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Neuromorphic vision sensors: Principle, progress and perspectives

Fuyou Liao1, 2, Feichi Zhou2 and Yang Chai1, 2,

+ Author Affiliations

 Corresponding author: Yang Chai, e-mail: ychai@polyu.edu.hk

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Abstract: Conventional frame-based image sensors suffer greatly from high energy consumption and latency. Mimicking neurobiological structures and functionalities of the retina provides a promising way to build a neuromorphic vision sensor with highly efficient image processing. In this review article, we will start with a brief introduction to explain the working mechanism and the challenges of conventional frame-based image sensors, and introduce the structure and functions of biological retina. In the main section, we will overview recent developments in neuromorphic vision sensors, including the silicon retina based on conventional Si CMOS digital technologies, and the neuromorphic vision sensors with the implementation of emerging devices. Finally, we will provide a brief outline of the prospects and outlook for the development of this field.

Key words: image sensorssilicon retinaneuromorphic vision sensorsphotonic synapses



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Fig. 1.  (Color online) Schematic diagram of (a) the composition of human visual system, (b) multilayer structure of human retina, and (c) a biological synapse.

Fig. 2.  (Color online) (a) Abstracted pixel schematic of DVS. (b) Principle of operation[45]. (c) The response of a DVS array to a person moving in the field of view of the sensor. (d) A DVS array is observing a 500 Hz spiral on an analog oscilloscope. (e) The DVS output is a continuous sequence of address events (x, y) in time. Red and blue events represent an increase or decrease change of light, respectively[15].

Fig. 3.  (Color online) (a) Abstracted pixel schematic of ATIS pixel. (b) The principle of operation of two types of asynchronous AER events. (c) Change detection events recorded (upper) and gray-level updates at the corresponding pixel positions (below)[15, 16].

Fig. 4.  (Color online) The circuit and output of DAVIS vision sensor. (a) The pixel circuit of DAVIS pixel combines an APS with a DVS. (b) A snapshot from DAVIS sensors illustrating a captured APS frame in gray scale with the DVS events in color. The football was flying toward the person. Inset: 5 ms of output right after the frame capture of the football. (c) Space-time 3D view of DVS events during 40 ms of a white rectangle spinning on a black disk at 100 Hz. Green events are older and red events are newer[49].

Fig. 5.  (Color online) Neuromorphic vision sensors based on ORRAM. (a) I–V characteristics of ORRAM with optical set and electrical reset. Inset, schematic structure of the MoOx ORRAM and its cross-section scanning electron microscopy (SEM) image. Scale bar, 100 nm. (b) Light-tunable synaptic characteristics under light intensity of 0.22, 0.45, 0.65 and 0.88 mW/cm2, respectively, with a pulse width of 200 ms. (c) Illustrations of the image memory function of ORRAM array. The letter F was stimulated with a light intensity of 0.88 mW/cm2. (d) Images before (left columns) and after (right columns) ORRAM image sensor pre-processing. (e) The image recognition rate with and without ORRAM image preprocessing[17].

Fig. 6.  (Color online) NN vision sensors. (a) Schematic of the 2D Perovskite/Graphene optical synaptic device[21]. (b) Schematic of an artificial optic-neural synapse device based on h-BN/WSe2 heterostructure[20]. (c) Optical image of WSe2/h-BN/Al2O3 vdW heterostructure based device (left) and its structural diagram (right)[19]. (d) Optical microscope image of the photodiode array consisting of 3 × 3 pixels. The upper right: Schematic of a WSe2 photodiode. The bottom right: SEM image of the pixel. (e) Schematics of the classifier. (f) Schematics of the autoencoder[18].

Fig. 7.  (Color online) A hemispherical retina based on perovskite nanowire array and its properties. (a) Side view of a completed EC-EYE. (b) The structure diagram of the EC-EYE. (c) Photocurrent and responsivity depend on light intensity of a perovskite nanowire photoreceptor. (d) I–V characteristics and the response of individual pixels. (e) The comparison of field of view (FOV) of the planar and hemispherical image sensors. (f) The reconstructed letter ‘A’ image of EC-EYE and its projection on a flat plane[23].

Table 1.   Comparison of three representative silicon retina.

