Micro-Nozzle Simulation and Test for an Electrothermal Plasma Thruster

Croteau, Tyler J

01 December 2018

With an increased demand in Cube Satellite (CubeSat) development for low cost science and exploration missions, a push for the development of micro-propulsion technology has emerged, which seeks to increase CubeSat capabilities for novel mission concepts. One type of micro-propulsion system currently under development, known as Pocket Rocket, is an electrothermal plasma micro-thruster. Pocket Rocket uses a capacitively coupled plasma, generated by radio-frequency, in order to provide neutral gas heating via ion-neutral collisions within a gas discharge tube. When compared to a cold-gas thruster of similar size, this gas heating mechanism allows Pocket Rocket to increase the exit thermal velocity of its gaseous propellant for increased thrust. Previous experimental work has only investigated use of the gas discharge tube's orifice for propellant expansion into vacuum. This thesis aims to answer if Pocket Rocket may see an increase in thrust with the addition of a micro-nozzle, placed at the end of the gas discharge tube. With the addition of a conical ε = 10, α = 30° micro-nozzle, performance increases of up to 6% during plasma operation, and 25% during cold gas operation, have been observed. Propellant heating has also been observed to increase by up to 60 K within the gas discharge tube.

Propulsion

Electric Propulsion

Plasma

CubeSat

CFD

Nozzle

Propulsion and Power

Evaluación de un propulsor electrospray para misiones de CubeSats de tres unidades

Maldonado Aylwin, Ignacio Javier

January 2018

Ingeniero Civil Eléctrico / Las misiones de satélites tipo CubeSat actualmente no tienen planificado el periodo posterior a la vida operacional del satélite. Al ser lanzados cada vez en mayor cantidad, estas naves tienen el potencial de congestionar el espacio en órbita terrestre baja y presentar un peligro creciente de colisiones. Dentro de las estrategias para remover a estas naves de la órbita es la de descenso controlado o deorbitación realizado con propulsores eléctricos. Dentro de las tecnologías existentes de propulsores eléctricos se encuentra el electrospray que presenta una alternativa atractiva para su uso en satélites tipo CubeSat. En el presente trabajo se evalúa esta tecnología y su uso en la deorbitación de CubeSats de tres unidades, para considerar su desarrollo para misiones futuras. En la primera parte del presente trabajo se presenta un marco teórico que permite entender las problemáticas que presenta el diseño y construcción de sistemas para CubeSats. Luego se explora la propulsión espacial eléctrica para estudiar su impacto los cambios orbitales de una órbita terrestre baja. Finalmente se presenta el fenómeno basal de la tecnología electrospray para luego comprenderlo en términos de su desempeño como sistema de propulsión espacial eléctrica. Se construyó un experimento en base a un capilar para estudiar las variables de importancia expuestas en la primera parte de este trabajo. En primer lugar se determinó la región de operación del experimento donde se producía de forma estable el fenómeno basal del electrospray, cuantificando las variables de importancia. De esta región de estabilidad se calcularon los parámetros de desempeño propulsivo de empuje e impulso específico en base un modelo físico. Luego se realizan pruebas para estudiar el comportamiento del experimento ante el vacío presente fuera de la atmósfera terrestre. Una vez determinados los parámetros de desempeño propulsivo, se realizan cálculos para determinar el desempeño total de un propulsor práctico utilizando esta tecnología en los puntos de operación que maximizan cada parámetro respectivamente. Junto al desempeño, se estima el volumen utilizado y la cantidad de propelente factible. Finalmente se evaluó el desempeño del propulsor propuesto en términos de vida orbital mediante la simulación en el software STK. Estas simulaciones incluyen dos maniobras cuyos resultados son comparados a los resultados de una caída sin la asistencia de propulsión. Mediante las simulaciones se obtuvieron reducciones significativas a la vida orbital del satélite lo que el propulsor posee el desempeño suficiente para su uso en deorbitación de CubeSats de tres unidades.

Propulsión eléctrica

Cubesat

Electrospray

Predicting Crop Yield Using Crop Models and High-Resolution Remote Sensing Technologies

