Contrôle de topologie dans les réseaux de capteurs : de la théorie à la pratique / Topology Control in Wireless Sensor Networks : from Theory to Practice

Khadar, Fadila

15 December 2009

Les réseaux de capteurs sont des réseaux composés de petits objets communicants à faibles ressources (capacité de calcul, mémoire, batterie). Chaque capteur recueille des informations sur son environnement qu’il envoie, par radio, à une entité responsable du traitement de ces données en utilisant les autres capteurs comme relais. Lors d’un tel déploiement, un nombre important de capteurs sont déployés pour s’assurer de la couverture de la zone à surveiller. Ceci implique que chaque capteur maintienne, pour chacun des capteurs avoisinants, des informations dont le maintien est coûteux en terme de communication et de mémoire. L’objectif de cette thèse est de réduire le nombre de ces capteurs avoisinants tout en préservant les fonctionnalités du réseau. L’ensemble des capteurs avoisinants est défini par la portée de communication radio. Le contrôle de topologie vise à réduire l’ensemble des voisins logiques d’un nœud, tandis que le contrôle de portée vise à sélectionner la meilleure portée pour atteindre ces voisins tout en réduisant l’ensemble physique des voisins d’un nœud. Ces travaux se proposent d’étudier, d’un point de vue théorique, les performances obtenues par le contrôle de topologie et le contrôle de puissance. Nous étudions des algorithmes définis dans le cadre de l’utilisation d’un modèle de couche physique idéale, et les adaptons à une utilisation avec un modèle de couche physique réaliste. D’un point de vue pratique, nous avons développé une pile de communication, Goliath, intégrant le contrôle de topologie. Lors de son utilisation, les capteurs utilisent une puissance de transmission inférieure à la puissance maximale sans impacter les performances du réseau. / Wireless Sensor Networks are networks of small communicating devices with constrainted resources. They are usually deployed in risky or difficult to access areas. Each sensor gathers information about its environment and send it to a dedicated entity using other sensors as relays. A large number of sensors may be deployed to ensure the coverage of given area. This large number implies that each sensor has to maintain, for each neighboring sensor, information about its activity for instance. Maintaining this information is memory consuming and implies a huge communication overhead. The aim of this thesis is to reduce the number of neighboring sensor while keeping network services up. The set of neighboring nodes is defined by the communication range. Topology control aims at logically reducing the number of neighboring sensors while power control aims at physically reducing this number. In this work, we theoretically study the bounds that can be obtained by using topology and power control. We study algorithms defined with a ideal physical layer model and show how to adapt them to be used with a realistic physical layer. On a practical side, we developped a communication stack, Goliath, that includes topology and power control. We evaluate the performances of Goliath with and without topology control and power adjustment. When Goliath uses power adjustment, sensors use a transmission power smaller than the maximum power without any impact of the performances of the network.

Pile de communication

Desenvolvimento de um equipamento para execução de estacas hélice segmentada / Development of equipment for execution of segmented auger piles

Barreto, Gilmar Wilian

03 February 2005

Esta dissertação apresenta o desenvolvimento de um equipamento para a execução de estacas escavadas com injeção sob pressão, logo após a fase de escavação, de argamassa de cimento e areia. O processo utiliza segmentos de trados que são introduzidos no solo através da combinação de rotação e empuxo axial de compressão. A extração dá-se simultaneamente à injeção de argamassa, e o monitoramento das pressões de injeção é feito através de um manômetro, com o objetivo de garantir a integridade do fuste. Um motor a diesel fornece até 92 kW a 1800 rpm e é responsável pelo acionamento dos diversos conjuntos hidráulicos. O equipamento, montado numa plataforma sobre pneus, é autopropelido e autocarregável podendo ser transportado em caminhões comuns com dois eixos traseiros. Esse tipo de estaca, denominado estaca hélice segmentada, poderá representar uma alternativa interessante às estacas tradicionais, principalmente em locais onde as construções vizinhas possam sofrer danos devido à utilização de estacas de deslocamento ou onde os custos envolvidos na utilização de equipamento mais pesado e sofisticado possam inviabilizar a sua aplicação / This work presents the development of equipment for execution of segmented auger piles with injection of cement mortar under pressure, soon after the excavation phase. The process uses segmented augers that are installed in the ground through the rotation and pull-down combination. The extraction is made at the same time as the cement mortar injection and the injection pressures are monitored by a manometer, to assure the shaft integrity. A diesel motor offers up 92 kW at 1800 rpm and is responsible for the movement of several hydraulic units. The equipment mounted on a tire platform, is self-propelling and can raise itself to be loaded onto common trucks. This kind of pile, called segmented pile, will be an interesting alternative for the traditional piles, mainly at sites where the neighboring constructions will be damage by the utilization of the displacement pile, or where the costs involved in the utilization of heavier and sophisticated equipment can make its application unfeasible

estaca

estaca injetada

hélice segmentada

inject pile

pile

segmented pile

Desenvolvimento de um equipamento para execução de estacas hélice segmentada / Development of equipment for execution of segmented auger piles

