Aerodynamic Analysis
The aerodynamic performance of the wing was analyzed using ANSYS Fluent, where a wind tunnel simulation was created around half of the wing. The computational domain was meshed with a CFD-compatible triangular grid, as shown, ensuring accurate airflow analysis around the wing surface. The mesh was refined to capture critical aerodynamic effects while maintaining computational efficiency.
Weichen Luo
Project Engineers
Aerodynamic Analysis
The aerodynamic performance of the wing was analyzed using ANSYS Fluent, where a wind tunnel simulation was created around half of the wing. The computational domain was meshed with a CFD-compatible triangular grid, as shown, ensuring accurate airflow analysis around the wing surface. The mesh was refined to capture critical aerodynamic effects while maintaining computational efficiency.
Weichen Luo
Project Engineers
Aerodynamic Analysis
The aerodynamic performance of the wing was analyzed using ANSYS Fluent, where a wind tunnel simulation was created around half of the wing. The computational domain was meshed with a CFD-compatible triangular grid, as shown, ensuring accurate airflow analysis around the wing surface. The mesh was refined to capture critical aerodynamic effects while maintaining computational efficiency.
Weichen Luo
Project Engineers
Aerodynamic Analysis
The aerodynamic performance of the wing was analyzed using ANSYS Fluent, where a wind tunnel simulation was created around half of the wing. The computational domain was meshed with a CFD-compatible triangular grid, as shown, ensuring accurate airflow analysis around the wing surface. The mesh was refined to capture critical aerodynamic effects while maintaining computational efficiency.
Weichen Luo
Project Engineers
AI enabled payload dispensing
Our AI/autonomy stack powers the wildfire-response VTOL: it fuses onboard sensors to stabilize flight, navigate to targets, and compute precise payload-release timing in challenging conditions. We tune the system in simulation and refine it with flight data to improve accuracy, reliability, and responsiveness—bringing safer, faster aerial support to firefighters.
Finn Johnson
Project Engineers
AI enabled payload dispensing
Our AI/autonomy stack powers the wildfire-response VTOL: it fuses onboard sensors to stabilize flight, navigate to targets, and compute precise payload-release timing in challenging conditions. We tune the system in simulation and refine it with flight data to improve accuracy, reliability, and responsiveness—bringing safer, faster aerial support to firefighters.
Finn Johnson
Project Engineers
AI enabled payload dispensing
Our AI/autonomy stack powers the wildfire-response VTOL: it fuses onboard sensors to stabilize flight, navigate to targets, and compute precise payload-release timing in challenging conditions. We tune the system in simulation and refine it with flight data to improve accuracy, reliability, and responsiveness—bringing safer, faster aerial support to firefighters.
Finn Johnson
Project Engineers
AI enabled payload dispensing
Our AI/autonomy stack powers the wildfire-response VTOL: it fuses onboard sensors to stabilize flight, navigate to targets, and compute precise payload-release timing in challenging conditions. We tune the system in simulation and refine it with flight data to improve accuracy, reliability, and responsiveness—bringing safer, faster aerial support to firefighters.
Finn Johnson
Project Engineers