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Description  |
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BACKGROUND OF THE INVENTION
As a method to obtain a three dimensional image from two stereoscopically
photographed films have been known the lenticular method, polarization
method, complementary color method, etc by which stereoscopic observation
of the three dimensional image is permitted.
Conventionally, the distances in the directions of three dimensional
coordinates (axes x, y and z) has been calculated or measured with respect
to the three dimensional image which was prepared by the method described
above. This procedure was carried out by the following methods, that is, a
method of measuring and magnifying the distance on a film or printing
paper, a method for measurement by plotting the coordinates of axes X and
Y of a scale reduced image on a certain appropriate section paper and
diagramming the image in reference to the known and pre-calculated points
or a method of measuring the distance based on an image on an optical
film. In all these conventional methods, it was necessary to set the known
points of the subject on a photographic image to be used and to measure in
advance the distances of the above points in the directions of axes x, y
and z on the subject. Accordingly, in case of measuring the internal
positions of the subjects such as a brain and metallic cast product, that
is, the position or distances among several points in the three
dimensional space, it was impossible to measure an accurate distance since
previous setting of the points which were the reference points for
measurement and previous measurement of the distances of the above points
in the directions of axes x, y and z were impossible.
On the other hand, it is possible to prepare a three dimensional image and
to practise these dimensional measurement which permits accurate
measurement of the distance and position on an actual subject by measuring
the distance and position of the points on the above three dimensional
image; therefore a clear and precise three dimensional image has been
required. However, the conventional projector to obtain the three
dimensional image is constructed as shown in FIG. 1 and has been unable to
provide a clear and precise three dimensional image. In other words, as
shown in FIG. 1, the left side film stand 3 and the right side film stand
4 on which the left side film 1 and the right side film 2 stereoscopically
photographed are set are required, the left side condenser lens 5 and the
right side condenser lens 6 such as Fresnel lenses are arranged below the
left and right side film stands 3 and 4 and furthermore the left side
light source 7 and the right side light source 8 are provided below the
condenser lenses 5 and 6. The left side lens 9 and the right side lens 10
are arranged at the focal positions of the condenser lenses 5 and 6 above
the film stands 3 and 4, and the left side first mirror 11 and the right
side first mirror 12 which are inclined to 45.degree. to change the
optical axis to the horizontal direction are arranged to oppose each other
above lenses 9 and 10. The left side second mirror 13 and the right side
second mirror 14 are slidably provided at the intermediate positions
between the left side first mirror 11 and the right side first mirror 12
to change the direction of the optical axis to the above and the third
mirror 16 is arranged to lead the light from the second mirrors 13 and 14
to the screen 15. The left side polarizing filter 17 and the right side
polarizing filter 18 which polarize the light passing through the films 1
and 2 are vertically arranged between the first mirrors 11 and 12 and the
second mirrors 13 and 14. In the conventional apparatus constructed as
described above, when the images of the left side film 1 and the right
side film 2 are projected onto the screen 15, the images deviate from each
other as shown in FIG. 1. If the second mirrors 13 and 14 are slid to
adjust the angle to completely overlap the images and to eliminate such
deviation, the images are distorted toward the right and left side
peripheries. When such image is viewed through the polarizing glasses,
only a three dimensional image with distortion and out-of-focus part can
be observed and it cannot be used for accurate three dimensional
measurement. In other words, this is because the measured points which are
photographed on the right and left side films do not agree on the three
dimensional image or are projected deviated from the original positions as
the magnification and contraction ratios differ at each part of the image.
SUMMARY
An object of the present invention is to provide a method and an apparatus
for easy and accurate measurement of a position or a distance in a three
dimensional space, which could not conventionally be measured, based on
three dimensional images.
Another object of the present invention is to measure the true value
(actual value) of the position on the distance in the three dimensional
images obtained from stereoscopic photography of the subject in reference
to three basic factors, that is, the center of optical axis of an X-ray
tube or a camera which is indexed from the films at the time of
stereoscopic photography, distance of movement from the first photographic
point to the second photographic point and distance from the X-ray tube or
the lenses to the film while observing the above stereoscopically
photographed films.
