Μελέτη αλγορίθμων ψηφιακής επεξεργασίας σήματος για ομόδυνο δέκτη QPSK σε οπτικά συστήματα μεγάλων αποστάσεων υψηλής φασματικής απόδοσης / DSP algorithms for optical polarization division multiplexed quadrature phase shift keying systems with coherent intradyne phase and polarization diversity receivers

Πέτρου, Κωνσταντίνος

20 October 2010

The scope of this dissertation is to investigate the merits and implications of using multilevel modulation formats in optical communications systems. Following the trend in academia and industry, special focus is placed on quadrature phase-shift keying (QPSK), and specifically on polarization division multiplexed (PDM) QPSK. A special kind of receiver is investigated thoroughly, the digital coherent receiver, the equivalent of the coherent quadrature demodulator in classical communications nomenclature. A large number of digital signal processing (DSP) algorithms are implemented, some of them novel, and their performance is examined, analyzed, and compared in a number of practical system scenarios. The impact of transmitter / receiver imperfections and a number of optical fiber impairments on system performance is studied. Experimental results taken from proof-of-concept experiments are also analyzed. / Η διατριβή αυτή έχει ως σκοπό τη μελέτη οπτικών τηλεπικοινωνιακών συστημάτων που χρησιμοποιούν τετραδικές διαμορφώσεις φάσης, πολυπλεξία κατά πόλωση και σύμφωνους ψηφιακούς δέκτες διαφοροποίησης φάσης και πόλωσης. Μελετήθηκαν αλγόριθμοι επεξεργασίας σήματος κατάλληλοι για εξάλειψη της επίδρασης των φαινομένων διάδοσης και των μη ιδανικοτήτων οπτικών τηλεπικοινωνιακών συστημάτων. Η μελέτη έγινε με προσομοίωση Monte-Carlo, με χρήση ημιαναλυτικής μεθόδου προσδιορισμού της πιθανότητας σφάλματος τηλεπικοινωνιακού συστήματος και με ανάλυση πειραματικών δεδομένων. Τα πειραματικά δεδομένα ελήφθησαν από οπτικό τηλεπικοινωνιακό σύστημα με τετραδική διαμόρφωση φάσης και πολυπλεξία κατά πόλωση με ρυθμούς συμβόλων 0.1-10 GBd (0.4-40 Gb/s). Μελετήθηκαν αλγόριθμοι επανένωσης των πολώσεων, αλγόριθμοι αποπολύπλεξης των πολώσεων, αλγόριθμοι διόρθωσης της ανισοσταθμίας ορθογωνιότητας, αλγόριθμοι εκτίμησης και αφαίρεσης της ενδιάμεσης συχνότητας και αλγόριθμοι εκτίμησης και αφαίρεσης του θορύβου φάσης των laser.

Optical fiber communications

Polarization

Quadrature phase shift keying

Polarization division multiplexing

Signal processing algorithms

621.382 7

Πόλωση

Generation of Modulated Microwave Signals using Optical Techniques for Onboard Spacecraft Applications

Yogesh Prasad, K R

January 2013

This thesis deals with optical synthesis of unmodulated and modulated microwave signals. Generation of microwave signals based on optical heterodyning is discussed in detail. The effect of phase noise of laser on heterodyned output has been studied for different phase noise profiles. Towards this, we propose a generic algorithm to numerically model the linewidth broadening of a laser due to phase noise. Generation of microwave signals is demonstrated practically by conducting an optical heterodyning experiment. Signals ranging in frequency from 12.5 MHz to 27 GHz have been generated. Limitations of optical heterodyning based approach in terms of phase noise performance and frequency stability are discussed and practically demonstrated. A hardware-efficient Optical Phase Locked Loop (OPLL) is proposed to overcome these issues. Phase noise tracking performance of the proposed OPLL has been experimentally demonstrated. Phase noise values as low as -105 dBc/Hz at 10 KHz offset have been achieved. Optical modulators, owing to their extremely low electro-optic response time, can support high frequency modulating signals. This makes them highly attractive in comparison to their microwave counterparts. In this thesis, we propose techniques to generate microwave signals modulated at very high bit rates by down-converting the corresponding modulated optical signals to microwave domain. Down-conversion required for this process is achieved by optical heterodyning. The proposed concept has been theoretically analyzed, simulated and experimentally validated. Amplitude Modulated and ASK modulated microwave signals have been generated as Proof-of-Concept. Limitations posed by OPLL in generation of angle modulated microwave signals by optical heterodyning have been brought out. Schemes overcoming these limitations have been proposed towards generation of BPSK and QPSK modulated microwave signals. Integrated Optics (IO) technology has been studied as a means of implementation of the proposed concepts. IO components like Sinusoidal bends, Y-branch splitters and Electro-Optic-Modulators (EOMs) have been designed towards optical synthesis of modulated microwave signals. Propagation of modulated optical signal through these IO components has also been studied. An all-optic scheme based on Optical Beam Forming is proposed for transmission of QPSK modulated signal. Limitation of phase-shifting based approach, in terms of beam-squint, has been brought out. True-Time-Delay based approach has been proposed for applications demanding wide instantaneous bandwidth to avoid beam-squint. Algorithms / numerical methods required for analyses and simulations associated with the above-mentioned tasks have been evolved. This study is envisaged to provide useful insight into the realization of high-speed, compact, light-weight data transmitting systems based on Integrated Optics for future onboard spacecraft applications. This work, we believe, is a step towards realization of an Integrated Optic System-on-Chip solution for specific microwave data transmission applications.

Microwave Photonics

Microwave Generation

Millimeter-wave Generation

Optical Heterodyning

Integrated Optics

Microwave Signals

Optical Beam Forming Network (OBFN)

Electro-Optic Modulators (EOM)

Microwave Signal Generation

Modulated Microwave Signals

Optical Phased Locked Loop (OPLL)

True-Time Delay

Phased Array Antenna

Optical Signal Processing

Electronic Engineering

Communication For a Space Sunshade System

Granberg, Moa, Silfverberg, Nikolina

January 2024

By placing millions of space sunshades, of the order of 104 m2 at the sub-Lagrangian point L1',between the sun and Earth, solar radiation can be reduced enough to achieve the necessary temper-ature reduction to enable a slow down of the global warming. The vast amount of space sunshadesposes significant challenges on the communication system, as the probability of interference, whichcan distort information, increases with the number of simultaneously communicating units.This thesis aims to design a potential structure for the communication system that minimizesinterference as much as possible. To reduce the number of simultaneously communicating units, thesunshades are arranged in cell formation, where a mother is placed in the center with daughtersaround that only communicate with their specific cell mother. Direct communication betweenthe Earth and space sunshades is not possible as the interference from solar radiation can causesignificant distortion on the signals. Therefore, relay satellites are placed in orbit around thesub-Lagrangian point L1' at a sufficient distance to avoid the effects of solar radiation. Thus, thecommunication between the mothers and Earth is instead routed via the relay satellites. Sincecommunication between such a large number of entities in space has not been investigated before,this approach could provide a possible basic design framework for designing such infrastructure inthe future.

Satellite communication

Relay satellite

Lagrange point

Sub-Lagrange point

Space sunshade

Sunshade system

TT&C

Transfer frame

Telemetry packet

Communication scheme

Ka-frequency band

Forward error correction

Modulation

Channel capacity

Bandpass modulation

Quadrature phase shift keying

Code division multiple access

Cell configuration

Interference

Link budget

Link margin

Solar exclusion zone

Sun outage

Satellites in multiple layers

Physical Sciences

Fysik