Sea-Ice Detection from RADARSAT Images by Gamma-based Bilateral Filtering

Xie, Si

January 2013

Spaceborne Synthetic Aperture Radar (SAR) is commonly considered a powerful sensor to detect sea ice. Unfortunately, the sea-ice types in SAR images are difficult to be interpreted due to speckle noise. SAR image denoising therefore becomes a critical step of SAR sea-ice image processing and analysis. In this study, a two-phase approach is designed and implemented for SAR sea-ice image segmentation. In the first phase, a Gamma-based bilateral filter is introduced and applied for SAR image denoising in the local domain. It not only perfectly inherits the conventional bilateral filter with the capacity of smoothing SAR sea-ice imagery while preserving edges, but also enhances it based on the homogeneity in local areas and Gamma distribution of speckle noise. The Gamma-based bilateral filter outperforms other widely used filters, such as Frost filter and the conventional bilateral filter. In the second phase, the K-means clustering algorithm, whose initial centroids are optimized, is adopted in order to obtain better segmentation results. The proposed approach is tested using both simulated and real SAR images, compared with several existing algorithms including K-means, K-means based on the Frost filtered images, and K-means based on the conventional bilateral filtered images. The F1 scores of the simulated results demonstrate the effectiveness and robustness of the proposed approach whose overall accuracies maintain higher than 90% as variances of noise range from 0.1 to 0.5. For the real SAR images, the proposed approach outperforms others with average overall accuracy of 95%.

SAR image segmentation

Bilateral filter

Sea ice

Geography

A comparison of imaging methods using GPR for landmine detection and a preliminary investigation into the SEM for identification of buried objects

Gilmore, Colin G.

13 January 2005

Part I: Various image reconstruction algorithms used for subsurface targets are reviewed. It is shown how some approximate wavefield inversion techniques: Stripmap Synthetic Aperture Radar (SAR), Kirchhoff Migration (KM) and Frequency-Wavenumber (FK) migration are developed from various models for wavefield scattering. The similarities of these techniques are delineated both from a theoretical and practical perspective and it is shown that Stripmap SAR is, computationally, almost identical to FK migration. A plane wave interpretation of both Stripmap SAR and FK migration is used to show why they are so similar. The electromagnetic assumptions made in the image reconstruction algorithms are highlighted. In addition, it is shown that, theoretically, FK and KM are identical. Image reconstruction results for KM, Stripmap SAR and FK are shown for both synthetic and experimental Ground Penetrating Radar (GPR) data. Subjectively the reconstructed images show little difference, but computationally, Stripmap SAR (and therefore, FK migration) are much more efficient. Part II: A preliminary investigation into the use of the Singularity Expansion Method (SEM) for use in identifying landmines is completed using a Finite-Difference Time-Domain code to simulate a simplified GPR system. The Total Least Squares Matrix Pencil Method (TLS-MPM) is used to determine the complex poles from an arbitrary late-time signal. Both dielectric and metallic targets buried in lossless and lossy half-spaces are considered. Complex poles (resonances) of targets change significantly when the objects are buried in an external medium, and perturbation formulae for Perfect Electric Conductor (PEC) and dielectric targets are highlighted and used. These perturbation formulae are developed for homogenous surrounding media, and their utilization for the half-space (layered medium) GPR problem causes inaccuracies in their predictions. The results show that the decay rate (real part) of the complex poles is not suitable for identification in this problem, but that with further research, the resonant frequency (imaginary part) of the complex poles shows promise as an identification feature.

GPR

Target Identification

Seismic Migration

Stripmap SAR

Landmines

SEM

CNR

Improvement of Differential Interferometric Synthetic Aperture Radar (D-InSAR) technique to accurate and overall displacement monitoring in geothermal fields for sustainable resource use / 持続可能資源使用を目指した地熱フィールドでの高精度で全域にわたる変位モニタリングのための差分干渉SAR処理法の改良

Panggea, Ghiyats Sabrian

23 March 2022

京都大学 / 新制・課程博士 / 博士(工学) / 甲第23863号 / 工博第4950号 / 新制||工||1773(附属図書館) / 京都大学大学院工学研究科都市社会工学専攻 / (主査)教授 小池 克明, 教授 須崎 純一, 准教授 柏谷 公希 / 学位規則第4条第1項該当 / Doctor of Philosophy (Engineering) / Kyoto University / DGAM

Geothermal

SAR

D-InSAR

source modeling

lineament

permeability zone

500

Fast target tracking technique for synthetic aperture radars

Kauffman, Kyle J.