A further object of the invention is to set the center of the optical axis
without being skewed on a film at the time of stereoscopic photography and
to index it on the film stereoscopically photographed.
A further another object of the invention is to provide a projector having
a half mirror so that the clear and precise three dimensional image is
obtained by perfectly aligning the optical axes passing through each film.
BRIEF DESCRIPTION OF THE DRAWINGS
FIG. 1 shows an arrangement of the optical system of the conventional
apparatus,
FIG. 2 is a schematic illustration of the apparatus for stereoscopic
photography in accordance with the present invention,
FIG. 3 is a linear diagram for explaining the equations,
FIG. 4 is a perspective view of a preferable embodiment of the film holder,
FIG. 5 is a diagram describing the principle of a preferable embodiment of
the apparatus in accordance of the present invention, and
FIG. 6 shows an arrangement of the optical system in accordance with the
present invention.
DETAILED DESCRIPTION OF THE INVENTION
The following describes the measuring method according to the present
invention.
In FIG. 2, the distance between the points A and B of the subject 20
arranged above the film 19 is measured. When the X-ray is irradiated onto
the subject 20 from the first photographic point O.sub.1 as much as the
photographic distance f away from the film 19, the image of the point
x.sub.O1 on the perpendicular extending from the first photographic point
O.sub.1 forms the center of the light axis without being skewed and the
points A and B are photographed skewed as the points A.sub.1 and B.sub.1.
Then the film 19 is replaced, the X-ray tube is moved in parallel with the
film 19 by distance d from the first photographic point O.sub.1 to the
second photographic point O.sub.2. When the X-ray is irradiated from this
second photographic point O.sub.2 onto the subject, the image of the point
X.sub.02 on the perpendicular extending from the second photographic point
O.sub.2 forms the center of the optical axis without being skewed and the
points A and B are photographed skewed as the points A.sub.2 and B.sub.2.
Stereoscopic photography of the subject 20 is carried out by the above
procedures and the O.sub.1 films are stereoscopically photographed from
the positions of the first photographic point O.sub.1 and the O.sub.2 film
stereoscopically photographed from the position of the second photographic
point O.sub.2 are obtained.
In FIG. 3, the points A and B on the O.sub.1 film are as follows:
Point A: x.sub.01 A.sub.1 = x.sub.01 A.sub.0 + A.sub.0 A.sub.1
point B: x.sub.01 B.sub.1 = x.sub.01 B.sub.0 + B.sub.0 B.sub.1
in this case, the points A.sub.0 and B.sub.0 show the positions on the
perpendiculars extending from the points A and B on the film 19 but they
are not photographed.
The points A and B on the 02 film are as follows:
Point A: x.sub.02 A.sub.2 = x.sub.02 A.sub.0 + A.sub.0 A.sub.2
point B: x.sub.02 B.sub.2 = x.sub.02 B.sub.0 + B.sub.0 B.sub.2
when the first photographic point 0.sub.1 is superposed on the second
photographic point 0.sub.2, 0.sub.1 A.sub.1 is equal to 0.sub.2 a .sub.1
and the photographic point moves parallel by distance d in parallel with
the subject 0.sub.1 B.sub.1 is equal to 0.sub.2 b.sub.1.
Accordingly, .DELTA. A A.sub.2 A.sub.1 .about. .DELTA. 0.sub.2 A.sub.2
a.sub.1 is given.
O.sub.2 x.sub.02 : A.sub.2 a.sub.1 = A A.sub.o : A.sub.2 A.sub.1
in the above equation, 0.sub.2 x.sub.02 is the photographic distance f
given as O.sub.2 x.sub.O2 = f.
If A.sub.2 a.sub.1 = P is given, the following relationship is obtained.
