Stabilità e variabilità del cammino in acqua

La camminata, sia in acqua sia a secco, è un esercizio praticato frequentemente in ambito riabilitativo. Lo scopo di questa tesi è di confrontare variabilità e stabilità del cammino dentro e fuori dall’acqua, al fine di comprendere le caratteristiche dei due tipi di cammino. L’analisi si è focalizzata sulla valutazione di misure di stabilità e variabilità che non erano mai state indagate prima per la camminata in acqua: Harmonic Ratio, Plot di Poincarè, moltiplicatori di Floquet, esponenti di Lyapunov, multiscale entropy, recurrence rate, determinism, averaged diagonal line length, maximum diagonal line length e divergenza. Gli indici sono stati calcolati su camminate di 30 e di 90 passi. Da questa analisi possiamo stimare anche quale parametro è già affidabile a 30 passi e non cambia se analizzato a 90 o se un parametro necessita di più passi per risultare affidabile. Inoltre è stata effettuata indagine statistica tramite test di Kruskal-Wallis. Dall'analisi è emerso che la camminata in acqua è più stabile, meno smooth, c’è un maggiore controllo posturale lungo gli assi antero-posteriore e medio-laterale e che il cammino è condotto in maniera meno automatica.

Semi-engineered earthquake-resistant structures: one-storey buildings built up with gabion-box walls

This thesis studies the static and seismic behavior of simple structures made with gabion box walls. The analysis was performed considering a one-story building with standard dimensions in plan (6m x 5m) and a lightweight timber roof. The main focus of the present investigation is to find the principals aspects of the seismic behavior of a one story building made with gabion box walls, in order to prevent a failure due to seismic actions and in this way help to reduce the seismic risk of developing countries where this natural disaster have a significant intensity. Regarding the gabion box wall, it has been performed some calculations and analysis in order to understand the static and dynamic behavior. From the static point of view, it has been performed a verification of the normal stress computing the normal stress that arrives at the base of the gabion wall and the corresponding capacity of the ground. Moreover, regarding the seismic analysis, it has been studied the in-plane and out-of-plane behavior. The most critical aspect was discovered to be the out-of-plane behavior, for which have been developed models considering the “rigid- no tension model” for masonry, finding a kinematically admissible multiplier that will create a collapse mechanism for the structure. Furthermore, it has been performed a FEM and DEM models to find the maximum displacement at the center of the wall, maximum tension stresses needed for calculating the steel connectors for joining consecutive gabions and the dimensions (length of the wall and distance between orthogonal walls or buttresses) of a geometrical configuration for the standard modulus of the structure, in order to ensure an adequate safety margin for earthquakes with a PGA around 0.4-0.5g. Using the results obtained before, it has been created some rules of thumb, that have to be satisfy in order to ensure a good behavior of these structure.