AN EVALUATION OF THREE DIFFERENT IMAGE CAPTURE METHODS FOR MEASUREMENT AND ANALYSIS 
OF DEFORMATION WITHIN A GEOTECHNICAL CENTRIFUGE 
J. Chen, S. Robson, M.A.R. Cooper, & R.N.Taylor* 
Engineering Surveying Research Centre 
*Geotechnical Engineering Research Centre 
Department of Civil Engineering, City University, 
London. EC1V OHB, UK 
Email:J.Chen Gcity.ac.uk 
ISPRS Commission V, Working Group V/III 
KEY WORDS: Acquisition, Analysis, On line, Video, JPEG 
ABSTRACT 
In a geotechnical centrifuge experiment, long image sequences are often captured to obtain information about how soil responds to 
load. Information obtainable from the on-line dynamic deformation analysis of such sequential images can be important in order to 
visualise and monitor progress and ultimately to control the course of the experiment. In this paper, the geometric qualities of three 
methods which can be used for the analysis and storage of long image sequences are evaluated: (1) use of an S-VHS video recorder; 
(2) use of J-PEG image compression; and (3) the on-line measurement of target image co-ordinates by an analysis procedure based 
on the sequential update of prior knowledge. The precision and accuracy obtained with respect to the S-VHS video recorder and 
different J-PEG compression factors are discussed. A suitable algorithm for on-line dynamic target location and deformation analysis 
of the sequential images produced during centrifuge tests has been derived and successfully applied in practical experiments. 
1. INTRODUCTION 
Settlement can be a problem during soft ground tunnelling in 
urban areas where buildings can be put at risk. Settlement and 
ground movement can be simulated in the laboratory using a 
geotechnical centrifuge (Taylor, 1995). The high forces 
generated by the centrifuge allow not only the soil model to be 
scaled down but also for a corresponding reduction in the time 
for deformation to take place. The soil sample is placed in a box 
with a perspex face. Targets are placed in the visible face of the 
soil and their locations imaged and measured. Target 
movements are traced in image space to obtain deformation 
information and after appropriate transformations mathematical 
models can be used to analyse the geotechnical performance of 
the soil. Typical experimental duration's range from a few hours 
to a couple of days. An analysis of sequential images of the soil 
model under loading within the centrifuge can provide useful 
information about the response of the soil. If measurements of 
the imaged targets can be obtained quickly enough the 
information derived can then be used to optimise the 
experiment. Initial research into the sequential tracking of 400 
to 700 small circular targets in centrifuge experiments has been 
reported (Clarke at al, 1995). 
There are several important requirements for the successful 
  
Figure 1 Discrepancy vectors from two consecutive S-VHS 
images 
70 
capture and analysis of sequential images in a centrifuge 
experiment: rapid image grabbing; large data storage capacity 
and most importantly; images must be of sufficient quality for 
measurement and quantitative deformation analysis. This paper 
describes comparative experiments to assess the geometric 
performance of a weighted centroid target location algorithm 
between direct frame grabbing, S-VHS video recording, and J- 
PEG compression. A methodology for the on-line tracking of 
target images leading to dynamic deformation analysis without 
the need to store each image is also discussed. 
2. THE CAPTURE OF IMAGE SEQUENCES WITH A S- 
VHS RECORDER 
A S-VHS recorder has been used to archive image sequences 
during centrifuge tests, a frame grabber can then be used off- 
line to capture individual images of interest. The use of a S- 
VHS recorder to store images on tape has the advantage of 
providing large storage capacity and the ability to capture 
sequential images at camera frame rate. The accuracy of target 
location from taped images has been evaluated by Hoflinger and 
Beyer, 1993, and by Shortis et al, 1993. Under ideal conditions, 
target location accuracy can be better than one of tenth of a 
pixel. However in our case, in which black targets are inserted 
into grey sand and clay soils, target location errors are typically 
much larger. In this application, each imaged target is small, 
  
Figure 2 Discrepancy vectors from two consecutive directly 
grabbed images 
International Archives of Photogrammetry and Remote Sensing. Vol. XXXI, Part B5. Vienna 1996 
typically oc 
is also lov 
backgrounc 
differences 
grabbing ir 
discrepancy 
consecutive 
subsequent 
Figure 2 sh 
consecutive 
camera witl 
were stable 
magnitude 
caused by t 
geometric 
recorder is 
grabbing. 
To rigorous 
VHS syste 
different ty 
Both retro- 
sizes were 
board bein; 
for the retr 
an optical I 
bench and 
camera. A 
record the s 
grabbing. A 
using the S 
different tar 
cases, a cer 
been used 
illustrated i 
° 
8 
1 
RMS location errors (pixels) 
o 
a 
S 
si 
~ 
o 
8 
& 
  
sad 
40 60 80 
Targe 
Figure 3 RMS 
targets using 
Figures 3 ar 
different ta 
targets capt 
small (imag 
pixels in : 
procedure v 
RMS target 
The results 
used, but t 
indications. 
retro-reflect 
a very sma 
than 1/20th 
good contra 
order of 1/2 
or contrast |