Boef23/B09_WP4_5_Python
Nov 2024 – Jan 2025
3 Months active
Languages Used
Python
Technical Skills
AerodynamicsAerospace EngineeringComputational EngineeringDocumentationEngineeringEngineering Calculations
MartijnVDV
PROFILE
Martijnvdv
Over three months, contributed to the Boef23/B09_WP4_5_Python repository by developing and refining a structural analysis and inertia calculation platform for aerospace applications. Built a cohesive framework for wingbox inertia and centroid calculations, consolidating legacy tooling and improving geometry handling for future extensibility. Enhanced the core platform with robust batch processing, expanded API capabilities, and improved authentication, while optimizing database access and observability. Applied Python and numerical computing techniques to deliver accurate engineering calculations, focusing on maintainability through code cleanup, refactoring, and documentation. Addressed technical debt and stability, enabling faster feature delivery and more reliable structural engineering workflows.
Overall Statistics
Feature vs Bugs
81%Features
Repository Contributions
188Total
Bugs
6
Commits
188
Features
26
Lines of code
1,270
Activity Months3
Your Network
38 peopleSame Organization
@student.tudelft.nl29
Shared Repositories
9
Work History
January 2025
140 Commits • 21 Features
Jan 1, 2025January 2025 performance summary for Boef23/B09_WP4_5_Python. The month focused on establishing a solid core platform, expanding API capabilities, hardening the data layer, improving observability, and cleaning up the codebase to enable safer, faster delivery of business features.
140 Commits • 21 Features
Jan 1, 2025January 2025 performance summary for Boef23/B09_WP4_5_Python. The month focused on establishing a solid core platform, expanding API capabilities, hardening the data layer, improving observability, and cleaning up the codebase to enable safer, faster delivery of business features.
January 2025
December 2024
13 Commits • 1 Features
Dec 1, 2024December 2024 monthly summary for Boef23/B09_WP4_5_Python. Focused on delivering a cohesive Wingbox inertia and centroid framework, merging past and future inertia tooling, and laying groundwork for scalable structural analysis.
December 2024
13 Commits • 1 Features
Dec 1, 2024December 2024 monthly summary for Boef23/B09_WP4_5_Python. Focused on delivering a cohesive Wingbox inertia and centroid framework, merging past and future inertia tooling, and laying groundwork for scalable structural analysis.
November 2024
35 Commits • 4 Features
Nov 1, 2024Monthly summary for 2024-11: In Boef23/B09_WP4_5_Python, delivered features and improvements that drive business value and reliability. Key features include Moment_of_inertia module enhancements with h_Fs tuning, plus broad codebase refinements (Batch 2). An experimental retry approach was explored to increase feature resilience. Batch 3 updates addressed maintenance and technical debt across the repository. Major bugs fixed/stabilizations include correcting h_Fs calibration and aligning versioning/documentation to improve reliability of inertia calculations. Overall impact: improved accuracy of inertia calculations, more maintainable code, and stronger release reliability, reducing downstream risk and enabling faster future feature delivery. Technologies/skills demonstrated: Python development, numerical computation tuning, version control discipline, code refactoring, documentation improvements, and experimental design for resilience.
35 Commits • 4 Features
Nov 1, 2024Monthly summary for 2024-11: In Boef23/B09_WP4_5_Python, delivered features and improvements that drive business value and reliability. Key features include Moment_of_inertia module enhancements with h_Fs tuning, plus broad codebase refinements (Batch 2). An experimental retry approach was explored to increase feature resilience. Batch 3 updates addressed maintenance and technical debt across the repository. Major bugs fixed/stabilizations include correcting h_Fs calibration and aligning versioning/documentation to improve reliability of inertia calculations. Overall impact: improved accuracy of inertia calculations, more maintainable code, and stronger release reliability, reducing downstream risk and enabling faster future feature delivery. Technologies/skills demonstrated: Python development, numerical computation tuning, version control discipline, code refactoring, documentation improvements, and experimental design for resilience.
November 2024
Activity
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Quality Metrics
Correctness79.2%
Maintainability84.2%
Architecture70.8%
Performance67.2%
AI Usage20.0%
Skills & Technologies
Programming Languages
Python
Technical Skills
AerodynamicsAerospace EngineeringBytecode CompilationCode CleanupCode RefactoringComputational EngineeringComputational Fluid DynamicsConfigurationConfiguration ManagementData VisualizationDocumentationEngineeringEngineering CalculationsEngineering SoftwareGeometry Calculation
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