[1] Ministry of Development of the People’s Republic of China (中华人民共和国建设部), General Administration of Quality Supervision, Inspection and Quarantine of the People’s Republic of China (中华人民共和国国家质量监督检验检疫总局). Navigation Standard in Inland River (GB50139-2014). Beijing: China Plan Press, 2014 (in Chinese) [2] Ministry of Transport of the People’s Republic of China (中华人民共和国交通运输部). Hydrological Code for Port and Waterway. Beijing: China Communication Press, 2014(in Chinese) [3] He M (何 蒙), Lyu D-Q (吕殿青), Li J-B (李景保), et al. Variation of ecological water demand and its contributing factors in the southern three outlets of Jingjiang River in the Yangtze River under the condition of hydrologic variation. Chinese Journal of Applied Ecology (应用生态学报), 2017, 28(8): 2554-2562 (in Chinese) [4] Li J-B (李景保), Luo Z-H (罗中海), Ye Y-Y (叶亚亚), et al. Eco-hydrological impacts of Three Gorges Reservoir’s operation on three outfalls of Chingjiang River. Chinese Journal of Applied Ecology (应用生态学报), 2016, 27(4): 1285-1293 (in Chinese) [5] Xu Q-Q (徐强强), Xie P (谢 平), Li P-Y (李培月), et al. Variation analysis of lowest navigable water levels in major rivers in Guangdong Province. Journal of Hydroelectric Engineering (水力发电学报), 2016, 35(7): 44-54 (in Chinese) [6] Milly P, Julio B, Malin F, et al. Stationarity is dead. Science, 2008, 319: 573-574 [7] Strupczewski WG, Singh VP, Feluch W. Non-stationary approach to at-site flood frequency modelling. I. Maximum likelihood estimation. Journal of Hydrology, 2001, 248: 123-142 [8] Strupczewski WG, Kaczmarek Z. Non-stationary approach to at-site flood frequency modelling. II. Weighted least squares estimation. Journal of Hydrology, 2001, 248: 143-151 [9] Strupczewski WG, Singh VP, Mitosek HT. Non-stationary approach to at-site flood frequency modelling. III. Flood analysis of Polish rivers. Journal of Hydrology, 2001, 248: 152-167 [10] Xie P (谢 平), Chen G-C (陈广才), Xia J (夏军). Hydrological frequency calculation principle of inconsistent annual runoff series under changing environments. Engineering Journal of Wuhan University (武汉大学学报:工学版), 2005, 38(6): 6-9 (in Chinese) [11] Li B-B (李彬彬), Xie P (谢 平), Zhang B (张波), et al. Diagnosis and identification for variance variation of hydrological series. Journal of Water Resources Research (水资源研究), 2014, 3(1): 29-33 (in Chinese) [12] Serinaldi F, Kilsby CG. Stationarity is undead: Uncertainty dominates the distribution of extremes. Advances in Water Resources, 2015, 77: 17-36 [13] Demirbilek Z, Sargent F. Deep-draft Coastal Navigation Entrance Channel Practice. Coastal Engineering Technical Note. Washington, DC: US Army Corp of Engineers, 1999 [14] Eloot K, Söhngen B. Update PIANC Incom WG 141: Design Guidelines for Inland Waterways. San Francisco, CA: 33rd PIANC World Congress, 2014: 1-20 [15] Zhang H (张 华), Huang Z-Y (黄志扬), Xiao L-B (肖烈兵), et al. Cumulative frequency of high tide level and maintenance dredging plans in estuarial areas. Port & Waterway Engineering (水运工程), 2015(4): 8-12 (in Chinese) [16] Liang Z-M (梁忠民), Hu Y-M (胡义明), Wang J (王 军). Advances in hydrological frequency analysis of non-stationary time series. Advances in Water Science (水科学进展), 2011, 22(6): 864-871 (in Chinese) [17] Xie P (谢 平), Chen G-C (陈广才), Lei H-F (雷红富), et al. Hydrological alteration diagnosis system. Journal of Hydroelectric Engineering (水力发电学报), 2010, 29(1): 85-91 (in Chinese) [18] Li L-J (李丽娟), Li H-B (李海滨), Wang J (王 娟). Analysis on hydrological and water quality character and their spatial and temporal distribution in Lancangjiang River. Scientia Geographica Sinica (地理科学), 2002, 22(1): 49-56 (in Chinese) [19] Wang W-S (王文圣), Jin J-L (金菊良), Ding J (丁晶). Stochastic Hydrology. 