January 2009

Title from first page of PDF document. Includes bibliographical references (p. 40).

Využití dat Sentinel-1 pro sledování managementu luk / Grassland management monitoring based on Sentinel-1 data

Doležal, Jan

January 2018

The main goal of this diploma thesis was to find and quantify the connection between coherence, entropy, polarimetric angle alpha obtained from Sentinel-1 radar data and grass cutting/pastures. The research was carried out in the area of the Krkonoše national park. To assemble and validate applied methodology, field data was collected 5 times. Hourly rainfall data from Czech hydrometeorological institute was available, but it did not have to be used - no rainfalls were recorded at the time of data acquisitions. Dependence between mowing and the value of coherence has been confirmed. After mowing, median coherence was higher than before mowing. The results were similar to VH as well as VV polarization. Coherence on polygons remained higher after 12-24 days. In total, two different data acquisition geometries (ascending and descending) were examined. The results in both cases were similar. For polarimetric parameters, no correlation between polarimetric parameters and grass mowing or pasture has been confirmed. Keywords: radar, SAR, Sentinel-1, coherence, polarimetry, grass mowing

Análise de desempenho de tráfego de dados assíncronos sobre bluetooth

CARVALHO, Carlos Giovanni Nunes

January 2003

Made available in DSpace on 2014-06-12T15:58:59Z (GMT). No. of bitstreams: 2 arquivo4796_1.pdf: 885863 bytes, checksum: 72c0efdf8b935cda71a6cbb65e325c61 (MD5) license.txt: 1748 bytes, checksum: 8a4605be74aa9ea9d79846c1fba20a33 (MD5) Previous issue date: 2003 / Aplicações de dados, que funcionam sobre o Bluetooth, tais como HTTP, FTP e real audio, irão necessitar de protocolos da camada de transporte da arquitetura TCP/IP (TCP e UDP) para enviar pacotes sobre os links wireless. Para aumentar o desempenho destas aplicações é preciso otimizar os recursos existentes, que na maioria dos dispositivos para este tipo de tecnologia são escassos. Alguns fatores influenciam o desempenho do tráfego de dados sobre estes dispositivos, normalmente, de tamanho reduzido e pouca autonomia de uso. Com isso, há uma crescente tentativa de torná-los mais eficientes, através do melhor aproveitamento de seus recursos. Este trabalho contempla a análise e o aumento de performance do tráfego de dados usando o serviço assíncrono Bluetooth. Mostramos, através dos resultados, que o melhor algoritmo de Segmentação e Remontagem (SAR) é o de Melhor Ajuste (BF), que na média, apresenta maior vazão, menor atraso e variação de atraso nas transmissões e menor porcentagem de perda de pacotes. Quanto as variantes do TCP, o Vegas apresentou-se a melhor escolha, com uma vazão média maior, uma menor porcentagem de perda de pacotes, menor atraso e variação de atraso, mas devido não haver implementações dessa variante, a solução mais conveniente é a utilização do New Reno, uma vez que utilizado com o algoritmo SAR-BF obteve melhor desempenho que os demais

Segmentação e Remontagem (SAR)

Variantes do TCP

Ad-hoc

Bluetooth

Wireless

Time Domain SAR Processing with GPUs for Airborne Platforms

Lagoy, Dustin

24 March 2017

A time-domain backprojection processor for airborne synthetic aperture radar (SAR) has been developed at the University of Massachusetts’ Microwave Remote Sensing Lab (MIRSL). The aim of this work is to produce a SAR processor capable of addressing the motion compensation issues faced by frequency-domain processing algorithms, in order to create well focused SAR imagery suitable for interferometry. The time-domain backprojection algorithm inherently compensates for non-linear platform motion, dependent on the availability of accurate measurements of the motion. The implementation must manage the relatively high computational burden of the backprojection algorithm, which is done using modern graphics processing units (GPUs), programmed with NVIDIA’s CUDA language. An implementation of the Non-Equispaced Fast Fourier Transform (NERFFT) is used to enable efficient and accurate range interpolation as a critical step of the processing. The phase of time- domain processed imagery is dif erent than that of frequency-domain imagery, leading to a potentially different approach to interferometry. This general purpose SAR processor is designed to work with a novel, dual-frequency S- and Ka-band radar system developed at MIRSL as well as the UAVSAR instrument developed by NASA’s Jet Propulsion Laboratory. These instruments represent a wide range of SAR system parameters, ensuring the ability of the processor to work with most any airborne SAR. Results are presented from these two systems, showing good performance of the processor itself.

