4,327 research outputs found
Biorthogonal partners and applications
Two digital filters H(z) and F(z) are said to be biorthogonal partners of each other if their cascade H(z)F(z) satisfies the Nyquist or zero-crossing property. Biorthogonal partners arise in many different contexts such as filterbank theory, exact and least squares digital interpolation, and multiresolution theory. They also play a central role in the theory of equalization, especially, fractionally spaced equalizers in digital communications. We first develop several theoretical properties of biorthogonal partners. We also develop conditions for the existence of biorthogonal partners and FIR biorthogonal pairs and establish the connections to the Riesz basis property. We then explain how these results play a role in many of the above-mentioned applications
Multifrequency Aperture-Synthesizing Microwave Radiometer System (MFASMR). Volume 1
Background material and a systems analysis of a multifrequency aperture - synthesizing microwave radiometer system is presented. It was found that the system does not exhibit high performance because much of the available thermal power is not used in the construction of the image and because the image that can be formed has a resolution of only ten lines. An analysis of image reconstruction is given. The system is compared with conventional aperture synthesis systems
Digital encoding of black and white facsimile signals
As the costs of digital signal processing and memory hardware are
decreasing each year compared to those of transmission, it is
increasingly economical to apply sophisticated source encoding
techniques to reduce the transmission time for facsimile documents.
With this intent, information lossy encoding schemes have been
investigated in which the encoder is divided into two stages.
Firstly, preprocessing, which removes redundant information from
the original documents, and secondly, actual encoding of the preprocessed
documents. [Continues.
Centralized and distributed semi-parametric compression of piecewise smooth functions
This thesis introduces novel wavelet-based semi-parametric centralized and distributed
compression methods for a class of piecewise smooth functions. Our proposed compression schemes are based on a non-conventional transform coding structure with simple
independent encoders and a complex joint decoder.
Current centralized state-of-the-art compression schemes are based on the conventional structure where an encoder is relatively complex and nonlinear. In addition, the
setting usually allows the encoder to observe the entire source. Recently, there has been
an increasing need for compression schemes where the encoder is lower in complexity
and, instead, the decoder has to handle more computationally intensive tasks. Furthermore, the setup may involve multiple encoders, where each one can only partially
observe the source. Such scenario is often referred to as distributed source coding.
In the first part, we focus on the dual situation of the centralized compression where
the encoder is linear and the decoder is nonlinear. Our analysis is centered around a
class of 1-D piecewise smooth functions. We show that, by incorporating parametric
estimation into the decoding procedure, it is possible to achieve the same distortion-
rate performance as that of a conventional wavelet-based compression scheme. We also
present a new constructive approach to parametric estimation based on the sampling
results of signals with finite rate of innovation.
The second part of the thesis focuses on the distributed compression scenario, where
each independent encoder partially observes the 1-D piecewise smooth function. We
propose a new wavelet-based distributed compression scheme that uses parametric estimation to perform joint decoding. Our distortion-rate analysis shows that it is possible
for the proposed scheme to achieve that same compression performance as that of a
joint encoding scheme.
Lastly, we apply the proposed theoretical framework in the context of distributed
image and video compression. We start by considering a simplified model of the video
signal and show that we can achieve distortion-rate performance close to that of a joint
encoding scheme. We then present practical compression schemes for real world signals.
Our simulations confirm the improvement in performance over classical schemes, both
in terms of the PSNR and the visual quality
Interactive Extraction of High-Frequency Aesthetically-Coherent Colormaps
Color transfer functions (i.e. colormaps) exhibiting a high frequency luminosity component have proven to be useful in the visualization of data where feature detection or iso-contours recognition is essential. Having these colormaps also display a wide range of color and an aesthetically pleasing composition holds the potential to further aid image understanding and analysis. However producing such colormaps in an efficient manner with current colormap creation tools is difficult. We hereby demonstrate an interactive technique for extracting colormaps from artwork and pictures. We show how the rich and careful color design and dynamic luminance range of an existing image can be gracefully captured in a colormap and be utilized effectively in the exploration of complex datasets
Image data compression using DCT (Discrete Cosine Transform) and interpolation And allied topics in digital image processing applied to satellite imaging.
Digital image processing plays an important role in modern scientific endeavors. It has specific uses in satellite imaging, remote sensing, telemetry and medical imaging. Image processing requires huge memory space to store the data, and to process the data in real time high speed computers are required
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