ParameterDVS[45, 46]ATIS[47, 48]DAVIS[49, 50]
Major functionAsynchronous temporal contrast event detectionDVS + Intensity measurement for each eventDVS + Synchronous imaging
Noise2.1%0.25%0.4% APS, 3.5% DVS
Pixel complexity26 transistors, 3 caps, 1 photodiode77 transistors, 3 caps, 2 photodiodes47 transistors, 3 caps,
1 photodiode
Power consumption (mW)2450–1755–14
Resolution128 × 128304 × 240240 × 180
Pixel size (μm2)40 × 4030 × 3018.5 × 18.5
Latency (μs)1543
Dynamic range120 dB125 dB130 dB DVS, 51 dB APS
Date of publication200820112013
ApplicationDynamic scenesSurveillanceDynamic scenes
DownLoad: CSV

Table 2.   Comparisons of neuromorphic vision sensors based on emerging devices.

Neuromorphic vision sensorsDevice structureTerminal numberLight wavelength (nm)Array sizeFunctionsRef.
ORAM vision sensorsWSe2/BN FETThree405–6383 × 9Multibit optoelectronic memory/broadband spectrum distinction[58]
CuIn7Se11 FETThree5433 pixelsOptoelectronic memory[53]
Pd/MoOx/ITOTwo3658 × 8Contrast enhancement/noise reduction[17]
NN vision sensorsGra./2D perovskite/
gra. FET
Three520High photo-responsivity/high stability/pattern recognition[21]
WSe2/h-BN FETThree405, 532, 655Colored and color-mixed pattern recognition/ultra-low power consumption[20]
WSe2 dual-gate FETFour65027 pixelsUltrafast recognition and encoding[18]
WSe2/h-BN/Al2O3 FETThree8 × 8Pattern recognition/edge enhancement/contrast correction[19]
Hemispherically shaped vision sensorsSilicon photodiodesTwo620–70016 × 16Hemispherical electronic eye cameras/arbitrary curvilinear shapes[32]
Silicon photodiodesTwo5328 × 8hemispherical shapes/FOV(140–180°)[30]
MoS2/graphene heterostructure FETThree515>12 × 12High-density array design/small optical aberration/simplified optics[22]
Silicon-based lateral P–i–N photodiodesTwo543, 594, 633676 pixelsHemisphere-like structures[66]
Ionic liquid/Perovskite nanowire/liquid-metalTwoSunlight10 × 10High responsivity /reasonable response speed/low detection limit/wide FOV[23]
DownLoad: CSV
[1]
McCulloch W S, Pitts W. A logical calculus of the ideas immanent in nervous activity. Bull Math Biophys, 1943, 5(4), 115 doi: 10.1007/BF02478259
[2]
Hebb D O. The organization of behavior: a neuropsychological theory. J Wiley; Chapman & Hall, 1949
[3]
Carver M. Analog VLSI and neural systems. Addison-Wesley, 1989
[4]
Maher M A C, Deweerth S P, Mahowald M A, et al. Implementing neural architectures using analog VLSI circuits. IEEE Trans Circuits Syst, 1989, 36(5), 643 doi: 10.1109/31.31311
[5]
Mead C. Neuromorphic electronic systems. Proc IEEE, 1990, 78(10), 1629 doi: 10.1109/5.58356
[6]
Hodgkin A L, Huxley A F. A quantitative description of membrane current and its application to conduction and excitation in nerve. J Physiol, 1952, 117(4), 500 doi: 10.1113/jphysiol.1952.sp004764
[7]
Merolla P A, Arthur J V, Alvarez-Icaza R, et al. A million spiking-neuron integrated circuit with a scalable communication network and interface. Science, 2014, 345(6197), 668 doi: 10.1126/science.1254642
[8]
Zidan M A, Strachan J P, Lu W D. The future of electronics based on memristive systems. Nat Electron, 2018, 1(1), 22 doi: 10.1038/s41928-017-0006-8
[9]
Wang C Y, Wang C, Meng F, et al. 2D layered materials for memristive and neuromorphic applications. Adv Electron Mater, 2019, 6(2), 1901107 doi: 10.1002/aelm.201901107
[10]
Tuma T, Pantazi A, Le Gallo M, et al. Stochastic phase-change neurons. Nat Nanotechnol, 2016, 11(8), 693 doi: 10.1038/nnano.2016.70
[11]
Kuzum D, Jeyasingh R G D, Lee B, et al. Nanoelectronic programmable synapses based on phase change materials for brain-inspired computing. Nano Lett, 2012, 12(5), 2179 doi: 10.1021/nl201040y
[12]
Yang C S, Shang D S, Liu N, et al. A synaptic transistor based on quasi-2D molybdenum oxide. Adv Mater, 2017, 29(27), 1700906 doi: 10.1002/adma.201700906
[13]
Tian H, Guo Q, Xie Y, et al. Anisotropic black phosphorus synaptic device for neuromorphic applications. Adv Mater, 2016, 28(25), 4991 doi: 10.1002/adma.201600166
[14]
Takeo O, Tsuyoshi H, Tohru T, et al. Short-term plasticity and long-term potentiation mimicked in single inorganic synapses. Nat Mater, 2011, 10(8), 591 doi: 10.1038/nmat3054
[15]
Posch C, Serrano-Gotarredona T, Linares-Barranco B, et al. Retinomorphic event-based vision sensors: bioinspired cameras with spiking output. Proc IEEE, 2014, 102(10), 1470 doi: 10.1109/JPROC.2014.2346153
[16]
Steffen L, Reichard D, Weinland J, et al. Neuromorphic stereo vision: A survey of bio-inspired sensors and algorithms. Front Neurorobot, 2019, 13, 28 doi: 10.3389/fnbot.2019.00028
[17]
