1. Hou, J., Robust numerical methods for shallow water flows and advective transport simulation on unstructured grids.ISBN: 978-3-8440-1857-8,Shaker Verlag, Aachen, Germany.
1. Wang N., Hou J., et al. A dynamic, convenient and accurate method for assessing the flood risk of people and vehicle. Science of the Total Environment, 2021, 797.
2. Li B, Hou J, Ma Y, et al., (2021). A coupled high-resolution hydrodynamic and cellular automata-based evacuation route planning model for pedestrians in flooding scenarios. Natural Hazards.
3. Hou, J., Zhou, N., Chen, G. et al. (2021). Rapid forecasting of urban flood inundation using multiple machine learning models. Natural Hazards, 108, 2335–2356.
4. Hou J, Chen G, Zhang Y, et al., (2021). A simulation study on risks of pedestrian evacuation from flooded staircases of different slopes in the underground space. Natural Hazards.
5. Kang Y D.,Hou J., et al.(2021). A Hydrodynamic-Based Robust Numerical Model for Debris Hazard and Risk Assessment. Journal of Sustainability, 2021, 13, 7955: 2-19.
6. Hou J., Li X.,et al.(2021).Effect of digital elevation model spatial resolution on depression storage. Hydrological Processes.2021,35(10).
7. Yang, L., Hou J. etc. (2021). Application of habitat suitability model coupling with high - precision hydrodynamic processes. Ecological Modelling,462,109792.
8. Kang Y D.,Hou J., et al.(2021). Two-dimensional hydrodynamic robust numerical model of soil erosion based on slopes and river basins. Journal of Arid Land, 2021, 13(10): 995-1014.
9. Hou J., MaY. etc.(2021). A river channel terrain reconstruction method for flood simulationsbased on coarse DEMs. Environmental Modelling & Software,140, 105035.
10. Wang J.,HouJ., et al.(2021). A non-uniform grid approach forhigh-resolution flood inundation simulation based on GPUs[J], Journal ofHydrodynamics.
11. Hou J., LiX. etc.(2021). A deep learning technique based flood propagation experiment. Journalof flood risk management.
12. Li B., Hou J., LiD., et al. (2021). Application of LiDAR UAV for High‑Resolution FloodModelling. Water Resources Management, 35, 1433–1447.
13. Hou J., ShiB , et al. A GPU-based robust numerical model for solute transport driven by torrentialflow conditions. Journal of Zhejiang University-SCIENCE A, 2021.
14. Bai G., Hou J.,Zhang Y.,et al. (2021). High-resolution simulation and monitoring of urbanflood processes at the campus scale[J], Journal of Hydrologic Engineering.
15. Hou J., ZhouN .,et al. (2021). Rapidforecasting of urban flood inundation using multiple machine learning models. NaturalHazards.
16. Han H , Hou J.,.etc. (2021), A deep learning technique based automatic monitoring method forexperimental urban flood inundation, Journal of Hydroinformatics.
17. Han H , Hou J.,.etc. (2021), Analysis of spatial and temporal variations of precipitation inXi’an city, China during 1951-2018, Journal of Water and Climate Change.
18. Hou J., Kang Y. etc. (2020), `AGPU-based numerical model coupling hydrodynamical and morphological processes´, International Journal of Sediment Research, 35,386-394.
19. Hou J., Li B., Tong Y. etc. (2020),`Cause Analysis for a New Type of Devastating Flash Flood´, Hydrology Research.51(1), 1-16.
20. Chen, G., Hou, J.,Nie Z., etc. (2020), `High-resolutionUrban Flood Forecasting by Using a Coupled Atmospheric and Hydrodynamic Flood Models´, Frontiers in earth science,10.
21. Pan Z., Tong Y., Hou J.,etc. (2020), Hole irrigation process simulation using a soil water dynamicalmodel with parameter inversion method, Agricultural Water Management.106542.
22. Shi, B., Hou, J., Tong, Y.etc. (2020), `High-resolution numerical method for simulating advective transport process´, Environmental Engineering andManagement Journal.
23. Xuan, N., Zekun W., Hou,J., etc. (2020), `CloggingMechanism of Pervious Concrete: From Experiments to CFD-DEM Simulations´, Construction and Building Materials.
24. Hou J., Wang, N., Guo, K., et al.(2020), Effects of the temporal resolution of storm data onnumerical simulations of urban flood inundation, Journal of Hydrology.589.
25. Li D., Hou J., Xia J., et al. (2020),An Efficient Method for Approximately Simulating Drainage Capability for Urban Flood[J]. Frontiers in Earth Science, 8.
26. Hou J., Han H. etc. (2019),`Experimental investigation for impacts of rain storms and terrain slopes onlow impact development effect in an idealized urban catchment ´, Journal ofHydrology, 579, 124-176.
27. Hou J., Zhang Y., Tong Y. etc. (2019), `Experimental study for effects of terrain features and rainfall intensity on infiltration rate of modelled permeable pavement´, Journal of Environmental Management, 243 , 177-186.
28. Wang C., Hou, J., David Miller etc. (2019), `Flood risk management in sponge cities: The role of integrated simulation and 3D visualization’, International Journal of Disaster Risk Reduction´.
