Time-Dependent Strategy for Improving Aortic Blood Flow Simulations with Boundary Control and Data Assimilation

TL;DR

This paper presents a novel integrated method combining data assimilation and boundary optimization to enhance the accuracy of time-dependent blood flow simulations in arteries, validated with synthetic noisy data.

Contribution

The study introduces a combined data assimilation and boundary optimization approach specifically designed for time-dependent blood flow simulations, improving predictive accuracy.

Findings

Reduced discrepancies in velocity magnitudes compared to noisy data

High correlation between optimized and exact pressure values

Improved wall shear stress predictions after optimization

Abstract

Understanding time-dependent blood flow dynamics in arteries is crucial for diagnosing and treating cardiovascular diseases. However, accurately predicting time-varying flow patterns requires integrating observational data with computational models in a dynamic environment. This study investigates the application of data assimilation and boundary optimization techniques to improve the accuracy of time-dependent blood flow simulations. We propose an integrated approach that combines data assimilation methods with boundary optimization strategies tailored for time-dependent cases. Our method aims to minimize the disparity between model predictions and observed data over time, thereby enhancing the fidelity of time-dependent blood flow simulations. Using synthetic time-series observational data with added noise, we validate our approach by comparing its predictions with the known exact solution, computing the L2 norm to demonstrate improved accuracy in time-dependent blood flow simulations. Our results indicate that the optimization process consistently aligns the optimized data with the exact data. In particular, velocity magnitudes showed reduced discrepancies compared to the noisy data, aligning more closely with the exact solutions. The analysis of pressure data revealed a remarkable correspondence between the optimized and exact pressure values, highlighting the potential of this methodology for accurate pressure estimation without any previous knowledge on this quantity. Furthermore, wall shear stress (WSS) analysis demonstrated the effectiveness of our optimization scheme in reducing noise and improving prediction of a relevant indicator determined at the postprocessing level. These findings suggest that our approach can significantly enhance the accuracy of blood flow simulations, ultimately contributing to better diagnostic and therapeutic strategies.