Zhou F, Zhou Z, Chen J, et al. Optoelectronic resistive random access memory for neuromorphic vision sensors. Nat Nanotechnol, 2019, 14(8), 776 doi: 10.1038/s41565-019-0501-3
[18]
Mennel L, Symonowicz J, Wachter S, et al. Ultrafast machine vision with 2D material neural network image sensors. Nature, 2020, 579(7797), 62 doi: 10.1038/s41586-020-2038-x
[19]
Wang C Y, Liang S J, Wang S, et al. Gate-tunable van der Waals heterostructure for reconfigurable neural network vision sensor. Sci Adv, 2020, 6(26), eaba6173 doi: 10.1126/sciadv.aba6173
[20]
Seo S, Jo S H, Kim S, et al. Artificial optic-neural synapse for colored and color-mixed pattern recognition. Nat Commun, 2018, 9(1), 1 doi: 10.1038/s41467-017-02088-w
[21]
Tian H, Wang X, Wu F, et al. High performance 2D perovskite/ graphene optical synapses as artificial eyes. 2018 IEEE International Electron Devices Meeting (IEDM), 2018, 38.6.1
[22]
Choi C, Choi M K, Liu S, et al. Human eye-inspired soft optoelectronic device using high-density MoS2-graphene curved image sensor array. Nat Commun, 2017, 8(1), 1 doi: 10.1038/s41467-016-0009-6
[23]
Gu L, Poddar S, Lin Y, et al. A biomimetic eye with a hemispherical perovskite nanowire array retina. Nature, 2020, 581(7808), 278 doi: 10.1038/s41586-020-2285-x
[24]
Boyle W S, Smith G E. Charge coupled semiconductor devices. Bell Syst Tech J, 1970, 49(4), 587 doi: 10.1002/j.1538-7305.1970.tb01790.x
[25]
Theuwissen A J. Solid-state imaging with charge-coupled devices. Springer Science & Business Media, 2006
[26]
Taylor S A. CCD and CMOS imaging array technologies: technology review. UK: Xerox Research Centre Europe, 1998
[27]
Bigas M, Cabruja E, Forest J, et al. Review of CMOS image sensors. Microelectron J, 2006, 37(5), 433 doi: 10.1016/j.mejo.2005.07.002
[28]
Kim Y, Chortos A, Xu W, et al. A bioinspired flexible organic artificial afferent nerve. Science, 2018, 360(6392), 998 doi: 10.1126/science.aao0098
[29]
Lee G J, Choi C, Kim D H, et al. Bioinspired artificial eyes: Optic components, digital cameras, and visual prostheses. Adv Funct Mater, 2017, 28(24), 1705202 doi: 10.1002/adfm.201705202
[30]
Song Y M, Xie Y, Malyarchuk V, et al. Digital cameras with designs inspired by the arthropod eye. Nature, 2013, 497(7447), 95 doi: 10.1038/nature12083
[31]
Jeong K H, Kim J, Lee L P. Biologically inspired artificial compound eyes. Science, 2006, 312(5773), 557 doi: 10.1126/science.1123053
[32]
Ko H C, Stoykovich M P, Song J, et al. A hemispherical electronic eye camera based on compressible silicon optoelectronics. Nature, 2008, 454(7205), 748 doi: 10.1038/nature07113
[33]
Posch C. Bio-inspired vision. J Instru, 2012, 7(01), C01054 doi: 10.1088/1748-0221/7/01/C01054
[34]
Gollisch T, Meister M. Eye smarter than scientists believed: Neural computations in circuits of the retina. Neuron, 2010, 65(2), 150 doi: 10.1016/j.neuron.2009.12.009
[35]
Masland R H. The fundamental plan of the retina. Nat Neurosci, 2001, 4(9), 877 doi: 10.1038/nn0901-877
[36]
Rodieck R W, Rodieck R W. The first steps in seeing. Sunderland, MA: Sinauer Associates, 1998
[37]
Cho D D, Lee T. A review of bioinspired vision sensors and their applications. Sens Mater, 2015, 27(6), 447 doi: 10.18494/SAM.2015.1083
[38]
Pereda A E. Electrical synapses and their functional interactions with chemical synapses. Nat Rev Neurosci, 2014, 15(4), 250 doi: 10.1038/nrn3708
[39]
Tan Z H, Yang R, Terabe K, et al. Synaptic metaplasticity realized in oxide memristive devices. Adv Mater, 2016, 28(2), 377 doi: 10.1002/adma.201503575
[40]
Yu H, Gong J, Wei H, et al. Mixed-halide perovskite for ultrasensitive two-terminal artificial synaptic devices. Mater Chem Front, 2019, 3(5), 941 doi: 10.1039/C9QM00061E
[41]
Etienne-Cummings R, Van der Spiegel J. Neuromorphic vision sensors. Sens Actuators A, 1996, 56(1/2), 19 doi: 10.1016/0924-4247(96)01277-0
[42]
Indiveri G, Douglas R. Neuromorphic vision sensors. Science, 2000, 288(5469), 1189 doi: 10.1126/science.288.5469.1189
[43]
Moini A. Vision chips. Springer Science & Business Media, 1999
[44]
Lichtsteiner P, Posch C, Delbruck T. A 128 × 128 120 db 30 mW asynchronous vision sensor that responds to relative intensity change. 2006 IEEE International Solid State Circuits Conference – Digest of Technical Papers, 2006, 2060
[45]
Lichtsteiner P, Posch C, Delbruck T. A 128 × 128 120 dB 15 μs latency asynchronous temporal contrast vision sensor. IEEE J Solid-State Circuits, 2008, 43(2), 566 doi: 10.1109/JSSC.2007.914337
[46]
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    Received: 05 June 2020 Revised: 09 July 2020 Online: Accepted Manuscript: 08 September 2020Uncorrected proof: 11 September 2020Published: 09 January 2021

