Ran Guo
- Probabilistic seismic performance assessment of aqueduct structures considering different sources of uncertainty. In: Structures, v. 70 (December 2024). (2024):
- The numerical simulation of particulate reinforced composites by using a two-dimensional VCFEM formulated with plastic, thermal, and creep strain. In: Composite Structures, v. 330 (February 2024). (2024):
- Finite Element Method with 3D Polyhedron-Octree for the Analysis of Heat Conduction and Thermal Stresses in Composite Materials. In: Composite Structures, v. 327 (January 2024). (2024):
- Influences of clamping methods and weaving architectures on the ballistic performance of 3D orthogonal woven fabrics. In: Composite Structures, v. 319 (September 2023). (2023):
- Two-scale modeling of particle crack initiation and propagation in particle-reinforced composites by using microscale analysis based on Voronoi cell finite element model. In: Composite Structures, v. 316 (July 2023). (2023):
- Study on hybrid stress element of three-dimensional arbitrary polyhedron. In: Composite Structures, v. 311 (May 2023). (2023):
- (2022): Planning Strategy for Urban Building Energy Conservation Supported by Agent-Based Modeling. In: Buildings, v. 12, n. 12 (1 December 2022).
- Monte Carlo simulation for exploring the mechanical properties of particle-reinforced composites based on the scale boundary finite element method. In: Composite Structures, v. 297 (October 2022). (2022):
- Two-scale Modeling of Composites damage with Voronoi cell finite element method for microscale computation. In: Composite Structures, v. 291 (July 2022). (2022):
- Interval-thresholding effect of cooling and recreational services of urban parks in metropolises. In: Sustainable Cities and Society, v. 79 (April 2022). (2022):
- Modelling interfacial cracking and matrix cracking in particle reinforced composites using the extended Voronoi cell finite element method. In: Composite Structures, v. 255 (January 2021). (2021):
- A two dimensional VCFEM formulated with plastic, creep and thermal strain for simulate fatigue of porous material. In: Composite Structures, v. 252 (November 2020). (2020):