A.sub.2 A.sub.1 = A.sub.2 a.sub.1 - d = P -d
If the height of the point A from the film 19 is A A.sub.O = x, the
following is given.
f :P = x : (P - d)
P .multidot. x = f .multidot. (P - d)
##EQU1##
From .DELTA. B B.sub.2 B.sub.1 .about. .DELTA. O.sub.2 B.sub.2 b.sub.1, the
following is obtained.
O.sub.2 x.sub.O2 : B.sub.2 b.sub.1 = B B.sub.O : B.sub.2 B.sub.1
in the above equation, O.sub.2 x.sub.O2 is the photographic distance f
given as O.sub.2 x.sub.O2 = f.
If B.sub.2 b.sub.1 = Q is given,
B.sub.2 B.sub.1 = B.sub.2 b.sub.1 - d = Q - d
If the height of the point B from the film 19 is B B.sub.O = y, the
following is given.
f : Q = y : (Q - d)
Q .multidot. y = f (Q - d)
##EQU2##
In FIG. 3, the distance (depth) z between the points A and B in the
direction of axis z is given as follows:
##EQU3##
Accordingly, the distance (depth) of any point on the film 19 in the
direction of axis z can be measured by measuring values P and Q and
substitute the measured values to the above expression of relation.
Then the distance A.sub.O B.sub.O between the points A and B in the
direction of axis x is to be obtained. The center of the optical axis is
photographed just below the perpendicular extending from the X-ray tube
without being skewed and the images of other points are differently
skewed, depending on the depths and positions. Since the distances of all
points in the direction of axis z can be measured accurately as described
above, the distance in the direction of axis x can be expressed as a
function of the distance from the center of the optical axis and the
distance in the direction of axis z.
In FIG. 3, the following expressions are given:
##EQU4##
A.sub.O B.sub.O = A.sub.O x.sub.O2 - B.sub.O x.sub.O2 (3)
Since .DELTA. A A.sub.O A.sub.2 and .DELTA. O.sub.2 x .sub.02 A.sub.2 are a
right triangle respectively and have the angle .angle. O.sub.2 A.sub.2
x.sub.O2 in common, the following is obtained.
.DELTA. A A.sub.O A.sub.2 .about. .DELTA. O.sub.2 x .sub.O2 A.sub.2 (4)
a.sub.o x.sub.O2 = A.sub.2 x.sub.02 - A.sub.2 A.sub.O
from from the equation (4), f:A.sub.z = P.sub.2x : A.sub.2 A.sub.O
(P.sub.2x = A.sub.2 x.sub.O2) is obtained.
##EQU5##
Similarly,
.DELTA. B B.sub.2 B.sub.O .about. .DELTA. O.sub.2 B.sub.2 x.sub.O2 (5)
b.sub.o x.sub.O2 = B.sub.2 x.sub.O2 - B.sub.2 B.sub.O
from the equation (5), f : B.sub.z = Q 2x :B.sub.2 B.sub.O (Q.sub.2x =
B.sub.2 x.sub.O2) is obtained.
##EQU6##
If the above equations are substituted in the equation (3), the following
is obtained.
##EQU7##
Then, the distance Y between the points A and B in the direction of axis y
is to be obtained. This distance is obtained in the same method as the
distance in the direction of axis x described above on the assumption that
the film 19 is turned by 90.degree. in FIG. 3.
##EQU8##
Where, P.sub.2y : distance of the image of point A from the point x.sub.O2
in the direction of axis y
Q.sub.2y : distance of the image of point B from the point x.sub.O2 in the
direction of axis y
Then, the linear distance L (true value) between the points A and B is to
be obtained. Value L is expressed as a function of values Z, X and Y
described in the foregoing and given as below.
