Camera including a zoom lens having simultaneous focusing and zooming

A camera having a zoom lens in which the zoom lens includes: first and second lens components for focusing the light from an object on the focal plane; a lens barrel for guiding movements of the first and the second lens components, in which the lens barrel includes a first guide portion for guiding movement of the first lens component and a second guide portion for guiding movement of the second lens component; and a moving driver for moving the first lens component along the first guide portion and for moving the second lens component along the second guide portion so that the first and the second lens components focus the light on the focal plane at plural focal lengths, and a focal point adjustment, including focusing and focusing compensation, is conducted continuously from the first focal length to the second focal length of the plural focal lengths.

BACKGROUND OF THE INVENTION 
This invention is related to a zoom lens barrel which holds a zoom lens as 
a photographic lens of a camera. 
Recently, it became common to use a zoom lens as a photographic lens in the 
field of lens-shutter cameras and single-lens reflex cameras. The zoom 
lens is a lens capable of changing its focal length or magnification. 
There is a keen competition of technologies to maximize the magnification 
ratio, which is the ratio of the longest focal distance to the shortest 
focal distance, of the zoom lens and to minimize the size of the zoom lens 
barrel. The technology to maximize the magnification ratio is contrary to 
that to minimize the size; however, there are different kinds of proposals 
of zoom lens barrels which do not increase the barrel size in a high 
magnification ratio. 
For one example of the proposals, a zoom lens barrel is disclosed in 
Japanese Patent Publication Open to the Public Inspection No. 259210/86, 
and the applicant of the present invention disclosed a zoom lens barrel in 
Japanese Patent Publication Open to the Public Inspection No. 226562/94. 
Although the conventional zoom lens barrels realize the focal length 
variation or zooming and the focal point control or focusing with 
respective mechanisms, in the above-mentioned disclosure, zooming and the 
focusing are both realized with the same mechanism so that a remarkably 
small zoom lens barrel can be configured. 
In the above-mentioned disclosure, so called step zoom method, in which 
predetermined number of focal length steps are provided between the 
longest focal length and the shortest forcal length, is used. The step 
zoom method will be explained with a figure showing zooming 
characteristics in FIG. 1. In the figure, the horizontal axis indicates 
the variation of the focal length, W indicates the case that the focal 
length is set at the shortest, M.sub.1 and M.sub.2 indicate the cases that 
the forcal length is set gradually longer, and T indicates the case that 
the focal length is set at the longest. Therefore, there are four steps to 
change the focal length in zooming. The vertical axis indicates the moving 
amounts of the front and rear components of the zoom lens in the optical 
axis. The front component a helicoidally coupled with a rotatable cam 
barrel so that the front component linearly moves as the lens frame 
rotates. On the other hand, the rear component is driven by the cam which 
is engraved on the cam barrel as a guide portion to move the lens 
component. The cam is arranged so that the photographing distance U is 
varied as a continuous wedge shape between .infin. (the infinite distance) 
and N (the shortest distance). For example, when the focal length is set 
at W and focusing is conducted, the front and rear components move between 
W and 1 according to the photographing distance. When zooming is conducted 
to shift one step to the telephoto side, the front and rear components 
move to the position of M.sub.1 through the position of 1. As in the same 
manner, when zooming is conducted to shift two steps to the telephoto 
side, they move to the position of M.sub.2 through the positions of 1, 
M.sub.1, and 2. As explained, the zoom lens is configured so that the 
movements of the front and rear components alternatively conduct focusing 
and zooming; therefore, the mechanism for focusing and the mechanism for 
zooming are unitedly configured so that the number of parts is reduced and 
the zoom lens barrel can be configured small. 
The invention, according to the above-explained disclosure, is remarkably 
effective for the minimization of the zoom lens barrel and the camera, to 
which the invention is applied, has been brought into production. However, 
the zoom lens used in the product camera is of two magnifications. If the 
invention is applied to a camera having a zoom lens of a higher 
magnification than two magnifications, there are disadvantages in the 
configuration. 
