[1] Wolpaw J R, Birbaumer N, McFarland D J et al. Brain-computer interfaces for communication and control[J]. Clinical Neurophysiology, 113, 767-791(2002).

[2] Liu M C. Rearch on pattern recognition algorithms for motor-imagery-based brain-computer interface[D](2009).

[3] Wolpaw J R, Wolpaw E W. Brain-computer interfaces principles and practice[M]. Fu Y F, Yang Q H, Xu B L, et al, Transl, 1-561(2017).

[4] Edelman B J, Johnson N, Sohrabpour A et al. Systems neuroengineering: understanding and interacting with the brain[J]. Engineering, 1, 292-308(2015).

[5] Shi S J. EEG based brain-computer interface on hearing[D](2010).

[6] Liu Y, Yang Y, Sun M et al. Highly specific noninvasive photoacoustic and positron emission tomography of brain plaque with functionalized croconium dye labeled by a radiotracer[J]. Chemical Science, 8, 2710-2716(2017).

[7] Liu Y, Liu H, Yan H et al. Aggregation-induced absorption enhancement for deep near-infrared Ⅱ photoacoustic imaging of brain gliomas in vivo[J]. Advanced Science, 6, 1801615(2019).

[8] Wang R F, Liu H J, Zhang C L. Prospect of study and application on PET receptor imaging[J]. Chinese Journal of Medical Imaging Technology, 22, 1599-1603(2006).

[9] Villringer A, Planck J, Hock C et al. Near infrared spectroscopy (NIRS): a new tool to study hemodynamic changes during activation of brain function in human adults[J]. Neuroscience Letters, 154, 101-104(1993).

[10] Naseer N, Hong K S. fNIRS-based brain-computer interfaces: a review[J]. Frontiers in Human Neuroscience, 9, 3(2015).

[11] Jöbsis F F. Noninvasive, infrared monitoring of cerebral and myocardial oxygen sufficiency and circulatory parameters[J]. Science, 198, 1264-1267(1977).

[12] Delpy D T, Cope M, van der Zee P et al. Estimation of optical pathlength through tissue from direct time of flight measurement[J]. Physics in Medicine and Biology, 33, 1433-1442(1988).

[13] Cope M, Delpy D T. System for long-term measurement of cerebral blood and tissue oxygenation on newborn infants by near infra-red transillumination[J]. Medical and Biological Engineering and Computing, 26, 289-294(1988).

[14] Fantini S, Franceschini M A, Gratton E et al. Non-invasive optical mapping of the piglet brain in real time[J]. Optics Express, 4, 308-314(1999).

[15] McCormick P W, Stewart M, Lewis G et al. Intracerebral penetration of infrared light: technical note[J]. Journal of Neurosurgery, 76, 315-318(1992).

[16] Hu H B. Development and application of near-infrared spectroscopy[D](2010).

[17] Coyle S, Ward T, Markham C et al. On the suitability of near-infrared (NIR) systems for next-generation brain-computer interfaces[J]. Physiological Measurement, 25, 815-822(2004).

[18] Sitaram R, Zhang H H, Guan C T et al. Temporal classification of multichannel near-infrared spectroscopy signals of motor imagery for developing a brain-computer interface[J]. NeuroImage, 34, 1416-1427(2007).

[19] Naseer N, Hong M J, Hong K S. Online binary decision decoding using functional near-infrared spectroscopy for the development of brain-computer interface[J]. Experimental Brain Research, 232, 555-564(2014).

[20] Gallegos-Ayala G, Furdea A, Takano K et al. Brain communication in a completely locked-in patient using bedside near-infrared spectroscopy[J]. Neurology, 82, 1930-1932(2014).

[21] Abdalmalak A, Milej D, Yip L C M et al. Assessing time-resolved fNIRS for brain-computer interface applications of mental communication[J]. Frontiers in Neuroscience, 14, 105(2020).

[22] Li C Q. Near infrared spectroscopy and brain monitoring[J]. Foreign Medical Sciences Section on Neurology & Neurosurgery, 22, 70-72(1995).