L = .sqroot.X.sup.2 + Y.sup.2 + Z.sup.2
as described above, the distance between the points A and B on the subject
20 in the three dimensional directions is measured using the functions of
the distance d between the first photographic point O.sub.1 and the second
photographic point O.sub.2, photographic distance f between the X-ray tube
and the film 19 and distances from the center points x.sub.O1 and x.sub.O2
of the optical axes to each image at the measured point. Accordingly, it
is necessary to obtain the center of the optical axis on the photographed
film 19. The following describes a method of obtaining the center point of
the optical axis.
Based on the photographed films, the position of the center of the optical
axis can be calculated by realizing the relative positions of three
factors, the X-ray tube, subject and films, based on two stereoscopically
photographed films if the subject is available. In general cases, however,
only the films are available and the subject is unavailable. Therefore,
the photography is performed with the film holder 21 as shown in FIG. 4 at
the time of photography. The film holder 21 is made up by hinging two
frames, and two indicators 24, 25 and 26, 27 are provided on each of
opposing sides 22 and 23 of the upper frame so that the indicators can
slide along the sides and one of similar indicators 30 and 31 is provided
on each of opposing other sides 28 and 29 of the upper frame. These
indicators 24, 25, 26, 27, 30 and 31 are made of material such as lead
which does not admit the X-ray in case of the X-ray photography.
Before the photography, the following operations are to be performed. In
the X-ray room, the beams are emitted into the X-ray tube 34 from two beam
sources 32 and 34 provided at the specified height so that the optical
axes intersect orthogonally each other and the X-ray tube 34 is positioned
so that the beams pass through two center marks 35 and 36 on the outer
peripheral surface and the end face of the outer casing of the X-ray tube
34 which indicates the center of the X-ray tube. While one beam is kept
passing through the center mark 36 on the outer peripheral surface of the
outer casing of the X-ray tube 34, the X-ray tube 34 is moved in parallel
by d/2. This operation is carried out by superposing one (37) of two
optical axis marks 37 and 38 indicated with a distance of d/2 at both
sides of the center mark 35 inscribed on the end surface of the outer
casing of the X-ray tube with the other beam. At this position, that is,
the first photographic point O.sub.1, the weight 39 is suspended from the
center of the X-ray tube toward the film holder 21. The indicators 24, 25,
30 and 31 are slid and fixed so that the line between the indicators 24
and 25 of the film holder 21 intersects the line between the indicators 30
and 31 at the position marked by the weight 39. This intersection
indicates the center x.sub.O1 of one optical axis. Then the X-ray tube 34
is moved parallel by d in the reverse direction to the above case. The
direction of this movement is parallel with the line between the
indicators 30 and 31 and this operation is performed by aligning one beam
with one optical axis mark 38 different from that described above while
the other beam is kept aligned with the center mark 36 inscribed on the
outer peripheral surface of the outer casing of X-ray tube 34. At this
position, that is, the second photographic point O.sub.2, the weight 39 is
suspended from the center of the X-ray tube toward the film holder 21. The
indicators 26 and 27 are moved and fixed so that the line between the
indicators 26 and 27 of the film holder 21 intersects the line between the
indicators 30 and 31 at the position marked by the weight 39. This
intersection indicates the center point x.sub.O2 of the other optical
axis. After thus determining the first and second photographic points
O.sub.1 and O.sub.2 and the center points x.sub.O1 and x.sub.O2 of the
optical axis, the film 19 is set on the film holder 21 and the subject is
mounted thereon. The O.sub.1 film is obtained by irradiating the X-ray to
the subject from the first photographic point. When the film is replaced
without moving the subject and the X-ray is irradiated onto the subject
from the second photographic point O.sub.2, the O.sub.2 film is obtained.
The indicators are photographed with the subject on the O.sub.1 and
O.sub.2 films and indicate the centers of two optical axes as described
above.
The following describes the apparatus which performs the measurement by the
stereoscopic photography using two films prepared as described above. FIG.
