Electrical properties of individual ZnO nanowires

Solar electric propulsion (SEP) is the dominant design option for employing low-thrust propulsion on a space mission. Spacecraft solar arrays power the SEP system but are subject to blackout periods during solar eclipse conditions. Discontinuity in power available to the spacecraft must be accounted for in trajectory optimization, but gradient-based methods require a differentiable power model. This work presents a power model that smooths the eclipse transition from total eclipse to total sunlight with a logistic function. Example trajectories are computed with differential dynamic programming, a second-order gradient-based method.

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Low-Thrust Many-Revolution Trajectory Optimization via Differential Dynamic Programming and a Sundman Transformation

Aziz

Parker²,

Scheeres

et al. 2018

J of Astronaut Sci

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Near-Earth Asteroid Characterization and Observation (NEACO) Mission to Asteroid (469219) 2016 HO3

Venigalla

Baresi

Aziz

et al. 2019

Journal of Spacecraft and Rockets

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Hybrid Differential Dynamic Programming in the Circular Restricted Three-Body Problem

Aziz

Scheeres

Lantoine

2019

Journal of Guidance, Control, and Dynamics

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LightForce photon-pressure collision avoidance: Efficiency analysis in the current debris environment and long-term simulation perspective

et al. 2016

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This work provides an efficiency analysis of the LightForce space debris collision avoidance scheme in the current debris environment and describes a simulation approach to assess its impact on the long-term evolution of the space debris environment. LightForce aims to provide just-in-time collision avoidance by utilizing photon pressure from ground-based industrial lasers. These ground stations impart minimal accelerations to increase the miss distance for a predicted conjunction between two objects. In the first part of this paper we will present research that investigates the short-term effect of a few systems consisting of 20 kW class lasers directed by 1.5 m diameter telescopes using adaptive optics. The results found such a network of ground stations to mitigate more than 85 percent of conjunctions and could lower the expected number of collisions in Low Earth Orbit (LEO) by an order of magnitude. While these are impressive numbers that indicate LightForce's utility in the short-term, the remaining 15 % of possible collisions contain (among others) conjunctions between two massive objects that would add large amount of debris if they collide. Still, conjunctions between massive objects and smaller objects can be mitigated. Hence, we choose to expand the capabilities of the simulation software to investigate the overall effect of a network of LightForce stations on the long-term debris evolution. In the second part of this paper, we will present the planned simulation approach for that effort. For the efficiency analysis of collision avoidance in the current debris environment, we utilize a simulation approach that uses the entire Two Line Element (TLE) catalog in LEO for a given day as initial input. These objects are propagated for one year and an all-on-all conjunction analysis is performed. For conjunctions that fall below a range threshold, we calculate the probability of collision and record those values. To assess efficiency, we compare a baseline (without collision avoidance) conjunction analysis with an analysis where LightForce is active. Using that approach, we take into account that collision avoidance maneuvers could have effects on third objects. Performing all-on-all conjunction analyses for extended period of time requires significant computer resources; hence we implemented this simulation utilizing a highly parallel approach on the NASA Pleiades supercomputer.

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The Plume Chaser mission: Two-spacecraft search for organics on the dwarf planet Ceres

Nayak

Mauro

Stupl

et al. 2016

Advances in Space Research

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Gtoc 9: Results From The University Of Colorado At Boulder (Team Cu Boulder)

Parrish¹,

Scheeres²,

Tardivel³

et al. 2018

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Correction: Differential Dynamic Programming in the Three-Body Problem

Aziz

Scheeres

Lantoine

2018

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Jonathan Aziz

A Smoothed Eclipse Model for Solar Electric Propulsion Trajectory Optimization

Low-Thrust Many-Revolution Trajectory Optimization via Differential Dynamic Programming and a Sundman Transformation

Near-Earth Asteroid Characterization and Observation (NEACO) Mission to Asteroid (469219) 2016 HO3

Hybrid Differential Dynamic Programming in the Circular Restricted Three-Body Problem

LightForce photon-pressure collision avoidance: Efficiency analysis in the current debris environment and long-term simulation perspective

The Plume Chaser mission: Two-spacecraft search for organics on the dwarf planet Ceres

Gtoc 9: Results From The University Of Colorado At Boulder (Team Cu Boulder)

Correction: Differential Dynamic Programming in the Three-Body Problem

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