[23] Strangman G, Boas D A, Sutton J P. Non-invasive neuroimaging using near-infrared light[J]. Biological Psychiatry, 52, 679-693(2002).

[24] Xu W T. Brain blood-oxygen detection based on near-infrared spectroscopy[D](2014).

[25] Gagnon L, Cooper R J, Yücel M A et al. Short separation channel location impacts the performance of short channel regression in NIRS[J]. NeuroImage, 59, 2518-2528(2012).

[26] Yamamoto T, Maki A, Kadoya T et al. Arranging optical fibres for the spatial resolution improvement of topographical images[J]. Physics in Medicine and Biology, 47, 3429-3440(2002).

[27] Derosière G, Mandrick K, Dray G et al. NIRS-measured prefrontal cortex activity in neuroergonomics: strengths and weaknesses[J]. Frontiers in Human Neuroscience, 7, 583(2013).

[28] Jiang J, Jiao X J, Pan J J et al. Emotional state recognition based on functional near-infrared spectroscopy[J]. Acta Optica Sinica, 36, 0317002(2016).

[29] Torricelli A, de Contini D, Pifferi A et al. Time domain functional NIRS imaging for human brain mapping[J]. NeuroImage, 85, 28-50(2014).

[30] Shin J, Kwon J, Im C H. A ternary hybrid EEG-NIRS brain-computer interface for the classification of brain activation patterns during mental arithmetic, motor imagery, and idle state[J]. Frontiers in Neuroinformatics, 12, 5(2018).

[31] Shin J, von Lühmann A, Blankertz B et al. Open access repository for hybrid EEG-NIRS data[C]. //2018 6th International Conference on Brain-Computer Interface (BCI), January 15-17, 2018, Gangwon, Korea (South)., 1-4(2018).

[32] Ding X M, Wang B Y, Liu D Y et al. Multi-channel brain functional imaging system based on lock-in photon counting[J]. Chinese Journal of Lasers, 46, 0107001(2019).

[34] Yang Q, Ge S. Classification of a single channels fNIRS signal for a brain computer interface[C]. //2014 7th International Conference on Biomedical Engineering and Informatics, October 14-16, 2014, Dalian, China., 46-50(2014).

[35] Xu G, Li X L, Liu X M. A simple design of functional near-infrared spectroscopy system[J]. Spectroscopy and Spectral Analysis, 35, 552-556(2015).

[36] Yin X X, Shi G, Wang Z D et al. Development of one-channel fNIRS system and physiological noise reduction in brain hemodynamic responses[C]. //2015 IEEE International Conference on Robotics and Biomimetics (ROBIO), December 6-9, 2015, Zhuhai, China., 763-768(2015).

[37] Zhang Y Y, Li Z. Review of noise sources and denoising methods based on functional near-infrared spectroscopy for brain imaging[J]. Infrared, 40, 35-46(2019).

[38] Zhang Y. Study of signal extraction method in brain activity measurement by near infrared spectroscopy[D](2011).

[39] Kohno S, Miyai I, Seiyama A et al. Removal of the skin blood flow artifact in functional near-infrared spectroscopic imaging data through independent component analysis[J]. Journal of Biomedical Optics, 12, 062111(2007).

[40] Virtanen J, Noponen T E J, Meriläinen P. Comparison of principal and independent component analysis in removing extracerebral interference from near-infrared spectroscopy signals[J]. Journal of Biomedical Optics, 14, 054032(2009).

[41] Hsu S H, Pion-Tonachini L, Palmer J et al. Modeling brain dynamic state changes with adaptive mixture independent component analysis[J]. NeuroImage, 183, 47-61(2018).

[42] Zhang Y H, Brooks D H, Franceschini M A et al. Eigenvector-based spatial filtering for reduction of physiological interference in diffuse optical imaging[J]. Journal of Biomedical Optics, 10, 011014(2005).

[43] Franceschini M A, Joseph D K, Huppert T J et al. Diffuse optical imaging of the whole head[J]. Journal of Biomedical Optics, 11, 054007(2006).

[44] Zhang Q, Brown E N, Strangman G E. Adaptive filtering to reduce global interference in evoked brain activity detection: a human subject case study[J]. Journal of Biomedical Optics, 12, 064009(2007).