5 shows the principle of the apparatus. The film stand 40 is constructed
so that the O.sub.1 film 41 and O.sub.2 film 42 are set in parallel
arrangement. Two Fresnel lenses 43 and 44 are provided below the film
stand 40 and two light sources 45 and 46 are provided further below the
Fresnel lenses 43, 44. The light sources 45 and 46 preferably employs the
xenon lamps to absorb heat but are not restricted by this preference. The
left side first mirror 47 is provided with inclination at 45.degree. above
the O.sub.1 film 41 to change the direction of the light to the horizontal
direction. The left side lens 48 which receives the light from the left
side first mirror 47 is provided at the focal position of the Fresnel lens
43, magnifies the image and leads the light to the left side second mirror
49. The left side second mirror 49 is provided in parallel with the left
side first mirror 47 to change the light to the vertical direction. The
left side polarizing filter 50 is horizontally provided above the left
side second mirror 49 and the half mirror 51 is provided with inclination
of 45.degree. above the left side polarizing filter 50. The third mirror
53 is provided with inclination of 45.degree. above the half mirror 51 to
lead the light to the screen 52 provided at the front side. The right side
lens 54 is vertically provided at the focal position of the Fresnel lens
above the O.sub.2 film 42 and the right side first mirror 55 is provided
with inclination of 45.degree. above the right side lens 54 to change the
light to the horizontal direction and to lead it to the half mirror 51.
The right side polarizing filter 56 is vertically provided at an
intermediate position between the right side first mirror 55 and the half
mirror 51. The left side polarizing filter 50 and the right side
polarizing filter 56 are mounted so that they are rotated respectively at
different 90.degree. angle. The y-axis table 57 which is slid to forward
and backward is provided in a plane parallel with the film stand 40 and
the x-axis table 58 which moves orthogonally against the movement of the
y-axis table is provided above the y-axis table 57. Furthermore, the
z-axis table 59 which moves in the same direction as the x-axis table 58
is provided above the x-axis table.
The left side marker 61 is fixed to the tip end of the arm 60 which is
fixed on the x-axis table 58 to slide on the O.sub.1 film. The right side
marker 63 is fixed to the tip end of the arm 62 which is fixed on the
z-axis table 59 to slide on the O.sub.2 film 42. Accordingly, the left
side marker 61 and the right side marker 63 operate differently only when
the z-axis table 59 is driven and the distance between the left side
marker 61 and the right side marker 63 increases or decreases. In other
case, the left side marker is operated with the right side marker. The
above-mentioned tables 57, 58 and 59 are moved through the feed screws
(not shown) which are rotated by the motor (not shown) though it does not
mean that their movements are limited. The feed screws are provided with
the rotary encoders 64, 65 and 66 and the amounts of movement of the
tables 57, 58 and 59 can be known by counting the numbers of pulses
generated from the rotary encoders 64, 65 and 66. The rotary encoders 64,
65 and 66 are connected to the data processor 68 which is connected to the
digital indicator 67 indicating the measured values on the films 41 and
42, while said data processor 68 is connected to the micro computer 69
capable of calculating based on the input and digital-indicating the
results of calculation. The micro computer 69 performs calculations based
on the equations described in the foregoing and displays values Z X Y and
L (true values).
The following describes the operation of the apparatus in accordance with
the present invention. The O.sub.1 film 41 and the O.sub.2 film 42 are set
in parallel arrangement at the specified positions on the film stand 40.
