Multi-tasking och knäkontroll bland idrottande kvinnor med och utan främre korsbandsskada : En pilotstudie / Multitasking and knee control among women football players with and without ACL injury : A pilot study

Andersson, Philip, Lindholm, Axel

January 2022

Studiedesign: Kvantitativ experimentell studie Syfte: Det primära syftet var att undersöka hur knäledens kinematik påverkas av simultana kognitiva uppgifter under hopplandningar bland fotbollsaktiva kvinnor med och utan främre korsbandsskada. Det sekundära syftet var att, genom poweranalyser, beräkna gruppstorlekar och vilka variabler som bör analyseras i framtida studier. Metod: Sju kvinnor med och sex kvinnor utan korsbandsskada utförde tre olika hopptester med och utan maximalt upphopp. Test 1 utfördes utan tillägg av kognitiva uppgifter, test 2 involverade elementen reaktionstid och inhibitorisk kontroll, test 3 involverade elementen reaktionstid, inhibitorisk kontroll och arbetsminne. Knäledens kinematik i alla tre plan (maxvärden och rörelseomfång) och maximal hopphöjd i upphoppet jämfördes mellan grupperna och testerna. Upprepad mixad ANOVA med effekterna Test, Grupp, och interaktionen Test*Grupp genomfördes och dess effektstorlekar användes i poweranalyserna.  Resultat: Det skedde mindre rörelse i sagittalplan och mer rörelse i frontalplan hos korsbandsgruppen samt att knäledens kinematik skiljer sig åt mellan grupperna under mer kognitivt krävande situationer simultant med idrottsspecifik rörelse. Power-analyserna för interaktionseffekten Test*Grupp med upphopp visade att 9/10 variabler kräver <100 testpersoner för att få en signifikant statistisk skillnad med en power på 80%.  Motsvarande resultat för landning utan upphopp visade att 5/9 variabler kräver <100 testpersoner. Konklusion: Hopplandningar med olika antal simultana kognitiva uppgifter visade på skillnader i knäkinematik mellan individer med och utan tidigare korsbandsskada, mellan testerna oberoende grupptillhörighet samt mellan testerna beroende på grupptillhörighet. De variabler som visade signifikanta skillnader vid landning följt av maximalt upphopp var hopphöjd, Max knäadduktion, Min knäflexion, Max knäutåtrotation och ROM knäadduktion-abduktion. Vid endast landning var det maximal knäflexion och Max knäabduktion som hade signifikanta värden.

ACL injury

Kogniton

Knee kinematic

Landing control

Främre korsbandsskada

Kognition

Knäkinematik

Landningskontroll

Physiotherapy

Sjukgymnastik

The design and implementation of vision-based autonomous rotorcraft landing

De Jager, Andries Matthys

03 1900

Thesis (MScEng (Electrical and Electronic Engineering))--University of Stellenbosch, 2011. / ENGLISH ABSTRACT: This thesis presents the design and implementation of all the subsystems required to perform precision autonomous helicopter landings within a low-cost framework. To obtain high-accuracy state estimates during the landing phase a vision-based approach, with a downwards facing camera on the helicopter and a known landing target, was used. An e cient monocular-view pose estimation algorithm was developed to determine the helicopter's relative position and attitude during the landing phase. This algorithm was analysed and compared to existing algorithms in terms of sensitivity, robustness and runtime. An augmented kinematic state estimator was developed to combine measurements from low-cost GPS and inertial measurement units with the high accuracy measurements from the camera system. High-level guidance algorithms, capable of performing waypoint navigation and autonomous landings, were developed. A visual position and attitude measurement (VPAM) node was designed and built to perform the pose estimation and execute the associated algorithms. To increase the node's throughput, a compression scheme is used between the image sensor and the processor to reduce the amount of data that needs to be processed. This reduces processing requirements and allows the entire system to remain on-board with no reliance on radio links. The functionality of the VPAM node was con rmed through a number of practical tests. The node is able to provide measurements of su cient accuracy for the subsequent systems in the autonomous landing system. The functionality of the full system was con rmed in a software environment, as well as through testing using a visually augmented hardware-in-the-loop environment. / AFRIKAANSE OPSOMMING: Hierdie tesis beskryf die ontwikkeling van die substelsels wat vir akkurate outonome helikopter landings benodig word. 'n Onderliggende doel was om al die ontwikkeling binne 'n lae-koste raamwerk te voltooi. Hoe-akkuraatheid toestande word benodig om akkurate landings te verseker. Hierdie metings is verkry deur middel van 'n optiese stelsel, bestaande uit 'n kamera gemonteer op die helikopter en 'n bekende landingsteiken, te ontwikkel. 'n Doeltreffende mono-visie posisie-en-orientasie algoritme is ontwikkel om die helikopter se posisie en orientasie, relatief tot die landingsteiken, te bepaal. Hierdie algoritme is deeglik ondersoek en vergelyk met bestaande algoritmes in terme van sensitiwiteit, robuustheid en uitvoertyd. 'n Optimale kinematiese toestandswaarnemer, wat metings van GPS en inersiele sensore kombineer met die metings van die optiese stelsel, is ontwikkel en deur simulasie bevestig. Hoe-vlak leidingsalgoritmes is ontwikkel wat die helikopter in staat stel om punt-tot-punt navigasie en die landingsprosedure uit te voer. 'n Visuele posisie-en-orientasie meetnodus is ontwikkel om die mono-visie posisie-en orientasie algoritmes uit te voer. Om die deurset te verhoog is 'n saampersingsalgoritme gebruik wat die hoeveelheid data wat verwerk moet word, te verminder. Dit het die benodigde verwerkingskrag verminder, wat verseker het dat alle verwerking op aanboord stelsels kan geskied. Die meetnodus en mono-visie algoritmes is deur middel van praktiese toetse bevestig en is in staat om metings van voldoende akkuraatheid aan die outonome landingstelsel te verskaf. Die werking van die volledige stelsel is, deur simulasies in 'n sagteware en hardeware-indie- lus omgewing, bevestig.