It is necessary to provide more steps as a zoom lens of a higher 
magnification is used in order to use the characteristics of the high 
magnification ratio to advantage. An enlarged figure of zooming 
characteristics is shown in FIG. 2. When the focal length is set at 
M.sub.W and focusing is conducted in the same manner as the one previously 
explained, the rear component moves between 1 and 2. Next, when zooming is 
conducted to shift one step to the telephoto side, the rear component 
moves to 3 through 1 and 2 so that the focal length becomes M.sub.T. In 
this figure of zooming characteristics, the number of zooming steps is 
supposed to be increased by using a zoom lens of a high magnification 
ratio and the focal length M.sub.M is provided between M.sub.W and 
M.sub.T. If zooming is conducted to shift one step from M.sub.W, the rear 
component moves to 4 through 2 so that the focal length becomes M.sub.M. 
According to the figure, as it is easily understood, when the angle 
.theta..sub.1 between 2 and 3 is compared with the angle .theta..sub.2 
between 2 and 4, the angle .theta..sub.2 is larger than .theta..sub.1 ; 
therefore, the mechanical stress on the movement of the rear component is 
increased and the movement of the rear component may be difficult if the 
angle is too steep. 
Therefore, it is necessary to elongate the step interval in order to make 
the angle .theta..sub.2 smaller and the movement of the rear component 
easier. However, if the step interval is elongated in relation to the 
horizontal axis of the figure, a circumferential length of the cam barrel, 
which forms a cam, or a diameter of the cam barrel becomes larger; 
therefore, it results in a large lens barrel. 
SUMMARY OF THE INVENTION 
In accordance with above-mentioned problems, the present invention provides 
a zoom lens barrel in which: there is no enlargement of a circumferential 
length or a diameter of the cam barrel and there is no increase of 
mechanical stress even if a number of steps is increased as the 
magnification ratio is increased. 
The above-mentioned problems are solved by a zoom lens of a camera 
according to the present invention. The zoom lens includes: first and 
second lens components; a lens barrel having first and second guide 
portions; moving means to move the first and the second lens components, 
in which the first guide portion guides the movement of the first lens 
component and the second guide portion guides the movement of the second 
lens component. Further, in the second guide portion, it is configured 
that a focal point adjustment is conducted continuously from the first 
focal length to the second focal length, which is different from the first 
focal length. The moving means moves the first and the second lens 
components respectively along the first and the second guide portions so 
that the focal point adjustment is conducted at different focal lengths.

DETAILED DESCRIPTION OF THE INVENTION 
FIG. 15 is an outside view of a camera according to the present invention, 
and 100 shows an outside view of its zoom lens. Further, an example of the 
barrel of the zoom lens will be explained in detail by referring FIGS. 3 
through 5. 
FIG. 3 is a decomposed perspective view of the zoom lens barrel according 
to the present invention. FIG. 4 is a horizontal cross sectional view of 
the zoom lens barrel in which the upper half of the barrel shows the 
position of the lens at a wide angle focal length and the lower half of 
the barrel shows that at a telephoto focal length. FIG. 5 is a composition 
explanation of the fixing plate. 
1 is a fixed barrel which is uniformly fixed to the main body of a camera 
on the inner surface of fixed barrel 1, female helicoid 1a is provided and 
guide grooves 1b, for linear guide 21 which will be explained later, are 
provided at both right and left hand sides of female helicoid 1a in the 
manner that guide grooves 1b are across female helicoid 1a. 2 is a cam 
barrel in which male helicoid 2a, which couples with female helicoid 1a, 
and large gear 2b are uniformly provided on the outer surface, first 
helical guide portion or female helicoid 2c and second guide portion or 
cam groove 2d, which is an inner cam, are provided on the inner surface, 
and rib 2e is provided at the inner rear end. The outer diameter of large 
gear 2b is formed smaller than the inner diameter of male helicoid 2a so 
as to minimize the barrel size. If cam barrel 2 and large gear 2b are 
uniformly made of resin, it is possible to form it with a uniform mold of 
one way withdrawal without providing separate molds; therefore, a high 
precision part is produced with a simple configuration mold. 