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      Fuyou Liao, Feichi Zhou, Yang Chai. Neuromorphic vision sensors: Principle, progress and perspectives[J]. Journal of Semiconductors, 2021, 42(1): 013105. doi: 10.1088/1674-4926/42/1/013105 F Y Liao, F C Zhou, Y Chai, Neuromorphic vision sensors: Principle, progress and perspectives[J]. J. Semicond., 2021, 42(1): 013105. doi: 10.1088/1674-4926/42/1/013105.Export: BibTex EndNote
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      Fuyou Liao, Feichi Zhou, Yang Chai. Neuromorphic vision sensors: Principle, progress and perspectives[J]. Journal of Semiconductors, 2021, 42(1): 013105. doi: 10.1088/1674-4926/42/1/013105

      F Y Liao, F C Zhou, Y Chai, Neuromorphic vision sensors: Principle, progress and perspectives[J]. J. Semicond., 2021, 42(1): 013105. doi: 10.1088/1674-4926/42/1/013105.
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      Neuromorphic vision sensors: Principle, progress and perspectives

      doi: 10.1088/1674-4926/42/1/013105
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      • Author Bio:

        Fuyou Liao received his Ph.D. degree in 2020 at Fudan University. Now he is a postdoctoral researcher at The Hong Kong Polytechnic University Shenzhen Research Institute. He has published papers in reputed journals, such as Nano Research, Small, ACS Applied Electronic Materials, etc. His research interest is two-dimensional materials-based electronic and optoelectronic devices

        Yang Chai is an Associate Professor at the Hong Kong Polytechnic University, the vice president of Physical Society of Hong Kong, and a member of The Hong Kong Young Academy of Sciences. He has published over 100 papers, including Nature, Nature Nanotechnology, Nature Electronics, etc. His current research interest is low-dimensional material for electron device application

      • Corresponding author: e-mail: ychai@polyu.edu.hk
      • Received Date: 2020-06-05
      • Revised Date: 2020-07-09
      • Published Date: 2021-01-10

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