Synthetic Aperture Radar (SAR)

GPU

UAVSAR

Airborne SAR

Motion Compensation

NERFFT

SCH Coordinates

SAR Interferometry (INSAR)

FMCW Radar

Aerospace Engineering

Electrical and Computer Engineering

Geophysics and Seismology

Signal Processing

Deep Learning for Compressive SAR Imaging with Train-Test Discrepancy

McCamey, Morgan R.

21 June 2021

No description available.

Computer Engineering

Computer Science

Electrical Engineering

SAR

deep learning

machine learning

compressive sensing

CS

signal recovery

SAR imaging

synthetic SAR

image recovery

compressed SAR

compressed signals

DNN

neural network

Studium receptorů pro opioidy / Study of opioid receptors

Cechová, Kristína

January 2016

1 ABSTRACT In this Thesis, we studied properties of μ-, δ-, and κ-opioid receptors in lymphocytes isolated from rat spleen. This splenocytes were exposed to mitogen concanavalin A or opiate morphine and cultivated for 48 hours. Under physiological conditions, level of opioid receptors in immune cells is very low. Due to various factors such as presence of opioids, mitogens, long-term exposition to stress, expression of these receptors can be amplified. In this study we demonstrated, that concanavalin A causes up-regulation of μ-, δ- and κ-opioid receptors in lymphocytes isolated from rat spleen. In control cells no significant signal of μ- or δ-receptors was observed. In contrast, κ-opioid receptors were detected already in control cells. Concanavalin A stimulation caused a 2.4 - fold increase of these receptors. In lymphocytes treated with morphine only μ-opioid receptors were up-regulated, whereas in control cells, there was no signal for these receptor type. δ-opioid receptors were not detected in control or morphine treated cells. κ-opioid receptors were determined in control and also in morphine affected lymphocytes but the amount of these receptors wasn't changed by morphine. Detection of μ-, δ- and κ-opioid receptors using Western blot technique in lymphocytes isolated from rat spleen, that were...

High-Speed and Low-Power Techniques for Successive-Approximation-Register Analog-to-Digital Converters

Swindlehurst, Eric Lee

01 April 2020

Broadband wireless communication systems demand power-efficient analog-to-digital converters (ADCs) in the GHz and medium resolution regime. While high-speed architectures such as the flash and pipelined ADCs are capable of GHz operations, their high-power consumption reduces their attractiveness for mobile applications. On the other hand, the successive-approximation-register (SAR) ADC has an excellent power efficiency, but its slow speed has traditionally limited it to MHz applications. This dissertation puts forth several novel techniques to significantly increase the speed and power efficiency of the SAR architecture and demonstrates them in a low-power 10-GHz SAR ADC suitable for broadband wireless communications. The proposed 8-bit, 10-GHz, 8× time-interleaved SAR ADC utilizes a constant-matching DAC with symmetrically grouped unit finger capacitors to maximize speed by reducing the total DAC capacitance to 32 fF and minimizing the bottom plate parasitic capacitance. The capacitance reduction also saves power as both the DAC size and the driving logic size are reduced. An optimized asynchronous comparator loop and smaller driver logic push the single channel speed of the SAR ADC to 1.25 GHz, thus minimizing the total number of timeinterleaved channels to 8 to reach 10 GHz. A dual-path bootstrapped switch improves the spurious-free dynamic range (SFDR) of the sampling by creating an auxiliary path to drive the non-linear N-well capacitance apart from the main signal path. Using these techniques, the ADC achieves a measured signal-to-noise-and-distortion ratio (SNDR) and SFDR of 36.9 dB and 59 dB, respectively with a Nyquist input while consuming 21 mW of power. The ADC demonstrates a record-breaking figure-of-merit of 37 fJ/conv.-step, which is more than 2× better than the next best published design, among reported ADCs of similar speeds and resolutions.

SAR ADC

DAC

bootstrapped switch

time-interleaved

Engineering