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Quantum Information Processing

Erschienen in:

01.06.2020

Quantum circuit design of approximate median filtering with noise tolerance threshold

verfasst von: HaiYing Xia, YuFang Xiao, ShuXiang Song, HaiSheng Li

Erschienen in: Quantum Information Processing | Ausgabe 6/2020

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Abstract

Quantum median filtering is an important step for many quantum signal processing algorithms. Current quantum median filtering designs show limitations in either computational complexity or incomplete noise detection. We propose a design of quantum median filtering, which uses approximate median filtering with noise tolerance threshold to remove salt-and-pepper noise. Instead of calculating the median, we search an approximate median by sorting four times, which reduces the computational complexity from \(O\left( {21{q^2} + 63q} \right) \) to \(O\left( {12{q^2} + 36q} \right) \). Here, q is the qubit used to represent the gray value. Furthermore, we adopt a two-level threshold to detect the noise points as much as possible. Finally, we design a complete quantum circuit to implement the approximate median filtering. The computational complexity of our proposed circuit is \(O\left( {10{n^2} + 14{q^2}} \right) \) for a NEQR quantum image with a size of \({2^n} \times {2^n}\). The complexity analysis shows that our proposed method significantly speeds up the filtering process compared with the classical filtering methods and the existing quantum filtering methods. In addition, the simulation results prove the proposed approximate median filtering is feasible.

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Nielsen, M.A., Chuang, I.L.: Quantum Computation and Quantum Information. Cambridge University Press, Cambridge (2010)MATH

Li, H.S., Chen, X., Xia, H.Y., et al.: A quantum image representation based on bitplanes. IEEE Access 6, 62396–62404 (2018)

Vlasov, A.Y.: Quantum computations and images recognition. arxiv:quant-ph/9703010 (1997). Accessed 20 Oct 2018

Beach, G., Lomont, C., Cohen, C.: Quantum image processing. In: Proceedings of the 32nd IEEE Conference Applied Imagery Pattern Recognition, Bellingham, WA, USA, 39-44 (2003)

Iliyasu, A.M.: Roadmap to talking quantum movies: a contingent inquiry. IEEE Access 7(99), 23864–23913 (2019)

Venegasandraca, S.E.: Storing, processing, and retrieving an image using quantum mechanics. Proc. SPIE Int. Soc. Opt. Eng. 5105(8), 1085–1090 (2003)

Latorre, J.I.: Image compression and entanglement. arxiv:quant-ph/0510031 (2005). Accessed 18 Feb 2019

Venegas-Andraca, S.E., Ball, J.L.: Processing images in entangled quantum systems. Quantum Inf. Process. 9(1), 1–11 (2010)MathSciNet

Le, P.Q., Dong, F., Hirota, K.: A flexible representation of quantum images for polynomial preparation, image compression, and processing operations. Quantum Inf. Process. 10(1), 63–84 (2011)MathSciNetMATH

10.

Yan, F., Iliyasu, A.M., Venegas-Andraca, S.E.: A survey of quantum image representations. Quantum Inf. Process. 15, 1–35 (2016)ADSMathSciNetMATH

11.

Zhang, Y., Lu, K., Gao, Y.: NEQR: a novel enhanced quantum representation of digital images. Quantum Inf. Process. 12(8), 2833–2860 (2013)ADSMathSciNetMATH

12.

Sun, B., Iliyasu, A.M., Yan, F., Dong, F., et al.: An RGB multi-channel representation for images on quantum computers. J. Adv. Comput. Intell. Intell. Info 17(3), 404–417 (2013)

13.

Yuan, S., Mao, X., Xue, Y., et al.: SQR: a simple quantum representation of infrared images. Quantum Inf. Process. 13(6), 1353–1379 (2014)ADSMathSciNetMATH

14.

Li, H., Zhu, Q., Zhou, R., et al.: Multi-dimensional color image storage and retrieval for a normal arbitrary quantum superposition state. Quantum Inf. Process. 13(4), 991–1011 (2014)ADSMathSciNetMATH

15.

