Is this project an undergraduate, graduate, or faculty project?

Undergraduate

Project Type

group

Campus

Daytona Beach

Authors' Class Standing

Divyeshwari Vansadia, Senior

Lead Presenter's Name

Divyeshwari P. Vansadia

Lead Presenter's College

DB College of Arts and Sciences

Faculty Mentor Name

Dr. Surabhi Singh

Abstract

The target is to develop a toolbox for the ascent trajectory of a launch vehicle using an analytical/numerical approach. The mission profile would be optimized from Launch to payload delivery in the Lower Earth Orbit (LEO). Reduce launch delays due to inaccuracy in estimating atmospheric and wind profiles.

The toolbox includes trajectory optimization within the atmosphere to achieve LEO, Orbit transfer maneuvers, and Orbit maintenance to counter the effects the atmospheric drag and oblateness to ensure payload delivery to the intended orbit. Input factors are independent (e.g., orbital elements, satellite orientation) and dependent (e.g., engine staging, burn rate, atmospheric drag). They collectively shape the rocket's trajectory and performance throughout the flight.

The toolbox, designed for use in industry for early mission design, uses impulsive movements to accelerate the optimization process.

Did this research project receive funding support (Spark, SURF, Research Abroad, Student Internal Grants, Collaborative, Climbing, or Ignite Grants) from the Office of Undergraduate Research?

Yes, Spark Grant

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Toolbox for optimizing spacecraft ascent trajectory from launch to lower earth orbit

The target is to develop a toolbox for the ascent trajectory of a launch vehicle using an analytical/numerical approach. The mission profile would be optimized from Launch to payload delivery in the Lower Earth Orbit (LEO). Reduce launch delays due to inaccuracy in estimating atmospheric and wind profiles.

The toolbox includes trajectory optimization within the atmosphere to achieve LEO, Orbit transfer maneuvers, and Orbit maintenance to counter the effects the atmospheric drag and oblateness to ensure payload delivery to the intended orbit. Input factors are independent (e.g., orbital elements, satellite orientation) and dependent (e.g., engine staging, burn rate, atmospheric drag). They collectively shape the rocket's trajectory and performance throughout the flight.

The toolbox, designed for use in industry for early mission design, uses impulsive movements to accelerate the optimization process.

 

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