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61	Integrating Spatial Audio in Voice Guidance Systems Lopes Batres, Mario January 2020 (has links) Navigation systems are commonly used in our daily lives. Research has shown that spatial audio presents one opportunity for more effectively communicating to the driver the direction of the next manoeuvre. This thesis project proposes a new feature for the spatialisation of the audio cues triggered by a mobile navigation system by using a virtualised vector-based panning (VVBP) architecture for the encoding and decoding. The prototype developed during this thesis enables the spatialisation using headphones- or speakers- based systems. This study aims to promote a new sound experience to the user, which can be used to increase the safety and performance of driving. Based on an expert review and a user test, the application was tested on different scenarios. The participants selected during these sessions were part of HERE Technologies, which made possible to reach design experts who knew the current application provided by the company beforehand, making easier the comparison with the proposal. This selection could also present a limitation on the study since the users might have a personal bias for seeing new features in a product which have already worked on. Analysis of the results obtained during the testing session demonstrated high satisfaction with the feature by the users and a better understanding of their surroundings. Consequently, this indicates that spatial audio can improve the performance of driving by introducing a new source of information for positioning the next turn or obstacle. Further research is needed to identify other factors that could strengthen the effectiveness of the product. / Navigationssystem används ofta i våra dagliga liv. Forskning har visat att rumsligt ljud ger ett tillfälle att effektivare kommunicera till föraren i riktningen för nästa manöver. Detta avhandlingsprojekt föreslår en ny funktion för spatialisering av ljudkoder som utlöses av ett mobilnavigeringssystem med hjälp av en virtualiserad vektorbaserad panorering (VVBP) arkitektur för kodning och avkodning. Prototypen som utvecklats under denna avhandling möjliggör spatialisering med hörlurar eller högtalarbaserade system. Denna studie syftar till att främja en ny ljudupplevelse för användaren, som kan användas för att öka säkerheten och prestandan vid körning. Baserat på en expertgranskning och ett användartest testades applikationen på olika scenarier. Deltagarna som valdes ut under dessa sessioner var en del av HERE Technologies, som gjorde det möjligt att nå konstruktionsexperter som kände till den nuvarande applikationen från företaget i förväg, vilket underlättar jämförelsen med förslaget. Detta val kan också utgöra en begränsning av studien eftersom användarna kan ha en personlig fördom för att se nya funktioner i en produkt som redan har arbetat med. Analys av resultaten som erhölls under testperioden visade hög tillfredsställelse med funktionen hos användarna och en bättre förståelse för deras omgivning. Konsekvensen indikerar att rumsligt ljud kan förbättra körförmågan genom att införa en ny informationskälla för positionering av nästa sväng eller hinder. Ytterligare forskning behövs för att identifiera andra faktorer som kan stärka produktens effektivitet. spatial sound driving navigation guidance augmented reality rumsligt ljud körning navigering förstärkt verklighet Computer and Information Sciences Data- och informationsvetenskap
62	Assessment of Asymmetric Flight on Solar UAS Belfield, Eric 01 December 2016 (has links) (PDF) An investigation was conducted into the feasibility of using an unconventional flight technique, asymmetric flight, to improve overall efficiency of solar aircraft. In this study, asymmetric flight is defined as steady level flight in a non-wings-level state in- tended to improve solar incidence angle. By manipulating aircraft orientation through roll angle, solar energy collection is improved but aerodynamic efficiency is worsened due to the introduction of additional trim drag. A point performance model was devel- oped to investigate the trade-off between improvement in solar energy collection and additional drag associated with asymmetric flight. A mission model with a focus on aircraft orbits was then developed via integration of the point performance model over a set of discrete points. It is shown that there is a non-zero bank angle where optimal net power is achieved for a given aircraft orientation, flight condition, and sun position. The study also shows that there is improvement in overall efficiency over conventional flight for various orbit shapes and winds aloft. This indicates that there is potential value in not only flight path planning, but also in orientation planning for solar aircraft. asymmetric flight aircraft performance solar aircraft UAS Aerodynamics and Fluid Mechanics Aeronautical Vehicles Other Aerospace Engineering