3 is a front component sliding frame in which front component lens frame 4, 
for holding front component lens 5 of a positive composite focal length, 
is fixed with screws from its front side. The manufacturing size error of 
lens-related parts is compensated by arranging the fixing place of the 
screws. On the outside circumferential surface of front component sliding 
frame 3, there are provided male helicoid 3a, which is coupled with female 
helicoid 2c, guide groove 3b, for linear guide 21 which will be explained 
later, and a hole 3c for guide shaft 11 which will be explained later. 6 
is a rear component sliding frame in which rear component lens 7 of a 
negative composite focal length is held with the inner circumferential 
surface. The rear component sliding frame 6 is provided with guide groove 
6a, for linear guide 21 which will be explained later, and rear component 
cam pin 8 which is coupled with cam groove 2d, and guide shaft 11 is 
protruded on the front side. 13 is a shaft spring which is inserted into 
guide shaft 11. 12 is a E-shaped fixing ring for preventing shaft spring 
13 from being displaced. 21 is a linear guide which is slidablly coupled 
with guide groove 1b of fixed barrel 1 with protrusion 21a. Linear guide 
21 also rotatably supports driving gear 44, which will be explained later, 
with another protrusion 21b, and is slidably coupled with guide grooves 3b 
and 6a with arm 21c which is bent toward the front side. 22 is a guide 
fixing plate which couples cam barrel 2 to linear guide 21. 23 is a guide 
fixing shaft which couples linear guide 21 to guide fixing plate 22 and 
holds cam barrel 2 with rib 2e. 24 is a fixing screw for fixing linear 
guide 21 to guide fixing shaft 23. 
31 is a barrel driving motor in which propeller 33 is attached to shaft 32 
so that continuous pulse signals, indicating the movement of front 
component lens 5 and rear component lens 7, are obtained from 
photo-interrupter 34. 35 is a pinion directly connected to the motor. The 
rotation of barrel driving motor 31 is transferred to the fifth gear, 
having a long body in an optical axis direction, through first gear 36, 
second gear 37, third gear 38, and fourth gear 42, and the rotation is 
further transferred to the driving gear 44. Driving gear 44 is coupled 
with large gear 2b of cam barrel 2. Propeller 40 is attached to shaft 39 
of third gear 38, and discontinuous pulse signals, indicating the movement 
of front component lens 5 and rear component lens 7, are obtained from 
photo-interrupter 41. The interval of the discontinuous pulse signals is 
set longer than that of the pulse signals generated from photo-interrupter 
34. 
52 is a shutter and 53 is a shutter driving motor which is mounted on front 
component sliding frame 3. 51 is FPC circuit board which connects shutter 
driving motor 53 to printed circuit board 54, on which electric parts of 
the main body are assembled. FPC circuit board 51 is connected with 
shutter driving motor 53, wired to a back side of the camera through a 
space between arm 21c of linear guide 21 and the inner circumferential 
surface of cam barrel 2, returned at the back side end of cam barrel 2, 
and further wired to a front side of the camera through a space between 
the outer circumferential surface of cam barrel 2 and fixed barrel 1. Hole 
1c is provided on fixed barrel 1 at a position where it is closer to the 
front side of the camera than the end side of cam barrel 2 when cam barrel 
2 is moved forward to the maximum position. FPC circuit board 51 is 
connected to printed circuit board 54 at the main body side by wired 
through hole 1c and on the outer circumferential surface of fixed barrel 
1. 51a shows FPC circuit board 51 at the position that the lens barrel is 
shrunk to the minimum length. 61 is an outside shape of the camera, 
decoration ring 62 is attached to cam barrel 2, and front barrel 63 is 
attached to front component sliding frame 3. 
