Influence of Unequilateral Apertures of the "Trunced Pyramid" and "Double Pyramid" Laplacian Digital Filters on the Accuracy of Television Measuring Systems

封面

如何引用文章

全文:

开放存取 开放存取
受限制的访问 ##reader.subscriptionAccessGranted##
受限制的访问 订阅存取

详细

In the modern world, digital image processing requires increasing the speed of the processing methods and algorithms used. One way to improve performance is to transform spatial filters into filters with a recursively separable form of implementation. The recursion property implies the use of previous output values of a function to form the current sample. The property of separability is understood as division into processing by column and row of a matrix of digital image values. The transformation of spatial filters consists of changing the aperture of the masks into a non-orthogonal (non-equilateral) form, which reduces the number of computational operations and speeds up the processing process, while maintaining its efficiency. The paper presents a description of the non-equilateral apertures of the previously developed “truncated pyramid” and “double pyramid”Laplacian digital filters. For non-equilateral apertures, results were obtained for the first time on their use for television measuring systems. From which it can be seen that a “truncated pyramid” Laplacian filter with non-equilateral processing apertures is recommended for use in TIS, since it increases the efficiency of measuring the range to objects of interest while reducing processing time. Based on the results of processing with modified filters, sets of processed images were obtained for each of the 10 original images. For each set of processed images, measurements of the peak signal-to-noise ratio, standard deviation and selection of the optimal central coefficient of the filter mask were carried out, for subsequent assessment of the effectiveness of processing with modified filters. The assessment of the influence of recursively separable “truncated pyramid” and “double pyramid” Laplacian filters with non-equilateral aperture masks on the accuracy of television measurement systems consisted of considering their influence on measuring the distance (from the camera) to the object of interest in the image, when – control of processing time. Based on the evaluation results, we can conclude that by using pre-processing of images with modified digital filters, the accuracy of measuring the distance from the camera to the measurement object is improved, while reducing processing time.

全文:

受限制的访问

作者简介

K. Rylov

Tomsk State University of Control Systems and Radioelectronics

编辑信件的主要联系方式.
Email: tstr70@mail.ru
俄罗斯联邦, Tomsk

K. Kupriyanova

Tomsk State University of Control Systems and Radioelectronics

Email: kuprianovak8@gmail.com
俄罗斯联邦, Tomsk

A. Kamensky

Tomsk State University of Control Systems and Radioelectronics

Email: andru170@mail.ru
俄罗斯联邦, Tomsk

参考

  1. Kuryachiy M.I., Rudnikovich A.S., Semenov E.V. [Television measuring systems based on TMS320C6000 processors]. Televizionnye izmeritel'nye sistemy na baze processorov TMS320C6000 // Reports of the international conference DSPA. 2003. V. 2. No. 52. P. 1–4.
  2. Korotaev V.V., Krasnyashchikh A.V. [Television measuring systems]. Televizionnye izmeritel'nye sistemy; Textbook. St. Petersburg: St. Petersburg State University ITMO, 2008. 108 p.
  3. Gonzalez R.S., Woods R.E. [Digital image processing]. Cifrovaya obrabotka izobrazhenij. 3rd edition, corrected and expanded. M.: Tekhnosphere, 2012. 1104 p.
  4. Chun He, Ke Guo, Huayue Chen. An Improved Image Filtering Algorithm for Mixed Noise; A special issue of Applied Sciences (ISSN 2076-3417), belongs to the section “Computing and Artificial Intelligence” // Appl. Sci. 2021. 11(21). 10358. https://doi.org/10.3390/app112110358
  5. Sironi A., Tekin B., Rigamonti R., Lepetit V., Fua P. Learning Separable Filters // IEEE Transactions on Pattern Analysis and Machine Intelligence. 2015. V. 37. I. 1. P. 94–106. https://doi.org/10.1109/TPAMI.2014.2343229
  6. Minh N. Do, Vetterli M. Frame reconstruction of the laplacian pyramid. Acoustics, Speech, and Signal Processing, 1988. ICASSP-88 // 1988 International Conference on 6: 3641–3644. V. 6.
  7. Kamenskiy A.V. High-speed recursive-separable image processing filters // Computer Optics 2022; 46(4): 659–665. https://doi.org/10.18287/2412-6179-CO-1063
  8. Kamenskiy A.V., Kuryachiy M.I., Krasnoperova A.S., Ilyin Y.V., Akaeva Т.М., Boyarkin S.E. / High-speed recursive-separable image processing filters with variable scanning aperture sizes // Computer Optics, 2023. 47(4): 605–613. https://doi.org/10.18287/2412-6179-CO-1240
  9. Sai S.V., Kamensky A.V., Kuryachiy M.I. [Modern methods of analyzing and improving the quality of digital images: monograph]. Sovremennye metody analiza i povysheniya kachestva cifrovyh izobrazhenij: monografiya; Ministry of Sciences and Higher Education of the Russian Federation, Pacific State University. Khabarovsk: Pacific Publishing House. state Univ., 2020. 173 p.
  10. Kupriyanova K.S., Rylov K.A., Kamenskiy A.V. [Study of the unevenness of the aperture edge on the characteristics of digital filters Laplacian “truncated pyramid” and Laplacian “double pyramid”]. Vliyanie neravnostoronnih apertur na harakteristiki cifrovyh fil'trov laplasian “usechennaya piramida” i laplasian “dvojnaya piramida” // Proceedings of the 33rd Int. conf. computer graphics and machine vision. Moscow, September 19–21. 2023. P. 482–491.
  11. Smirnov V.M. [Measuring the size of the aperture on the degree of limitation of impulse noise with median filtering]. Vliyanie razmera apertury na stepen' ustraneniya impul'snogo shuma pri mediannoj fil'tracii // Scientific session of the Guap. 2019. P. 22–29.
  12. Kapustin V.V., Zahlebin A.S., Movchan A.K., Kuriyachiy M.I., Kruticov M. Experimental assessment of the distance measurement accuracy using the active-pulse television measuring system and a digital terrain model // Computer Optics. 2022. V. 46(6): 948–954. https://doi.org/10.18287/2412-6179-CO-1114

补充文件

附件文件
动作
1. JATS XML
下载
2. Fig. 1. Structural diagram of the LTP

下载 (98KB)
索引源数据
3. Fig. 2. Structural diagram of the LDP

下载 (109KB)
索引源数据
4. Fig. 3. 7 × 5 mask of the LTP filter

下载 (44KB)
索引源数据
5. Fig. 4. 7 × 5 mask of the LDP filter

下载 (44KB)
索引源数据
6. Fig. 5. Algorithm of LR operation

下载 (148KB)
索引源数据
7. Fig. 6. Algorithm of FR operation

下载 (148KB)
索引源数据
8. Fig. 7. View of the polygon from the TMS location

下载 (187KB)
索引源数据
9. Fig. 8. Test images: a) TI No. 1 Transparant-1; b) TI No. 2 Transparant-3; c) TI No. 3 Transparant-2

下载 (132KB)
索引源数据
10. Fig. 9. Processing result of TI No. 1: a) original image; processed images: b) LTP filter, c) LDP filter

下载 (158KB)
索引源数据
11. Fig. 10. Processing result of TI No. 2: a) original image; processed images: b) LTP filter, c) LDP filter

下载 (139KB)
索引源数据
12. Fig. 11. Processing result of TI No. 3: a) original image; processed images: b) LTP filter, c) LDP filter

下载 (174KB)
索引源数据

版权所有 © Russian Academy of Sciences, 2024