63	Effect Of Operator Control Configuration On Unmanned Aerial System Trainability Neumann, John 01 January 2006 (has links) Unmanned aerial systems (UAS) carry no pilot on board, yet they still require live operators to handle critical functions such as mission planning and execution. Humans also interpret the sensor information provided by these platforms. This applies to all classes of unmanned aerial vehicles (UAV's), including the smaller portable systems used for gathering real-time reconnaissance during military operations in urban terrain. The need to quickly and reliably train soldiers to control small UAS operations demands that the human-system interface be intuitive and easy to master. In this study, participants completed a series of tests of spatial ability and were then trained (in simulation) to teleoperate a micro-unmanned aerial vehicle equipped with forward and downward fixed cameras. Three aspects of the human-system interface were manipulated to assess the effects on manual control mastery and target detection. One factor was the input device. Participants used either a mouse or a specially programmed game controller (similar to that used with the Sony Playstation 2 video game console). A second factor was the nature of the flight control displays as either continuous or discrete (analog v. digital). The third factor involved the presentation of sensor imagery. The display could either provide streaming video from one camera at a time, or present the imagery from both cameras simultaneously in separate windows. The primary dependent variables included: 1) time to complete assigned missions, 2) number of collisions, 3) number of targets detected, and 4) operator workload. In general, operator performance was better with the game controller than with the mouse, but significant improvement in time to complete occurred over repeated trials regardless of the device used. Time to complete missions was significantly faster with the game controller, and operators also detected more targets without any significant differences in workload compared to mouse users. Workload on repeated trials decreased with practice, and spatial ability was a significant covariate of workload. Lower spatial ability associated with higher workload scores. In addition, demographic data including computer usage and video gaming experience were collected and analyzed, and correlated with performance. Higher video gaming experience was also associated with lower workload. Human-computer interaction training simulation control interface unmanned systems input devices aerial vehicle
64	System Integration and Attitude Control of a Low-Cost Spacecraft Attitude Dynamics Simulator Kinnett, Ryan L 01 March 2010 (has links) (PDF) The CalPoly Spacecraft Attitude Dynamics Simulator mimics the rotational dynamics of a spacecraft in orbit and acts as a testbed for spacecraft attitude control system development and demonstration. Prior to this thesis, the simulator platform and several subsystems had been designed and manufactured, but the total simulator system was not yet capable of closed-loop attitude control. Previous attempts to make the system controllable were primarily mired by data transport performance. Rather than exporting data to an external command computer, the strategy implemented in this thesis relies on a compact computer onboard the simulator platform to handle both attitude control processing and data acquisition responsibilities. Software drivers were created to interface the computer’s data acquisition boards with Matlab, and a Simulink library was developed to handle hardware interface functions and simplify the composition of attitude control schemes. To improve the usability of the system, a variety of actuator control, hardware testing, and data visualization utilities were also created. A closedloop attitude control strategy was adapted to facilitate future sensor installations, and was tested in numerical simulation. The control model was then updated to interface with the simulator hardware, and for the first time in the project history, attitude control was performed onboard the CalPoly spacecraft attitude dynamics simulator. The demonstration served to validate the numerical model and to verify the functionality of the entire simulator system. Astrodynamics Space Vehicles