When the left side light source 45 emits a light, the light passes through
the left side Fresnel lens 43 and the left side film 41, changes its axial
direction to the horizontal direction by being reflected at the left side
first mirror 47 and is condensed to the left side lens 48. The light which
is condensed to and passes through the left side lens 48 is reflected by
the left side second mirror 49 to change its axial direction to the
vertical direction and a light of special phase is eliminated by hte left
side polarizing filter 50. Furthermore this light passes through the half
mirror 51 from the rear side to the front side with slight refraction. On
the other hand, when the right side light source 46 emits a light, the
light passes through the right side Fresnel lens 44 and the right side
film 42 and is condensed to the right side lens 54. The light which is
condensed to and passes through the right side lens 54 is reflected by the
right side first mirror 55 to change its axial direction to the horizontal
direction and reaches the right side polarizing filter 56, where the light
of special phase is eliminated. Furthermore the light reaches the half
mirror 51 and is reflected thereon. At this time, the optical axis is
aligned with the optical axis of the light coming from the rear side of
the half mirror 51 through the left side film 41, and the light reaches
the third mirror 53 together with the light coming from the rear side of
the half mirror 51 and is reflected by the third mirror 53. Accordingly,
the images of the left side film 41 and the right side film 42 are
completely overlapped, magnified and projected onto the screen 52. When
this overlapped image is viewed through a pair of polarizing glasses of
which the rotation angle is made different by 90.degree. at the left side
and the right side, the left side eye can see the image of the left side
film 41 and the right side eye can see the image of the right side film 42
and thus a clear and precise three dimensional image can be obtained.
The y-axis table 57 and the x-axis table 58 are moved while observing the
three dimensional image and the left side marker 61 is aligned with the
center point x.sub.O1 of the optical axis of the film 41. Then the z-axis
table 59 is moved and the right side marker 63 is aligned with the center
point x.sub.O2 of the optical axis of the O.sub.2 film 42. Thus, the
markers 61 and 63 are set at the center points x.sub.O1 and x.sub.O2 of
the optical axis and the displays 67 and 69 are reset to make the values
of three axes zero. Then the tables 57, 58 and 59 are moved to align the
markers 61 and 63 with the first measuring point A in the three
dimensional image while observing the three dimensional image. Under this
condition, the left side marker 61 is aligned with the point A.sub.1 (FIG.
3) on the O.sub.1 film 41 and the right side marker 63 with the point
A.sub.2 (FIG. 3) on the O.sub.2 film 42, and the amount of movement in
three axial directions is calculated and displayed. In FIG. 3, x.sub.O1
A.sub.1 (= x.sub.O2 a.sub.1) and x.sub.O2 A.sub.2 are measured and the
following is obtained.
A.sub.2 a.sub.1 = P = x.sub.O2 A.sub.2 + x.sub.02 a.sub.1
When the distance d (= x.sub.01 x.sub.O2) between the first photographic
point O.sub.1 and the second photographic point O.sub.2 and the distance f
between the X-ray tube and the films are inputted in the micro computer
69, the following values are calculated,
##EQU9##
where, A.sub.O Y.sub.O1 is a distance between the center point x.sub.O1 of
the optical axis and the point A.sub.O in the direction of axis y, and
moreover the following is calculated and
L =.sqroot.A.sub.z.sup.2 + A.sub.O x.sub.O1 .sup.2 + A.sub.O Y.sub.O1
.sup.2
digital-displayed on the micro computer 69.
Then, the measured values and calculated values are stored in the memory of
the micro computer 69 and the reference operation for determing this first
measuring point A as the reference point is performed. By this operation,
the displays of the micro computer 69 are reset to 0 (zero) and therefore
the displays always indicate 0 when the left side and right side markers
61 and 63 are aligned with the first measuring point A.
When the markers 61 and 63 are moved to the second measuring point B,
x.sub.O1 B.sub.1 (= x.sub.O2 b.sub.1) and x.sub.O2 A.sub.2 are measured
and the following obtained. B.sub.2 b.sub.1 = Q = x.sub.O2 B.sub.2 +
x.sub.O2 b.sub.1 (See FIG. 3.)
In the micro computer 69, the following values are calculated,
##EQU10##
where, B.sub.O y.sub.O1 is the distance from the center point x.sub.O1 of
the optical axis to point B.sub.O in the direction of axis y.
L = .sqroot.B.sub.z.sup.2 + B.sub.O x.sub.O1.sup.2 + B.sub.O Y.sub.O1
.sup.2
and the following values based on the first measuring point A as the
reference point are calculated and displayed on the displays of the micro
computer 69.
