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Front. Inform. Technol. Electron. Eng.  2016, Vol. 17 Issue (1): 32-40    DOI: 10.1631/FITEE.1500171
    
Image meshing via hierarchical optimization
Institute of Artificial Intelligence, Zhejiang University, Hangzhou 310027, China
Image meshing via hierarchical optimization
Hao XIE,Ruo-feng TONG()
Institute of Artificial Intelligence, Zhejiang University, Hangzhou 310027, China
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摘要:

Vector graphic , as a kind of geometric representation of raster images, has many advantages, e.g., definition independence and editing facility. A popular way to convert raster images into vector graphics is {image meshing}, the aim of which is to find a mesh to represent an image as faithfully as possible. For traditional meshing algorithms, the crux of the problem resides mainly in the high non-linearity and non-smoothness of the objective, which makes it difficult to find a desirable optimal solution. To ameliorate this situation, we present a hierarchical optimization algorithm solving the problem from coarser levels to finer ones, providing initialization for each level with its coarser ascent. To further simplify the problem, the original non-convex problem is converted to a linear least squares one, and thus becomes convex, which makes the problem much easier to solve. A dictionary learning framework is used to combine geometry and topology elegantly. Then an alternating scheme is employed to solve both parts. Experiments show that our algorithm runs fast and achieves better results than existing ones for most images.
Abstract:

Vector graphic , as a kind of geometric representation of raster images, has many advantages, e.g., definition independence and editing facility. A popular way to convert raster images into vector graphics is {image meshing}, the aim of which is to find a mesh to represent an image as faithfully as possible. For traditional meshing algorithms, the crux of the problem resides mainly in the high non-linearity and non-smoothness of the objective, which makes it difficult to find a desirable optimal solution. To ameliorate this situation, we present a hierarchical optimization algorithm solving the problem from coarser levels to finer ones, providing initialization for each level with its coarser ascent. To further simplify the problem, the original non-convex problem is converted to a linear least squares one, and thus becomes convex, which makes the problem much easier to solve. A dictionary learning framework is used to combine geometry and topology elegantly. Then an alternating scheme is employed to solve both parts. Experiments show that our algorithm runs fast and achieves better results than existing ones for most images.
Key words: Image meshing    Hierarchical optimization    Convexification
收稿日期: 2015-05-27 出版日期: 2016-01-05
CLC:  TP391.7  
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http://www.zjujournals.com/xueshu/fitee/CN/Y2016/V17/I1/32

  
1: HierarchyEstablishment
2: MeshInitialization
3: $i\Leftarrow N - 1$
4: while Level i ≥ 0 do
5: ????ObjectiveConvexification(i)
6: ????AlternatingOptimization(i)
7:????$i\Leftarrow i - 1$
8: end while
  
  
  
Image SR (%) PSNR (dB)
Adams(2011) Xieet al.(2014) Ours
Lena127.375928.860029.7244
229.826330.954431.3691
330.980131.991832.1422
Fruits125.926926.958927.7363
228.532729.442429.7518
329.962930.802430.5960
Flowe125.802826.971827.7477
227.921729.607129.9863
328.661530.800930.9495
Falcon127.319629.966630.4886
228.532331.972932.1160
328.867532.787732.7106
Car123.164524.647825.0299
225.694126.885727.2032
326.816327.949028.0324
Fish123.987325.230125.9045
226.629627.763628.1316
328.107429.216629.2648
Leaf126.806127.881628.6272
228.839529.984630.3554
329.592431.000831.1287
Swan124.482625.961426.7547
226.989028.378328.9821
328.365129.701930.0601
Frog127.440428.977629.8903
229.884831.058431.5725
330.879131.968932.2853
  
  
  
Image Resolution SR(%) Time(s)
Lena512×51212.03
23.66
36.23
Fruits512×48011.75
23.10
35.19
Flower400×30010.66
21.02
31.61
Falcon400×28010.59
20.86
31.33
Car400×30010.64
21.04
31.61
Fish320×40010.66
21.05
31.66
Leaf373×40010.83
21.36
32.20
Swan286×40010.60
20.95
31.48
Frog357×40010.90
21.44
  
  
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