Ziliani, Matteo Giuseppe

01 1900

By 2050, food consumption and agricultural water use will increase as a result of a global population that is projected to reach 9 billion people. To address this food and water security challenge, there has been increased attention towards the concept of sustainable agriculture, which has a broad aim of securing food and water resources while preserving the environment for future generations. An element of this is the use of precision agriculture, which is designed to provide the right inputs, at the right time and in the right place. In order to optimize nutrient application, water intakes, and the profitability of agricultural areas, it is necessary to improve our understating and predictability of agricultural systems at high spatio-temporal scales. The underlying goal of the research presented herein is to advance the monitoring of croplands and crop yield through high-resolution satellite data. In addressing this, we explore the utility of daily CubeSat imagery to produce the highest spatial resolution (3 m) estimates of leaf area index and crop water use ever retrieved from space, providing an enhanced capacity to provide new insights into precision agriculture. The novel insights on crop health and conditions derived from CubeSat data are combined with the predictive ability of crop models, with the aim of improving crop yield predictions. To explore the latter, a sensitivity analysis-linked Bayesian inference framework was developed, offering a tool for calibrating crop models while simultaneously quantifying the uncertainty in input parameters. The effect of integrating higher spatio-temporal resolution data in crop models was tested by developing an approach that assimilates CubeSat imagery into a crop model for early season yield prediction at the within-field scale. In addition to satellite data, the utility of even higher spatial resolution products from unmanned aerial vehicles was also examined in the last section of the thesis, where future research avenues are outlined. Here, an assessment of crop height is presented, which is linked to field biomass through the use of structure from motion techniques. These results offer further insights into small-scale field variabilities from an on-demand basis, and represent the cutting-edge of precision agricultural advances.

Crop Yield Prediction

Crop Modeling

CubeSat

Data Assimilation

APSIM

LAI

Analysis of Star Identification Algorithms due to Uncompensated Spatial Distortion

Brätt, Steven Paul

01 May 2013

With the evolution of spacecraft systems, we see the growing need for smaller, more affordable, and robust spacecrafts that can be jettisoned with ease and sent to sites to perform a myriad of operations that a larger craft would prohibit, or that can be quickly manipulated from performing one task into another. The developing requirements have led to the creation of Nano-Satellites, or CubeSats. The question then remains, how to navigate the expanse of space with such a minute spacecraft? A solution to this is using the stars themselves as a means of navigation. This can be accomplished by measuring the distance between stars in a camera image and determining the stars' identities. Once identified, the spacecraft can obtain its position and facing. A series of star identification algorithms called Lost in Space Algorithms (LISAs) are used to recognize the stars in an image and assess the accuracy and error associated with each algorithm. This is done by creating various images from a simulated camera, using a program called MATLAB, along with images of actual stars with uncompensated errors. It is shown how suitable these algorithms are for use in space navigation, what constraints and impediments each have, and if low quality cameras using these algorithms can solve the Lost in Space problem.

Algorithm

CubeSat

Error

Hipparcos

Identification

Star

Engineering

Mechanical Engineering

Distributed Electrical Power System in Cubesat Applications

Burt, Robert

01 December 2011

The single bus voltage distributed architecture is the mainstay architecture for small satellite spacecraft. Even large satellites follow this architecture. While they may have more than one voltage that is distributed, such as a high voltage bus and a low voltage bus, within a subsystem, there is usually one bus voltage. Each subsystem component is responsible for further regulation or point-of-load regulation. The Nano-satellite class, and more particularly the cubesat, have broken away from this norm and overwhelmingly implement a centralized architecture. With the advances of small, highly efficient monolithic dc-dc converters, this thesis researches the possibilities of implementing the distributed architecture at the cubesat scale. The Goal is to create a very efficient electrical power system design that has a high degree of utility, allowing it to be used for multiple missions, without having to redesign the system every time.

Architecture

Converter

Cubesat

Distributed

EPS

Power

Electrical and Computer Engineering

Plasma Velocity Vector Instrument for Small Satellites (PVVISS)

Hatch, William Smith

01 May 2016

Low-earth orbit (LEO) contains plasma which can impact satellite charging and radio frequency (RF) communications. Quantifying both the composition and movement of ions in LEO can improve efficiency of the forecasting models that predict the impact plasma will have on satellite communications and accuracy of global positioning satellite measurements. Two instruments known as the Retarding Potential Analyzer (RPA) and the Ion Drift Meter (IDM) have been used in tandem to measure ionospheric properties including ion temperature, velocity, and density. These instruments are costly and occupy large areas on a spacecraft. In recent years, space mission budgets have diminished. This change has driven innovation towards creating new instruments which are compatible with smaller and cheaper satellites yet still yield measurements of comparable quality. This thesis presents the design of a new instrument that encompasses the functionality of both the RPA and IDM, known as the Plasma Velocity Vector Instrument for Small Satellites (PVVISS). PVVISS has compact form factor and low power requirements, making it a viable option for smaller, low cost nano-satellite sized missions. Missions utilizing the PVVISS sensor will allow increased exploration of the ionospheric impact on satellite communications.