Next, the basic motion of the zoom lens barrel will be explained. 
In the zoom lens barrel according of the present example, there are 
provided plural portions in which suspension control of lens driving for 
focusing is conducted within a zooming portion in prior techniques. Front 
component lens 5 and rear component lens 7 are driven by the same 
mechanism, and thereby zooming and focusing are conducted. Therefore, in 
case that zooming or focusing is conducted, driving motor 31 drives in 
response to the signals not shown, the driving force is transferred to 
fifth gear 43 through the chain of gears 35, 36, 37, 38, and 42, and fifth 
gear 43 transfers the driving force to driving gear 44 which is furnished 
with linear guide 21. Driving gear 44 is coupled with large gear 2b so as 
to rotate cam barrel 2; thereby, cam barrel 2, which is coupled with fixed 
barrel 1 through a helicoid portion, is moved in an optical axis 
direction. Here, cam barrel 2 is moved forward or backward in the optical 
axis direction depending on the rotation direction of driving motor 31. On 
rib 2e of cam barrel 2, linear guide 21 is uniformly attached by guide 
fixing plate 22, guide fixing shaft 23, and fixing screw 24; however, 
linear guide 21 is prevented from being rotated by protrusions 21a at both 
sides and guide groove 1b of fixed barrel 1 so as to be moved only in the 
optical axis direction. In the same manner, front component sliding frame 
3 is prevented from being rotated by guide groove 3b and arm 21c of linear 
guide 21. Further, rear component sliding frame 6 is also prevented from 
being rotated as well as front component sliding frame 3 because guide 
shaft 11, which is protruded from rear component sliding frame 6, goes 
through front component sliding frame 3. Therefore, when cam barrel 2 is 
rotated, front component sliding frame 3, which is coupled with cam barrel 
2 through a helicoid portion, and rear component sliding frame 6, which is 
coupled with cam barrel 2 through a cam are moved forward or backward in 
the optical axis direction. 
Cam groove 2d of cam barrel 2 is formed in the manner that a groove, having 
an angle smaller than a leading angle of female helicoid 2c, and a groove, 
having an angle larger than the leading angle, are alternatively provided 
so that rear component sliding frame 6 moves in a discontinuous 
wedge-shaped path while front component sliding frame 3 moves in a linear 
path by helicoid. This will be explained in detail later with a figure of 
zooming lines; however in summary, driving for focusing and zooming is 
realized by the same mechanism because plural focusing portions are 
provided within a zooming portion. 
With the movement of cam barrel 2, the coupling position of fifth gear 43 
and driving gear 44 is moved in the optical direction; however, coupling 
of the two is kept no matter how much cam barrel 2 moves since fifth gear 
43 has a long body in the optical direction. Further, rib 2e of cam barrel 
2 has a function of supporting cam barrel 2, in rotation, with the inner 
circumferential surface of rib 2e in addition to a function of preventing 
linear guide 21 from its removal by a thrust. Therefore, rib 2e prevents 
cam barrel 2 from being deformed when cam barrel 2 transfers driving 
force. 
The condition, that linear guide 21 and guide fixing plate 22 are 
assembled, will be explained by referring FIGS. 5(A) and 5(B). In FIG. 
5(A), for effective assembling, two pieces of fixing plates 22 are 
temporally fixed to linear guide 21 respectively with fixing screws 24. 
Linear guide 21 is assembled into cam barrel 2 from the back side of the 
camera; then, fixing plates 22 are rotated on fixing screws 24 as axes in 
a clockwise direction. Fixing plates 22 are coupled with linear guide 21 
with six fixing screws 24 and 25 as shown in FIG. 5(B). In this manner, it 
is possible that linear guide 21 functions, as a single part, to guide cam 
barrel 2 and front component sliding frame 3; therefore, linearity of 
front component sliding frame 3 is high and effectivity of driving force 
for linear movement is high. 