[45] Zhang Y, Liu X, Liu D et al. Evoked hemodynamic response estimation to auditory stimulus using recursive least squares adaptive filtering with multidistance measurement of near-infrared spectroscopy[J]. Journal of Healthcare Engineering, 2018, 7609713(2018).

[46] Pinti P L, Merla A, Aichelburg C et al. A novel GLM-based method for the Automatic IDentification of functional Events (AIDE) in fNIRS data recorded in naturalistic environments[J]. NeuroImage, 155, 291-304(2017).

[47] Santosa H, Hong M J, Kim S P et al. Noise reduction in functional near-infrared spectroscopy signals by independent component analysis[J]. The Review of Scientific Instruments, 84, 073106(2013).

[48] Jang K E, Tak S, Jung J et al. Wavelet minimum description length detrending for near-infrared spectroscopy[J]. Journal of Biomedical Optics, 14, 034004(2009).

[49] Robertson F C, Douglas T S, Meintjes E M. Motion artifact removal for functional near infrared spectroscopy: a comparison of methods[J]. IEEE Transactions on Biomedical Engineering, 57, 1377-1387(2010).

[50] Cooper R J, Selb J, Gagnon L et al. A systematic comparison of motion artifact correction techniques for functional near-infrared spectroscopy[J]. Frontiers in Neuroscience, 6, 147(2012).

[51] Virtanen J, Kotilahti K M, Ilmoniemi R et al. Accelerometer-based method for correcting signal baseline changes caused by motion artifacts in medical near-infrared spectroscopy[J]. Journal of Biomedical Optics, 16, 087005(2011).

[52] Siddiquee M R, Xue T, Marquez J S et al. Sensor fusion in human cyber sensor system for motion artifact removal from NIRS signal[C]. //2019 12th International Conference on Human System Interaction (HSI), June 25-27, 2019, Richmond, USA, 192-196(2019).

[53] Rayyan A K, Noman N, Sajid S et al. Cortical tasks-based optimal filter selection: an fNIRS study[J]. Journal of Healthcare Engineering, 2020, 9152369(2020).

[54] Verdière K J, Roy R N, Dehais F. Detecting pilot’s engagement using fNIRS connectivity features in an automated vs. manual landing scenario[J]. Frontiers in Human Neuroscience, 12, 6(2018).

[55] Matthews F, Pearlmutter B A, Wards T E et al. Hemodynamics for brain-computer interfaces[J]. IEEE Signal Processing Magazine, 25, 87-94(2008).

[56] Holper L, Biallas M, Wolf M. Task complexity relates to activation of cortical motor areas during uni- and bimanual performance: a functional NIRS study[J]. NeuroImage, 46, 1105-1113(2009).

[57] Sereshkeh A R, Yousefi R, Wong A T et al. Online classification of imagined speech using functional near-infrared spectroscopy signals[J]. Journal of Neural Engineering, 16, 016005(2019).

[58] Shin J, Müller K R, Hwang H J. Near-infrared spectroscopy (NIRS)-based eyes-closed brain-computer interface (BCI) using prefrontal cortex activation due to mental arithmetic[J]. Scientific Reports, 6, 36203(2016).

[59] Yin X X, Xu B L, Jiang C H et al. A hybrid BCI based on EEG and fNIRS signals improves the performance of decoding motor imagery of both force and speed of hand clenching[J]. Journal of Neural Engineering, 12, 036004(2015).

[60] Saadati M, Nelson J, Ayaz H. Multimodal fNIRS-EEG classification using deep learning algorithms for brain-computer interfaces purposes[M]. //Ayaz H. Advances in neuroergonomics and cognitive engineering, 953, 209-220(2020).

[61] Borgheai S B, McLinden J, Zisk A H et al. Enhancing communication for people in late-stage ALS using an fNIRS-based BCI system[J]. IEEE Transactions on Neural Systems and Rehabilitation Engineering, 28, 1198-1207(2020).

