Your search keyword '"Satyadharma, Adhika"' showing total 3 results

1. Assessing physics-informed neural network performance with sparse noisy velocity data.

Author

Satyadharma, Adhika, Chern, Ming-Jyh, Kan, Heng-Chuan, Harinaldi, and Julian, James

Subjects

*SPECIAL functions, *DATA quality, *NOISE, *VELOCITY

Abstract

The utilization of data in physics-informed neural network (PINN) may be considered as a necessity as it allows the simulation of more complex cases with a significantly lower computational cost. However, doing so would also make it prone to any issue with the data quality, including its noise. This study would primarily focus on developing a special loss function in the PINN to allow an effective utilization of noisy data. However, a study regarding the data location and amount was also conducted in order to allow a better data utilization in PINN. This study was conducted on a lid-driven cavity flow at Re = 200, 1000, and 5000 with a dataset of less than 100 velocity data and a maximum noise of 10% of the maximum velocity. The results show that by ensuring the data are distributed in a certain configuration, it has zero noise, and by using as much data as possible, the computational cost of PINN can be significantly reduced compared to without using any data at all. For Re = 200, it is 7.4 faster by using data, and this speedup is potentially higher for higher Re cases. For the noise in particular, it does not only make the PINN more inaccurate but also necessitate the usage of more data as this is the only way to make it more accurate. This issue though is capable to be solved with our new method, which only uses the data as an approximate solution, and the governing equation would figure out the details. This method was also shown to be capable to improve the PINN accuracy with the potential to almost completely eliminating the noise effect. [ABSTRACT FROM AUTHOR]

Published

2024

2. Flow Control with Multi-DBD Plasma Actuator on a Delta Wing

Author

Harinaldi, Muhammad Denni Kesuma, Irwansyah, Ridho, Julian, James, Satyadharma, Adhika, Harinaldi, Muhammad Denni Kesuma, Irwansyah, Ridho, Julian, James, and Satyadharma, Adhika

Abstract

In this study, an experiment was carried out to measure the performance of a delta wing with 65° swept angle. The measurement of lift and drag on the delta wing with and without plasma actuator was the main focus of this research. Multi-DBD plasma actuator was implemented on top of the wing. The experiment was conducted in a wind tunnel with a free stream velocity of 5.74 m/s or at Reynolds number of 83000. The performance of the wing was positively affected by the use of plasma actuator, indicated by the increasing lift coefficient and the decreasing drag coefficient, as maximum increase of 0.078 in lift coefficient and 0.053 decrease in drag coefficient were obtained.

Published

2021

3. The Performance of a Gradient-Based Method to Estimate the Discretization Error in Computational Fluid Dynamics.

Author

Satyadharma, Adhika and Harinaldi

Subjects

DISCRETIZATION methods, COMPUTATIONAL fluid dynamics

Abstract

Although the grid convergence index is a widely used for the estimation of discretization error in computational fluid dynamics, it still has some problems. These problems are mainly rooted in the usage of the order of a convergence variable within the model which is a fundamental variable that the model is built upon. To improve the model, a new perspective must be taken. By analyzing the behavior of the gradient within simulation data, a gradient-based model was created. The performance of this model is tested on its accuracy, precision, and how it will affect a computational time of a simulation. The testing is conducted on a dataset of 36 simulated variables, simulated using the method of manufactured solutions, with an average of 26.5 meshes/case. The result shows the new gradient based method is more accurate and more precise then the grid convergence index(GCI). This allows for the usage of a coarser mesh for its analysis, thus it has the potential to reduce the overall computational by at least by 25% and also makes the discretization error analysis more available for general usage. [ABSTRACT FROM AUTHOR]

Published

2021