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synthesized versions of it. The authors utilize a SSIM based
measure to adjust the reconstruction settings. This is close
to the proposed approach in this paper. The main difference
is that we do not need to process the available key frames
but instead work only on synthetic views.
III. AUTOMATIC PARAMETRIZATION
The aim of automatic parametrization is to determine
optimal values for different reconstruction parameter-types.
In this case optimality means that the parameter value is near
or equal the value a human operator would have chosen for
the given data. Figure 1 depicts examples for the influences
of different parameter-types.
(a) ColourCorrection
value 0. (b) ColourCorrection
value 7. (c) Difference image.
(d) PoseEstimation
value 0. (e) PoseEstimation
value 7. (f) Difference image.
(g) SmoothnessTerm
value 0. (h) SmoothnessTerm
value 4. (i) Difference image.
(j) MaxIterations value
0. (k) MaxIterations
value 7. (l) Difference image.
Fig. 1. Reconstruction effects of different parameter-types shown on
Model 0001 in Subfigures (a) to (c), Model 0019 in Subfigures (d) to (f),
Model 0010 in Subfigures (g) to (i), and Model 0033 in Subfigures (j) to
(l). The images in the last column highlight the differences. The parameter
values are set to the extremes, to better demonstrate the effects.
Thefollowingprocedure illustrateshowanon-professional
human operator could select a good parameter setting:
1) The operator sets or alters a parameter value. 2) The operator lets the reconstruction run.
3) The operator inspects the result from different views
if it is better or worse than before.
4) The operator repeats the steps until some level of
reconstruction quality is reached.
Based on this we propose an approach using pair-
wise view comparison of different reconstructions. For a
parameter-typeα the accumulator matrixMα is a symmetric
matrix defined as
Mα(k,l) := n
∑
i:=0 SIM(Vi(Rα,k),Vi(Rα,l)) (4)
where k,l are elements of the ordered parameter value set
Pα andRα,k is the reconstruction. Elements inPα are chosen
such there is an increasing influence of the parameter to the
observed visual effect. n is the number of equally spaced
views aroundRα,k, whereas each viewVi is a 2D projection
of the 3D object. For comparison of two images as similarity
SIM the Peak Signal to Noise Ratio (PSNR) is used.
We assume that for humans the skin area is very important
for quality judgement. Therefore the images are converted
into the Hue, Saturation, Value (HSV) colour space before
comparison.This shouldmake thecomparisonmoresensitive
to skin parts, see Sedlacek [9]. A detailed evaluation and
discussion of this step follows in Subsection IV-C and
Section V.
Pixel-wisecomparison isperformedonlyon thebust itself,
since the background is masked out during comparison.
Given this framework we propose the optimal parameter
value oα∈Pα to be defined as
oα :=argmax
k∈Pα ∑
l∈Pα Mα(k,l). (5)
Literally speaking the parameter value oα creates 2D
views which are most similar to the views created with
all other values. The hypothesis is that this is also a good
parameter value which a human would choose.
IV. EVALUATION
Due to the lack of free datasets for bust reconstruction,
an own dataset has been built up during an open house
presentation in the company.
A. Dataset
The dataset contains 32 3D human bust scans showing
different people, further called models. The data is acquired
with a turntable and an off-the-shelf RGB-D sensor. Each
individual is scanned in eight key poses. For the detailed
set-up of the scan process see Heindl et al. [1].
For the reconstruction four different parameter-types are
inspected: colourcorrection level, number of steps for pose
estimation, surfacesmoothness termandmaximal iterationof
the bundle adjustment. These types form the parameter set
S={ ColourCorrection, PoseEstimation, SmoothnessTerm,
MaxIterations}. Foradetailedexplanationof the reconstruc-
tionsoftwareand theparameter semanticsseeagainHeindlet
al. [1].
116
Proceedings of the OAGM&ARW Joint Workshop
Vision, Automation and Robotics
- Titel
- Proceedings of the OAGM&ARW Joint Workshop
- Untertitel
- Vision, Automation and Robotics
- Autoren
- Peter M. Roth
- Markus Vincze
- Wilfried Kubinger
- Andreas Müller
- Bernhard Blaschitz
- Svorad Stolc
- Verlag
- Verlag der Technischen Universität Graz
- Ort
- Wien
- Datum
- 2017
- Sprache
- englisch
- Lizenz
- CC BY 4.0
- ISBN
- 978-3-85125-524-9
- Abmessungen
- 21.0 x 29.7 cm
- Seiten
- 188
- Schlagwörter
- Tagungsband
- Kategorien
- International
- Tagungsbände