NAVAL SURFACE WARFARE – A COST EFFECTIVENESS ANALYSIS OF HARD-KILL VERSUS SOFT-KILL FOR SHIP SELF DEFENSE

This project is relevant to military acquisition, U.S. Navy financial management, and Naval Surface Warfare. It examines the cost-effectiveness analysis of potential Navy Surface Ship Electronic Warfare (EW) and vertical launch missile systems (VLS). Our intent is that the research informs the Program Executive Office Information Warfare Systems (PEO/IWS) and OPNAV N96/N2N6 by illustrating the capabilities and costs of EW and missile systems. We examined the effectiveness of Navy systems against a myriad of threat missiles, using estimated percent kill (Pk) calculations that encompassed the underlying sensors consisting of command and control, communications, detection, engagement, and tracking. Our results indicate that the electronic warfare systems, specifically the SLQ-32 (v)7, is the most cost-effective system to deter threat missiles, because of the re-load cost associated with missile systems, specifically the SM-6, SM-2, and ESSM. While the SLQ-32 is the most cost-effective system, we understand the need for redundancy, and we cannot completely disregard defensive missile systems. It is our hope that this research will ultimately aid in strategic decision-making for long-term employment weapons load outs on various ship classes. With more money invested in electronic warfare defense systems, the load out on surface assets can theoretically shift to a more offensive mindset, while still maintaining defensive missiles for the applicable threat environment.Lieutenant, United States NavyLieutenant, United States NavyLieutenant, United States NavyApproved for public release. Distribution is unlimited

China\u27s Nuclear Force Modernization

Relations between Washington and Beijing improved swiftly in the wake of the 9/11 terrorist attacks, especially in comparison to the nadir that had been reached during the April 2001 EP-3 incident. This new tide of cooperation has included counterterrorism initiatives, regional partnership in such complex situations as Afghanistan and North Korea, and even some modest agreement on the importance of maintaining the status quo with respect to Taiwan\u27s status.https://digital-commons.usnwc.edu/usnwc-newport-papers/1023/thumbnail.jp

Advanced signal processing tools for ballistic missile defence and space situational awareness

