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High ratio wavelet video compression through real-time rate-distortion estimation.Jackson, Edmund Stephen. January 2003 (has links)
The success of the wavelet transform in the compression of still images has prompted an
expanding effort to exercise this transform in the compression of video. Most existing video
compression methods incorporate techniques from still image compression, such techniques
being abundant, well defined and successful. This dissertation commences with a thorough
review and comparison of wavelet still image compression techniques. Thereafter an
examination of wavelet video compression techniques is presented. Currently, the most
effective video compression system is the DCT based framework, thus a comparison between
these and the wavelet techniques is also given.
Based on this review, this dissertation then presents a new, low-complexity, wavelet video
compression scheme. Noting from a complexity study that the generation of temporally
decorrelated, residual frames represents a significant computational burden, this scheme uses
the simplest such technique; difference frames. In the case of local motion, these difference
frames exhibit strong spatial clustering of significant coefficients. A simple spatial syntax is
created by splitting the difference frame into tiles. Advantage of the spatial clustering may then
be taken by adaptive bit allocation between the tiles. This is the central idea of the method.
In order to minimize the total distortion of the frame, the scheme uses the new p-domain rate-distortion
estimation scheme with global numerical optimization to predict the optimal
distribution of bits between tiles. Thereafter each tile is independently wavelet transformed and
compressed using the SPIHT technique.
Throughout the design process computational efficiency was the design imperative, thus leading
to a real-time, software only, video compression scheme. The scheme is finally compared to
both the current video compression standards and the leading wavelet schemes from the
literature in terms of computational complexity visual quality. It is found that for local motion
scenes the proposed algorithm executes approximately an order of magnitude faster than these
methods, and presents output of similar quality. This algorithm is found to be suitable for
implementation in mobile and embedded devices due to its moderate memory and
computational requirements. / Thesis (M.Sc.Eng.)-University of Natal, Durban, 2003.
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A proportional timing generator for measuring intermodulation product distortion on television transposers.Bouwer, Paul Frederick. January 1989 (has links)
Broadcasting authorities presently measure intermodulation distortion by
applying a three tone simulation of a composite video and sound signal to the
transposer and then measuring the relative amplitude of the major in-band
intermodulation product (nominally at vision carrier frequency plus 1,57 MHz in
the 625 line I/PAL System) on a spectrum analyser. This method is slow and
requires a skilful operator to achieve repeatable results. Furthermore it tests the
common RF amplification equipment at one luminance level and one
chrominance level and therefore does not subject the transposer equipment to
operation over its full range.
A new sampling measurement technique has been proposed which overcomes
all these problems by selectively mixing, while transmitting a colour bar test
pattern, the demodulated output video signal of the frequency transposer with
a pulse train coinciding with a particular colour. This thesis describes the
design of a very stable proportional timing generator and its application to the
measurement of intermodulation distortion on frequency transposers.
The timing generator, which locks automatically onto the video signal and
produces narrow sampling pulses which coincide accurately with a particular
section of each line over a 50°C temperature range, is applicable to all PAL and
NTSC TV Systems. / Thesis (Ph.D.)-University of Natal, Durban, 1989.
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