FIG. 6 is a block diagram of the present example and explains the motions 
of a photographic lens with the figure of zooming lines in FIG. 7. 
FIG. 7 shows zooming lines in which focal length variation is divided to 
eight steps, horizontal axis shows the variation of focal length, and 
vertical axis shows the movement of the front and rear components of the 
photographic lens in their optical axis direction. The front component 
moves linearly by helicoid drive, the rear component moves repeatedly 
alternatively in a direction to be further from the front component and in 
a direction to be closer to the front component by the cam of cam barrel 
2. 
For example, in case that focal length is W, CPU 70 detects pulse signals 
generated from photo-interrupter 41 by the predetermined rotation of 
barrel driving motor 31 and CPU 70 stops the front and rear component, 
which are moving from the position of the focal length W, at the position 
of the focal length M.sub.1 when zoom button S.sub.T is pressed and one 
step of zooming is conducted to the telephoto side. If one more step of 
zooming is conducted, the position of focal length is shifted from M.sub.1 
to M.sub.2. 
Hereinafter, the motion in zooming will be explained in detail. 
When signal S.sub.T is inputted to CPU 70 by pressing zooming button 
S.sub.T at the position of focal length W, CPU 70 controls barrel driving 
motor 31 to rotate in the normal direction so that front component lens 5 
and rear component lens 7 are moved by the chain of gears 35 through 44 
and propeller 40 is rotated. If signals from photo-interrupter 41 to CPU 
70 vary when propeller 40 runs through photo-interrupter 41, CPU 70 
controls barrel driving motor 31 to stop its rotation so as to stop front 
component lens 5 and rear component lens 7 at the position of focal length 
M.sub.1. 
If zooming button S.sub.T is further pressed, it is possible to stop the 
lenses at the position of one of the focal lengths M.sub.2 through T as in 
the same manner explained above. 
When lens components are at the position of one of the focal length M.sub.1 
through T and signal S.sub.W is inputted to CPU 70 by pressing zooming 
button S.sub.W, CPU 70 controls barrel driving motor 31 to rotate in the 
reverse direction. As in the same manner explained above, when signals 
from photo-interrupter 41 to CPU 70 vary, it is possible that CPU 70 
controls barrel driving motor 31 to stop its rotation so as to stop the 
lenses at the position of one of the focal lengths W through M.sub.6. 
As explained above, it is possible to conduct zooming of eight steps 
between the focal lengths of W and T in this example. 
On the other hand, when the focal length is W for example, ranging 
information, generated from auto-focusing circuit (not shown), is inputted 
into CPU 70 when switches S.sub.1 and S.sub.2 are turned on by pressing a 
release button. CPU 70 sets a predetermined number of pulses according to 
the ranging information and the zooming position (W, M.sub.1 through 
M.sub.6, and T) CPU 70 controls barrel driving motor 31 to rotate in the 
normal direction, to drive front component lens 5 and rear component lens 
7 through the chain of gears 35 through 44, and to rotate propeller 33 so 
that pulse signals are inputted into CPU 70 from photo-interrupter 34 and 
the pulse signals are counted. When the pulse count achieves to the 
predetermined pulse number, barrel driving motor 31 is stopped and 
focusing is conducted. Then, shutter (not shown) is driven and exposure to 
a photographic film is conducted. After the exposure is finished, barrel 
driving motor 31 is rotated in the reverse direction, the predetermined 
pulse number is counted, and barrel driving motor 31 is stopped when the 
lenses are returned to the original zooming position. 
When the focal length is M.sub.1, focusing, by which focal point can be 
between the minimum focal distance and the infinity, is conducted while 
the front and rear components are moved in the portion between M.sub.1 and 
M.sub.2. 
As explained above, focusing in the present example is conducted by one way 
rotation of barrel driving motor 31 at any of the portions. This is 
because the magnification change of a finder is synchronized with that of 
photographing lens and back-lashes of cams and driving gears are absorbed. 
