Latest Articles for Aerodynamics

This article presents a new method for quick pressure calculations from velocity data.

Research reveals techniques for improving performance of low-aspect-ratio wings through airflow management.

New methods improve control of turbulent separation bubbles for better vehicle efficiency.

Research focuses on active systems to reduce aerodynamic drag in cars.

Exploring the complexities of turbulent flow close to surfaces.

This article examines fluid behavior around long shapes under varied conditions.

Research focuses on improving designs in fluid dynamics through topology optimization techniques.

New methods aim to prevent loss of control for safer flight operations.

A new method improves accuracy in predicting electron behavior in hypersonic conditions.

New slip-wall models improve accuracy and efficiency in simulating turbulent flows.

Research shows promise in reducing drag with multi-agent reinforcement learning.

Study reveals how textured surfaces affect fluid movement and flow dynamics.

A study on airflow instability affecting aircraft performance during flight.

Research on new propulsion systems aims to improve satellite operations in very low Earth orbits.

A new dataset enhances the study of car aerodynamics for better design efficiency.

Learn about turbulent boundary layers and their impact on vehicle performance.

This study evaluates simulation methods for accurate aircraft lift predictions.

Learn how coaxial rotors improve helicopter performance at high speeds.

Analyzing flow patterns and their impacts on hypersonic vehicle performance.

A competition focuses on using ML for airfoil design simulations.

A new method improves aircraft design calculations for lift and drag.

This study analyzes how road conditions affect vehicle airflow and pressure distribution.

New method improves speed and accuracy in gas flow simulations.

Study reveals how fabric properties impact parachute performance during landing.

This study analyzes three-dimensional turbulent boundary layers around swept blunt bodies.

A new framework improves energy capture in airborne wind energy systems with flexible tethers.

Open dataset aids study of Windsor body aerodynamics for improved car design.

Exploring the role of surrogate models in improving aircraft design efficiency.

The HOPU method enhances predictions in turbulent flow through advanced computational techniques.

An in-depth look at how wing movements affect flight efficiency.

Examining how Reynolds number influences airflow and performance in low-aspect-ratio wings.

This study examines how airfoil movements impact lift in aviation and wind energy.

A new approach enhances airfoil designs through machine learning and data-driven methods.

New dataset enhances automotive aerodynamics research and design efficiency.

Examining how tip speed ratio affects wind turbine efficiency and wake behavior.

New method uses strain measurements for aerodynamic load estimation in hypersonic flight.

Examining how different shapes influence air movement over surfaces.

This study reveals how fetch length affects turbulent boundary layer recovery in fluid dynamics.

Exploring the Lattice Boltzmann Method for fluid dynamics in transonic flows.

Study explores crater formation from air jet impacts on granular materials.