Objective

2

Visual information is the main source of human perception of outside information. The visual system of the human brain

as the most important means of obtaining information from the outside world

has a near-perfect information processing capability

which is far superior to existing computer vision systems in all aspects. The model description of the visual information processing mechanism can provide a novel way of solving engineering application problems

such as image analysis and understanding. Therefore

the study of the visual information processing mechanism has become an important direction in brain and cognitive science research. The complexity of the visual system lies in the complexity of information transmission between neurons; multiple information paths exist

and high cortical information demonstrates feedback regulation. Visual computing is an important means of studying visual information processing mechanisms and promoting the development of computer vision-related applications. Researchers can study the coding and processing of visual information from different ranges

such as microcosmic to macroscopic and molecular to behavioral

with the continuous improvement of the technical means of visual mechanism research. However

only the experimental data

which are organized organically from different levels and angles

can help determine the laws and mechanisms of nature. Contour detection is crucial to understanding the function and application of a high cortex visual perception.

Method

2

This study considers the process of visual information transmission by taking the entire visual paths as the object in studying the visual response characteristics of different mechanisms in the paths and constructing the visual fusion model of multiple visual pathways. The response model of the antagonistic mechanism of ganglion cells in the pathway is improved

the negative value of the primary contour response is preserved

and several features of the non-classical receptive field of the lateral geniculate nucleus are enhanced. We designed and implemented a multi-oriented simple cell receptive field model based on the DOG negative effect and constructed a visual fusion model of the complex cells of the primary visual cortex to suppress texture and enhance contours through the visual information differences among various visual pathways. We simulated the transmission and processing of visual information in the visual pathway. First

we realized the rapid extraction of primary contour information according to the antagonistic mechanism of ganglion cells. Then

the difference between the Gaussian function and the DOG function was constructed to simulate the modulation of the non-classical receptive field of the LGN

which could suppress the background texture. A multi-oriented receptive field model of a simple cell in the V1 region was constructed

and an improved evaluation model that considers the negative effect of DOG was proposed. A visual response fusion method based on parallel processing was provided to enhance target contour given the capability of the complex cells in the V1 region to represent advanced visual features.

Result

2

Visual test and quantitative calculation results show that the method has an enhanced contour detection capability in a natural image with complex background and can detect certain weak contour edge information in the image. The miss rate of the DG method is low

but the error rate is high. The CORF method reduces the error rate but increases the miss rate. The mistake rate of the CORF method is improved compared with the DG method

but the miss rate is increased. The overall performance of the CORF method remains low

although the overall performance is higher in the CORF method than in the DG method. The SSC method strengthens the texture suppression while retaining the main contour and achieving improved detection results. However

the SSC method produces additional burrs at the periphery of the main contour

thereby resulting in insufficiently smooth contour lines. The proposed method has clear background and contours

thereby effectively suppressing the background of the texture and enhancing the contour of the subject. The method achieves a certain balance between the error and miss rates

thus improving the overall performance. In addition

the method can effectively suppress the texture background of the adjacent area of the subject contour

in which the extracted contour lines are smooth

and the burr phenomenon in the SSC method is removed. This study selected 40 natural scene graphs from the RuG contour detection database for contour detection experiments and compared them using three typical methods of natural image contour detection

namely

DG

CORF

and SSC

to verify the effectiveness of the proposed method in the contour detection of natural scene images. Results show that the main contours detected by the method proposed in this paper are complete

and the image purity is high. Overall

results reflect the biological intelligence of the proposed contour detection method. The average P index of the proposed method is 0.45

which indicates a better contour detection performance than the contrast methods.

Conclusion

2

In this paper

we improved the classical receptive field responses of ganglion cells in the visual pathway. We studied the enhancement effect of the LGN cells in the visual pathway by considering the visual pathway the main body of the non-classical receptive field regulation mechanism. We focused on the negative effects of the DOG produced by the antagonistic mechanism of ganglion cells and designed a multi-oriented simple cell receptive field model. We introduced a parallel mechanism in multiple visual pathways for visual information processing

and the visual pathway was divided into the main and vice paths. We proposed a method that uses the visual information difference of the different visual pathways for suppressing the texture and enhancing the contours. The proposed method has enhanced natural contour detection and extraction capabilities

especially in detecting several weak contour edges in images. The new model constructed in this study will help in elucidating the function and internal mechanisms of the visual pathway and provide a new approach for image analysis and understanding based on visual mechanism.