Gilmar Wilian Barreto

03 February 2005

Esta dissertação apresenta o desenvolvimento de um equipamento para a execução de estacas escavadas com injeção sob pressão, logo após a fase de escavação, de argamassa de cimento e areia. O processo utiliza segmentos de trados que são introduzidos no solo através da combinação de rotação e empuxo axial de compressão. A extração dá-se simultaneamente à injeção de argamassa, e o monitoramento das pressões de injeção é feito através de um manômetro, com o objetivo de garantir a integridade do fuste. Um motor a diesel fornece até 92 kW a 1800 rpm e é responsável pelo acionamento dos diversos conjuntos hidráulicos. O equipamento, montado numa plataforma sobre pneus, é autopropelido e autocarregável podendo ser transportado em caminhões comuns com dois eixos traseiros. Esse tipo de estaca, denominado estaca hélice segmentada, poderá representar uma alternativa interessante às estacas tradicionais, principalmente em locais onde as construções vizinhas possam sofrer danos devido à utilização de estacas de deslocamento ou onde os custos envolvidos na utilização de equipamento mais pesado e sofisticado possam inviabilizar a sua aplicação / This work presents the development of equipment for execution of segmented auger piles with injection of cement mortar under pressure, soon after the excavation phase. The process uses segmented augers that are installed in the ground through the rotation and pull-down combination. The extraction is made at the same time as the cement mortar injection and the injection pressures are monitored by a manometer, to assure the shaft integrity. A diesel motor offers up 92 kW at 1800 rpm and is responsible for the movement of several hydraulic units. The equipment mounted on a tire platform, is self-propelling and can raise itself to be loaded onto common trucks. This kind of pile, called segmented pile, will be an interesting alternative for the traditional piles, mainly at sites where the neighboring constructions will be damage by the utilization of the displacement pile, or where the costs involved in the utilization of heavier and sophisticated equipment can make its application unfeasible

