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341
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Discrim. Factor
0 2 4 6 8 10 12 14 16 18 20 22 24
Time in Hours
Phase quality (single difference) Code quality (single difference)
ame ms= 05m
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Figure 2. Theoretical instantaneous discrimination for dual frequency measurements
Ionospheric sensitivity of the ambiguity search: In the theoretical investigation presented above, systematic errors
have been neglected. In practice, however, they are often the limiting factor. The high discrimination potential of the
ambiguity search in the dual frequency mode precisely lies in the fact that unbiased L1- and L2 phase measurements are
available. The systematic errors introduced by the ionosphere, however, are frequency dependent and therefore leads to
lack of discrimination. Fortunately for many applications over short distances the biases introduced by the ionosphere
are small enough to be entirely neglected for the ambiguity search. This maximal distance is strongly depending on the
overall ionospheric activity and on the latitude and may typically range between 3 and 15 km. In the case where the
ionospheric bias can not be neglected, a stochastic modeling may be applied [Bock et al. 1984, Beutler et al. 1989, Co-
card 1994]. This leads to a better, i.e. bias-free estimation, but weakens the discrimination of the ambiguity search and
thus longer integration times become necessary in order to securely retrieve the correct integer values of the ambigui-
ties.
6. INFLUENCE OF NOT SOLVED AMBIGUITIES ON THE COORDINATE DETERMINATION
If it is not possible to securely fix the ambiguities to integer, because the GPS-data is too poor (for example. in the case
of single frequency data over short time spans, or distances of some hundreds of kilometers between reference station
and rover), it is still possible to compute the coordinates by using the best real valued estimate of the ambiguities. Con-
sequently the GPS-coordinates are affected by these wrong ambiguity values. In a first approximation the introduced
error shows a linear behavior (offset and linear drift) over time. Such ‘floating point’ solutions have often been and are
still used in the aerophotogrammetry, i.e., where the linear behavior of the GPS-solution is then modeled by additional
drift parameters in a combined GPS/bundle block adjustment. In this case, however, additional perpendicular strips at
the end of the blocks become necessary in order to stabilize the geometry.
7. ON-LINE VERSUS OFF-LINE MODE
The major problem in realizing an on-line solution is the data link between the reference station and the moving re-
ceiver. In the case where only a differential code solution at the meter level is sought after, only range correction values
have to be transmitted with an update rate of 5-10 sec. In many countries such services have been already or will be
installed commercially in the near future. In the case of Switzerland a DGPS-service is going to be installed in 1995. Its
aim is a country-wide coverage. Range correction values are broadcast at a baud rate of about 50 bits/sec. The user has
to be equipped by a special receiver with integrated decoder connected to the GPS-receiver and providing for the range
correction values.
IAPRS, Vol. 30, Part 5W1, ISPRS Intercommission Workshop "From Pixels to Sequences", Zurich, March 22-24 1995
