http://orcid.org/0000-0001-5696-1220
References
- Zhuo C, Zhiyuan L, Li Z, et al. The impact of social assessment threats on decision-making behavior in social distress: a study based on resting state fMRI. Magn Reson Imaging. 2018;(05):360–367.
- Xianchang Z, Rong X, Zhentao Z. The default network pattern of human brain: a dynamic causal model based on 7T fMRI. Prog Biochem Biophys. 2018; 45(05):536–543.
- Bollmann S, Puckett AM, Cunnington R, et al. Serial correlations in single-subject fMRI with sub-second TR. Neuroimage. 2018;166:152–166.
- Cassidy B, Bowman FD, Rae C, et al. On the reliability of individual brain activity networks. IEEE Trans Med Imaging. 2018;37(2):649–662.
- Alegria AA, Wulff M, Brinson H, et al. Real-time fMRI neurofeedback in adolescents with attention deficit hyperactivity disorder. Hum Brain Mapp. 2017;38(6):3190–3209.
- Zheng Z, Yonghua X, Lixia Y, et al. Effect of head-related noise on the complexity of resting state fMRI signal. Chin J Med Imaging. 2016;22(03):212–216.
- Shirer WR, Jiang H, Price CM, et al. Optimization of rs-fMRI pre-processing for enhanced signal-noise separation, test-retest reliability, and group discrimination. Neuroimage. 2015;117:67–79.
- Wei L, Zhuo C, Li Z, et al. Modulation of motivation on reaction attack-based on individual differences of resting state fMRI. Magn Reson Imaging. 2016;7(08):602–607.
- Members & Collaborators of the Wellcome Department of Imaging Neuroscience. Statistical Parametric Mapping Introduction [EB/OL]. 2014. http://www.fil.ion.ucl.ac.uk/spm/
- Fan F, Changwei L. Analysis of atmospheric turbulence phase screen based on wavelet analysis. Acta Opt Sin. 2017;37(01):35–43.
- Depeursinge A, Puspoki Z, Ward JP, et al. Steerable wavelet machines (SWM): learning moving frames for texture classification. IEEE Trans Image Process. 2017; 26(4):1626–1636.
- Shahamat H*, Pouyan AA. Feature selection using genetic algorithm for classification of schizophrenia using fMRI data. J AI Data Mining. 2015;3(1):30–37.
- Gilpin S, Davidson I. A flexible ILP formulation for hierarchical clustering. Artif Intell. 2017;244:95–109.
- Xinyu Z, Hongbo G, Jianhui Z, et al. A review of automatic driving technology based on deep learning. J Tsinghua Univ (Science and Technology). 2018;58(04):438–444.
- Hongmeng L, Di Z, Xuebin C. Early diagnosis of Alzheimer's disease based on deep learning of enhanced AlexNet. Comput Sci. 2017;44(S1):50–60.
- Lee D, Yoo J, Tak S, et al. Deep residual learning for accelerated MRI using magnitude and phase networks. IEEE Trans Biomed Eng. 2018;65(9):1985–1995.
- Zhao G, Liu F, Oler JA, et al. Bayesian convolutional neural network based MRI brain extraction on nonhuman primates. Neuroimage. 2018;175:32–44.
- Kawahara J, Brown CJ, Miller SP, et al. BrainNetCNN: convolutional neural networks for brain networks; towards predicting neurodevelopment. NeuroImage. 2017;146:1038–1049.
- Sarraf S, Tofighi G. Deep learning-based pipeline to recognize Alzheimer's disease using fMRI data[C] 2016 Future Technologies Conference (FTC); San Francisco, CA; 2016. p. 816–820.
- Suk H-I, Shen D. Deep learning-based feature representation for ad/mci classification. In: International Conference on Medical Image Computing and Computer-Assisted Intervention. California (CA): Springer; 2013. p. 583–590.
- Suk H-I, Shen D, Alzheimer’s disease neuroimaging initiative, et al. Deep learning in diagnosis of brain disorders. In: Recent Progress in Brain and Cognitive Engineering. Netherlands: Springer; 2015. p. 203–213.
- Suk H-I, Lee S-W, Shen D, et al. Latent feature representation with stacked auto-encoder for AD/MCI diagnosis. Brain Struct Funct. 2015;220(2):841–859.
- Zhaochen Z, Junzhong Y. Classification method of fMRI data based on convolutional neural network. Pattern Recognit Artif Intell. 2017;30(6):549–558.
- Pereira S, Pinto A, Alves V, et al. Brain tumor segmentation using convolutional neural networks in MRI images. IEEE Trans Med Imaging. 2016;35(5):1240–1251.
- Roy S, Butman JA, Pham DL. Robust skull stripping using multiple MR image contrasts insensitive to pathology. Neuroimage. 2017;146:132–147.
- Kamnitsas K, Ledig C, Newcombe VFJ, et al. Efficient multi-scale 3D CNN with fully connected CRF for accurate brain lesion segmentation. Med Image Anal. 2017;36:61–78.
- Zhao Y, Dong Q, Zhang S, et al. Automatic recognition of fMRI-derived functional networks using 3D convolutional neural networks. IEEE Trans Biomed Eng. 2017;65(9):1975–1984.
- Razavian AS, Azizpour H, Sullivan J, et al. CNN features off-the-shelf: an astounding baseline for recognition. IEEE CVPRW. 2014:1;512–519.
- Zhou B, Lapedriza A, Xiao J, et al. Learning deep features for scene recognition using places database. NIPS. 2014;487–495.
- Karri SPK, Chakraborty D, Chatterjee J. Transfer learning based classification of optical coherence tomography images with diabetic macular edema and dry age-related macular degeneration. Biomed Opt Express. 2017;8(2):579.
- Jiang F, Liu H, Yu S, et al. Breast mass lesion classification in mammograms by transfer learning[c]//international conference on bioinformatics and computational biology. ACM. 2017:59–62.
- Jin X, Chi J, Peng S, et al. Deep image aesthetics classification using inception modules and fine-tuning connected layer. International Conference on Wireless Communications & Signal Processing. Yangzhou: IEEE; 2016. p. 1–6.
- Zhong Z, Jin L, Xie Z. High performance offline handwritten Chinese character recognition using GoogLeNet and directional feature maps. Computer Vision and Pattern Recognition. 2015;846–850.
- Smeets PA, Kroese FM, Evers C, et al. Allured or alarmed: counteractive control responses to food temptations in the brain. Behav Brain Res. 2013;248(1):41–45.
- Olhede SC, Walden AT. Generalized Morse wavelets. IEEE Trans Signal Process. 2002;50(11):2661–2670.
- Lilly JM, Olhede SC. Higher-order properties of analytic wavelets. IEEE Trans Signal Process. 2009;57(1):146–160.
- Kocahan O, Tiryaki E, Coskun E, et al. Determination of phase from the ridge of CWT using generalized Morse wavelet. Meas Sci Technol. 2018;29:035203.