[62] Tai K, Chau T. Single-trial classification of NIRS signals during emotional induction tasks: towards a corporeal machine interface[J]. Journal of Neuroengineering and Rehabilitation, 6, 39(2009).

[63] Abibullaev B, An J. Classification of frontal cortex haemodynamic responses during cognitive tasks using wavelet transforms and machine learning algorithms[J]. Medical Engineering & Physics, 34, 1394-1410(2012).

[64] Qureshi N K, Naseer N, Noori F M et al. Enhancing classification performance of functional near-infrared spectroscopy- brain-computer interface using adaptive estimation of general linear model coefficients[J]. Frontiers in Neurorobotics, 11, 00033(2017).

[65] von Lühmann A, Ortega-Martinez A, Boas D A et al. Using the general linear model to improve performance in fNIRS single trial analysis and classification: a perspective[J]. Frontiers in Human Neuroscience, 14, 00030(2020).

[66] Noori F M, Naseer N, Qureshi N K et al. Optimal feature selection from fNIRS signals using genetic algorithms for BCI[J]. Neuroscience Letters, 647, 61-66(2017).

[67] Power S D, Kushki A, Chau T. Automatic single-trial discrimination of mental arithmetic, mental singing and the no-control state from prefrontal activity: toward a three-state NIRS-BCI[J]. BMC Research Notes, 5, 1-10(2012).

[68] Musallam S. Cognitive control signals for neural prosthetics[J]. Science, 305, 258-262(2004).

[69] Yoo S S, Fairneny T, Chen N K et al. Brain-computer interface using fMRI: spatial navigation by thoughts[J]. Neuroreport, 15, 1591-1595(2004).

[70] Cui X, Bray S, Reiss A L. Speeded near infrared spectroscopy (NIRS) response detection[J]. PLoS One, 5, e15474(2010).

[71] Zhang S, Zheng Y C, Wang D F et al. Application of a common spatial pattern-based algorithm for an fNIRS-based motor imagery brain-computer interface[J]. Neuroscience Letters, 655, 35-40(2017).

[72] Jiang X Y, Gu X, Mei Z N et al. A modified common spatial pattern algorithm customized for feature dimensionality reduction in fNIRS-based BCIs[C]. //2018 40th Annual International Conference of the IEEE Engineering in Medicine and Biology Society (EMBC), July 18-21, 2018, Honolulu, HI, USA., 5073-5076(2018).

[73] Jiang X Y, Gu X, Xu K et al. Independent decision path fusion for bimodal asynchronous brain-computer interface to discriminate multiclass mental states[J]. IEEE Access, 7, 165303-165317(2019).

[74] Zhang J, Zhao H D, Li Y H et al. Classifier for recognition of fine-grained vehicle models under complex background[J]. Laser & Optoelectronics Progress, 56, 041501(2019).

[75] Sun Z H. Study on support vector machine and its application in control[D](2003).

[76] Batula A M, Ayaz H, Kim Y E. Evaluating a four-class motor-imagery-based optical brain-computer interface[C]. //2014 36th Annual International Conference of the IEEE Engineering in Medicine and Biology Society, August 26-30, 2014, Chicago, IL, USA., 2000-2003(2014).

[77] Dadgostar M, Setarehdan S K, Shahzadi S et al. Classification of schizophrenia using SVM via fNIRS[J]. Biomedical Engineering: Applications, Basis and Communications, 30, 1850008(2018).

[78] Zhao X X, Liu G, Li W X et al. Infrared spectroscopy combined with LDA and BPNN based on wavelet transform to detect citrus osbeck anthracnose[J]. Chinese Journal of Lasers, 41, 115003(2014).

[79] Luu S, Chau T. Decoding subjective preference from single-trial near-infrared spectroscopy signals[J]. Journal of Neural Engineering, 6, 016003(2009).

[80] Wang X B, Ma X, Wang X C. Infrared spectral pattern recognition of watercolor pen ink based on artificial neural network[J]. Laser & Optoelectronics Progress, 57, 153005(2020).

[81] Truong Q D K, Masahiro N. Functional near infrared spectroscope for cognition brain tasks by wavelets analysis and neural networks[J]. International Journal of Biological and Life Sciences, 4, 28-33(2008).

