Click on the images below to view animated sequences in the MPEG 1 Video Format

This sequence shows a constructed attractor (time series of the
light intensity as a function of time in an AC driven Neon Geissler
tube vs. the analog derivative of the time series), one cycle of the
time series, the % voltage vs acquisition number, and the FFT of the
time series. This sequence illustrates the hysteresis inherent in the
system (different behavior at the same voltages, the only difference
being if the voltage was being ramped up or down previously).

This sequence depicts the behavior of the system (An AC driven Neon
Geissler tube) during one orbit (one period of the system). The FFT of
the segment is depicted, along with the location of the segment on the
attractor, the time series, and the analog derivative of the time series.

Here we see a beautiful high-speed video
sequence of chaotic water drop behavior.
This sequence forms the basis of the NDL paper
"Experimental Issues in the Observation of Water Drop Dynamics"

This sequence compares an AC plasma rotating optics image
and a DC plasma rotating optics image. We also see the effect
of looking at cross-sections, effectively looking at intensity
as a function of lateral position in the plasma in time.

Here we see extracted frames from a series of high-speed video
sequences. We see the behavior of an R.F. Excited Argon Plasma,
first change in R.F. Power, then a change in antenna separation.

Here we see ground breaking high speed video
footage showing the "birth" of a striation.

Here we see high speed video footage of the electrode
region of an AC Neon discharge in a geissler tube.

Here we see how the high speed video frames are used to
extract intensity plots as a function of position and time.

Here we see the behavior of an AC Neon Geissler
discharge as a function of position along the discharge.

Here we see a logo rendered for a video presentation
at one of the conferences attended by NDL.

Here we see a standard 30 frame per second video sequence
showing moving striations in an R.F. excited Argon Plasma.

Here we see highspeed video of an R.F. excited Argon plasma
exhibiting very high speed transverse wave stratification.

Here we see a video strobe technique developed by NDL. By using
standard video (and varying the exposure time electronically) in
conjunction with an analog scope a unique view of a systems behavior
can be viewed in real-time.

This sequence shows the top, side, front, and isometric
views of the first sequence rendered by the AWOL team.

The two images below link to 3D files in the VRML format.

A VRML viewer is provided here if needed, click on the GLView3 now logo!

A VRML surface depicting rotating optics data from a Neon Plasma discharge.
The surface shows Position (X), Time (Y), and Light Intensity (Z).

This VRML file shows the first AH-64 Cockpit crash
sequence validation data generated by the AWOL team.

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Click on the images below to view animated sequences in the MPEG 1 Video Format

This sequence depicts the behavior of the system (An AC driven Neon Geissler tube) during one orbit (one period of the system). The FFT of the segment is depicted, along with the location of the segment on the attractor, the time series, and the analog derivative of the time series.

Here we see a beautiful high-speed video sequence of chaotic water drop behavior. This sequence forms the basis of the NDL paper "Experimental Issues in the Observation of Water Drop Dynamics"

This sequence compares an AC plasma rotating optics image and a DC plasma rotating optics image. We also see the effect of looking at cross-sections, effectively looking at intensity as a function of lateral position in the plasma in time.

Here we see extracted frames from a series of high-speed video sequences. We see the behavior of an R.F. Excited Argon Plasma, first change in R.F. Power, then a change in antenna separation.

Here we see ground breaking high speed video footage showing the "birth" of a striation.

Here we see high speed video footage of the electrode region of an AC Neon discharge in a geissler tube.

Here we see how the high speed video frames are used to extract intensity plots as a function of position and time.

Here we see the behavior of an AC Neon Geissler discharge as a function of position along the discharge.

Here we see a logo rendered for a video presentation at one of the conferences attended by NDL.

Here we see a standard 30 frame per second video sequence showing moving striations in an R.F. excited Argon Plasma.

Here we see highspeed video of an R.F. excited Argon plasma exhibiting very high speed transverse wave stratification.

Here we see a video strobe technique developed by NDL. By using standard video (and varying the exposure time electronically) in conjunction with an analog scope a unique view of a systems behavior can be viewed in real-time.

This sequence shows the top, side, front, and isometric views of the first sequence rendered by the AWOL team.

The two images below link to 3D files in the VRML format.

A VRML viewer is provided here if needed, click on the GLView3 now logo!

A VRML surface depicting rotating optics data from a Neon Plasma discharge. The surface shows Position (X), Time (Y), and Light Intensity (Z).

This VRML file shows the first AH-64 Cockpit crash sequence validation data generated by the AWOL team.

This sequence depicts the behavior of the system (An AC driven Neon
Geissler tube) during one orbit (one period of the system). The FFT of
the segment is depicted, along with the location of the segment on the
attractor, the time series, and the analog derivative of the time series.

Here we see a beautiful high-speed video
sequence of chaotic water drop behavior.
This sequence forms the basis of the NDL paper
"Experimental Issues in the Observation of Water Drop Dynamics"

This sequence compares an AC plasma rotating optics image
and a DC plasma rotating optics image. We also see the effect
of looking at cross-sections, effectively looking at intensity
as a function of lateral position in the plasma in time.

Here we see extracted frames from a series of high-speed video
sequences. We see the behavior of an R.F. Excited Argon Plasma,
first change in R.F. Power, then a change in antenna separation.

Here we see ground breaking high speed video
footage showing the "birth" of a striation.

Here we see high speed video footage of the electrode
region of an AC Neon discharge in a geissler tube.

Here we see how the high speed video frames are used to
extract intensity plots as a function of position and time.

Here we see the behavior of an AC Neon Geissler
discharge as a function of position along the discharge.

Here we see a logo rendered for a video presentation
at one of the conferences attended by NDL.

Here we see a standard 30 frame per second video sequence
showing moving striations in an R.F. excited Argon Plasma.

Here we see highspeed video of an R.F. excited Argon plasma
exhibiting very high speed transverse wave stratification.

Here we see a video strobe technique developed by NDL. By using
standard video (and varying the exposure time electronically) in
conjunction with an analog scope a unique view of a systems behavior
can be viewed in real-time.

This sequence shows the top, side, front, and isometric
views of the first sequence rendered by the AWOL team.

A VRML surface depicting rotating optics data from a Neon Plasma discharge.
The surface shows Position (X), Time (Y), and Light Intensity (Z).

This VRML file shows the first AH-64 Cockpit crash
sequence validation data generated by the AWOL team.