PERSISTENT SURVEILLANCE FOR

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PERSISTENT SURVEILLANCE FOR

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Optical characterization requires immersion in index-matching fluid. ... Contact images on high resolution film. High precision film digitizer ... – PowerPoint PPT presentation

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Title: PERSISTENT SURVEILLANCE FOR

1
Radiographic Dimension Measurement of Dry DVB
Foam Shells
PERSISTENT SURVEILLANCE FOR PIPELINE PROTECTION
AND THREAT INTERDICTION
Haibo Huang Rich Stephens Brian Vermillion Dan
Goodin Bernie Kozioziemski (LLNL)
HAPL Meeting, Livermore, California June 20-21,
2005
IFT/P2005-072
2
Summary

IFE program uses 4.1 mm O.D. foam shells
Require dimension variations measured to lt1 mm
Optical characterization requires immersion in
index-matching fluid.
X-Radiograph system already developed tested
Contact images on high resolution film
High precision film digitizer
Analysis algorithm to handle extreme noise
For the first time, large dry DVB foam shells can
be measured

3
IFE Point Design for DVB Foam Shells
Average Foam Wall 289 20 mm
Non-concentricity (NC) lt 1
NC (OD/ID Center Offset)/WallAverage
equivalent to WallMax-WallMin lt 6 mm
CH Wall (1-5) 1 mm Out-Of-Round
(OOR) lt 1
OOR(ODmax-ODmin)/RadiusAverage
equivalent to Rmax-Rmin 10 mm
4100 200 mm

Sufficient to measure interface radii vs angle to
1 mm

4
Foam is difficult to characterize
interior
wall

Visible light measurements require index matching
fluid
Time-consuming
Potential dimension errors
OD changes by 1-5
Thicker CH, larger OD change
X-radiographs are noisy due to large density
fluctuations
Obscures interfaces

100 mm
Area Average
Single line
Transmission (a.u.)
Radius (um)
5
X-radiography works when digitized properly

12bit, 4 MB, Cooled CCD
Measure whole shell to 0.8 mm
Plan APO Microscope lens
Flat field gt CCD compatible
Large N.A. gt high resolution
Type K1a film
Finest grain
Glass substrate gt stable
Software
Noise reduction and rejection
Edge analysis

6
Accurate interface profiling require lens
correction

Must correct lens distortion
Calibrate with stage micrometer
Verify with circular standards
Each lens calibrated separately

3µm pixel error
Does radius and shape change with position?
7
Foam structure causes unique analysis problems

Traditional vision-based analysis does not work
with low contrast, noisy image
Reduce noise by azimuthal averaging
Reject noise by data correlation
Limit search range
Interface very wavy with thin overcoat
Flattening (Step 3)
Extended interface structure
Fresnel simulation determines offset

8
Capturing edge information
1) Inspect thickness variation by 360 unwrapping
Angle
Radius
2) Sharpen interface with 2nd derivative
D. Bernat, R.B. Stephens, Fusion Technology, V31,
P473, 1997
Angle
Radius
9
Mapping interface requires careful consideration
3) Sharp outside edge good for auto alignment
Separates wavy interfaces gt narrows search range
4) Reject noise by correlating peak/valley
locations
Reduces the image to a set of R(q) files
Angle
Radius
10
Calculating interfaces and walls
5) Unflatten and record data
4X lens radius measurement repeatability lt0.4 mm
11
Correcting Walls
6) Apply offset correction (under development)

Measured profile has width
Relation fixed between profile and interface
Specific to shell type and lens
Described by markers (peak/valley) and offsets
Offset understood by modeling
Affected by phase contrast, pixel size, X-ray
spectrum etc.

12
Porosity may affect interface sharpness

Phase contrast shows as white ring at the sharp
interfaces of dissimilar materials
Strong at CH/RF foam, CH/Be interfaces
but not for CH/DVB Diffused due to pore size?

50 mm
50 mm
0.1 mm pore
1 mm pore
CH on DVB foam
CH on RF Foam
13
Estimated X-Radiography Capabilities
After applying offsets determined by Fresnel
calculation
14
Special concerns for DVB foam shells