Increasing of the accuracy of vertical angle measurements of geodetic instrumentation/Geodeziniu prietaisu vertikaliu kampu matavimo tikslumo didinimas.
Brucas, D. ; Siaudinyte, L. ; Rybokas, M. 等
1. Introduction
Many of modern measurement instruments used in geodesy, surveying,
construction and machine engineering rely on precise measurements of
angular values. Instruments such as theodolites, tacheometers, total
stations, laser scanners, laser trackers measure both horizontal and
vertical angle values. Same as all other measurement instrumentation
these devices can produce sometimes quite significant errors of
measurements (both random and systematic), which might affect the
outcome results of measurements [1-3].
Precise testing and calibration of these instruments might both
determine the random errors, thus stating the uncertainty values for
each particular instrument and systematic errors (biases) which allow
increasing of measurement accuracy by numerical removal of known
systematic error values from the measurement results. At the moment
there exist several standards for testing of such instrumentation by
trigonometric methods implementing several static point of collimation
[2]. Such method of testing nonetheless might allow analysis of only few
measured angular values of instrument, with only several systematic and
random errors values determined (though there can be a huge number of
values generated by instrument encoder). Obviously such testing cannot
provide unambiguous information on instrument accuracy (especially
systematic errors values) [4-6].
Precise testing and especially calibration of angle measuring
equipment require some quite special and high accuracy equipment which
is hardly available for industrial use. Such horizontal and vertical
angle calibration instrumentation is usually possessed and operated by
large instrumentation producing companies or large users and not
available for wider public. Additionally representatives a average users
of instrumentation are hardly interested in additional investments to
increase the accuracy of their instruments [7].
If calibration of horizontal angle measures can be realized
implementing different types of horizontal precise rotary tables (of
different accuracy) available in industry, calibration of vertical angle
measurements is a serious problem since very special instrumentation is
needed for this task. That instrumentation is often highly specialized,
expensive bulky and require high qualification to operate, therefore it
is not widely spread in the world [8-10].
Nonetheless since it is obvious that measurement accuracy
increasing can be ensured by precise calibration, testing on
implementing vertical calibration of geodetic instrumentation are
performed at Institute of Geodesy, Vilnius Gediminas Technical
University.
2. The set up
The calibrated instrument is precisely leveled and placed at
certain height the telescope of the instrument in 90[degrees] position
would be pointed to the center line of the leveled reference scale. The
vertical angle measured between two lines of the reference scale is
compared with reference angle expressed:
[phi] = arctg [h/l], (1)
where h is vertical distance between the measured lines known from
the calibrated reference scale; l is horizontal distance between the
calibrated instrument and the reference scale. The principle of this
method for calibration of vertical angle measuring systems has been in
details described in papers previously presented by authors [11] and
shown in Fig. 1.
In this method vertical position of the reference scale is very
important because it might be one of the biggest sources of uncertainty
due to vertical distance determination. Thermal expansion and
compression effect also have to be evaluated. Horizontal distance
measurements can be performed by using the function of reflectorless
distance measurements of total station. However, many total stations do
not have such function and another way of measuring horizontal distance
has to be applied. The attention should be paid to uncertainty due to
pointing. Uncertainty due to pointing can influence measurement results
because the widths of the cross-line of the telescope and the line of
the reference scale differ depending on the distance between the
calibrated instrument and the reference scale. Pointing to the center of
the line of the reference scale influences repeatability of the angle
measurement results. Another uncertainty in this method is due to the
repeatability of distance measurements of total station as well as
uncertainty due to limited display resolution of the device. Both of
them should be taken into an account be cause the horizontal distance is
one of two main parameters for the determination of the reference angle.
The accuracy of the reference angle determination depends on the
parameters of instrumentation used in this method. The horizontal
distance between the total station and the reference scale should fit
instrument's focusing range which usually is not less than 1.5 m.
The closer the reference scale is to the calibrated instrument the
bigger range can be calibrated. However, because of the focusing range
of total stations the calibration range of this method is 90[degrees][+
or -] 17[degrees]. The advantage of this method is that depending on the
reference scale grating and the horizontal distance between the scale
and calibrated instrument many angle values can be measured avoiding
relatively big measurement pitches performed by other methods (pitches
of 10[degrees] or 30[degrees]).
