Gaussian-Hermite Moment Invariants of General Vector Functions to
Rotation-Affine Transform
- URL: http://arxiv.org/abs/2201.00877v1
- Date: Mon, 3 Jan 2022 20:56:15 GMT
- Title: Gaussian-Hermite Moment Invariants of General Vector Functions to
Rotation-Affine Transform
- Authors: Hanlin Mo, Hua Li, Guoying Zhao
- Abstract summary: In this paper, we focus on constructing moment invariants of general vector functions.
This is the first time that a uniform frame has been proposed in the literature to construct moment invariants.
Based on synthetic and popular datasets of vector-valued data, the experiments are carried out to evaluate the stability and discriminability of these invariants.
- Score: 39.58178582162608
- License: http://arxiv.org/licenses/nonexclusive-distrib/1.0/
- Abstract: With the development of data acquisition technology, multi-channel data is
collected and widely used in many fields. Most of them can be expressed as
various types of vector functions. Feature extraction of vector functions for
identifying certain patterns of interest is a critical but challenging task. In
this paper, we focus on constructing moment invariants of general vector
functions. Specifically, we define rotation-affine transform to describe real
deformations of general vector functions, and then design a structural frame to
systematically generate Gaussian-Hermite moment invariants to this transform
model. This is the first time that a uniform frame has been proposed in the
literature to construct orthogonal moment invariants of general vector
functions. Given a certain type of multi-channel data, we demonstrate how to
utilize the new method to derive all possible invariants and to eliminate
various dependences among them. For RGB images, 2D and 3D flow fields, we
obtain the complete and independent sets of the invariants with low orders and
low degrees. Based on synthetic and popular datasets of vector-valued data, the
experiments are carried out to evaluate the stability and discriminability of
these invariants, and also their robustness to noise. The results clearly show
that the moment invariants proposed in our paper have better performance than
other previously used moment invariants of vector functions in RGB image
classification, vortex detection in 2D vector fields and template matching for
3D flow fields.
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