CIPA 2003 XIX th International Symposium, 30 September - 04 October, 2003, Antalya, Turkey
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responsible for controlling the narrative accuracy of TLS,
while point accuracy has the greatest impact on geometric
accuracy (although intuitively both point density and point
accuracy will effect each type of accuracy).
In previous photogrammetric/topographic specifications the
required accuracy of a measurement has been determined by
scaling the width of the standard output line width to
calculate the required “real-world” accuracy. For example
for survey output at a scale of 1:20 and a standard line width
of 0.18 mm, an accuracy of 3.6 mm would be required.
Originally this was applied when hard copy output was
required. However, with most deliverables from survey
projects likely to be digital this assumption is less
appropriate as data could be plotted at potentially any scale.
The use of scale however still provides some control as to the
use of the data, providing the user with information relating
to the accuracy of the information. Scale was also useful in
suggesting the practical dimensions of objects for any
particular scale - based on the size of a standard A1 sheet.
Figure 2 A background scan, top, and a detail scan,
below, of the area marked with a rectangle.
The previous metric survey specification however defines a
different level of accuracy when using different techniques,
despite requesting survey at the same scales. In order to
maintain continuity with previous measurement practises it
was decided to adopt the same required level of geometric
accuracy as that required for building survey. By applying
this level of precision to scan data the use of the majority of
laser scanners operating over 2 m is unsuited to survey at
1:10 scale, however survey at 1:20, 1:50 and 1:100 scale are
all possible. The choice of an appropriate point density is a
subjective decision and although it is acknowledged that as
high a point density as possible may be desirable this must be
balanced with storage requirements.
It was also important that the specification acknowledged the
practical constraints on the data that can be captured. For
example it is difficult to scan every portion of a complex
structure, especially when scanning from ground level where
it is not possible to record elevated window ledges or
doorways in full. Where such areas are required it should be
noted in the project brief and it may be necessary to amend
the data collection process or investigate other methodologies
all together.
Scanning in heavy rain is deemed unsuitable, mainly due to
concerns of having water droplets on the scanning window
which may cause diffraction of the measurement beam,
resulting in erroneous measurements.
The likely need for two levels of recording is also
emphasised. Background scans are appropriate for the
spatial location and orientation of areas of detail which are
scanned at a higher resolution, Figure 2 gives an example of
using detail and background scanning using a Cyrax 2500.
The process of registration differs between each TLS on the
market. Some systems opt for the conventional survey
approach of using a known reference object and known
instrument position while other systems use a resection
solution as performed in photogrammetry. It is necessary to
specify for both methods of registration as each has a valid
pedigree. For resection calculations the residuals of the
estimated parameters are required to meet the accuracy of
individual scan point measurements. Where registration is
performed using a known scanner location and a known RO
the precision of the scanner coordinates must be shown to
equal the standard requirement of 4 mm for an XYZ control
point as defined in the current metric survey specification for
English Heritage. Cloud matching routines are deemed
suitable, providing additional targets are used to confirm the
accuracy of the procedure meets the specification.
A particular feature of TLS, especially for cultural heritage
survey, is the amount of additional information captured
during the survey process. This includes imagery, sketches
and notes. Copies of any data captured on site to aid the
survey process are required on delivery to ensure any
subsequent processing has all the available information.
Where specific additional information is required it will be
noted in the project brief. Imagery showing the scanned area
is required for all surveys and to ensure any imagery is useful
for interpretation this must have a resolution of at least 1500
x 1000 pixels.
As most sites in the UK under the care of English Heritage
are open to the public, the safety of visitors is vital. Lasers
have a justifiable reputation for being dangerous. A set
standard is required to define the necessary precautions that
should be taken. The specification adopts the classification
and requirements of IEC 60825 (IEC, 2001). All laser
classifications should be quoted to this standard. It is noted
that at least three different specifications for laser
classification exist; the European IEC standard; BS
60825:1994 and the American ANSI standard (ANSI, 2000).
Classification between these specifications is not consistent