65	Autonomous Formation Flying and Proximity Operations Using Differential Drag On the Mars Atmosphere Villa, Andres Eduardo 01 June 2016 (has links) (PDF) Due to mass and volume constraints on planetary missions, the development of control techniques that do not require fuel are of big interest. For those planets that have a dense enough atmosphere, aerodynamic drag can play an important role. The use of atmospheric differential drag for formation keeping was first proposed by Carolina L. Leonard in 1986, and has been proven to work in Earth atmosphere by many missions. Moreover, atmospheric drag has been used in the Mars atmosphere as aerobraking technique to decelerate landing vehicles, and to circularize the orbit of the spacecraft. Still, no literature was available related to formation flying on Mars. To analyze the use of differential drag on the Mars atmosphere, the researcher accessed the two high resolution models available: NASA’s Mars-GRAM and ESA’s Mars Climate Database. These models allowed the simulation of conditions that a spacecraft would experience while in orbit around the planet. To explore the feasibility, the researcher first conducted a study where Mars atmosphere density was compared to Earth atmosphere, determining its applicability. Then, a simulation using MATLAB® was conducted, using a Keplerian two-body problem including the effects of Mars zonal harmonics (i.e. J2) and drag perturbations. Two 6U CubeSat were used in the simulation with deployable drag plates of different sizes, giving the possibility of having five differential drag scenarios as means of formation control. The conclusions showed that, although with some limitations, the use of differential drag as means of autonomous formation flying and proximity operations control is feasible using proven techniques previously validated in Low Earth Orbit. Lyapunov control was selected as the control strategy, where three different methods were evaluated and compared. Mars Formation Flying Proximity Operations Differential Drag Lyapunov Control Theory Guidance Navigation Perturbations Aerospace Engineering Astrodynamics
66	A Novel All Wheel Drive Torque Vectoring Control System Applied to Four Wheel Independent Drive Electric Motor Vehicles Utilizing Super Twisting and Linear Quadratic Regulator Methods Schmutz, Kenneth Daniel 01 December 2018 (has links) (PDF) This thesis contains the design and simulation test results for the implementation of a new all-wheel drive (AWD) torque vectoring (TV) control system. A separate algorithm using standard control methods is included in this study for a comparison. The proposed controller was designed to be applied to an AWD independent drive electric vehicle, however the main concepts can be re-purposed for other vehicle drive train configurations. The purpose of the control system is to assist the driver in achieving a desired vehicle trajectory whilst also maintaining stability and control of the vehicle. This is accomplished by measuring various real time parameters of the vehicle and using this information as feedback for the control system to act on. The focus of this thesis resides on the controller. Hence, this study assumes perfect observation of feedback parameters, therefore some uncertainties are not accounted for. Using feedback parameters, the control system will manage wheel slip whilst simultaneously generating a torque around the center of gravity of the vehicle by applying a torque differential between the left and right wheels. The proposed TV algorithm is simulated in MATLAB/Simulink along with another separate TV algorithm for comparison. Both algorithms are comprised of two main parts: a slip ratio controller applied to each wheel individually and stability controller that manages yaw rate and side slip of the vehicle. The new algorithm leverages the super twisting algorithm for the slip ratio controller and uses a fusion of a linear quadratic regulator with the integral term of a super twisting algorithm to implement the yaw rate and side slip controller. The other algorithm used for comparison derives its implementation for the slip ratio controller and yaw rate and side slip controllers from simple and standard first order sliding mode control methods. Both control algorithms were tested in three different main tests: anti-lock braking, sine dwell (SD) steering, and constant steering angle (CSA) tests. To increase the comprehensive nature of the study, the SD and CSA tests were simulated at 3 speeds (30,50, and 80 mph) and the steering angle parameter was varied from 2 to 24 degrees in increments of 2. The result of this study proves that the proposed controller is a feasible option for use in theory. Simulated results show advantages and disadvantages of the new controller with respect to the standard comparison controller. Both controllers are also shown to provide positive impacts on the vehicle response under most test conditions. Vehicle Dynamics Automotive Engineering Electronic Stability Control Traction Control Anti-lock Braking Control
