Frequency shifts with pressure in CO laser lines

Laguna-Ayala, Alejandro Gabriel

January 1979

No description available.

Frequencies of oscillating systems.

Chemical lasers.

Heterodyning (Electronics)

Heterodyne digital control and frequency estimation in magnetic resonance force microscopy /

Kriewall, Thomas E.,

January 2004

Thesis (Ph. D.)--University of Washington, 2004. / Vita. Includes bibliographical references (leaves 98-104).

Decorrelation time of speckle targets observed with a heterodyne-reception optical radar

Lau, Sun Tong

January 1982

Thesis (M.S.)--Massachusetts Institute of Technology, Dept. of Electrical Engineering and Computer Science, 1982. / MICROFICHE COPY AVAILABLE IN ARCHIVES AND ENGINEERING. / Includes bibliographical references. / by Sun Tong Lau. / M.S.

Optical radar

Laser speckle

Heterodyning (Electronics)

Atmospheric turbulence

Correlation (Statistics)

Coherent radar

The Process of Implementing a RF Front-End Transceiver for NASA's Space Network

Wilder, Ali, Pannu, Randeep, Haj-Omar, Amr

10 1900

Software defined radio (SDR) introduces endless possibilities for future communication technologies. Instead of being limited to a static segment of the radio spectrum, SDR allows RF front-ends to be more flexible by using digital signal processing (DSP) and cognitive techniques to integrate adaptive hardware with dynamic software. We present the design and implementation of an innovative RF front-end transceiver architecture for application into a SDR test-bed platform. System-level requirements were extracted from the Space Network User Guide (SNUG). Initial system characterization demonstrated image leakage due to poor filtering and mixer isolation issues. Hence, the RF front-end design was re-implemented using the Weaver architecture for improved image rejection performance.

Software defined radio (SDR)

Heterodyning

Image Rejection

S-band Single Access (SSA)

Weaver Architecture

High frequency water vapor density measurements using the beat frequency method

Elorriaga Montenegro, Estefania

15 June 2012

This document describes the design and deployment of a first generation water vapor density sensing unit, the HumiSense. This device is based on an open, air-filled capacitor which is part of a resonant circuit. The frequency of the resonant circuit mixed with a fixed frequency oscillator is the basis of the method to generate a signal that is associated to the change in water vapor density within the open capacitor with time. The physical testing results were inconclusive given that there were many unresolved artifacts in the data. Several suggestions for improving the device for future device generations were provided. / Graduation date: 2013

Water vapor density

Turbulence

Beat Frequency method

Heterodyne system

Capacitive sensor

Coaxial capacitor

Detectors -- Design and construction

Heterodyning (Electronics)

Detecting Structural Defects Using Novel Smart Sensory and Sensor-less Approaches

Baghalian, Amin

17 October 2017

Monitoring the mechanical integrity of critical structures is extremely important, as mechanical defects can potentially have adverse impacts on their safe operability throughout their service life. Structural defects can be detected by using active structural health monitoring (SHM) approaches, in which a given structure is excited with harmonic mechanical waves generated by actuators. The response of the structure is then collected using sensor(s) and is analyzed for possible defects, with various active SHM approaches available for analyzing the response of a structure to single- or multi-frequency harmonic excitations. In order to identify the appropriate excitation frequency, however, the majority of such methods require a priori knowledge of the characteristics of the defects under consideration. This makes the whole enterprise of detecting structural defects logically circular, as there is usually limited a priori information about the characteristics and the locations of defects that are yet to be detected. Furthermore, the majority of SHM techniques rely on sensors for response collection, with the very same sensors also prone to structural damage. The Surface Response to Excitation (SuRE) method is a broadband frequency method that has high sensitivity to different types of defects, but it requires a baseline. In this study, initially, theoretical justification was provided for the validity of the SuRE method and it was implemented for detection of internal and external defects in pipes. Then, the Comprehensive Heterodyne Effect Based Inspection (CHEBI) method was developed based on the SuRE method to eliminate the need for any baseline. Unlike traditional approaches, the CHEBI method requires no a priori knowledge of defect characteristics for the selection of the excitation frequency. In addition, the proposed heterodyne effect-based approach constitutes the very first sensor-less smart monitoring technique, in which the emergence of mechanical defect(s) triggers an audible alarm in the structure with the defect. Finally, a novel compact phased array (CPA) method was developed for locating defects using only three transducers. The CPA approach provides an image of most probable defected areas in the structure in three steps. The techniques developed in this study were used to detect and/or locate different types of mechanical damages in structures with various geometries.

Structural Health Monitoring

SHM

Sensor-less SHM

SSHM

Sensor-free SHM

Heterodyning Effect

Guided Waves

Defect Detection

Loose Bolt Detection

Crack Detection

Beam Forming

Phased Array

Monitoring of Pipes

Nonlinear Guided Waves

Nonlinear Wave Modulation Spectroscopy

NWMS

Surface Response to Excitation

SuRE

Acoustics, Dynamics, and Controls

Electro-Mechanical Systems

Signal Processing

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