaging ◽

Ultrasonic Transducer ◽

Absolute Error ◽

Data Reconstruction ◽

Reconstruction Method ◽

Water Tank ◽

Volume Data ◽

Imaging Technology ◽

Linear Arrays

In this paper, we propose a multi-perspective ultrasound imaging technology with the cylindrical motion of four piezoelectric micromachined ultrasonic transducer (PMUT) rotatable linear arrays. The transducer is configured in a cross shape vertically on the circle with the length of the arrays parallel to the z axis, roughly perpendicular to the chest wall. The transducers surrounded the breast, which achieves non-invasive detection. The electric rotary table drives the PMUT to perform cylindrical scanning. A breast model with a 2 cm mass in the center and six 1-cm superficial masses were used for the experimental analysis. The detection was carried out in a water tank and the working temperature was constant at 32 °C. The breast volume data were acquired by rotating the probe 90° with a 2° interval, which were 256 × 180 A-scan lines. The optimized segmented dynamic focusing technology was used to improve the image quality and data reconstruction was performed. A total of 256 A-scan lines at a constant angle were recombined and 180 A-scan lines were recombined according to the nth element as a dataset, respectively. Combined with ultrasound imaging algorithms, multi-perspective ultrasound imaging was realized including vertical slices, horizontal slices and 3D imaging. The seven masses were detected and the absolute error of the size was approximately 1 mm where even the image of the injection pinhole could be seen. Furthermore, the breast boundary could be seen clearly from the chest wall to the nipple, so the location of the masses was easier to confirm. Therefore, the validity and feasibility of the data reconstruction method and imaging algorithm were verified. It will be beneficial for doctors to be able to comprehensively observe the pathological tissue.

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Recovering spectral images from compressive measurements using designed coded apertures and Matrix Completion Theory

Ingenieria y Universidad ◽

10.11144/javeriana.iyu21-2.rsic ◽

2017 ◽

Vol 21 (2) ◽

Author(s):

Tatiana Gelvez ◽

Hoover Rueda ◽

Henry Arguello

Keyword(s):

Imaging Techniques ◽

Matrix Completion ◽

Spectral Imaging ◽

Spatial Location ◽

Low Rank ◽

Coded Aperture ◽

Reconstruction Algorithms ◽

Spectral Image ◽

The Matrix ◽

Spectral Imager

<p>Spectral imaging aims to capture and process a 3-dimensional spectral image with a large amount of spectral information for each spatial location. Compressive spectral imaging techniques (CSI) increases the sensing speed and reduces the amount of collected data compared to traditional spectral imaging methods. The coded aperture snapshot spectral imager (CASSI) is an optical architecture to sense a spectral image in a single 2D coded projection by applying CSI. Typically, the 3D scene is recovered by solving an L1-based optimization problem that assumes the scene is sparse in some known orthonormal basis. In contrast, the matrix completion technique (MC) allows to recover the scene without such prior knowledge. The MC reconstruction algorithms rely on a low-rank structure of the scene. Moreover, the CASSI system uses coded aperture patterns that determine the quality of the estimated scene. Therefore, this paper proposes the design of an optimal coded aperture set for the MC methodology. The designed set is attained by maximizing the distance between the translucent elements in the coded aperture. Visualization of the recovered spectral signals and simulations over different databases show average improvement when the designed coded set is used between 1-3 dBs compared to the complementary coded aperture set, and between 3-9 dBs compared to the conventional random coded aperture set.</p>

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