# Hayden Project Hayden Project is a MATLAB 3DOF interceptor-versus-target engagement simulation repository for the AERO 3220 Spring 2026 coursework. The project is driven by the PDFs in [`docs/`](./docs) and implemented through the MATLAB files in [`code/`](./code). ## What The Docs Define - [`docs/AERO 3220 3DOF Information Spring 26.pdf`](./docs/AERO%203220%203DOF%20Information%20Spring%2026.pdf) defines the assignment, required plots, and evaluation settings. - [`docs/Atmosphere Model SI Units.pdf`](./docs/Atmosphere%20Model%20SI%20Units.pdf) provides the SI-unit atmosphere equations for temperature, pressure, density, acoustic speed, and Mach number for the lower-atmosphere branch shown in the handout. - [`docs/Missile and Target Data for 3DOF Spring 26.pdf`](./docs/Missile%20and%20Target%20Data%20for%203DOF%20Spring%2026.pdf) is the source packet for the missile and target geometry, propulsion, and drag data that must be transcribed into the simulation. ## Instructor Clarification Per professor guidance documented on `2026-03-28`: - The atmosphere model must be written and integrated into the 3DOF simulation. - The final atmosphere implementation must include the stratosphere model for altitudes above `11 km`. - The source files are intentionally incomplete until the missing `XX` values are replaced with real numbers from the assignment material. ## Assignment Baseline The course handout specifies these evaluation values: - Velocity pursuit guidance gain: `0.5` - Blind range: `2 m` - Acquisition range: `5000 m` - Lateral acceleration limit: `40 g` - Time after missile launch to initiate velocity-pursuit guidance: `0.5 s` - Terminal proportional-navigation gain: `4` - Commit time: `50 s` - Missile initial elevation angle: `40 deg` The required outputs are: - Target and missile trajectories in the vertical plane (`x` vs `z`) - Target speed versus time - Missile speed versus time - Missile Mach number versus time - Missile acceleration magnitude versus time since missile launch ## Current Code State - [`code/Interceptor_3DOF.m`](./code/Interceptor_3DOF.m) is the top-level driver script and writes `Ttrajectory.csv` and `Mtrajectory.csv`. - [`code/T3dxdt.m`](./code/T3dxdt.m) and [`code/M3dxdt.m`](./code/M3dxdt.m) contain the target and interceptor dynamics models. - [`code/getGuidance.m`](./code/getGuidance.m) holds the guidance-law logic. - [`code/getMD.m`](./code/getMD.m) computes miss distance near the point of closest approach. At the moment, the repository is a partially completed assignment skeleton rather than a finished simulation: - Multiple required values are still marked as `XX`. - `getRho.m` is referenced by the code but is not present in the repository, so the atmosphere model has not been integrated yet. - When `getRho.m` is added, it must support both the lower-atmosphere branch and the required stratosphere branch for `z > 11 km`. - The missile/target data packet still needs to be fully transcribed into MATLAB arrays and constants. ## Working Expectations - Keep units in SI unless a source document explicitly states otherwise. - Treat `/docs` and direct instructor clarifications as authoritative for assignment requirements and parameter values. - Record assumptions, extracted tables, unresolved issues, and verification status in [`MEMORY.md`](./MEMORY.md). - Track the active execution queue in [`TODO.md`](./TODO.md). ## For AI Agents Read [`MEMORY.md`](./MEMORY.md) before making changes. Use [`MEMORY.md`](./MEMORY.md) for durable handoff context and [`TODO.md`](./TODO.md) for the live task queue, and update the one that changed so the next agent can continue without re-discovering context.