Preparation and characterization of polyethylene based nanocomposites for potential applications in packaging

Gill, Yasir Q.

January 2015

The objective of my work was to develop HDPE clay nanocomposites for packaging with superior barrier (gas and water) properties by economical processing technique. This work also represents a comparative study of thermoplastic nanocomposites for packaging based on linear low density polyethylene (LLDPE), high density polyethylene (HDPE) and Nylon12. In this study properties and processing of a series of linear low density polyethylene (LLDPE), high density polyethylene (HDPE) and Nylon 12 nanocomposites based on Na-MMT clay and two different aspect ratio grades of kaolinite clay are discussed.

WOK : A Simulation Model for DFS and Link Adaptation in IEEE 802.11a WLAN / WOK : en simuleringsmodell för DFS och länkadaption i IEEE 802.11a WLAN

Janson, Magnus, Karlsson, Magnus

January 2004

<p>With the 1999 introduction of IEEE 802.11b, the 2.4 GHz Wireless Local Area Network (WLAN) standard, the WLAN market finally began to experience the growth levels that had been expected for so long. Now, 5 GHz solutions, with the IEEE 802.11a standard leading the way, offer higher throughput and more efficient use of the spectrum. Just as the 2.4 GHz band, the 5 GHz band is unlicensed. A common concern to all unlicensed bands is interference between devices using the spectrum. Furthermore, in the 5 GHz band, WLAN cells can interfere with radar systems operating at the same frequencies. </p><p>This report describes a software model, WOK, suitable for simulations of IEEE 802.11a WLANs operating in various environments and under various ambient conditions. The WOK model can be configured extensively with respect to topology, traffic behavior, channel models, signal attenuation, interference sources and radar systems. </p><p>Further, the concepts of Dynamic Frequency Selection (DFS) and link adaptation are explored in the context of the IEEE 802.11a standard. DFS aims to avoid channels occupied by radar systems and link adaptation aims to maximize the throughput based on current ambient conditions. A DFS algorithm and a link adaptation algorithm are implemented at the Medium Access Control (MAC) layer and evaluated using the WOK model.</p>

Datorteknik

simulation

model

DFS

Dynamic Frequency Selection

link adaptation

algorithm

WLAN

wireless

MAC

PHY

IEEE 802.11a

IEEE 802.11h

access point

transmission rate

radar

noise

interference

SNR

OMNeT++

Datorteknik

Computer engineering

Datorteknik

WOK : A Simulation Model for DFS and Link Adaptation in IEEE 802.11a WLAN / WOK : en simuleringsmodell för DFS och länkadaption i IEEE 802.11a WLAN

Janson, Magnus, Karlsson, Magnus

January 2004

With the 1999 introduction of IEEE 802.11b, the 2.4 GHz Wireless Local Area Network (WLAN) standard, the WLAN market finally began to experience the growth levels that had been expected for so long. Now, 5 GHz solutions, with the IEEE 802.11a standard leading the way, offer higher throughput and more efficient use of the spectrum. Just as the 2.4 GHz band, the 5 GHz band is unlicensed. A common concern to all unlicensed bands is interference between devices using the spectrum. Furthermore, in the 5 GHz band, WLAN cells can interfere with radar systems operating at the same frequencies. This report describes a software model, WOK, suitable for simulations of IEEE 802.11a WLANs operating in various environments and under various ambient conditions. The WOK model can be configured extensively with respect to topology, traffic behavior, channel models, signal attenuation, interference sources and radar systems. Further, the concepts of Dynamic Frequency Selection (DFS) and link adaptation are explored in the context of the IEEE 802.11a standard. DFS aims to avoid channels occupied by radar systems and link adaptation aims to maximize the throughput based on current ambient conditions. A DFS algorithm and a link adaptation algorithm are implemented at the Medium Access Control (MAC) layer and evaluated using the WOK model.