Autonomous helicopter landing

Pose estimation

Vision based position -- Measurement

Dissertations -- Electronic engineering

Theses -- Electronic engineering

Helicopters -- Landing -- Control

Drone aircraft -- Control

Helicopters -- Altitude -- Measurement

Vision-based Strategies for Landing of Fixed Wing Unmanned Aerial Vehicles

Marianandam, Peter Arun

January 2015

Vision-based conventional landing of a fixed wing UAV is addressed in this thesis. The work includes mathematical modeling, interface to a software for rendering the outside scenery, image processing techniques, control law development and outdoor experimentation. This research focuses on detecting the lines or the edges that flank the landing site, use them as visual cues to extract the geometrical parameters such as the line co-ordinates and the line slopes, that are mapped to the control law, to align and conventionally land the fixed wing UAV. Pre-processing and image processing techniques such as Canny Edge detection and Hough Transforms have been used to detect the runway lines or the edges of a landing strip. A Vision-in-the-Loop Simulation (VILS) set up on a personal computer or laptop, has been developed, without any external camera/equipment or networking cables that enables visual serving toper form vision-based studies and simulation. UAV mass, inertia, engine and aero data from literature has been used along withUAV6DOF equations to represent the UAV mathematical model. The UAV model is interfaced to a software using UDP data packets via ports, for rendering the outside scenery in accordance with the UAV’s translation and orientation. The snapshots of the outside scenery, that is passed through an internet URL by including the ‘http’ protocol, is image processed to detect the lines and the line parameters for the control. VILS set has been used to simulate UAV alignment to the runway and landing. Vision-based alignment is achieved by rolling the UAV such that the landing strip that is off center is brought to the center of the image plane. A two stage proportional aileron control input using the line co-ordinates, bringing the midpoints of the top ends of the runway lines to the center of the image, followed by bringing the mid points of the bottom ends of the runway lines to the center of the image has been demonstrated through simulation. A vision-based control for landing has been developed, that consists of an elevator command that is commiserate with the acceptable range of glide slope followed by a flare command till touch down, which is a function of the flare height and estimated height from the 3rd order polynomial of the runway slope obtained by characterization. The feasibility of using the algorithms for a semi-prepared or unprepared landing strip with no visible runway lines have also been demonstrated. Landing on an empty tract of land and in poor visibility condition, by synthetically drawing the runway lines based on a single 3rd order slope. vs height polynomial solution are also presented. A fixed area, and a dynamic area search for the Hough peaks in the Hough accumulator array for the correct detection of lines are addressed. A novel technique for crosswind landing, quite different from conventional techniques, has been introduced, using only the aileron control input for correcting the drift. Three different strategies using the line co-ordinates and the line slopes, with varying levels of accuracy have been presented and compared. About 125 landing data of a manned instrumented prototype aircraft have been analysed to corroborate the findings of this research. Outdoor experiments are also conducted to verify the feasibility of using the line detection algorithm in a realistic scenario and to generate experimental evidence for the findings of this research. Computation time estimates are presented to establish the feasibility of using vision for the problem of conventional landing. The thesis concludes with the findings and direction for future work.

Computer Vision

Image Processing

Fixed Wing Unmanned Aerial Vehicles

Vision-in-the-Loop-Simulation (VILS)

Vision Based Runway Alignment

Autonomous Landing Control

Vision Based Landing

Manned Fixed Wing Aircraft Landing Data

Cross Wind Landing

Vision-Based Landing

Vision-Based Cross Wind Landing

Fixed Wing UAVs

Aerospace Engineering