International Archives of the Photogrammetry, Remote Sensing and Spatial Information Sciences, Vol XXXV, Part B5. Istanbul 2004
intersection is carried out at the same epoch À . As a
consequence, instead of using the C4, to build up
C, - the variance-covariance matrix output of KF is
used. This analysis will be looked at in the next
section.
4. INTEGRATING PHOTOGRAMMETRY
AND INS IN A KALMAN FILTER
The previously described initialisation remains the
same. The items that differ are: the employment of
the lever-arm and angles transformation, and the
Kalman Filter.
Before talking about these items, we consider the
flowchart of Figure 4. The algorithm can be depicted
as follows:
Known initial
position
Initialisation
Capture photos
in image (x, y) and compute
their X, Y, Z by intersection
;
:
Measure features’ coordinates 1
:
'
Move ^s" seconds
and capture photos
|
Measure features” coordinates in image
(x, y) of known X, Y, Z. Compute Xq.
Yo. Zo. 0. ©, K of the two images by
resection
Apply lever arm and
boresight corrections
Prediction, = 100 Hz t
[RR IMU output
Update. | Hz
Kalman Filter
Output position and
attitude
Lr Apply lever arm and
peer boresight corrections
Perform intersection to
map (mare) features
Figure 4: Flowchart of the Photogrammetric and INS
integration
Initialisation:
l. Position and attitude of the two cameras
considered as known
2. Intersection is employed to map objects
After mapping enough objects:
1. Vehicle moves
2. Resection computes the cameras’ EOP
using the features mapped from the
previous location
o
Lever-arm and angles transformation (and
boresight) are applied to the EOPs to
determine the IMU's position and attitude
4. IMU and resection outputs are integrated in
Kalman Filter to compute filtered position
and attitude of the current location
Lever-arm and angles transformation (and
boresight) are applied to the filtered
position and attitude to determine the EOP
of the cameras
6. Intersection is used to map more objects
from the current location
7. Vehicle moves and algorithm repeats
Un
"The lever-arm and angles transformation are different
in steps 3 and 5. In the following, only the angles
transformation is discussed; the lever-arm is dealt
with similarly.
4.1 Angles Transformation
The angles transformation applied in Step 5 is used to
transform the output of the KF to the camera's
reference frame to perform the mapping. This is well
documented in the relevant literature (Skaloud and
Schaer, 2003). The complete transformation is:
"n
Ra = RS Rg) RS, (15)
where Rz, = transformation matrix between
mapping and camera frames
Rf = transformation matrix between IMU
and camera frames (depends on the
definition of the axes)
Rj = transformation matrix between IMU
and carth-fixed frames, i.e., KF output
R$, = transformation matrix between
Earth-fixed and mapping frames
The boresight correction applied in Step 3, is exactly
the inverse of Equation (15). In the step, the user is
going from R$, to Rj, and this takes place as
follows:
1°, XL Ar
R£-RS [Ri] n$ (16)
In this stage, we showed the relations among the
coordinate systems for the transfer of position and
attitude. In the second section, the KF is described.
4.2 Data Integration Via Kalman Filter
The navigation KF can link either the INS
measurements (orientation rates and accelerations) or
the integrated values (coordinates, velocity,
orientation) with external measurements.
In open spaces, GPS measurements play the role of
external measurements. In areas with limited GPS
