Continuation in US Foreign Policy: An Offensive Realist Perspective

Prifti, Bledar

20 October 2014

This dissertation is a study of US foreign policy that aims at maintaining its regional hegemonic status and preventing the emergence of another regional hegemon by implementing the offshore balancing strategy. US intervention during the 2003 Iraq War, strained US-Iran relationship, and the establishment of the Islamic State of Iraq and the Levant (ISIL) in early 2014 compel a reevaluation of US foreign policy. Two major claims of this dissertation include: (1) US foreign policy is consistent with offensive realist theoretical claims; and (2) US foreign policy is characterized by continuity when it comes to issues related to America's strategic interests. Utilizing a case study and comparative case study methodology, this dissertation outlines the following findings. The first finding of this dissertation is that US foreign policy actions under the Bush Doctrine, which led to the 2003 Iraq War, were dictated by the anarchic status of the international system, the possession by Iraq of military capabilities that could harm or destroy America, fear from and suspicion of Iraq's intentions, the need to ensure survival in an anarchic system, and the need to maximize relative power vis-à-vis other states. All these factors led to three main pattern of behavior: fear, self-help, and power maximization. Because there was no other regional great power capable and willing to balance Iraq, the US was forced to rely on direct balancing by threatening Iraq to take military actions, creating an anti-Iraqi alliance, and maximizing its relative power by destroying Iraq's military capabilities. Second, US foreign policy under the Bush Doctrine was a continuation of the 20th century foreign policy. US foreign policy during the 20th century was dictated by three major patterns of behavior: fear, self-help, and power maximization. In realizing its foreign policy goals, the US had to rely on buck-passing and balancing strategies. Whenever there was no regional great power able and willing "to carry the buck", the US would rely on direct balancing by either threatening the aggressor, creating alliances with other regional states, or utilizing additional resources of its own. Four major presidential doctrines and related occurrences were utilized to test the claim: the Roosevelt Corollary, the Truman Doctrine, the Carter Doctrine, and the Reagan Doctrine. The last finding of this dissertation is that US foreign policy toward Iran constitutes continuity and is dictated by US need to maintain regional hegemony by acting as an offshore balancer. In addition, the US and Iran share mutual strategic interests in several occasions, and a strategic win or loss for one state is a win or loss for the other. Like that of the US, Iran's foreign policy is guided by rationality. The Iran-Contra affair, the Armenia-Azerbaijan conflict, and the Russia-Chechnya conflict support the claim that Iran's foreign policy is based on rationality instead of religious ideology as argued by many scholars. Also, the 2001 Afghanistan war, the 2003 Iraq war, and the establishment of the ISIL support the claim that the US and Iran share mutual strategic interests. Cooperation is often desirable and in some cases inevitable. Despite this strong claim, US-Iran relationship has its own limitations because neither the US nor Iran would accept a too powerful other that could establish absolute dominance in the region.

ISIL

offshore balancer

power maximization

regional hegemony

Survival

American Politics

International Relations

POWER MAXIMIZATION FOR PYROELECTRIC, PIEZOELECTRIC, AND HYBRID ENERGY HARVESTING

Shaheen, Murtadha A

01 January 2016

The goal of this dissertation consists of improving the efficiency of energy harvesting using pyroelectric and piezoelectric materials in a system by the proper characterization of electrical parameters, widening frequency, and coupling of both effects with the appropriate parameters. A new simple stand-alone method of characterizing the impedance of a pyroelectric cell has been demonstrated. This method utilizes a Pyroelectric single pole low pass filter technique, PSLPF. Utilizing the properties of a PSLPF, where a known input voltage is applied and capacitance Cp and resistance Rp can be calculated at a frequency of 1 mHz to 1 Hz. This method demonstrates that for pyroelectric materials the impedance depends on two major factors: average working temperature, and the heating rate. Design and implementation of a hybrid approach using multiple piezoelectric cantilevers is presented. This is done to achieve mechanical and electrical tuning, along with bandwidth widening. In addition, a hybrid tuning technique with an improved adjusting capacitor method was applied. An toroid inductor of 700 mH is shunted in to the load resistance and shunt capacitance. Results show an extended frequency range up to 12 resonance frequencies (300% improvement) with improved power up to 197%. Finally, a hybrid piezoelectric and pyroelectric system is designed and tested. Using a voltage doubler, circuit for rectifying and collecting pyroelectric and piezoelectric voltages individually is proposed. The investigation showed that the hybrid energy is possible using the voltage doubler circuit from two independent sources for pyroelectrictity and piezoelectricity due to marked differences of optimal performance.

POWER MAXIMIZATION

PYROELECTRIC

PIEZOELECTRIC

HYBRID ENERGY HARVESTING

Acoustics, Dynamics, and Controls

Ceramic Materials

Electro-Mechanical Systems

Energy Systems

Polymer and Organic Materials

Optimal Design and Inference for Correlated Bernoulli Variables using a Simplified Cox Model

