Deep learning variable-density low-quality electronic speckle stripe direction extraction method

A technology of electronic speckle and deep learning, applied in neural learning methods, instruments, biological neural network models, etc., can solve problems such as poor contrast, low calculation signal-to-noise ratio, complex parameter adjustment, etc., and achieve the effect of high direction accuracy

Pending Publication Date: 2019-11-19
TIANJIN UNIV
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Problems solved by technology

Although there are many traditional methods for calculating the direction of texture images, for calculating the direction of low-quality speckle images with low signal-to-noise ratio, variable density, poor contrast, and fine stripes, the parameter adjustment is complicated, and the calculation results need to be improved.

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  • Deep learning variable-density low-quality electronic speckle stripe direction extraction method
  • Deep learning variable-density low-quality electronic speckle stripe direction extraction method
  • Deep learning variable-density low-quality electronic speckle stripe direction extraction method

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Embodiment Construction

[0034] In order to overcome the deficiencies of the prior art, the present invention aims to propose a new low-quality, variable-density electronic speckle interference (ESPI) fringe direction calculation method. The invention builds an end-to-end ESPI fringe pattern direction calculation network, and realizes the automatic batch direction field acquisition of multiple low-quality, variable-density electronic speckle interference fringe patterns.

[0035] The electronic speckle fringe batch automatic fringe direction field calculation method based on the FingerNet convolutional neural network, the specific technical solution adopted includes the following steps:

[0036] Step 1: Construct training data set and verification data set respectively;

[0037] Step 2: Construct a network model for calculating the direction of low-quality, variable-density electronic speckle stripes;

[0038] Step 3: optimize the parameters in the backpropagation process through the gradient descent...

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Abstract

The invention belongs to the technical field of optical detection and image processing, and relates to a deep learning variable-density low-quality electronic speckle stripe direction automatic acquisition method in order to realize batch full-automatic acquisition of a direction field for multiple low-quality variable-density ESPI stripe graphs, which comprises the following steps: 1, respectively constructing a training data set and a verification data set; 2, constructing a network model for calculating low-quality and variable-density electronic speckle stripe directions; 3, optimizing parameters in the back propagation process through a gradient descent method to perform model training; and 4, inputting the verification data set into the network, training the network model by using the training data set to obtain a model, verifying the model, testing the generalization ability of the model, and finally automatically obtaining the stripe direction by using the trained and verifiedmodel. The method is mainly applied to optical detection and image processing occasions.

Description

technical field [0001] The invention belongs to the technical field of optical detection and image processing, and relates to a batch automatic direction calculation method of electronic speckle interference fringes based on deep learning. Background technique [0002] Electronic speckle interferometry technology, as a modern optical measurement method developed on the basis of modern high-tech achievements, has the advantages of high accuracy, rapid response, and non-contact throughout the field. It has achieved good results in the measurement of three-dimensional surface topography of objects, the measurement of mechanical properties of materials, the measurement of in-plane displacement, vibration monitoring, and the measurement of thermal deformation of test pieces. However, there is strong granular noise in the speckle fringe image, which greatly limits the visibility and resolution of the fringe. In addition, the noise spectrum and the fringe spectrum are mixed togethe...

Claims

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Application Information

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Patent Type & Authority Applications(China)
IPC IPC(8): G06K9/46G06N3/04G06N3/08
CPCG06N3/084G06V10/462G06N3/048G06N3/045
Inventor 唐晨田璐璐
Owner TIANJIN UNIV
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