[FIGURE 1 OMITTED]
3. Results of the measurements
The vertical angle of three tacheometers (NIKON DTM352, Trimble
5605, Topcon DT9) were calibrated for testing purposes. The results of
tests are shown in Figs. 27. Figs. 2, 4 and 6 show the unprocessed
results obtained by the calibration, thus Figs. 3, 5 and 7 show the
partially processed data with typical curve determined and removed
(biases removed).
In Fig. 2 the results of vertical angle calibration of tacheometer
NIKON DTM352 (with stated 5" st. dev. of measurements) with the
horizontal distance of 3.3052 m are given. According to calculations the
standard deviation of measurements was 4.18", which fits into
boundaries of stated accuracy [12]. Nonetheless according to the results
some systematic errors of measurements can be still visible. These
systematic errors are represented by the Typical curve (Fig. 2), which
is a standard 2nd degree polynomial curve.
After removing of systematic errors (biases) from the measurement
results obtained data are given in Fig. 3. The standard deviation of
measurements after the removal of systematic errors is in range of
3.10", which gives the possibility of increasing of accuracy by
approx. 1" of vertical measurements implementing calibration data.
Similarly the results of calibration of tacheometer Trimble 5605
(with stated 5" st. dev. of measurements) at horizontal distance of
3.2865 m are given in Fig. 4. The standard deviation of measurements in
this case was 2.51", which is far better than the stated standard
deviation (5"). After removing of systematic errors (2nd degree
polynomial typical curve), the standard deviation reached 2.12",
therefore in this case it is possible to increase the accuracy of
measurements by 0. 4".
The results of calibration of vertical angle measurements of
tacheometer Topcon DT9 (with stated 9" st. dev. of measurements) at
horizontal distance 3.3128 m are given in Fig. 6. Here the determined
standard deviation of measurements was 10.18", which is exceeds the
stated accuracy by more than 1".
[FIGURE 2 OMITTED]
[FIGURE 3 OMITTED]
[FIGURE 4 OMITTED]
[FIGURE 5 OMITTED]
[FIGURE 6 OMITTED]
After removing of obvious systematic errors from the data (Fig. 6,
3rd degree polynomial typical curve), it was possible to achieve
remarkable increase of accuracy of measurements (Fig. 7), the standard
deviation of measure-merits this time dropped down to 4.22".
Therefore considering the systematic errors of measurements determined
and removing them could allow providing the measurements of same
accuracy (5") implementing tacheometers of lower accuracy.
[FIGURE 7 OMITTED]
As can be seen from graphs, most of the calibrated instruments
fulfill the standard deviation requirements. Nonetheless implementing
the vertical angle calibration data it is possible to achieve the
increase of accuracy from 0.4" to almost 6". Such drastic
increase of accuracy could allow implementing the instrumentation in
completely new areas of measurement.
4. Conclusions
1. A method of vertical angle calibration of geodetic angle
measuring equipment was tested on several geodetic instruments
(tacheometers).
2. Determined measurement deviations allowed determining the biases
of measurements present at all of the tested instruments.
3. Removing of the systematic errors (biases) from the measurement
results allowed increasing the accuracy (st, deviation) of measurements
from 0.4" to up to 6".
4. Considerable increase of accuracy of measurements of one of the
instruments could allow its implementation in areas requiring equipment
of higher level.
http://dx.doi.org/ 10.5755/j01.mech.20A7884
Received May 17, 2013
Accepted June 18, 2014
Acknowledgments
This research is funded by the European Social Fund under the
project No. VP1-3.1-SMM-07-K-01-102.
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D. Brucas *, L. Siaudinyte **, M. Rybokas ***, G. Kulvietis ****,
D. Sabaitis *****
* Vilnius Gediminas Technical University, Sauletekio al. 11,
LT-10223 Vilnius, Lithuania, E-mail: domka@ktv.lt
** Vilnius Gediminas Technical University, Sauletekio al. 11,
LT-10223 Vilnius, Lithuania,
E-mail: lauryna.siaudinyte@vgtu.lt
*** Vilnius Gediminas Technical University, Sauletekio al. 11,
LT-10223 Vilnius, Lithuania,
E-mail: mindaugas.rybokas@vgtu.lt
**** Vilnius Gediminas Technical University, Sauletekio al. 11,
LT-10223 Vilnius, Lithuania, E-mail: gk@vgtu.lt ***** Vilnius Gediminas
Technical University, Sauletekio al. 11, LT-10223 Vilnius, Lithuania,
E-mail: deividas@vilma.lt