The research presented in this Thesis deals with signal processing algorithms for the classification of sensitive targets for defence applications and with novel solutions for the detection of space objects. These novel tools include classification algorithms for Ballistic Targets (BTs) from both micro-Doppler (mD) and High Resolution Range Profiles (HRRPs) of a target, and a space-borne Passive Bistatic Radar (PBR) designed for exploiting the advantages guaranteed by the Forward Scattering (FS) configuration for the detection and identification of targets orbiting around the Earth.;Nowadays the challenge of the identification of Ballistic Missile (BM) warheads in a cloud of decoys and debris is essential in order to optimize the use of ammunition resources. In this Thesis, two different and efficient robust frameworks are presented. Both the frameworks exploit in different fashions the effect in the radar return of micro-motions exhibited by the target during its flight.;The first algorithm analyses the radar echo from the target in the time-frequency domain, with the aim to extract the mD information. Specifically, the Cadence Velocity Diagram (CVD) from the received signal is evaluated as mD profile of the target, where the mD components composing the radar echo and their repetition rates are shown.;Different feature extraction approaches are proposed based on the estimation of statistical indices from the 1-Dimensional (1D) Averaged CVD (ACVD), on the evaluation of pseudo-Zerike (pZ) and Krawtchouk (Kr) image moments and on the use of 2-Dimensional (2D) Gabor filter, considering the CVD as 2D image. The reliability of the proposed feature extraction approaches is tested on both simulated and real data, demonstrating the adaptivity of the framework to different radar scenarios and to different amount of available resources.;The real data are realized in laboratory, conducting an experiment for simulating the mD signature of a BT by using scaled replicas of the targets, a robotic manipulator for the micro-motions simulation and a Continuous Waveform (CW) radar for the radar measurements.;The second algorithm is based on the computation of the Inverse Radon Transform (IRT) of the target signature, represented by a HRRP frame acquired within an entire period of the main rotating motion of the target, which are precession for warheads and tumbling for decoys. Following, pZ moments of the resulting transformation are evaluated as final feature vector for the classifier. The features guarantee robustness against the target dimensions and the initial phase and the angular velocity of its motion.;The classification results on simulated data are shown for different polarization of the ElectroMagnetic (EM) radar waveform and for various operational conditions, confirming the the validity of the algorithm.The knowledge of space debris population is of fundamental importance for the safety of both the existing and new space missions. In this Thesis, a low budget solution to detect and possibly track space debris and satellites in Low Earth Orbit (LEO) is proposed.;The concept consists in a space-borne PBR installed on a CubeSaT flying at low altitude and detecting the occultations of radio signals coming from existing satellites flying at higher altitudes. The feasibility of such a PBR system is conducted, with key performance such as metrics the minimumsize of detectable objects, taking into account visibility and frequency constraints on existing radio sources, the receiver size and the compatibility with current CubeSaT's technology.;Different illuminator types and receiver altitudes are considered under the assumption that all illuminators and receivers are on circular orbits. Finally, the designed system can represent a possible solution to the the demand for Ballistic Missile Defence (BMD) systems able to provide early warning and classification and its potential has been assessed also for this purpose.The research presented in this Thesis deals with signal processing algorithms for the classification of sensitive targets for defence applications and with novel solutions for the detection of space objects. These novel tools include classification algorithms for Ballistic Targets (BTs) from both micro-Doppler (mD) and High Resolution Range Profiles (HRRPs) of a target, and a space-borne Passive Bistatic Radar (PBR) designed for exploiting the advantages guaranteed by the Forward Scattering (FS) configuration for the detection and identification of targets orbiting around the Earth.;Nowadays the challenge of the identification of Ballistic Missile (BM) warheads in a cloud of decoys and debris is essential in order to optimize the use of ammunition resources. In this Thesis, two different and efficient robust frameworks are presented. Both the frameworks exploit in different fashions the effect in the radar return of micro-motions exhibited by the target during its flight.;The first algorithm analyses the radar echo from the target in the time-frequency domain, with the aim to extract the mD information. Specifically, the Cadence Velocity Diagram (CVD) from the received signal is evaluated as mD profile of the target, where the mD components composing the radar echo and their repetition rates are shown.;Different feature extraction approaches are proposed based on the estimation of statistical indices from the 1-Dimensional (1D) Averaged CVD (ACVD), on the evaluation of pseudo-Zerike (pZ) and Krawtchouk (Kr) image moments and on the use of 2-Dimensional (2D) Gabor filter, considering the CVD as 2D image. The reliability of the proposed feature extraction approaches is tested on both simulated and real data, demonstrating the adaptivity of the framework to different radar scenarios and to different amount of available resources.;The real data are realized in laboratory, conducting an experiment for simulating the mD signature of a BT by using scaled replicas of the targets, a robotic manipulator for the micro-motions simulation and a Continuous Waveform (CW) radar for the radar measurements.;The second algorithm is based on the computation of the Inverse Radon Transform (IRT) of the target signature, represented by a HRRP frame acquired within an entire period of the main rotating motion of the target, which are precession for warheads and tumbling for decoys. Following, pZ moments of the resulting transformation are evaluated as final feature vector for the classifier. The features guarantee robustness against the target dimensions and the initial phase and the angular velocity of its motion.;The classification results on simulated data are shown for different polarization of the ElectroMagnetic (EM) radar waveform and for various operational conditions, confirming the the validity of the algorithm.The knowledge of space debris population is of fundamental importance for the safety of both the existing and new space missions. In this Thesis, a low budget solution to detect and possibly track space debris and satellites in Low Earth Orbit (LEO) is proposed.;The concept consists in a space-borne PBR installed on a CubeSaT flying at low altitude and detecting the occultations of radio signals coming from existing satellites flying at higher altitudes. The feasibility of such a PBR system is conducted, with key performance such as metrics the minimumsize of detectable objects, taking into account visibility and frequency constraints on existing radio sources, the receiver size and the compatibility with current CubeSaT's technology.;Different illuminator types and receiver altitudes are considered under the assumption that all illuminators and receivers are on circular orbits. Finally, the designed system can represent a possible solution to the the demand for Ballistic Missile Defence (BMD) systems able to provide early warning and classification and its potential has been assessed also for this purpose

Research Naval Postgraduate School, v.13, no.1, February 2003

NPS Research is published by the Research and Sponsored Programs, Office of the Vice President and Dean of Research, in accordance with NAVSOP-35. Views and opinions expressed are not necessarily those of the Department of the Navy.Approved for public release; distribution is unlimited

Missile Defense, Extended Deterrence, and Nonproliferation in the 21st Century

The following papers were commissioned as part of the Missile Defense, Extended Deterrence, and Nonproliferation in the 21st Century project supported by the Project on Advanced Systems and Concepts for Countering Weapons of Mass Destruction (PASCC). The papers have two general purposes: 1) to create a body of work that provides an overview of the missile defense developments in major regions of the world; and 2) to provide emerging scholars the opportunity to conduct research, publish, and connect with each other. We believe we have succeeded on both counts. The papers written for this project will be valuable for academics and policymakers alike, and will be published and disseminated by the Center for International and Security Studies at Maryland. This element of the project has also been successful in further bringing together a new cadre of experts in the field and developing the next generation of academics and public servants who will benefit from their participation in this project. These papers were completed in the Fall of 2016