Signal Processing Design of Low Probability of Intercept Waveforms

This thesis investigates a modification to Differential Phase Shift Keyed (DPSK) modulation to create a Low Probability of Interception/Exploitation (LPI/LPE) communications signal. A pseudorandom timing offset is applied to each symbol in the communications stream to intentionally create intersymbol interference (ISI) that hinders accurate symbol estimation and bit sequence recovery by a non-cooperative receiver. Two cooperative receiver strategies are proposed to mitigate the ISI due to symbol timing offset: a modified minimum Mean Square Error (MMSE) equalization algorithm and a multiplexed bank of equalizer filters determined by an adaptive Least Mean Square (LMS) algorithm. Both cooperative receivers require some knowledge of the pseudorandom symbol timing dither to successfully demodulate the communications waveform. Numerical Matlab® simulation is used to demonstrate the bit error rate performance of cooperative receivers and notional non-cooperative receivers for binary, 4-ary, and 8-ary DPSK waveforms transmitted through a line-of-sight, additive white Gaussian noise channel. Simulation results suggest that proper selection of pulse shape and probability distribution of symbol timing offsets produces a waveform that is accurately demodulated by the proposed cooperative receivers and significantly degrades non-cooperative receiver symbol estimation accuracy. In typical simulations, non-cooperative receivers required 2-8 dB more signal power than cooperative receivers to achieve a bit error rate of 1.0%. For nearly all reasonable parameter selections, non-cooperative receivers produced bit error rates in excess of 0.1%, even when signal power is unconstrained

Achieving Secrecy Capacity of the Gaussian Wiretap Channel with Polar Lattices

In this work, an explicit wiretap coding scheme based on polar lattices is proposed to achieve the secrecy capacity of the additive white Gaussian noise (AWGN) wiretap channel. Firstly, polar lattices are used to construct secrecy-good lattices for the mod-$\Lambda_s$ Gaussian wiretap channel. Then we propose an explicit shaping scheme to remove this mod-$\Lambda_s$ front end and extend polar lattices to the genuine Gaussian wiretap channel. The shaping technique is based on the lattice Gaussian distribution, which leads to a binary asymmetric channel at each level for the multilevel lattice codes. By employing the asymmetric polar coding technique, we construct an AWGN-good lattice and a secrecy-good lattice with optimal shaping simultaneously. As a result, the encoding complexity for the sender and the decoding complexity for the legitimate receiver are both O(N logN log(logN)). The proposed scheme is proven to be semantically secure.Comment: Submitted to IEEE Trans. Information Theory, revised. This is the authors' own version of the pape

A high-fidelity multiphysics system for neutronic, thermalhydraulic and fuel-performance analysis of Light Water Reactors

Das Verhalten des Kerns in einem Leichtwasserreaktor (LWR) wird von neutronenphysikalischen, thermohydraulischen und thermomechanischen Phänomenen dominiert. Komplexe Rückkopplungsmechanismen verbinden diese physikalischen Bereiche. Einer der aktuellen Tendenzen in der Reaktorphysik ist daher die Implementierung von Multiphysik-Methoden, die diese Wechselwirkungen erfassen, um eine konsistente Beschreibung des Kerns zu liefern. Ein weiterer wichtiger Arbeitsbereich ist die Entwicklung von High-Fidelity-Rechenprogrammen, die die Modellierungsauflösung erhöhen und starke Vereinfachungen eliminieren, die in räumlich homogenisierten Simulationen verwendet werden. Multiphysik- und High-Fidelity-Methoden sind auf die Verfügbarkeit von Hochleistungsrechnern angewiesen, die die Machbarkeit und den Umfang dieser Art von Simulationen begrenzen. Das Ziel dieser Arbeit ist die Entwicklung eines Multiphysik-Simulationssystems, das in der Lage ist, gekoppelte neutronenphysikalische, thermohydraulische und thermomechanische Analysen von LWR-Kernen mit einer High-Fidelity-Methodik durchzuführen. Um dies zu erreichen, wird die Monte-Carlo-Teilchentransportmethode verwendet, um das Verhalten der neutronenphysikalischen Effekte zu simulieren, ohne auf größere physikalische Näherungen zurückzugreifen. Für die Abbrandrechnungen bezüglich des gesamten Kerns, wird eine gebietsbezogene Datenaufteilung der Partikelverfolgung vorgeschlagen und implementiert. Die Kombination der Monte-Carlo-Methode mit der Thermohydraulik auf Unterkanalebene und eine vollständige Analyse des Brennstoffverhaltens aller Brennstäbe beschreibt eine extrem detaillierte Darstellung des Kerns. Die erforderliche Rechenleistung erreicht die Grenzen aktueller Hochleistungsrechner. Auf der Softwareseite wird ein innovativer objektorientierter Kopplungsansatz verwendet, um die Modularität, Flexibilität und Wartbarkeit des Programms zu erhöhen. Die Genauigkeit dieses gekoppelten Systems von drei Programmen wird mit experimentellen Daten von zwei in Betrieb befindlichen Kraftwerken, einem Pre-Konvoi DWR und dem Temelín II WWER-1000 Reaktor, bewertet. Für diese beiden Fälle werden die Ergebnisse der Abbrandrechnung des gesamten Kerns anhand von Messungen der kritischen Borkonzentration und des Brennstabneutronenflusses validiert. Diese Simulationen dienen der Darstellung der hochmodernen Modellierungsfähigkeiten des entwickelten Werkzeugs und zeigen die Durchführbarkeit dieser Methodik für industrielle Anwendungen

High Speed Turbo Tcm Ofdm For Uwb And Powerline System

Turbo Trellis-Coded Modulation (TTCM) is an attractive scheme for higher data rate transmission, since it combines the impressive near Shannon limit error correcting ability of turbo codes with the high spectral efficiency property of TCM codes. We build a punctured parity-concatenated trellis codes in which a TCM code is used as the inner code and a simple parity-check code is used as the outer code. It can be constructed by simple repetition, interleavers, and TCM and functions as standard TTCM but with much lower complexity regarding real world implementation. An iterative bit MAP decoding algorithm is associated with the coding scheme. Orthogonal Frequency Division Multiplexing (OFDM) modulation has been a promising solution for efficiently capturing multipath energy in highly dispersive channels and delivering high data rate transmission. One of UWB proposals in IEEE P802.15 WPAN project is to use multi-band OFDM system and punctured convolutional codes for UWB channels supporting data rate up to 480Mb/s. The HomePlug Networking system using the medium of power line wiring also selects OFDM as the modulation scheme due to its inherent adaptability in the presence of frequency selective channels, its resilience to jammer signals, and its robustness to impulsive noise in power line channel. The main idea behind OFDM is to split the transmitted data sequence into N parallel sequences of symbols and transmit on different frequencies. This structure has the particularity to enable a simple equalization scheme and to resist to multipath propagation channel. However, some carriers can be strongly attenuated. It is then necessary to incorporate a powerful channel encoder, combined with frequency and time interleaving. We examine the possibility of improving the proposed OFDM system over UWB channel and HomePlug powerline channel by using our Turbo TCM with QAM constellation for higher data rate transmission. The study shows that the system can offer much higher spectral efficiency, for example, 1.2 Gbps for OFDM/UWB which is 2.5 times higher than the current standard, and 39 Mbps for OFDM/HomePlug1.0 which is 3 times higher than current standard. We show several essential requirements to achieve high rate such as frequency and time diversifications, multi-level error protection. Results have been confirmed by density evolution. The effect of impulsive noise on TTCM coded OFDM system is also evaluated. A modified iterative bit MAP decoder is provided for channels with impulsive noise with different impulsivity