Scale-invariant feature operator

Feature detection
Edge detection
Canny Deriche Differential Sobel Prewitt Robinson Roberts cross
Corner detection
Harris operator Shi and Tomasi Level curve curvature Hessian feature strength measures SUSAN FAST
Blob detection
Laplacian of Gaussian (LoG) Difference of Gaussians (DoG) Determinant of Hessian (DoH) Maximally stable extremal regions PCBR
Ridge detection
Hough transform
Hough transform Generalized Hough transform
Structure tensor
Structure tensor Generalized structure tensor
Affine invariant feature detection
Affine shape adaptation Harris affine Hessian affine
Feature description
SIFT SURF GLOH HOG
Scale space
Scale-space axioms Implementation details Pyramids
v t e

The Scale-invariant Feature Operator (or SFOP) is an algorithm in computer vision to detect local features in images. The algorithm was published by Förstner et al. in 2009.^[1]

The Scale-invariant Feature Operator (SFOP) is based on two theoretical concepts:

• spiral model^[2]
• feature operator^[3]

Desired properties of keypoint detectors:

• Invariance and repeatability for object recognition
• Accuracy to support camera calibration
• Interpretability: Especially corners and circles, should be part of the detected keypoints (see figure).
• As few control parameters as possible with clear semantics
• Complementarity to known detectors

scale-invariant corner/circle detector.

Maximize the weight ${\displaystyle w}$= 1/variance of a point ${\displaystyle p}$

${\displaystyle w(\mathbf {p} ,\alpha ,\tau ,\sigma )=\left(N(\sigma )-2\right){\frac {\lambda _{min}(M(\mathbf {p} ,\alpha ,\tau ,\sigma ))}{\Omega (\mathbf {p} ,\alpha ,\tau ,\sigma )}}}$  

comprising:

1. the image model^[2]

• Distance d of an edge from a reference point p in a spiral feature
• 
• 
• 

${\displaystyle {\begin{aligned}\Omega (\mathbf {p} ,\alpha ,\tau ,\sigma )&=\sum _{n=1}^{N(\sigma )}[(\mathbf {q} _{n}-\mathbf {p} )^{T}\mathbf {R} _{\alpha }\mathbf {\nabla } _{T}g(\mathbf {q} _{n})]^{2}G_{\sigma }(\mathbf {q} _{n}-\mathbf {p} )\\&=N(\sigma )\mathbf {tr} \left\{R_{\alpha }\mathbf {\nabla } _{\tau }\mathbf {\nabla } _{\tau }^{T}R_{\alpha }^{T}*\mathbf {p} \mathbf {p} ^{T}G_{\sigma }(\mathbf {p} )\right\}\end{aligned}}}$

2. the smaller eigenvalue of the structure tensor ${\displaystyle \underbrace {M(\mathbf {p} ,\alpha ,\tau ,\sigma )} _{\text{structure tensor}}=\underbrace {G_{\sigma }(\mathbf {p} )} _{\text{weighted summation}}*\underbrace {(R_{\sigma }\nabla _{\tau }\nabla _{\tau }^{T}R_{\sigma }^{T})} _{\text{squared rotated gradients}}}$

Reduce the 5-dimensional search space by

• linking the differentiation scale ${\displaystyle \tau }$ to the integration scale

${\displaystyle \tau =\sigma /3}$

• solving for the optimal ${\displaystyle {\hat {\alpha }}}$ using the model

${\displaystyle \Omega (\alpha )=a-b\cos(2\alpha -2\alpha _{0})}$

• and determining the parameters from three angles, e. g.

${\displaystyle \Omega (0^{\circ }),\Omega (60^{\circ }),\Omega (120^{\circ })\quad \rightarrow \quad a,b,\alpha _{0}\quad \rightarrow \quad {\hat {\alpha }}}$

• pre-selection possible:

${\displaystyle \alpha =0^{\circ }\,\rightarrow \,{\mbox{junctions}},\quad \alpha =90^{\circ }\,\rightarrow \,{\mbox{circular features}}}$

• non-maxima suppression over scale, space and angle

• thresholding the isotropy ${\displaystyle \lambda _{2(M)}}$:
  eigenvalues characterize the shape of the keypoint, smallest eigenvalue has to be larger than threshold ${\displaystyle T_{\lambda }}$
  derived from noise variance ${\displaystyle V(n)}$ and significance level ${\displaystyle S}$:

${\displaystyle T_{\lambda }(V(n),\tau ,\sigma ,S)={\frac {N(\sigma )}{16\pi \tau ^{4}}}V(n)\chi _{2,S}^{2}}$

• Results of different detectors on a Siemens star
• 
  Sfop: junctions red, circular features cyan
• 
  Edge-based Regions
• 
  Intensity-based Regions
• 
  MSER
• 
  Harris affine
• 
  Hessian affine
• 
  Lowe

• Corner detection
• Feature detection (computer vision)

• [1], the authors project website at University of Bonn