Retarding Potential Analyzer

Ion Drift Meter

CubeSat

Electrical and Computer Engineering

Design of Miniaturized Time-of-Flight Reflectron Mass Spectrometer for Upper Atmosphere Density Measurements

Pyle, Michelle Lynn

01 May 2016

Variations of gas and plasma density and composition in Earth’s thermosphere and ionosphere are key indicators of interactions between different layers of Earth’s atmosphere. The nature of interactions between neutral and ion species in the upper atmosphere is an active area of study in Heliophysics and there is much to learn about the dynamic relationship between the ionosphere and neutral thermosphere. Mass Spectrometers are among an array of instruments used to explore Earth’s upper atmosphere and other space environments. In the past, data from mass spectrometers flown in low earth orbit has been used to improve atmospheric models and to study the dynamics of the ionosphere and thermosphere. Historically, these instruments are substantial in size and deployed on larger satellite platforms. Data from these larger instruments generally provide information from a specific point in time at a single location. Studies of atmospheric density and composition with multiple locations for each time point could be performed by CubeSat swarms if proper instrumentation were available to fit CubeSat payload restrictions. The proposed miniaturized time-of-flight (TOF) mass spectrometer (MS) will have a mass resolution and range sufficient for measuring the composition of Earth’s thermosphere and ionosphere while operating within the power and space constraints of a CubeSat. The capabilities of this instrument could dramatically reduce the cost of future missions while simultaneously enhancing the science return. The design employs miniaturization of TOF-MS technology, including resolution refinement techniques used for larger instruments and standard concepts for TOF-MS components such as acceleration grids, a Bradbury-Nielsen wire gate, a gridless ion mirror, and microchannel plate detector.

Analog Circuit

CubeSat

Mass Spectrometer

Electrical and Computer Engineering

Calibration and Characterization of Cubesat Magnetic Sensors Using a Helmholtz Cage

Foley, Justin Dean

01 December 2012

Small satellites, and CubeSats in particular, have quickly become a hot topic in the aerospace industry. Attitude determination is currently one of the most intense areas of development for these miniaturized systems and future Cal Poly satellite missions will depend heavily on magnetometers. In order to utilize magnetometers as a viable source of attitude knowledge, precise calibration is required to ensure the greatest accuracy achievable. This paper outlines a procedure for calibrating and testing magnetometers on the next generation of Cal Poly CubeSates, utilizing a Helmholtz cage to simulate any desired orbital magnetic field that would be experienced by a spacecraft around Earth, as well as investigation of magnetic interference as a result of on-board electrical activity.

CubeSat

picosatellite

small satellite

Helmholtz

magnetic

magnetometer

Aerospace Engineering

Engineering

Development of an Imager System Optimized for Low-Power, Limited-Bandwidth Space Applications

Glassey, Kalia R

01 April 2009

A relatively new picosatellite standard, CubeSats have traditionally been used for simple educational missions. As CubeSats become more complex and utilize more complex sensors such as imagers, they gain enhanced credibility as satellite platforms. Imaging systems on CubeSats have the potential to be used for a variety of uses, such as earth and weather monitoring, attitude determination, and remote sensing. However the size and power limitations of CubeSats pose an interesting challenge to the design of a capable, robust imaging system. This thesis outlines the objectives and requirements of CP-3’s imaging system, and describes the development process and methods. Test results from the imaging system are included, as well as lessons learned gleaned from CP-3’s on-orbit operations. This document can serve as a guideline for other teams wishing to develop imaging systems. While other developers may have different requirements or constraints, this roadmap illustrates each of the many considerations that must be taken into account when designing an imaging system.

image compression

satellite

CubeSat

imager

CMOS

ISM S-band CubeSat Radio Designed for the PolySat System Board

Francis, Craig Lee

01 May 2016

Cal Poly’s PolySat CubeSat satellites have begun to conduct more complex and scientifically significant experiments. The large data products generated by these missions demonstrate the necessity for higher data rate communication than currently provided by the PolySat UHF radio. This thesis leverages the proliferation of consumer wireless monolithic transceivers to develop a 250kbps to 2000kbps, 2W CubeSat radio operating within the 2.45GHz Industrial, Scientific, and Medical (ISM) radio band. Estimating a link budget for a realistic CubeSat leads to the conclusion that this system will require a large deployable CubeSat antenna, large earth station satellite dish, and a fine-pointing attitude control system. Noise floor measurements of a CubeSat ground station demonstrate that terrestrial ISM interference can be minimized to below the thermal noise floor by carefully choosing the operating frequency. The radio is specifically designed as a daughter board for the PolySat System Board with a direct interface to the embedded Linux microprocessor. A state-of-the-art ZigBee transceiver evaluation board is measured to confirm its suitability for a CubeSat radio. A schematic is developed, which integrates the transceiver, power amplifier, low noise amplifier, amplifier protection circuitry, switching regulators, and RF power measurement into a single printed circuit board assembly (PCBA). The circuitry is then squeezed into a high-density, 1.4” x 3.3” layout. The PCBA is then manufactured, troubleshot, tuned, and characterized.

ISM

S-Band

CubeSat

PolySat

Radio

Transceiver

Electrical and Electronics