estaca

estaca injetada

hélice segmentada

inject pile

pile

segmented pile

Static axial pile foundation response using seismic piezocone data

Niazi, Fawad Sulaman

27 August 2014

Ever since the use of cone penetration testing (CPT) in geotechnical site investigations, efforts have been made to correlate its readings with the components of static axial pile capacity: unit base resistance (qb) and unit shaft resistance (fp). Broadly, the pile capacity analysis from CPT data can be accomplished via two main approaches: rational (or indirect) methods, and direct methods. The rational methods require a two-step approach, whereby CPT data are first used to provide assessments of geoparameters that are further utilized as input values within a selected analytical framework to enable the evaluation of the pile capacity components. In contrast, direct CPT methods use the measured penetrometer readings by scaling relationships or algorithms in a single-step process to obtain fp and qb for full-size piling foundations. The evolution of the CPT from mechanical to electrical to electronic versions and single-channel readings (i.e., measured tip resistance, qc) to the piezocone penetration test (CPTu), that provides three readings of point stress (qt), sleeve friction (fs), and porewater pressure (u1 or u2), has resulted in the concurrent development of multiple CPT-based geotechnical pile design methods. It is noted, however, that current CPT-based methods focus only on an estimate of "axial pile capacity", corresponding to a limiting load or force at full mobilization. A more comprehensive approach is sought herein utilizing the CPT readings towards producing a complete nonlinear load-displacement-capacity (Q-w-Qcap) on axial pile response. In particular, the seismic cone penetration test (SCPT) provides the profile of shear wave velocity (Vs) that determines the fundamental small-strain shear modulus: Gmax = gt?Vs2, where gt = total mass density of soil. With the penetrometer readings useful in assessing foundation capacity, the stiffness Gmax finds application within elastic continuum solutions towards evaluating the load-displacement (Q-w) response. In this study, a concise review of the deep foundation systems is presented, including pile types and characteristics, various arrangements of axial pile load testing in static mode, and interpretations of the load test data. In addition a comprehensive state-of-the-art review of CPT-based rational and direct methods of pile capacity evaluations is compiled. It is recognized that the direct methods offer more convenience in their straightforward approach in estimation of the pile capacity. The piezocone-based UniCone direct method proposed by Eslami and Fellenius (1997) is selected for further refinements, as it utilizes all three CPT readings in its design formulations. Concerning the analysis of pile deformations under axial loading, a brief review covers designs employing empirical formulations, analytical solutions, load-transfer (t-z) methods, numerical simulations, variational approaches, and those using hybrid methods. Specifically, the analytical elastic solution by Randolph and Wroth (1978; 1979) is covered in more detail since it is simple and convenient in application with extended applications to uplift and bidirectional O-cell types of loadings. This elastic approach also serves well in modeling a stacked pile solution for layered soil profiles. The last part of the review covers various shear modulus reduction schemes, since evaluation of the applicable stiffnesses is considered to be the most delicate phase in the nonlinear Q-w response analysis of axially loaded piles. It is identified that the most appropriate scheme applicable to static axial loading of pile foundations is the one that can be derived from the back-analyses of actual load tests within the framework of analytical elastic solution. In order to conduct a comprehensive research study on the axial Q-w-Qcap response of deep foundations from CPT readings, a large database is compiled. This includes 330 case records of pile load tests at 70 sites from 5 continents and 19 different countries of the world, where pile foundations were load tested under top-down compression or top-applied uplift (tension) loading, or both, or by bi-directional Osterberg cell setups. All test sites had been investigated using CPT soundings; in most cases by the preferred SCPTu that provides all four readings from the same sounding: qt, fs, u2, and Vs. In a few cases, sites were subjected to CPT or CPTu and the profiles of shear wave velocities were obtained by other field geophysical techniques, otherwise by empirical estimations. Results of the new correlation efforts are offered to derive coefficients Cse for shaft component and Cte for base component of the axial pile capacity from CPTu data. The UniCone type of soil classification chart is refined by delineating 11 soil sub-zones along with their respective Cse, in contrast to the 5 zones originally proposed. The CPT material index, Ic (Robertson, 2009) is then used to establish direct correlations linking Cse vs. Ic and Cte vs. Ic. Statistical relationships offer continuous functions for estimating the coefficients over a wide range of Ic values, thereby eliminating the need for use of the soil classification chart as well as improving the reliability in the evaluations of fp and qb. The effects of the pile loading direction (compression vs. uplift) and loading rate are also incorporated in the proposed design formulations. New sets of shear stiffness reduction curves are developed from the back-analysis of pile load tests and Gmax profiles obtained from the SCPT data. Alternative functions formats are provided in terms of hyperbolic tangent expressions or exponential curves, developed as normalized shear stiffness (G/Gmax) vs. logarithm of percent pseudo-strain (gp = w/d, where w = pile displacement and d = pile diameter). These charts offer convenience in the axial Q-w analysis of different pile categories within the framework of analytical elastic solution. The results also account for the plasticity characteristics of the soil formations within the database. A stacked pile model for Q-w analysis is presented in which certain adaptations are proposed in the elastic continuum solution. These adaptations enable plotting of separate modulus reduction curves (G/Gmax vs. gp) as function of depth for each layer, and treating pile as a stack of smaller pile segments embedded in a multi-layered soil media. The solution can be used to address the question of progressive failure with depth in a multi-layer soil media that exhibits nonlinear soil stiffness response. Finally, the closed-from analytical elastic pile solution for predicting the Q-w response is decoupled and modified to account for different setup cases and multi-stage loading of bi-directional O-cell tests. The decoupling accounts for separate assessments of the response to axial loading for different segments of pile shaft and different stages of loading, while the modifications include: (1) reduced maximum radius of influence for the upward displacements of the upper shaft segment, and (2) modeling the non-linear ground stiffness from the back-analysis of a well-documented dataset of O-cell load tests.

Pile foundation

Seismic piezocone test

Pile capacity

Axial pile displacement

Assessing Driven Steel Pile Capacity on Rock Using Empirical Approaches

Morton, Timothy Scott

17 August 2012

Methods of determining pile toe capacity for both small displacement driven steel piles and drilled sockets were collected. Working in conjunction with a local consulting firm, records of previous pile driving sites were collected. A process to determine quality data for use in this work was developed by the author including information from geotechnical site investigations, pile driving records and pile driving analysis records. By plotting unconfined compressive strength of rock versus measured ultimate pile toe capacity of these piles, a best fit line of 7.5qu and a series of confidence intervals were established for the site records. This best fit line was compared to all of the previously reviews design methods for calculating ultimate pile toe capacity. Rehnman and Broms (1971) was determined to be the most effective existing method while most of the methods for drilled sockets were overly conservative when applied to small displacement driven steel piles.

pile capacity

driven pile

toe capacity

Non-destructive testing of concrete piles using the sonic echo and transient shock methods

Chan, Hon-Fung Cyril

January 1987

No description available.

624.1

Pile defect testing

A theoretical study of pile driving

Simons, H. A.

January 1985

No description available.

624.1

Pile driving analysis

A field study of the behaviour of driven piles in soft clay

Ibrahim, Kamiran Abdul Razzak

January 1995

No description available.

624.1

Pile driving

The study of vertical and raked model piles in deep and shallow clay beds

Baligh, F. E. A.

January 1984

No description available.

624.1

Pile foundations

Pull-out tests on bent piles in sand

Al-Hadid, Tareq N. M.

January 1988

No description available.

624.1

Pile instability