[1] Jiang W-M (蒋维楣), Chen Y (陈 燕). The impact of anthropogenic heat on urban boundary layer structure. Chinese Journal of Atmospheric Sciences (大气科学), 2007, 31(1): 37-47 (in Chinese) [2] Fan H, Sailor DJ. Modeling the impacts of anthropogenic heating on the urban climate of Philadelphia: A compa-rison of implementations in two PBL schemes. Atmosphe-ric Environment, 2005, 39: 73-84 [3] Torrance KE, Shun JSW. Time-varying energy consumption as a factor in urban climate. Atmospheric Environment, 1976, 10: 329-337 [4] Sailor DJ. A review of methods for estimating anthropogenic heat and moisture emissions in the urban environment. International Journal of Climatology, 2011, 31: 189-199 [5] Ryo M, Manabu K, Hiroshi S, et al. Anthropogenic water vapor emissions in Tokyo. Water Resources Research, 2008, 44: 150-176 [6] Lu Y, Wang Q, Zhang Y, et al. An estimate of anthropogenic heat emissions in China. International Journal of Climatology, 2016, 36: 1134-1142 [7] Wagner M, Viswanathan V, Pelzer D, et al. Cellular automata-based anthropogenic heat simulation. Procedia Computer Science, 2015, 51: 2107-2116 [8] Klysik K. Spatial and seasonal distribution of anthropogenic heat emission in Lodz, Poland. Atmospheric Environment, 1996, 30: 3397-3404 [9] Lee SH, Song CK, Baik JJ, et al. Estimation of anthropogenic heat emission in the Gyeong in region of Korea. Theoretical and Applied Climatology, 2009, 96: 291-303 [10] Quah AKL, Roth M. Diurnal and weekly variation of anthropogenic heat emissions in a tropical city, Singapore. Atmospheric Environment, 2012, 46: 92-103 [11] Sailor DJ, Lu L. A top-down methodology for developing diurnal and seasonal anthropogenic heating profiles for urban areas. Atmospheric Environment, 2004, 38: 2737-2748 [12] Ichinose T, Shimodozono K, Hanaki K. Impact of anthropogenic heat on urban climate in Tokyo. Atmospheric Environment, 1999, 33: 3897-3909 [13] Kondo H, Kikegawa Y. Temperature variation in the urban canopy with anthropogenic energy use. Pure & Applied Geophysics, 2003, 160: 317-324 [14] Tong H (佟 华), Liu H-Z (刘辉志), Sang J-G (桑建国), et al. The impact of urban anthropogenic heat on Beijing heat environment. Climatic & Environmental Research (气候与环境研究), 2004, 9(3): 409-421 (in Chinese) [15] Wang Z-M (王志铭), Wang X-M (王雪梅). Estimation and sensitivity test of anthropogenic heat flux in Guangzhou. Journal of Applied Meteorological Science (应用气象学报), 2011, 31(4): 422-430 (in Chinese) [16] Zhan J-J (占俊杰), Dan L (丹 利). Diurnal and annual variation of anthropogenic heat estimation in Guangzhou City, China. Climatic & Environmental Research (气候与环境研究), 2014, 19(6): 726-734 (in Chinese) [17] Zhao Y (赵 炎), Lu J (卢 军). The investigation of anthropogenic heat emission of building group. Refri-geration & Air Conditioning (制冷与空调), 2011, 25 (suppl.): 239-244 (in Chinese) [18] Shi GY, Dai T, Tan SC, et al. Preliminary estimate of the global average annual climate forcing resulted from anthropogenic heat release. Advances in Climate Change Research, 2010, 6: 119-122 [19] Flanner MG. Integrating anthropogenic heat flux with global climate models. Geophysical Research Letters, 2009, 36: 270-274 [20] Chen B (陈 兵), Shi G-Y (石广玉), Dai T (戴 铁), et al. Climate forcing due to anthropogenic heat release over China. Climatic & Environmental Research (气候与环境研究), 2011, 16(6): 717-722 (in Chinese) [21] Kimura F, Takahashi S. The effects of land-use and anthropogenic heating on the surface temperature in the Tokyo Metropolitan area: A numerical experiment. Atmospheric Environment, 1991, 25: 155-164 [22] Hamilton IG, Davies M, Steadman P, et al. The significance of the anthropogenic heat emissions of London’s buildings a comparison against captured shortwave solar radiation. Building and Environment, 2009, 44: 807-817 [23] Narumi D, Kondo A, Shimoda Y. The effect of the increase in urban temperature on the concentration of photochemical oxidants. Atmospheric Environment, 2009, 43: 2348-2359 [24] Lee SH, Mckeen SA, Sailor DJ. A regression approach for estimation of anthropogenic heat flux based on a bottom-up air pollutant emission