Z = A.sub.z - B.sub.z
##EQU11##
L = .sqroot.Z.sup.2 + X.sup.2 + Y.sup.2
These values can be sotred in the memory of the micro computer 69. When the
markers 61 and 63 are moved to the third measuring point C, the distances
X, Y and Z in the three dimensional directions of axes from the first
measuring point A and the linear distance (true value) L can be measured.
When the reference operation is performed at an arbitrary measuring point,
the reference point moves to the said measuring point and subsequently the
distances from the said point are measured.
As described above, the three dimensional measurement by the method and the
apparatus in accordance with the present invention is carried out by
aligning the left side and right side markers 61 and 63 with the center
point x.sub.O1 and x.sub.O2 of the optical axis before aligning the
markers 61 and 63 with the three dimensional image projected on the screen
52 and driving the tables 57, 58 and 59 to move the markers 61 and 63 to
the first measuring point A after resetting the digital displays to zero.
The distance of movement in each axial direction is digitally displayed on
the displays for the axes x, y and z. When the markers 61 and 63 are moved
to the second measuring point B after the distance of movement has been
stored in the memory and the reference operation has been performed, the
distance of movement from the center points x.sub.O1 and x.sub.O2 of the
optical axis to the second measuring point B can be measured. With the
results of measurement substituted into the equations for calculation, the
true distance from an arbitrary measuring point A (O, O, O) to the
measuring point B (x, y, z) can be measured.
The above describes the measurement using two X-ray films which are
stereoscopically photographed. This measurement can be carried out
similarly with an ordinary camera. In other words, the first photographic
point O.sub.1 and the second photographic point O.sub.2 are the centers of
the left side and right side lenses for the ordinary camera. The distance
from the centers of the lenses recorded on the films to the images at the
arbitrary points on the films are measured in the same manner or by the
same means as described above by recording the centers of lenses on the
left side and right side films, and the position or the actual distances
among several points in the three dimensional space can be obtained by
utilizing the distance between the centers of lenses and the distance
between the lenses and the films in photography.
As described in the foregoing, the present invention permits measurement of
the actual distance between the arbitrary points in the three dimensional
space with the three dimensional images prepared from two stereoscopically
photographed by calculating the data during the photography, that is,
distance d between the first photographic point O.sub.1 and the second
photographic point O.sub.2, distance f from the X-ray tube to the film and
distances from the center points x.sub.O1 and x.sub.O2 of the optical axis
at the arbitrary points on the films which are measured while observing
the three dimensional images. In other words, in case of the present
invention, the distance between the specified points which is set in
advance need not be measured in advance. Accordingly, the method of
measurement in accordance with the present invention is highly effective
for diagnosing an affected part in a human body. The shape and position of
the affected part can be accurately measured in advance before operation
and therefore the operation can be performed precisely and efficiently.
Moreover, the recovery of the affected part after operation can be easily
checked and diagnosed and the present invention will exhibit a great
contribution in the field of medicine. In industrial application, this
method and apparatus will be advantageous in detection of internal defects
of cast products, easy inspection of qualities without destroying the
products since the shape and position of defects can be known from the
outside, inspection of parts in the plants without stopping the operation
and destroying the parts, prevention of accidents and troubles and great
saving of costs for employees and materials necessary for inspection.
In the apparatus in accordance with the present invention, the left side
marker 61 is attached with the arm 60 to the x-axis table 58 provided on
the y-axis table 57 and the right side marker 63 is attached with the arm
62 to the z-axis table 59 which is provided on the x-axis table 58 and
moves in the same direction as the x-axis table; therefore the parallax
measurement in the direction of axis x can be easily performed. Since the
movement and the amount of movement can be measured merely by providing
the feed screws and the motors on the tables 57, 58 and 59 and attaching
the rotary encoders to the feed screws, the contruction can be simple and
the calculation of actual values can be facilitated.
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