- Predicting compressive strength of concrete with iron waste: a BPNN approach. In: Asian Journal of Civil Engineering, v. 25, n. 7 (July 2024). (2024):
- Optimizing compressive strength in sustainable concrete: a machine learning approach with iron waste integration. In: Asian Journal of Civil Engineering, v. 25, n. 6 (24 June 2024). (2024):
- Machine learning-based prediction of concrete strengths with coconut shell as partial coarse aggregate replacement: a comprehensive analysis and sensitivity study. In: Asian Journal of Civil Engineering, v. 25, n. 4 (February 2024). (2024):
- Enhancing load capacity prediction of column using eReLU-activated BPNN model. In: Structures, v. 58 (December 2023). (2023):
- Efficient compressive strength prediction of concrete incorporating recycled coarse aggregate using Newton’s boosted backpropagation neural network (NB-BPNN). In: Structures, v. 58 (December 2023). (2023):
- Shear capacity prediction for FRCM-strengthened RC beams using Hybrid ReLU-Activated BPNN model. In: Structures, v. 58 (December 2023). (2023):
- Predictive modelling of surface chloride concentration in marine concrete structures: a comparative analysis of machine learning approaches. In: Asian Journal of Civil Engineering, v. 25, n. 2 (October 2023). (2023):
- Enhancing chloride concentration prediction in marine concrete using conjugate gradient-optimized backpropagation neural network. In: Asian Journal of Civil Engineering, v. 25, n. 1 (July 2023). (2023):
- Multi-objective optimized high-strength concrete mix design using a hybrid machine learning and metaheuristic algorithm. In: Asian Journal of Civil Engineering, v. 24, n. 3 (November 2022). (2022):
- An ensemble approach to improve BPNN model precision for predicting compressive strength of high-performance concrete. In: Structures, v. 45 (November 2022). (2022):
- Behaviour of asymmetric building with double variable frequency pendulum isolator. In: Structural Engineering and Mechanics, v. 34, n. 1 (January 2010). (2010):
- Seismic behavior of variable frequency pendulum isolator. In: Earthquake Engineering and Engineering Vibration, v. 7, n. 2 (June 2008). (2008):
- Seismic Response of Structures with Variable Friction Pendulum System. In: Journal of Earthquake Engineering, v. 13, n. 2 ( 2009). (2009):
- Response of the Double Variable Frequency Pendulum Isolator under Triaxial Ground Excitations. In: Journal of Earthquake Engineering, v. 14, n. 4 ( 2010). (2010):
- Seismic response of the double variable frequency pendulum isolator. In: Structural Control and Health Monitoring, v. 18, n. 4 (June 2011). (2011):
- Seismic behaviour of isolated fluid storage tanks: A-state-of-the-art review. In: KSCE Journal of Civil Engineering, v. 18, n. 4 (November 2013). (2013):
- Seismic response of liquid storage steel tanks with variable frequency pendulum isolator. In: KSCE Journal of Civil Engineering, v. 15, n. 6 (July 2011). (2011):
- Seismic Isolation of Bridges with Double Variable Frequency Pendulum Isolator. In: Advances in Structural Engineering, v. 15, n. 2 (February 2012). (2012):
- Behaviour of liquid storage tanks with VCFPS under near-fault ground motions. In: Structure and Infrastructure Engineering, v. 8, n. 1 (January 2012). (2012):
- Variable friction pendulum system for near-fault ground motions. In: Structural Control and Health Monitoring, v. 15, n. 4 (June 2008). (2008):