Zhang, Y., Lu, K., Gao, Y., et al.: A novel quantum representation for log-polar images. Quantum Inf. Process. 12(9), 3103–3126 (2013)ADSMathSciNetMATH

16.

Le, P.Q., Iliyasu, A.M., Dong, F., et al.: Fast geometric transformations on quantum images. IAENG Int. J. Appl. Math. 40(3), 113–123 (2010)MathSciNetMATH

17.

Le, P.Q., Iliyasu, A.M., Dong, F., et al.: Strategies for designing geometric transformations on quantum images. Theor. Comput. Sci. 412(15), 1406–1418 (2011)MathSciNetMATH

18.

Wang, J., Nan, Jiang, Luo, Wang: Quantum image translation. Quantum Inf. Process. 14(5), 1–16 (2014)MathSciNet

19.

Fan, P., Zhou, R.G., Jing, N., et al.: Geometric transformations of multidimensional color images based on NASS. Inf. Sci. 340, 191–208 (2016)

20.

Zhou, R.G., Tan, C., Ian, H.: Global and local translation designs of quantum image based on FRQI. Int. J. Theor. Phys. 56(4), 1382–1398 (2017)MathSciNetMATH

21.

Iliyasu, A.M., Le, P.Q., Dong, F., et al.: Watermarking and authentication of quantum images based on restricted geometric transformations. Inf. Sci. 186(1), 126–149 (2012)MathSciNetMATH

22.

Zhang, Y., Lu, K., Xu, K., et al.: Local feature point extraction for quantum images. Quantum Inf. Process. 14(5), 1573–1588 (2015)ADSMathSciNetMATH

23.

Zhang, Y., Lu, K., Gao, Y.H.: QSobel: a novel quantum image edge extraction algorithm. Sci. China Inf. Sci. 58(1), 1–13 (2015)ADSMATH

24.

Jiang, N., Yijie, Dang, Wang, J.: Quantum image matching. Quantum Inf. Process. 15(9), 3543–3572 (2016)ADSMathSciNetMATH

25.

Dang, Y., Jiang, N., Hu, H., et al.: Analysis and improvement of the quantum image matching. Quantum Inf. Process. 16(11), 269 (2017) ADSMathSciNetMATH

26.

Li, H.S., Qingxin, Z., Lan, S., et al.: Image storage, retrieval, compression and segmentation in a quantum system. Quantum Inf. Process. 12(6), 2269–2290 (2013)ADSMathSciNetMATH

27.

Caraiman, S., Manta, V.I.: Image segmentation on a quantum computer. Quantum Inf. Process. 14(5), 1693–1715 (2015)ADSMathSciNetMATH

28.

Iliyasu, A.M., Le, P.Q., Dong, F., et al.: Watermarking and authentication of quantum images based on restricted geometric transformations. Inf. Sci. 186, 126–149 (2012)MathSciNetMATH

29.

Zhang, W.W., Gao, F., Liu, B., et al.: A watermark strategy for quantum images based on quantum Fourier transform. Quantum Inf. Process. 12(4), 793–803 (2013)ADSMathSciNetMATH

30.

Yang, Y.G., Jia, X., Xu, P., et al.: Analysis and improvement of the watermark strategy for quantum images based on quantum Fourier transform. Quantum Inf. Process. 12(8), 2765–2769 (2013)ADSMathSciNetMATH

31.

Song, X.H., Wang, S., Liu, S., et al.: A dynamic watermarking scheme for quantum images using quantum wavelet transform. Quantum Inf. Process. 12(12), 3689–3706 (2013)ADSMathSciNetMATH

32.

Song, X.H., Niu, X.M.: Comment on: novel image encryption/decryption based on quantum fourier transform and double phase encoding. Quantum Inf. Process. 13(6), 1301–1304 (2014)ADSMathSciNetMATH

33.

Hua, T., Chen, J., Pei, D., et al.: Quantum image encryption algorithm based on image correlation decomposition. Int. J. Theor. Phys. 54(2), 526–537 (2015)MATH

34.

