'preted as a 
iency chan- 
scale. 
ucted from 
' to scale s 
1 frequency 
e matching 
of the con- 
discretizing 
(7) 
family 
A (8) 
4;f denote 
a scale s = 
er of levels 
arsest level, 
D;f denote 
f and A;f, 
n (9) 
(x) can be 
(10) 
be realized 
let function 
z) (11) 
z) (12) 
2 (13) 
$;,k (x) by. 
(14) 
tion 4, H is 
x conjugate 
For a 2-D image function f(z, y), a multiresolution analysis 
can be written as 
f(z,y)2 Avxf Fr Diaf t Dif t Dif 
= Af + Deaf - D25f - Daosf 
+D1,1$f + D12f + Disf 
ZA S IDjaf + D,2f + Djsf] (15) 
j=1 
Each approximation A;f(z,y) and difference component 
D; »f(z,y) can be fully characterized with a 2-D scaling func- 
tion ®(z,y) and its associated wavelet functions ¥,(z,y), 
p=1,23, 
Too Too 
Aj. m S Sau bv) (16) 
kz—oolz-—oo 
Too Too 
Djpf(z.y)-— NS SE dy pk V, pku(rz,y) (17) 
k-—oolz-—oo 
  
  
where 
1,,r—k y-l 
$;i(z, y) em 23 ( 2j ^ E, (7, k, l) € Z (18) 
1 r—k y-l 
dynt = < Fix. vu), 0; 115,4) > (20) 
di prt =< Hoy) spring) > (21) 
For a separable multiresolution analysis, the scaling function 
®(z,y) and wavelet functions ¥,(z,y),p = 1,2,3 can be 
written as 
S(z,y) = é(z)ó(y) (22) 
Vi(z,y) — ó(z)v(v) (23) 
Vo»(z,y) — v(z)ó(v) (24) 
Vs(z,y) = v(z)v(v) (25) 
where ó is a one-dimensional scaling function, v is the 1-D 
wavelet function associated with ó. Apparently V, V5, V3 
extract the details of the 2-D image function f(z, y) in the 
y-axis, x-axis and diagonal directions respectively. 
The representation (15) may be vividly called the wavelet 
pyramid of an image f(z, y). Given a discrete image f(z, y) 
with a limited support s = 1,2, (Mat gy — 1,2)... fy. 
the actual procedure for constructing this pyramid involves 
computing the coefficients ajx:, djp,k:, Which can be 
grouped into four matrices A;, D;p, P = 1,2,3, on each 
level 7 
A; = (a;,k,t)(n=1,2,. 2g =12,.., 24) (26) 
s 2 (27) 
2J 
Let h and g be the impulse response of the filter ó and v, the 
coefficients a; x, and dj pki, p = 1,2,3, can be computed 
via an iterative procedure. The wavelet pyramid of image 
f(z,y) and its constructing process are illustrated in Fig.1. 
(z|2 means dyadic subsampling). 
International Archives of Photogrammetry and Remote Sensing. Vol. XXXI, Part B3. Vienna 1996 
  
  
  
  
  
  
  
  
  
  
  
  
  
  
  
  
  
  
  
  
  
  
A3] Ds, 
D,;| D35 
A 
A, Dy; 
Dy, | D, 
A; D,, 
D, D, 3 
  
  
  
  
  
  
  
  
f(X,y) 
  
  
  
Figure 1: Wavelet pyramid of an image f(z, y) (left) and the 
flowchart for the analysis from level j — 1 to level 7 (right) 
3.2 Complex Wavelets for Phase-Based Matching 
Wavelet pyramid is ideal for scale adaptive image matching as 
it has the advantage at the good locality in both spatial and 
frequency domain. However, wavelet pyramid of an image is 
neither translation-invariant, nor rotation-invariant. At this 
stage, let us concentrate on the translation-invariance prob- 
lem, while assuming that either the rotation angle y of the 
matched image about its principal axis relative to the refer- 
ence image is small enough, or two stereo images have been 
resampled along the epipolar lines. 
The wavelet pyramid of real-valued wavelets is not 
translation-invariant implies that the phase information is not 
readily represented. In order to explore the phase information 
in the image signals and still on multiscales, complex-valued 
wavelets are a suitable representation as the translation in 
the spatial domain is represented as a rotation in the com- 
plex phase domain. This gives rise to the interpolability of the 
wavelet transform, yielding the possibility of subpixel match- 
ing through the multilevels of the wavelet pyramids. 
The complex wavelets used in this work were designed by 
Margarey and Kingsbury (1995), first used for motion estima- 
tion of video frames. Bergeaud and Mallat (1984) proposed 
similar complex wavelets. It should be pointed out that the 
similarity distance measures and various matching strategies 
to be described in the following sections are not limited to 
those particular wavelets used in this work, they may rather 
be generally applicable with other well-designed wavelets with 
good properties. 
For general image matching purpose, we require the wavelet 
filter pair (h, g) (impulse response of the scaling and wavelet 
function ó and V) to be compactly supported in spatial do- 
main, regular (differentiable up to a high order), symmetric