database. Atmospheric Environment, 2014, 95: 629-633 [25] Lee SH, Kim ST. Estimation of anthropogenic heat emission over South Korea using a statistical regression me-thod. Asia-Pacific Journal of Atmospheric Sciences, 2015, 51: 1-10 [26] Offerle B, Grimmond CSB, Fortuniak K. Heat storage and anthropogenic heat flux in relation to the energy ba-lance of a central European city centre. International Journal of Climatology, 2005, 25: 1405-1419 [27] Pigeon G, Legain D, Durand P, et al. Anthropogenic heat release in an old European agglomeration (Toulouse, France). International Journal of Climatology, 2007, 27: 1969-1981 [28] Kato S, Yamaguchi Y. Analysis of urban heat-island effect using ASTER and ETM+ data separation of anthropogenic heat discharge and natural heat radiation from sensible heat flux. Remote Sensing of Environment, 2005, 99: 44-54 [29] Zhou Y, Weng Q, Gurney KR, et al. Estimation of the relationship between remotely sensed anthropogenic heat discharge and building energy use. ISPRS Journal of Photogrammetry and Remote Sensing, 2012, 67: 65-72 [30] Xiao J-Y (肖捷颖), Zhang Q (张 倩), Wang Y (王燕), et al. Urban surface heat flux analysis based on remote sensing: A case study of Shijiazhuang City. Scientia Geographica Sinica (地理科学), 2014, 34(3): 338-343 (in Chinese) [31] Wong MS, Yang J, Nichol J, et al. Modeling of anthropogenic heat flux using HJ-1B Chinese small satellite image: A study of heterogeneous urbanized areas in Hong Kong. IEEE Geoscience & Remote Sensing Letters, 2015, 12: 1466-1470 [32] Zhu T-Y (朱婷媛). Reasearch on Quantitative Estimation of Anthropogenic Heat in Hangzhou based on Landsat Remote Sensing Data. Master Thesis. Hangzhou: Zhejiang University, 2015 (in Chinese) [33] Dhakal S, Hanaki K. Improvement of urban thermal environment by managing heat discharge sources and surface modification in Tokyo. Energy and Buildings, 2002, 34: 13-23 [34] Heiple S, Sailor DJ. Using building energy simulation and geospatial modeling techniques to determine high resolution building sector energy consumption profiles. Energy and Buildings, 2008, 40: 1426-1436 [35] Assimakopoulos MN, Mihalakakou G, Flocas HA. Simulating the thermal behaviour of a building during summer period in the urban environment. Renewable Energy, 2007, 32: 1805-1816 [36] Hsieh CM, Aramaki T, Hanaki K. Estimation of heat rejection based on the air conditioner use time and its mitigation from buildings in Taipei City. Building and Environment, 2007, 42: 3125-3137 [37] Nie WS, Sun T, Ni GH. Spatiotemporal characteristics of anthropogenic heat in an urban environment: A case study of Tsinghua Campus. Building and Environment, 2014, 82: 675-686 [38] Chow WTL, Salamanca F, Georgescu M, et al. A multi-method and multi-scale approach for estimating city-wide anthropogenic heat fluxes. Atmospheric Environment, 2014, 99: 64-76 [39] Lindberg F, Grimmond CSB, Yogeswaran N, et al. Impact of city changes and weather on anthropogenic heat flux in Europe 1995-2015. Urban Climate, 2013, 4: 1-15 [40] Belova I, Ginzburg A. Anthropogenic heat fluxes over Moscow agglomeration and other Russian and world cities. Geophysical Research Abstracts, 2010, 12: EGU2010-7262 [41] Chen B (陈 兵), Shi G-Y (石广玉), Wang B (王标), et al. Estimation of the anthropogenic heat release distribution in China from 1992 to 2009. Acta Meteorlo-gica Sinica (气象学报), 2012(4): 507-515 (in Chinese) [42] Sailor DJ, Vasireddy C. Correcting aggregate energy consumption data to account for variability in local weather. Environmental Modelling & Software, 2006, 21: 733-738 [43] Niu Q, Nie CQ, Lin F, et al. Model study of relationship between local temperature and artificial heat release. Science China, 2012, 55: 821-830 [44] Iamarino M, Beevers S, Grimmond CSB. High-resolution (space, time) anthropogenic heat emissions: London 1970-2025. International Journal of Climatology, 2012, 32: 1754-1767 [45] Smit R, Brown AL, Chan YC. Do air pollution emissions and fuel consumption models for roadways include the effects of congestion in the roadway traffic flow? Environmental Modelling & Software, 2008, 23: 1262-1270 |