3rd Ed. Beijing: China Water & Power Press, 2016 (in Chinese) [20] Fill HD, Stedinger JR. Homogeneity tests based upon Gumbel distribution and a critical appraisal of Dalrymple’s test. Journal of Hydrology,1995, 166: 81-105 [21] Castellarin A, Burn DH, Brath A. Homogeneity testing: How homogeneous do heterogeneous cross-correlated regions seem? Journal of Hydrology, 2008, 360: 67-76 [22] Milan S. Homogeneity and scale testing of generalized gamma distribution. Reliability Engineering & System Safety,2008, 93: 1809-1813 [23] Sahin S, Cigizoglu HK. Homogeneity analysis of Turkish meteorological data set. Hydrological Processes, 2010, 24: 981-992 [24] Lei H-F (雷红富), Xie P (谢 平), Chen G-C (陈广才), et al. Comparison and analysis on the perfor-mance of hydrological time series change-point testing methods. Water Resources and Power (水电能源科学), 2007, 25(4): 36-40 (in Chinese) [25] Zhou Y-Y (周园园), Shi Z-X (师长兴), Fan X-L (范小黎), et al. Advances in the research methods of abrupt changes of hydrologic sequences and their applications in drainage basins in China. Progress in Geography (地理科学进展), 2011, 30(11): 898-909 (in Chinese) [26] Zhang Y-H (张应华), Song X-F (宋献方). Techniques of abrupt change detection and trends analysis in hydroclimatic time-series: Advances and evaluation. Arid Land Geography (干旱区地理), 2015, 38(4): 652-665 (in Chinese) [27] Xie P (谢 平), Zhang B (张 波), Chen H-J (陈海健), et al. Inconsistent annual runoff process design method based on extreme value with common frequency: A case study in jump variation. Journal of Hydraulic Engineering (水利学报), 2015, 46(7): 828-835 (in Chinese) [28] Chen H-J (陈海健), Xie P (谢 平), Xie J-H (谢静红), et al. Variation analysis method for flood process homogeneity based on the information entropy: Taking the flood series of Longchun station in Dongjiang River basin as an example. Journal of Hydraulic Engineering (水利学报), 2015, 46(10): 1233-1239 (in Chinese) [29] Wang H-R (王红瑞), Gao X (高 雄), Chang J-Y (常晋源), et al. Hydrological time series model based on conditional heteroskedasticity analysis and its application. Systems Engineering: Theory & Practice (系统工程理论与实践), 2009, 29(11): 19-30 (in Chinese) [30] Wagener J. The adaptive lasso in high-dimensional sparse heteroscedastic models. Mathematical Methods of Statistics, 2013, 22: 137-154 [31] Modarres R, Ouarda TBMJ. Modelling heteroscedasticty of streamflow time series. Hydrological Sciences Journal, 2013, 58: 54-64 [32] Zevallos M, Hotta LK. Slope influence diagnostics in conditional heteroscedastic time series models. Brazilian Journal of Probability & Statistics,2015, 29: 34-52 [33] Peña-Arancibia JL, Zhang YQ, Pagendam DE, et al. Streamflow rating uncertainty: Characterisation and impacts on model calibration and performance. Environmental Modelling & Software, 2015, 63: 32-44 [34] Tu X-J (涂新军), Chen X-H (陈晓宏). Characteristics variability study of regional river runoff time series based on change point recognition. Journal of Natural Resources (自然资源学报), 2010, 25(11): 1930-1937 (in Chinese) [35] Liu X (刘 萱), Zhang W-Y (张文煜), Jia D-Y (贾东于) , et al. Research of abrupt changes of sandstorm frequency in Hexi Corridor in recent 50 years. Journal of Desert Research (中国沙漠), 2011, 31(6): 1579-1584 (in Chinese) [36] Wang D (王 冬), Li Y-T (李义天), Deng J-Y (邓金运), et al. Study on calculation method of design lowest navigable stage in scouring channel downstream of dams. Journal of Hydroelectric Engineering (水力发电学报), 2014, 33(1): 120-126 (in Chinese) [37] Zhan D-J (詹道江), Xu X-Y (徐向阳), Chen Y-F (陈元芳), Engineering Hydrology. 4th Ed. Beijing: China Water & Power Press, 2010 (in Chinese) [38] He D-M (何大明), Feng Y (冯 彦), Gan S (甘淑), et al. The hydrological effect of cross-border on hydropower exploitation in mainstream of Lancang River. Chinese Science Bulletin (科学通报),2006, 51(suppl.2): 14-20 (in Chinese) [39] Liu B (刘 波), Xiao Z-N (肖子牛). Observed (1951-2008) and rojected (2010-2099) climate change in the Lancang River Basin. Advances in Climate Change Research (气候变化研究进展), 2010, 6(3): 170-174 (in Chinese) |