-
Notifications
You must be signed in to change notification settings - Fork 29
/
LFBuild2DFreqFan.m
100 lines (88 loc) · 4.45 KB
/
LFBuild2DFreqFan.m
1
2
3
4
5
6
7
8
9
10
11
12
13
14
15
16
17
18
19
20
21
22
23
24
25
26
27
28
29
30
31
32
33
34
35
36
37
38
39
40
41
42
43
44
45
46
47
48
49
50
51
52
53
54
55
56
57
58
59
60
61
62
63
64
65
66
67
68
69
70
71
72
73
74
75
76
77
78
79
80
81
82
83
84
85
86
87
88
89
90
91
92
93
94
95
96
97
98
% LFBuild2DFreqFan - construct a 2D fan passband filter in the frequency domain
%
% Usage:
%
% [H, FiltOptions] = LFBuild2DFreqFan( LFSize, Slope1, Slope2, BW, FiltOptions )
% H = LFBuild2DFreqFan( LFSize, Slope, BW )
%
% This file constructs a real-valued magnitude response in 2D, for which the passband is a fan.
%
% Once constructed the filter must be applied to a light field, e.g. using LFFilt2DFFT. The
% LFDemoBasicFilt* files demonstrate how to contruct and apply frequency-domain filters.
%
% A more technical discussion, including the use of filters for denoising and volumetric focus, and
% the inclusion of aliases components, is included in:
%
% [2] D.G. Dansereau, O. Pizarro, and S. B. Williams, "Linear Volumetric Focus for Light Field
% Cameras," to appear in ACM Transactions on Graphics (TOG), vol. 34, no. 2, 2015.
%
% Inputs:
%
% LFSize : Size of the frequency-domain filter. This should match or exceed the size of the
% light field to be filtered. If it's larger than the input light field, the input is
% zero-padded to match the filter's size by LFFilt2DFFT.
%
% Slope1, Slope2 : Slopes at the extents of the fan passband.
%
% BW : 3-db Bandwidth of the planar passband.
%
% [optional] FiltOptions : struct controlling filter construction
% SlopeMethod : only 'Skew' is supported for now
% Precision : 'single' or 'double', default 'single'
% Rolloff : 'Gaussian' or 'Butter', default 'Gaussian'
% Order : controls the order of the filter when Rolloff is 'Butter', default 3
% Aspect2D : aspect ratio of the light field, default [1 1]
% Window : Default false. By default the edges of the passband are sharp; this adds
% a smooth rolloff at the edges when used in conjunction with Extent2D or
% IncludeAliased.
% Extent2D : controls where the edge of the passband occurs, the default [1 1]
% is the edge of the Nyquist box. When less than 1, enabling windowing
% introduces a rolloff after the edge of the passband. Can be greater
% than 1 when using IncludeAliased.
% IncludeAliased : default false; allows the passband to wrap around off the edge of the
% Nyquist box; used in conjunction with Window and/or Extent2D. This can
% increase processing time dramatically, e.g. Extent2D = [2,2]
% requires a 2^2 = 4-fold increase in time to construct the filter.
% Useful when passband content is aliased, see [2].
%
% Outputs:
%
% H : real-valued frequency magnitude response
% FiltOptions : The filter options including defaults, with an added PassbandInfo field
% detailing the function and time of construction of the filter
%
% User guide: <a href="matlab:which LFToolbox.pdf; open('LFToolbox.pdf')">LFToolbox.pdf</a>
% See also: LFDemoBasicFiltGantry, LFDemoBasicFiltIllum, LFDemoBasicFiltLytroF01, LFBuild2DFreqFan, LFBuild2DFreqLine,
% LFBuild4DFreqDualFan, LFBuild4DFreqHypercone, LFBuild4DFreqHyperfan, LFBuild4DFreqPlane, LFFilt2DFFT, LFFilt4DFFT,
% LFFiltShiftSum
% Copyright (c) 2013-2020 Donald G. Dansereau
function [H, FiltOptions] = LFBuild2DFreqFan( LFSize, Slope1, Slope2, BW, FiltOptions )
FiltOptions = LFDefaultField('FiltOptions', 'SlopeMethod', 'Skew'); % 'Skew' only for now
DistFunc = @(P, FiltOptions) DistFunc_2DFan( P, Slope1, Slope2, FiltOptions );
[H, FiltOptions] = LFHelperBuild2DFreq( LFSize, BW, FiltOptions, DistFunc );
TimeStamp = datestr(now,'ddmmmyyyy_HHMMSS');
FiltOptions.PassbandInfo = struct('mfilename', mfilename, 'time', TimeStamp, 'VersionStr', LFToolboxVersion);
end
%-----------------------------------------------------------------------------------------------------------------------
function Dist = DistFunc_2DFan( P, Slope1, Slope2, FiltOptions )
switch( lower(FiltOptions.SlopeMethod) )
case 'skew'
if( Slope2 < Slope1 )
t = Slope1;
Slope1 = Slope2;
Slope2 = t;
end
R1 = eye(2);
R2 = R1;
R1(1,2) = Slope1;
R2(1,2) = Slope2;
otherwise
error('Unrecognized slope method');
end
P1 = R1 * P;
P2 = R2 * P;
TransitionPt = LFSign(P1(2,:));
CurDist1 = max(0, TransitionPt .* P1(1,:));
CurDist2 = max(0,-TransitionPt .* P2(1,:));
Dist = max(CurDist1, CurDist2).^2;
end