[1] CARBONE J, YABO A, OLIVA D. Characterization and modelling of looming-sensitive neurons in the crab Neohelice[J]. Journal of comparative physiology A, 2018, 204(5):487-503.
[2] TOMSIC D, SZTARKER J, BERóN DE ASTRADA M, et al. The predator and prey behaviors of crabs:from ecology to neural adaptations[J]. Journal of experimental biology, 2017, 220(13):2318-2327.
[3] MEDAN V, DE ASTRADA M B, SCARANO F, et al. A network of visual motion-sensitive neurons for computing object position in an arthropod[J]. Journal of neuro science, 2015, 35(17):6654-6666.
[4] OLIVA D, TOMSIC D. Computation of object approach by a system of visual motion-sensitive neurons in the crab Neohelice[J]. Journal of neurophysiology, 2014, 112(6): 1477-1490.
[5] LUAN H, FU Q, ZHANG Y, et al. A looming spatial localization neural network inspired by MLG1 neurons in the crab neohelice[J]. Frontiers in neuroscience, 2022, 15:787256.
[6] BAHL A, SERBE E, MEIER M, et al. Neural mechanisms for Drosophila contrast vision[J]. Neuron, 2015, 88(6):1240-1252.
[7] DREWS M S, LEONHARDT A, PIROGOVA N, et al. Dynamic signal compression for robust motion vision in flies[J]. Current biology, 2020, 30:209-221.
[8] WIENECKE C F R, CLANDININ T R. Drosophila vision: an eye for change[J]. Current biology, 2020, 30(2): R66-R68.
[9] RIND F C, BRAMWELL D I. Neural network based on the input organization of an identified neuron signaling impending collision[J]. Journal of neurophysiology, 1996, 75(3):967-985.
[10] SUN P, Lü L, QIN J. Moving object extraction based on saliency detection and adaptive background model[J]. Optoelectronics letters, 2020, 16(1):59-64.