Analysis and forecast of water ecological footprint in karst area based on GRNN model
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摘要: 为揭示岩溶地区城市生态足迹的驱动因子与机制,评估和预测水资源可持续利用程度,根据岩溶地区水文地质特征及其与水生态足迹的相关性,分析了贵阳市2002-2014年水生态足迹的变化特征,并利用GRNN模型对其进行了时间序列预测。结果表明,贵阳市水生态足迹由2002年的12.79 万hm2上升至2014年的15.74 万hm2,整体呈波动上升趋势,其中,水量生态足迹变化特征主要由工业用水量决定,水质生态足迹变化特征主要由氨氮排放量决定。水生态承载力波动变化明显,且小于水生态足迹需水量,导致水资源可持续利用系数介于0.31~0.63之间。对贵阳市2015-2019年水生态足迹进行GRNN预测,表明水生态足迹呈现先升后降得趋势,水生态承载力变幅在4.315~8.038 万hm2之间,但水生态足迹与承载力的缺口大,水资源可持续利用系数偏低。因此,在水生态承载力有限的贵阳市,降低水生态足迹才是实现水资源可持续利用的关键。Abstract: In order to reveal the driving factors and mechanism of urban ecological footprint, evaluating and predicting the degree of sustainable utilization of water resources in karst area, the change characteristics of water ecological footprint in Guiyang City from 2002 to 2014 were analyzed, according to the hydrogeological features in karst area and its correlation with the water ecological footprint, and the GRNN model was used to predict and evaluate the water ecological footprint time series. The results showed that the water ecological footprint of Guiyang city rose from 12.79 Mhm2 in 2002 to 15.74 Mhm2 in 2014, of which the variety of water volume ecological footprint was determined by the industrial water consumption, water quality ecological footprint change was determined by the ammonia emissions. The fluctuation of the water ecological carrying capacity was obvious, and the water demand was less than the water ecological footprint, which led to the coefficient of sustainable utilization of water resources was between 0.34 and 0.61. The water ecological footprint from 2015 to 2019 in Guiyang city is predicted by the GRNN model, which show that the trend of water ecological footprint first increase and then decrease, and the water ecological carrying capacity ranged from 4.315 Mhm2 to 8.038 Mhm2. But the gap between the water ecological footprint and the carrying capacity is huge; the water resources sustainable utilization coefficient is low. Therefore, the reduction of the water ecological footprint is the key to sustainable development of the water resources in Guiyang city, of which the water ecological carrying capacity is limited in karst area.
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Key words:
- GRNN /
- karst /
- water ecological footprint /
- forecast
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[1] William E R. Ecological footprints and appropriated carrying capacity:what urban economics leaves out?[J]. Environment and Urbanization, 1992, 4(2):121-130. [2] Wackernagel M,William E R. Our ecological footprint:reducing human impact on the earth. Gabriela Is land,B. C.[N]. New Society Publishers,1996,2-17. [3] Wackernagel M, Onisto I, Bello P. National natural capital accounting with the ecological footprint concept[J]. Ecological Economics, 1999, 29:375-390. [4] 邓晓军,谢世友.水足迹分析理论与方法[J].资源开发与市场,2007,23(3):210-212. [5] 段锦,康慕谊,江源.基于淡水资源账户和污染账户的生态足迹改进模型[J].自然资源学报,2012,27(6):953-963. [6] 刘子刚,郑瑜. 基于生态足迹法的区域水生态承载力研究:以浙江省湖州市为例[J].资源科学,2011,33(6):1083-1088. [7] 徐中民,程国栋,张志强.生态足迹方法:可持续性定量研究的新方法:以张掖地区1995年生态足迹计算为例[J].生态学报,2001,21(9):1484-1493. [8] 谭秀娟,郑钦玉.我国水资源生态足迹分析与预测[J].生态学报,2009,29(7):3559-3568. [9] 黄林楠,张伟新,姜翠玲,等.水资源生态足迹计算方法[J].生态学报,2008,28(3):1279-1286. [10] 董朝阳,伍磊,童亿勤.生态足迹视角下的宁波市水资源可持续利用评价[J].农业现代化研究,2014,35(3):349-361. [11] 王俭,张朝星,于英谭,等.城市水资源生态足迹核算模型及应用:以沈阳市为例[J].应用生态学报,2012,23(8):2257-2262. [12] 张义,张合平,李丰生,等. 基于改进模型的广西水资源生态足迹动态分析[J].资源科学,2013,35(8):1601-1610. [13] 于冰,徐琳瑜. 城市水生态系统可持续发展评价:以大连市为例[J].资源科学,2014,36(12):2578-2583. [14] Hoekstra A Y, Hung P Q. Virtual water trade [J].Value of water research report series, 2002,(11):239-304. [15] 闵庆文,焦雯珺,成升魁. 污染足迹:一种基于生态系统服务的生态足迹[J].资源科学,2011,33(2):195-200. [16] 张义,张全平.基于生态服务的广西水生态足迹分析[J].生态学报,2013,33(13):4111-4124. [17] 崔东文. RBF与GRNN神经网络模型在河流健康评价中的应用:以文山州区域中小河流健康评价为例[J].中国农村水利水电,2012(3):56-62. [18] 伊良忠,章超,裴峥. 广义回归神经网络的改进及在交通预测中的应用[J].山东大学学报(自然科学版),2013,43(1):9-14. [19] 高红艳,刁承泰. 试论喀斯特地貌对城市建设的影响:以喀斯特山区城市贵阳市为例[J].中国岩溶,2010,29(1):81-86. -
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