The rotation direction of motor 31 for focusing can be one way rotation in 
the opposite direction of that of this example in any of the portions. 
Therefore, in this figure of zooming lines, zooming is performed by 
repeatedly changing the focal length step-wise between a focal length with 
the focus of the infinity and a focal length with the focus of the minimum 
focal distance so that focusing is conducted in all steps of the zooming 
portion between W and T. 
Consequently, when the zooming lines of FIG. 7 are compared with those of 
FIG. 1 as conventional techniques, while there are four steps of focal 
lengths in FIG. 1, there are eight steps, which is increased (doubled) 
from the conventional techniques, of focal lengths in FIG. 7 of this 
example. However, the moving angle of the rear component does not become 
steeper than that of conventional techniques and smooth movement of the 
rear component can be performed. 
In FIG. 7, the position of rear component lens 7 at the closest focal 
distance (N), which is moved from the position of W by focusing, is 
identical to the position of rear component lens 7 at the position of 
M.sub.1, which is moved from the position of W by zooming; however, it is 
not necessary to make them identical. The case that the two positions are 
identical and the other case that they are not identical will be explained 
by referring FIGS. 8(A) and 8(B). 
FIGS. 8(A) and 8(B) are the figures enlarging the cam shape of rear 
component lens 7 of FIG. 7 around M.sub.1. FIG. 8(A) is the example that 
the position of rear component lens 7 at the closest focal distance (N), 
which is moved from the position of W by focusing, is identical to the 
position of rear component lens 7 at the position of M.sub.1, which is 
moved from the position of W by zooming; and FIG. 8(B) is the example that 
the two positions are not identical. 
It is obvious from the figures, the case in FIG. 8(B) realizes smooth cam 
curves; therefore, the mechanical stress at the lens movement can be less 
than that in the case of FIG. 8(A). 
The facts explained above are also true in the positions of other focal 
lengths. Further, they are true in the example which will be explained 
hereinafter. 
In the example of FIG. 7, focusing is available from the closest focal 
distance to infinity; however, it is not necessary to arrange focusing 
available from the closest focal distance to infinity. It is possible that 
the cam shape is designed to control lens movement so as to perform 
focusing within a limited distance. 
Further, if the cam shape is designed to extend to the point exceeding the 
infinity position, which is fixed by the design reference of the lens, it 
becomes easier to compensate the discrepancy of focal point, which is 
created by the inconsistency of lens production, by using the extended 
portion as a cam for focal point adjustment. Therefore, in the example of 
the zoom lens barrel which is explained above, rear component lens 7 does 
not simply perform focusing and zooming but performs a focal point 
adjustment for picture-taking, which includes focusing and product 
dispersion compensation, and zooming. In other words, the zoom lens barrel 
of the present invention is capable of continuously performing the focal 
point adjustment between two different focal lengths by using the cam 
explained above. 
FIG. 9 is the figure of zooming lines which divides the range of the focal 
lengths of FIG. 1 to four steps. However, the angle of the moving path of 
rear component is rather smoother than that of FIG. 1 because its 
configuration is the same as that of FIG. 7; therefore, cam barrel 2 can 
move smoothly. 
The above-explained examples are zoom lenses which are configured to move 
two components of front and rear components. However, if a zoom lens is 
designed to have a high magnification ratio, it becomes necessary to have 
three components move. The figure of zooming lines of a zoom lens, which 
moves three components, will be explained hereinafter. 
FIG. 10 is the figure of zooming lines which divides the range of the focal 
lengths, of conventional techniques such as in FIG. 1, to four steps. In 
FIG. 10, focusing portions and zooming portions are provided separately. 
However, as a difference from FIG. 1, FIG. 9 shows a zoom lens which moves 
three component lenses wherein the first and third components move 
linearly by the motions of helicoids each having respective leading angle, 
and the second component moves in a path of continuous wedges by a cam. 