29. Hu P., Hou J., Zhi Z, etc. (2019), `An Improved Method Constructing 3D River Channel for Flood Modeling´, Water. 11, 403.
30. Wang T., Li P., Hou J. (2019) `Experimental investigation of freeze-thaw meltwater compound erosion and runoff energy consumption on loessal slopes´, Catena. 185,104310.
31. Hou J.,Han H., etc. (2018), `Effects of Morphological Change on Fluvial Flood Patterns Evaluated by a Hydro-geomorphological Model´, Journal of Hydroinformatics, 20(3), 633-644.
32. Hou J., Wang R., Liang Q. etc. (2018), `Efficient surface water flow simulation on static Cartesian grid with local refinement according to key topographic features´, Computer & Fluids, 176(15), 117-134.
33. Hou J, Liang Q., Wang G., Hinkelmann R., (2018), `Preface for special section on flood modeling and resilience`, Water Science and Engineering, 10(4), 265-266.
34. Hou J., Wang T. etc. (2018), `An Implicit Friction Source Term Treatment for Overland Flow Simulation Using Shallow Water Flow Model´, Journal of Hydrology, 564, 357-366.
35. Hou J., Guo K. etc. (2018), `Assessing slope forest effect on flood process caused by short-duration storm in small catchment´, Water, 10(9), 1-20.
36. Xia X., Liang Q., Ming X., Hou J. (2018), `Reply to comment by Lu et al. on 'An efficient and stable hydrodynamic model for overland flow and flood simulations'´, Water Resources Research, 54(1), 628-630.
37. Craig Lashford, Matteo Rubinato, Yanpeng Cai, Jingming Hou, etc. (2018), SuDS & Sponge Cities: A Comparative Analysis of the Implementation of Pluvial Flood Management in the UK and China, Sustainability.
38. Hou J., Wang R., Jing H, Liang Q. (2017), `An Efficient Dynamic Uniform Cartesian Grid System for Inundation Modelling`, Water Science and Engineering, 10(4), 267-274.
39. Xia X., Liang Q., Ming X., Hou J. (2017), `An efficient and stable hydrodynamic model with novel source term discretisation schemes for overland flow simulations´, Water Resources Research, 53(5), 3730-3759.
40. Liang, Q., Chen, K., Hou, J. & Wang, G. (2016), `Hydrodynamic Modelling of Flow Impact on Structures under Extreme Flow Conditions´, Journal of Hydrodynamics, accepted, 28(2), 267-274.
42. Hou, J., Qiuhua Liang, Q., Li, Z., et al. (2015), `Numerical error control for second order explicit TVD scheme with limiters in advection simulation´, Computer and Mathematics with Applications, 70(9), 2197–2209.
43. Hou, J., Liang, Q., Zhang, H. & Hinkelmann, R. (2015), `An efficient unstructured MUSCL scheme for solving shallow water equations´, Environmental Modelling and Software, 66, 131-152.
44. Liang, Q., Hou, J. & Xia, X. (2015), `Contradiction between Conservation Property and Mass Conservation in Adaptive Grid Based Shallow Flow Models:Cause and Solution´, International Journal for Numerical Methods in Fluids, 78(1), 17-36.
45. Liang, Q. & Hou, J. (2015), `Simulation of Tsunami Propagation Using Adaptive Cartesian Grids´, Coastal Engineering Journal, 57(4), 1550016-1-30.
47. Hou, J., Liang, Q., Zhang, H. & Hinkelmann, R. (2014), `Multislope MUSCL method applied to solve shallow water equations´, Computer and Mathematics with Applications, 68(12), 2012-2027.
48. Hou, J., Simons, F., Liang, Q. & Hinkelmann, R. (2014), `An improved hydrostatic non-negative water depth reconstruction for shallow water model´, Journal of Hydraulic Research, 52(3), 432–439.
49. Simons, F., Busse, T., Hou, J., Özgen, I. & Hinkelmann, R. (2014), `A model for overland flow and associated processes within the Hydroinformatics Modelling System`, Journal of Hydroinformatics, 16(2), 375-391.
50. Hou, J., Liang, Q., Simons, F. & Hinkelmann, R. (2013), `A Stable 2D Unstructured Shallow Flow Model for Simulations of Wetting and Drying over Rough Terrains´, Computer and Fluids, 82, 132-147.
51. Hou, J., Simons, F., Mahgoub, M. & Hinkelmann, R. (2013), `A robust well-balanced model on unstructured grids for shallow water flows with wetting and drying over complex topography', Computer Methods in Applied Mechanics and Engineering, 257, 126-149.
52. Hou, J., Liang, Q., Simons, F. & Hinkelmann, R. (2013), `A 2D well-balanced shallow flow model for unstructured grids with novel slope source treatment', Advances in Water Resources, 52, 107-131.
53. Hou, J., Simons, F. & Hinkelmann, R. (2013), `A new TVD method for advection simulation on 2D unstructured grids', International Journal for Numerical Methods in Fluids, 71(10), 1260-1281.
54. Hou, J., Simons, F. & Hinkelmann, R. (2012), `Improved TVD schemes for advection simulation on arbitrary grids', International Journal for Numerical Methods in Fluids, 70(3), 359-382.