Zhou, R.G., Wu, Q., Zhang, M.Q., et al.: Quantum image encryption and decryption algorithms based on quantum image geometric transformations. Int. J. Theor. Phys. 52, 1802–1817 (2013)MathSciNet

35.

Iliyasu, A.M., Le, P.Q., Dong, F., et al.: A framework for representing and producing movies on quantum computers. Int. J. Quantum Inf. 09(06), 1459–1497 (2011)MATH

36.

Yan, F., Iliyasu, A.M., Yang, H., et al.: Video encryption and decryption on quantum computers. Int. J. Theor. Phys. 54(8), 2893–2904 (2015)MathSciNetMATH

37.

Yan, F., Iliyasu, A.M., Khan, A.R., et al.: Measurements-based moving target detection in quantum video. Int. J. Theor. Phys. 55(4), 2162–2173 (3016)MATH

38.

Yan, F., Le, P.Q., Iliyasu, A.M., et al.: Assessing the similarity of quantum images based on probability measurements. In: 2012 IEEE Congress on Evolutionary Computation. Brisbane, Australia (2012)

39.

Yan, F., Iliyasu, A.M., Abdullah, et al.: A parallel comparison of multiple pairs of images on quantum computers. Int. J. Innov. Comput. Appl. 5, 199–212 (2016)

40.

Iliyasu, A.M., Yan, F., Kaoru, H.: Metric for estimating congruity between quantum images. Entropy 18(10), 360 (2016)ADS

41.

Liu, X.A., Zhou, R.G., El-Rafei, A.: Similarity assessment of quantum images. Quantum Inf. Process. 18(8), 244 (2019)ADS

42.

Zhou, R.G., Liu, X.A., Zhu, C., et al.: Similarity analysis between quantum images. Quantum Inf. Process. 17(6), 121 (2018)ADSMathSciNetMATH

43.

Lomont, C.: Quantum convolution and quantum correlation algorithms are physically impossible. arxiv:quant-ph/0309070 (2005). Accessed 20 Feb 2019

44.

Yuan, S., Lu, Y., Mao, X., Zhou, J., et al.: Quantum image filtering in the spatial domain. Int. J. Theor. Phys. 56(8), 1572–9575 (2017)

45.

Yuan, S., Lu, Y., Mao, X., et al.: Improved quantum image filtering in the spatial domain. Int. J. Theor. Phys. 57(3), 804–813 (2018)MathSciNetMATH

46.

Li, P., Liu, X., Xiao, H.: Quantum image weighted average filtering in spatial domain. Int. J. Theor. Phys. 56(11), 3690–3716 (2017)MATH

47.

Li, P., Liu, X., Xiao, H.: Quantum image median filtering in the spatial domain. Quantum Inf. Process. 17(3), 1573-1332 (2018)MathSciNet

48.

Jiang, S.X., Zhou, R.G., Hu, W.W., et al.: Improved quantum image median filtering in the spatial domain. Int. J. Theor. Phys. 58(7), 2115–2133 (2019)MathSciNetMATH

49.

Fan, P., Zhou, R.G., Hu, W.W., et al.: Quantum image edge extraction based on classical Sobel operator for NEQR. Quantum Inf. Process. 18(1), 1573-1332 (2019)MATH

50.

Dong, W., University, H., Kaifeng, et al.: Design of quantum comparator based on extended general toffoli gates with multiple targets. Comput. Sci. 39(9), 302–306 (2012)

51.

Barenco, A., Bennett, C.H., Cleve, R., et al.: Elementary gates for quantum computation. Phys. Rev. A 52(5), 3457–3467 (1995)ADS

Titel: Quantum circuit design of approximate median filtering with noise tolerance threshold
verfasst von: HaiYing Xia
YuFang Xiao
ShuXiang Song
HaiSheng Li
Publikationsdatum: 01.06.2020
Verlag: Springer US
Erschienen in: Quantum Information Processing / Ausgabe 6/2020
Print ISSN: 1570-0755
Elektronische ISSN: 1573-1332
DOI: https://doi.org/10.1007/s11128-020-02678-6

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