67	A Flight Simulation Study of the Simultaneous Non-interfering Aircraft Approach Reel, Brian H 01 May 2009 (has links) (PDF) Using a new implementation of a NASA flight simulation of the Quiet Short-Haul Research Aircraft, autopilots were designed to be capable of flying both straight in (ILS) approaches, and circling (SNI) approaches. A standard glideslope coupler was sufficient for most conditions, but a standard Proportional-Integral-Derivative (PID) based localizer tracker was not sufficient for maintaining a lateral track on the SNI course. To track the SNI course, a feed-forward system, using GPS steering provided much better results. NASA and the FAA embrace the concept of a Simultaneous, Non-Interfering (SNI) approach as a way to increase airport throughput while reducing the noise footprints of aircraft on approach. The NASA concept for the SNI approach for Short Takeoff and Landing (STOL) aircraft involves a straight in segment flown above the flight path of a normal approach, followed by a spiraling descent to the runway. As this is a procedure that would be utilized by regional airliners, it is assumed that it would be conducted under Instrument Flight Rules (IFR). GPS or INS guidance would be required to fly this approach, and it is likely that it would be necessary to fly the approach with a coupled autopilot: a stabilized, curving, instrument approach to decision altitude would be exceedingly difficult to fly. The autopilots in many current commuter and general aviation aircraft, however, were designed before the event of GPS, and do not have provisions for tracking curved paths. This study identifies problem areas in implementing the SNI circling approach on aircraft and avionics as they stand today and also gives examples of what can be done for the SNI approach to be successful. QSRA SNI Approach Coupler GPS Aeronautical Vehicles Other Aerospace Engineering
68	COMET: Constrained Optimization of Multiple-Dimensions for Efficient Trajectories Conrad, Michael Curt 01 December 2011 (has links) (PDF) The paper describes the background and concepts behind a master’s thesis platform known as COMET (Constrained Optimization of Multiple-dimensions for Efficient Trajectories) created for mission designers to determine and evaluate suitable interplanetary trajectories. This includes an examination of the improvements to the global optimization algorithm, Differential Evolution, through a cascading search space pruning method and decomposition of optimization parameters. Results are compared to those produced by the European Space Agency’s Advanced Concept Team’s Multiple Gravity Assist Program. It was found that while discrepancies in the calculation of ΔV’s for flyby maneuvers exist between the two programs, COMET showed a noticeable improvement in its ability to avoid premature convergence and find highly isolated solutions. Interplanetary Trajectory Optimization Differential Evolution Astrodynamics Propulsion and Power
69	Modeling of a Gyro-Stabilized Helicopter Camera System Using Neural Networks Layshot, Nicholas Joseph 01 December 2010 (has links) (PDF) On-board gimbal systems for camera stabilization in helicopters are typically based on linear models. Such models, however, are inaccurate due to system nonlinearities and complexities. As an alternative approach, artificial neural networks can provide a more accurate model of the gimbal system based on their non-linear mapping and generalization capabilities. This thesis investigates the applications of artificial neural networks to model the inertial characteristics (on the azimuth axis) of the inner gimbal in a gyro-stabilized multi-gimbal system. The neural network is trained with time-domain data obtained from gyro rate sensors of an actual camera system. The network performance is evaluated and compared with measured data and a traditional linear model. Computer simulation results show the neural network model fits well with the measured data and significantly outperforms a traditional model. Line-of-Sight image stabilization tracking system identification nonlinear camera control Controls and Control Theory
70	Implementation of a Scale Semi-autonomous Platoon to Test Control Theory Attacks Miller, Erik 01 July 2019 (has links) (PDF) With all the advancements in autonomous and connected cars, there is a developing body of research around the security and robustness of driving automation systems. Attacks and mitigations for said attacks have been explored, but almost always solely in software simulations. For this thesis, I led a team to build the foundation for an open source platoon of scale semi-autonomous vehicles. This work will enable future research into implementing theoretical attacks and mitigations. Our 1/10 scale car leverages an Nvidia Jetson, embedded microcontroller, and sensors. The Jetson manages the computer vision, networking, control logic, and overall system control; the embedded microcontroller directly controls the car. A lidar module is responsible for recording distance to the preceding car, and an inertial measurement unit records the velocity of the car itself. I wrote the software for the networking, interprocess, and serial communications, as well as the control logic and system control. Cooperative Adaptive Cruise Control Control Systems Automotive Platoon Self Driving Vehicle Semi-autonomous Vehicle

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