[1] P. Yeh, C. Gu. 3D displays: toward holographic video displays of 3D images. Chin. Opt. Lett., 11, 010901(2013).

[2] N. Kim, M. A. Alam, L. T. Bang, A. Phan, M. Piao, M. Erdenebat. Advances in the light field displays based on integral imaging and holographic techniques. Chin. Opt. Lett., 12, 60005(2014).

[3] D. Wang, Q. Wang, C. Shen, X. Zhou, C. Liu. Color holographic zoom system based on a liquid lens. Chin. Opt. Lett., 13, 072301(2015).

[4] X. Sui, Z. He, H. Zhang, L. Cao, D. Chu, G. Jin. Spatiotemporal double-phase hologram for complex-amplitude holographic displays. Chin. Opt. Lett., 18, 100901(2020).

[5] M. E. Lucente. Interactive computation of holograms using a look-up table. J. Electron. Imaging., 2, 28(1993).

[6] S. Jiao, Z. Zhuang, W. Zou. Fast computer generated hologram calculation with a mini look-up table incorporated with radial symmetric interpolation. Opt. Express., 25, 112(2017).

[7] T. Nishitsuji, T. Shimobaba, T. Kakue, N. Masuda, T. Ito. Fast calculation of computer-generated hologram using the circular symmetry of zone plates. Opt. Express., 20, 27496(2012).

[8] Y. Pan, X. Xu, S. Solanki, X. Liang, R. Tanjung, C. Tan, T. Chong. Fast CGH computation using S-LUT on GPU. Opt. Express., 17, 21(2009).

[9] P. W. M. Tsang, T. C. Poon, Y. M. Wu. Review of fast methods for point-based computer-generated holography [Invited]. Photon. Res., 6, 837(2018).

[10] X. Cao, M. Guan, L. Xia, X. Sang, Z. Chen. Highly efficient generation of holographic stereograms based on wavefront recording plane. Chin. Opt. Lett., 15, 120901(2017).

[11] H. Sannomiya, N. Takada, K. Suzuki, T. Sakaguchi, H. Nakayama, M. Oikawa, Y. Mori, T. Kakue, T. Shimobaba, T. Ito. Real-time spatiotemporal division multiplexing electroholography for 1,200,000 object points using multiple-graphics processing unit cluster. Chin. Opt. Lett., 18, 70901(2020).

[12] Y. Zhang, J. Liu, X. Li, A. Y. Wang. Fast processing method to generate gigabyte computer generated holography for three-dimensional dynamic holographic display. Chin. Opt. Lett., 14, 30901(2016).

[13] Y. Frauel, T. J. Naughton, O. Matoba, E. Tajahuerce, B. Javidi. Three-dimensional imaging and processing using computational holographic imaging. Proc. IEEE, 94, 636(2006).

[14] Z. Chen, X. Sang, Q. Lin, J. Li, X. Yu, X. Gao, B. Yan, C. Yu, W. Dou, A. L. Xiao. Acceleration for computer-generated hologram in head-mounted display with effective diffraction area recording method for eyes. Chin. Opt. Lett., 14, 80901(2016).

[15] S. Igarashi, T. Nakamura, M. Yamaguchi. Fast method of calculating a photorealistic hologram based on orthographic ray-wavefront conversion. Opt. Lett., 41, 1396(2016).

[16] R. H. Chen, T. D. Wilkinson. Computer generated hologram with geometric occlusion using GPU-accelerated depth buffer rasterization for three-dimensional display. Appl. Opt, 48, G21(2009).

[17] L. J. Rosenblum. Research issues in scientific visualization. IEEE Comput. Graph., 14, 61(1994).

[18] S. Napel, M. P. Marks, G. D. Rubin, M. D. Dake, C. H. McDonnell, S. M. Song, D. R. Enzmann, J. R. B. Jeffrey. CT angiography with spiral CT and maximum intensity projection. Radiology, 185, 607(1992).

[19] O. Kutter, R. Shams, N. Navab. Visualization and GPU-accelerated simulation of medical ultrasound from CT images. Comput. Meth. Prog. Bio., 94, 250(2009).

[20] Z. Lu, Y. Sakamoto. Holographic display methods for volume data: polygon-based and MIP-based methods. Appl. Opt., 57, A142(2018).

[21] Z. Lu, Y. Sakamoto. Holographic display method for volume data by volume rendering. Opt. Express., 27, 543(2019).

[22] M. Levoy. Display of surfaces from volume data. IEEE Comput. Graph., 8, 29(1988).