Bruce, Daniel

January 2008

<p>This thesis proposes a simplification of the model for dependent Bernoulli variables presented in Cox and Snell (1989). The simplified model, referred to as the simplified Cox model, is developed for identically distributed and dependent Bernoulli variables.</p><p>Properties of the model are presented, including expressions for the loglikelihood function and the Fisher information. The special case of a bivariate symmetric model is studied in detail. For this particular model, it is found that the number of design points in a locally D-optimal design is determined by the log-odds ratio between the variables. Under mutual independence, both a general expression for the restrictions of the parameters and an analytical expression for locally D-optimal designs are derived.</p><p>Focusing on the bivariate case, score tests and likelihood ratio tests are derived to test for independence. Numerical illustrations of these test statistics are presented in three examples. In connection to testing for independence, an E-optimal design for maximizing the local asymptotic power of the score test is proposed.</p><p>The simplified Cox model is applied to a dental data. Based on the estimates of the model, optimal designs are derived. The analysis shows that these optimal designs yield considerably more precise parameter estimates compared to the original design. The original design is also compared against the E-optimal design with respect to the power of the score test. For most alternative hypotheses the E-optimal design provides a larger power compared to the original design.</p>

Cox binary model

correlated binary data

log-odds ratio

D-optimality

E-optimality

power maximization

efficiency

Statistics

Statistik

Optimal Design and Inference for Correlated Bernoulli Variables using a Simplified Cox Model

Bruce, Daniel

January 2008

This thesis proposes a simplification of the model for dependent Bernoulli variables presented in Cox and Snell (1989). The simplified model, referred to as the simplified Cox model, is developed for identically distributed and dependent Bernoulli variables. Properties of the model are presented, including expressions for the loglikelihood function and the Fisher information. The special case of a bivariate symmetric model is studied in detail. For this particular model, it is found that the number of design points in a locally D-optimal design is determined by the log-odds ratio between the variables. Under mutual independence, both a general expression for the restrictions of the parameters and an analytical expression for locally D-optimal designs are derived. Focusing on the bivariate case, score tests and likelihood ratio tests are derived to test for independence. Numerical illustrations of these test statistics are presented in three examples. In connection to testing for independence, an E-optimal design for maximizing the local asymptotic power of the score test is proposed. The simplified Cox model is applied to a dental data. Based on the estimates of the model, optimal designs are derived. The analysis shows that these optimal designs yield considerably more precise parameter estimates compared to the original design. The original design is also compared against the E-optimal design with respect to the power of the score test. For most alternative hypotheses the E-optimal design provides a larger power compared to the original design.

Cox binary model

correlated binary data

log-odds ratio

D-optimality

E-optimality

power maximization

efficiency

Statistics

Statistik

Numerical Analysis and Parameter Optimization of Portable Oscillating-Body Wave Energy Converters

Capper, Joseph David

14 June 2021

As a clean, abundant, and renewable source of energy with a strategic location in close proximity to global population regions, ocean wave energy shows major promise. Although much wave energy converter development has focused on large-scale power generation, there is also increasing interest in small-scale applications for powering the blue economy. In this thesis, the objective was to optimize the performance of small-sized, portable, oscillating-body wave energy converters (WECs). Two types of oscillating body WECs were studied: bottom hinged and two-body attenuator. For the bottom-hinged device, the goal was to show the feasibility of an oscillating surge WEC and desalination system using numerical modeling to estimate the system performance. For a 5-day test period, the model estimated 517 L of freshwater production with 711 ppm concentration and showed effective brine discharge, agreeing well with preliminary experimental results. The objective for the two-body attenuator was to develop a method of power maximization through resonance tuning and numerical simulation. Three different geometries of body cross sections were used for the study with four different drag coefficients for each geometry. Power generation was maximized by adjusting body dimensions to match the natural frequency with the wave frequency. Based on the time domain simulation results, there was not a significant difference in power between the geometries when variation in drag was not considered, but the elliptical geometry had the highest power when using approximate drag coefficients. Using the two degree-of-freedom (2DOF) model with approximate drag coefficients, the elliptical cross section had a max power of 27.1 W and 7.36% capture width ratio (CWR) for regular waves and a max power of 8.32 W and 2.26% CWR for irregular waves. Using the three degree-of-freedom (3DOF) model with approximate drag coefficients, the elliptical cross section had a max power of 22.5 W and 6.12% CWR for regular waves and 6.18 W and 1.68% CWR for irregular waves. A mooring stiffness study was performed with the 3DOF model, showing that mooring stiffness can be increased to increase relative motion and therefore increase power. / Master of Science / As a clean, abundant, and renewable source of energy with a strategic location in close proximity to global population centers, ocean wave energy shows major promise. Although much wave energy converter development has focused on large-scale power generation, there is also increasing interest in small-scale applications for powering the blue economy. There are many situations where large-scale wave energy converter (WEC) devices are not necessary or practical, but easily-portable, small-sized WECs are suitable, including navigation signs, illumination, sensors, survival kits, electronics charging, and portable desalination. In this thesis, the objective was to optimize the performance of small-sized, oscillating body wave energy converters. Oscillating body WECs function by converting a device's wave-driven oscillating motion into useful power. Two types of oscillating body WECs were studied: bottom hinged and two-body attenuator. For the bottom-hinged device, the goal was to show the feasibility of a WEC and desalination system using numerical modeling to estimate the system performance. Based on the model results, the system will produce desirable amounts of fresh water with suitably low concentration and be effective at discharging brine. The objective for the two-body attenuator was to develop a method of power maximization through resonance tuning and numerical simulation. Based on the two- and three-degree-of-freedom model results with approximate drag coefficients, the elliptical cross section had the largest power absorption out of three different geometries of body cross sections. A mooring stiffness study with the three-degree-of-freedom model showed that mooring stiffness can be increased to increase power absorption.

Wave Energy Converter (WEC)

Wave Attenuator

Seawater Desalination

Geometry Optimization

Resonance Tuning

Power Maximization