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Rainer Sandau
2 AIRBORNE DIGITAL SENSORS: REQUIREMENTS
To have any chance of an impact in a market place spoilt for decades by high performance film cameras, an airborne
digital sensor must provide: large field of view and swath width; high resolution and accuracy, both geometric and
radiometric; linear sensor characteristics; multispectral imagery; stereo. The first requirement, however, seems to rule
out area CCD arrays, because most readily available models in mid 1999 are 4kx4k pixels or less, whereas a linear array
of 12,000 pixels is readily
vailable, requiring onl : ( ii
pie diet ai flight CCD lines CCD matrices (surface
lines. Considerable .
research work done in
Germany since the 1970s
has demonstrated the
suitability of three
panchromatic lines on the
focal plane, with
additional ~~ multispectral
lines near the nadir
(Albertz et al, 1996;
Sandau and Birwald,
1994; Sandau and Eckardt,
1996). This obviates the
need for multiple area
arrays to provide a wide S
field of view and a Figure 1. The alternatives: linear and area CCD arrays
multispectral ^ capability
(figure 1). The left-hand diagram suggests how the focal plane could be populated using the three-line principle: three
panchromatic lines give the geometry and stereo, whilst additional lines, their sensitivity controlled by filters, give the
multispectral information. In the right hand diagram, multiple area array CCDs and lenses are required to provide the
same ground pixel size and multispectral range as the three-line approach. Indeed, the three-line approach makes
possible a panchromatic, colour and false colour sensor, consisting of a single optical system and focal plane.
3 lines panchromatic stereo i multiple RGB + infrared arrays
3 to n lines multispectral : bincreaseFOVZ. ==
3 THREE-LINE SENSOR APPROACH
The three-line concept results in views forward from the aircraft,
vertically down and looking backward (figure 2). The imagery from
each scan line provides information about the objects on the ground
from different viewing angles assembled into strips. With three lines
there are three possible pairings for stereoscopic analysis — strips 1 and
2, 2 and 3, and 1 and 3. The angles are given in table 1. The gaps
between the 3 CCD lines in the focal plane can be filled with further
CCD lines to be used for multispectral imaging.
4 OPTICS AND FILTERS | |
The innovative optics of the ADS40 are designed for high-resolution
photogrammetric and remote sensing applications. The lens is similar in
its external dimensions, weight, resolution and light efficiency to the
lens of LH-Systems' RC30 film camera. However, both optical designs
are completely different owing to the different recording modes. While nedirvien ew
the minimisation of distortion is of prime interest in the case of the film backward view
lens, the most demanding requirement for the digital lens is
telecentricity at the image side. This specification is in general useful
for any digital camera, but absolutely critical for the ADS40 owing to
the requirement for the request for multispectral, narrow band recording.
Figure 2. Basic geometric characteristics of
three-line digital sensor
International Archives of Photogrammetry and Remote Sensing. Vol. XXXIII, Part Bl. Amsterdam 2000. 259