Datorteknik

simulation

model

DFS

Dynamic Frequency Selection

link adaptation

algorithm

WLAN

wireless

MAC

PHY

IEEE 802.11a

IEEE 802.11h

access point

transmission rate

radar

noise

interference

SNR

OMNeT++

Datorteknik

Computer Engineering

Datorteknik

Metapopulation dynamics of dengue epidemics in French Polynesia / Dynamique métapopulationelle des épidémies de dengue en Polynésie française

Teissier, Yoann

22 May 2017

La dengue circule en Polynésie française sur un mode épidémique depuis plus de 35 ans. Néanmoins, en dépit de la taille relativement faible de la population de Polynésie française, la circulation de la dengue peut persister à de faibles niveaux pendant de nombreuses années. L’objectif de ce travail de thèse est de déterminer si l'épidémiologie de la dengue dans le système insulaire de la Polynésie française répond aux critères d’un contexte de métapopulation. Après avoir constitué une base de données regroupant les cas de dengue répertoriés sur les 35 dernières années, nous avons réalisé des analyses épidémiologiques descriptives et statistiques. Celles-ci ont révélé des disparités spatio-temporelles distinctes pour l’incidence de la dengue des archipels et des îles, mais la structure de l'épidémie globale à l’échelle de la Polynésie française pour un même sérotype ne semble pas être affectée. Les analyses de la métapopulation ont révélé l'incidence asynchrone de la dengue dans un grand nombre d’îles. Celle-ci s’observe plus particulièrement par la différence de dynamique de l’incidence entre les îles plus peuplées et celles ayant une population plus faible. La taille critique de la communauté nécessaire à la persistance de la dengue n’est même pas atteinte par la plus grande île de Polynésie Française, Tahiti. Ce résultat suggère que la dengue peut uniquement persister grâce à sa propagation d’île en île. L'incorporation de la connectivité des îles à travers des modèles de migration humaine dans un modèle mathématique a produit une dynamique de la dengue davantage en adéquation avec les données observées, que les tentatives de modélisation traitant la population dans son ensemble. Le modèle de la métapopulation a été capable de simuler la même dynamique que les cas de dengue observés pour l'épidémie et la transmission endémique qui a suivi pour la période de 2001 à 2008. Des analyses complémentaires sur la différenciation de l'incidence de la maladie et de l'infection seront probablement instructives pour affiner le modèle de métapopulation de l'épidémiologie de la dengue en Polynésie française. / Dengue has been epidemic in French Polynesia for the past 35 years. Despite the relatively small population size in French Polynesia, dengue does not disappear and can persist at low levels for many years. In light of the large number of islands comprising French Polynesia, this thesis addresses the extent to which a metapopulation context may be the most appropriate to describe the epidemiology and persistence of dengue in this case. After compiling a database of dengue cases over the last 35 years, we used a number of descriptive and statistical epidemiological analyses that revealed distinct spatio-temporal disparity in dengue incidence for archipelago and islands. But the global structure of the epidemics of the same serotype were not affected. Metapopulation analyses revealed asynchronous dengue incidence among many of the islands and most notably larger islands lagged behind the smaller islands. The critical community size, which determines dengue persistence, was found to exceed even the largest island of Tahiti, suggesting that dengue can only exist by island-hopping. Incorporation of island connectedness through patterns of human migration into a mathematical model enabled a much better fit to the observed data than treating the population as a whole. The metapopulation model was able to capture to some extent the epidemic and low level transmission dynamics observed for the period of 2001-2008. Further analyses on differentiating incidence of disease and infection will likely prove informative for the metapopulation model of dengue epidemiology in French Polynesia.

Dengue

Épidémies

Métapopulation

Polynésie française

Modélisation

SEIR

Transmission endémique

Persistance

Infection

Migration

Population

Circulation insulaire

Population critique

Connections insulaires

Modèle

Logiciel R

Études statistiques

Identification des facteurs de risques

Densité de la population

Vecteur

Aedes aegypti

Géographie insulaire

Milieu tropical

Distance de vol du vecteur

Immunité de la population

Densité vectorielle

Taux de récupération de l’hôte

Mortalité du vecteur

Cycle de transmission des virus

Arbovirus

Dynamique de la dengue

Simulations

Dynamique épidémique

Dengue

Epidemics

Metapopulation

French Polynesia

Modeling

SEIR

Endemic transmission

Persistence

Infection

Migration

Population

Insular circulation

Critical population

Insular connections

Model

Ordinary differential equation (ODE)

R software

Statistical study

Risk factor identification

Population density

Vector

Aedes aegypti

Insular geography

Tropical environment

Vector flight distance

Population immunity

Vector density

Host recovery rate

Vector mortality

Virus transmission cycle

Arbovirus

Dengue dynamic

Simulations

Epidemic dynamics

614.4