Satellite Mission Analysis and Design based on Orekit

Trajectory optimization framework that uses indirect methods

B2XKlaim: a BPMN-to-X-Klaim toolchain for model-driven multi-robot mission design.

Aerospace Engineering Portfolio - GNC Systems, Mission Analysis, and Space Systems Design

Preliminary Design Of The Trajectory For An Interplanetary Mission Between Earth And Saturn With Natural Gravitatory Assistance From Jupiter

35 MCP tools for aerospace engineering — structural analysis, margin of safety, trusses, aerodynamics, compressible flow, thermodynamics, aircraft performance, rocket nozzle design, and mission planning

Natural-language to validated GMAT .script — RAG-grounded generation, lint-checked against gmat-script, with a model-agnostic CLI.

High-fidelity illumination modeling and N-body trajectory optimization for Enceladus mission design. Developed in MATLAB for the ESA-funded GIGANTES project.

Delta-v planner for circular-to-circular transfers (Hohmann, bi-elliptic, plane-change). Impulsive burns, quick trade-offs. Python 3.10+.

Research framework for early-phase autonomous rover operations design, combining MBSE, ConOps, AI planning, and validation-oriented simulation for robotic space exploration.

Depp Space Trajectory Design & Optimization in Python

A modular, professional-grade digital engineering and trajectory propagation platform for spacecraft propulsion systems. Includes high-fidelity physics models (Hall effect, gridded ion, chemical, nuclear, and VASIMR engines), multi-node thermal LPN solvers, power simulation, state estimation (EKF), and automated engineering advisor analytics.