[82] Naseer N, Qureshi N K, Noori F M et al. Analysis of different classification techniques for two-class functional near-infrared spectroscopy-based brain-computer interface[J]. Computational Intelligence and Neuroscience, 2016, 5480760(2016).

[83] Huve G, Takahashi K, Hashimoto M. Online recognition of the mental states of drivers with an fNIRS-based brain-computer interface using deep neural network[C]. //2019 IEEE International Conference on Mechatronics (ICM), March 18-20, 2019, Ilmenau, Germany., 238-242(2019).

[84] Nagasawa T, Sato T, Nambu I et al. Improving fNIRS-BCI accuracy using GAN-based data augmentation[C]. //2019 9th International IEEE/EMBS Conference on Neural Engineering (NER), March 20-23, 2019, San Francisco, CA, USA., 1208-1211(2019).

[85] Nagasawa T, Sato T, Nambu I et al. fNIRS-GANs: data augmentation using generative adversarial networks for classifying motor tasks from functional near-infrared spectroscopy[J]. Journal of Neural Engineering, 17, 016068(2020).

[86] Zhou Z H. Machine learning[M], 113-114(2016).

[87] Trakoolwilaiwan T, Behboodi B, Lee J et al. Convolutional neural network for high-accuracy functional near-infrared spectroscopy in a brain-computer interface: three-class classification of rest, right-, and left-hand motor execution[J]. Neurophotonics, 5, 011008(2017).

[88] Yang D, Hong K S, Yoo S H et al. Evaluation of neural degeneration biomarkers in the prefrontal cortex for early identification of patients with mild cognitive impairment: an fNIRS study[J]. Frontiers in Human Neuroscience, 13, 317(2019).

[89] Li H. Statistical learning method[M], 1-235(2012).

[90] Falk T H, Guirgis M, Power S et al. Taking NIRS-BCIs outside the lab: towards achieving robustness against environment noise[J]. IEEE Transactions on Neural Systems and Rehabilitation Engineering, 19, 136-146(2011).

[91] Seo Y W, Lee S D, Koh D K et al. Partial least squares-discriminant analysis for the prediction of hemodynamic changes using near infrared spectroscopy[J]. Journal of the Optical Society of Korea, 16, 57-62(2012).

[92] Li C G, Xu J C, Zhu Y F et al. Detecting self-paced walking intention based on fNIRS technology for the development of BCI[J]. Medical & Biological Engineering & Computing, 58, 933-941(2020).

[93] Weyand S, Schudlo L, Takehara-Nishiuchi K et al. Usability and performance-informed selection of personalized mental tasks for an online near-infrared spectroscopy brain-computer interface[J]. Neurophotonics, 2, 025001(2015).

[94] Naseer N, Hong K S, Khan M J et al. Analysis of classification performance of fNIRS signals from prefrontal cortex using various temporal windows[C]. //2015 10th Asian Control Conference (ASCC), May 31 - June 3, 2015, Kota Kinabalu, Malaysia., 1-5(2015).

[95] Hennrich J, Herff C, Heger D et al. Investigating deep learning for fNIRS based BCI[C]. //2015 37th Annual International Conference of the IEEE Engineering in Medicine and Biology Society (EMBC), August 25-29, 2015, Milan, Italy., 2844-2847(2015).

[96] Jin S H, Lee S H, Jang G et al. An application of common spatial pattern algorithm for accuracy improvement in classification of cortical activation pattern according to finger movement[C]. //2015 54th Annual Conference of the Society of Instrument and Control Engineers of Japan (SICE), July 28-30, 2015, Hangzhou, China., 1260-1264(2015).

[97] Zhang Z, Jiao X J, Xu F G et al. The investigation of brain-computer interface for motor imagery and execution using functional near-infrared spectroscopy[J]. Proceedings of the SPIE, 10245, 102450I(2017).

[98] Li R H, Potter T, Huang W T et al. Enhancing performance of a hybrid EEG-fNIRS system using channel selection and early temporal features[J]. Frontiers in Human Neuroscience, 11, 462(2017).

