[1] [1] Hayes R A, Feenstra B J. Video-speed electronic paper based on electrowetting[J]. Nature, 2003, 425(6956): 383–385.

[3] [3] Van Dijk R, Feenstra B J, Hayes R A, et al. 68. 3: Gray scales for video applications on electrowetting displays[J]. SID Sym-posium Digest of Technical Papers, 2006, 37(1): 1926–1929.

[4] [4] Jung H Y, ChoiU C, Park S H, et al. P-48: Development of driver IC with novel driving method for the electrowetting dis-play[J]. SID Symposium Digest of Technical Papers, 2012, 43(1): 1239–1242.

[5] [5] Zhang X M, Bai P F, Hayes R A, et al. Novel driving methods for manipulating oil motion in electrofluidic display pixels[J]. Jour-nal of Display Technology, 2016, 12(2): 200–205.

[6] [6] Chen Y C, ChiuY H, Lee W Y, et al. 56.3: A charge trapping suppression method for quick response electrowetting dis-plays[J]. SID Symposium Digest of Technical Papers, 2010, 41(1): 842–845.

[7] [7] Yi Z C, Shui L L, WangL, et al. A novel driver for active matrix electrowetting displays[J]. Displays, 2015, 37: 86–93.

[9] [9] Li F, Liu J H,Li G, et al. Displaying digital camera video on DVI monitor based on FPGA[J]. Laser & Infrared, 2011, 41(11): 1258–1262.

[10] [10] Shukla S, Chaudhari J P, Nayak R J, et al. Design of High-Speed LVDS data communication link using FPGA[C]//International Conference on Information and Com-munication Technology for Intelligent Systems. Cham, 2017: 1–9.

[11] [11] Luo Z, Tang Q S, Chen K, et al. Design of reconfigurable video scaling systems based on FPGA[J]. Electronic Science & Technology, 2017, 30(7): 83–86.

[12] [12] Chen Y C, ChiuY H, Lee W Y, et al. 56.3: A charge trapping suppression method for quick response electrowetting dis-plays[J]. SID Symposium Digest of Technical Papers, 2012, 41(1): 842–845.

[15] [15] Liang C C, Chen Y C, Chiu Y H, et al. 27.3: A decoupling driving scheme for low voltage stress in driving a large-area high-resolution electrowetting display[J]. SID Symposium Di-gest of Technical Papers, 2009, 40(1): 375–378.