[99] Liu X L, Hong K S. Detection of primary RGB colors projected on a screen using fNIRS[J]. Journal of Innovative Optical Health Sciences, 10, 1750006(2017).

[100] Hong K S, Bhutta M R, Liu X L et al. Classification of somatosensory cortex activities using fNIRS[J]. Behavioural Brain Research, 333, 225-234(2017).

[101] Gemignani J, Middell E, Barbour R L et al. Improving the analysis of near-infrared spectroscopy data with multivariate classification of hemodynamic patterns: a theoretical formulation and validation[J]. Journal of Neural Engineering, 15, 045001(2018).

[102] Tanveer M A, Khan M J, Qureshi M J et al. Enhanced drowsiness detection using deep learning: an fNIRS study[J]. IEEE Access, 7, 137920-137929(2019).

[103] Lucas R T, Juliana T, André M C et al. Subject-independent decoding of affective states using functional near-infrared spectroscopy[EB/OL]. (2020-09-05)[2021-01-07]. DOI:.

[104] Aydin E A. Subject-specific feature selection for near infrared spectroscopy based brain-computer interfaces[J]. Computer Methods and Programs in Biomedicine, 195, 105535(2020).

[105] Mehagnoul-Schipper D J, van der Kallen B F W, Colier W N J M et al. Simultaneous measurements of cerebral oxygenation changes during brain activation by near-infrared spectroscopy and functional magnetic resonance imaging in healthy young and elderly subjects[J]. Human Brain Mapping, 16, 14-23(2002).

[106] Sun J M. Research on artifact real-time removal method of EEG signal in EEG-fMRI hybrid brain-computer interface[D](2018).

[107] Fazli S, Mehnert J, Steinbrink J et al. Enhanced performance by a hybrid NIRS-EEG brain computer interface[J]. NeuroImage, 59, 519-529(2012).

[108] Morioka H, Kanemura A, Morimoto S et al. Decoding spatial attention by using cortical currents estimated from electroencephalography with near-infrared spectroscopy prior information[J]. NeuroImage, 90, 128-139(2014).

[109] Xiong X, Fu Y F, Zhang X B et al. Design and experiment of a multi-modal electroencephalogram-near infrared spectroscopy helmet for simultaneously acquiring at the same brain area[J]. Journal of Biomedical Engineering, 35, 290-296(2018).

[110] Safaie J, Grebe R, Abrishami M H et al. Toward a fully integrated wireless wearable EEG-NIRS bimodal acquisition system[J]. Journal of Neural Engineering, 10, 056001(2013).

[111] Anumanchipalli G K, Chartier J, Chang E F. Speech synthesis from neural decoding of spoken sentences[J]. Nature, 568, 493-498(2019).

[112] Touradj E, Jean-Marc V, Gary G. Brain-computer interface in multimedia communication[J]. IEEE Signal Processing Magzine, 20, 14-24(2003).

[113] Qi H T. Research of brain-computer interface based on motor imagery EEG[D](2012).

[114] Hasan B A S, Gan J Q. Unsupervised movement onset detection from EEG recorded during self-paced real hand movement[J]. Medical & Biological Engineering & Computing, 48, 245-253(2010).

[115] Hwang H J, Choi H, Kim J Y et al. Toward more intuitive brain-computer interfacing: classification of binary covert intentions using functional near-infrared spectroscopy[J]. Journal of Biomedical Optics, 21, 091303(2016).

[116] Naseer N, Hong K S. Classification of functional near-infrared spectroscopy signals corresponding to the right- and left-wrist motor imagery for development of a brain-computer interface[J]. Neuroscience Letters, 553, 84-89(2013).

[117] Schudlo L C, Chau T. Development of a ternary near-infrared spectroscopy brain-computer interface: online classification of verbal fluency task, stroop task and rest[J]. International Journal of Neural Systems, 28, 1750052(2018).

[118] Li C Y, Zhao W J. Decrypting the brain-computer interface: an interview with He Bin, dean of the Department of Biomedical Engineering, CMU[EB/OL]. [2020-04-18].. http:∥www.zhishifenzi.com/depth/depth/8785.html.