FIG. 11 is the figure of zooming lines of a zoom lens having three 
components in which focusing portions are provided in zooming portions. 
Although there are eight steps provided in the lines, the moving angle of 
the second component is almost the same as that of the second component 
moving in the zooming lines of four steps in FIG. 10 as explained above. 
Further, FIG. 12 is the figure of zooming lines which divides the focal 
lengths to four steps which is the same as that in FIG. 10. In FIG. 12, it 
is configured to set focusing portions are continuously provided in 
zooming portions; therefore, the moving angle of the second component is 
smoother than that of the second component in FIG. 10. 
In FIGS. 11 and 12, the rear component moves in a wedge-shaped path in 
which the peak of the wedge corresponds to the closest focal distance and 
the ravine of the wedge corresponds to the infinity. However, it is also 
possible to configure the lens so that the peak corresponds to the 
infinity and the ravine corresponds to the closest focal distance. 
Further, in the above-explained case of the zoom lens having three 
components, it is possible to configure the lens barrel as in the same 
manner of FIGS. 3 and 4. In other words, front component lens 5 and rear 
component lens 7 are supposed respectively as the first and second 
component lenses, the third component sliding frame for supporting the 
third component lens is arranged at the rear side of rear component 
sliding frame 6, the third component sliding frame is coupled with cam 
barrel 2 through helicoid portion which has a smaller leading angle than 
that of front component sliding frame 3, and the third component sliding 
frame is prevented from being rotated by linear guide 21. 
Next, the relationship between the zoom lens barrel and the range finder in 
this example will be explained. 
As explained above, in the step zooming method, the focal length of the 
lens varies step-wise; therefore, the magnification ratio of the range 
finder also varies step-wise. FIG. 13 shows one example of the method in 
which the relationship between the figure of zooming lines and the 
magnification change of the range finder is explained. In FIG. 13, the 
view angle of the range finder is set at that of distance A which is at 
the center between infinity (.infin.) and the closest focal distance (N). 
Therefore, the view angle of the range finder, when the focal length is 
set to W and release of the shutter is not yet executed, is set to that at 
position a. In the same manner, when it is set to M.sub.1, the view angle 
is set to that at position b; when it is set to M.sub.8, the view angle is 
set to that at position c; and when it is set to T, the view angle is set 
to that at position d. 
However, there are problems in the figure of zooming lines such as FIG. 13. 
The problems will be explained hereinafter. 
In FIG. 13, the minimum focal length W is set to make a focal point at the 
closest focal distance (N), and the maximum focal length T is set to make 
a focal point at infinity (.infin.). When the value of the focal length is 
displayed on a camera or catalog, the focal length, which is measured at 
the infinite point as defined in JIS (Japanese Industrial Standard), is 
normally indicated. Therefore, the focal lengths between M.sub.1 and T are 
indicated officially. However, the portion between W and M.sub.1 and T and 
T.sub.N are also the ranges in use, and the cam barrel needs to be rotated 
more than the officially-indicated range of the focal lengths. The length 
of the cam barrel in its circumferential direction or its outer diameter 
needs to be formed long enough for the rotation. 
Since the range finder is also in the same condition explained above as it 
is expected easily from FIG. 13, the range of magnification variation of 
the range finder needs to be wider for .alpha. and .beta. portions than 
that corresponding to the officially-written range of focal lengths. 
Therefore, the moving range of the range finder becomes large, the 
magnification ratio of the range finder becomes large, and it becomes 
difficult to assure a range finder performance. Further, the movement of 
magnification mechanisms of the range finder gains, mechanical loads gain, 
and the magnification mechanisms of the range finder becomes large. 
In order to solve the above problems, as shown in the figure of ideal 
zooming lines in FIG. 14, the position of the minimum focal length (W) of 
the zooming range is set to the infinity and the position of the maximum 
focal length (T) is set to the shortest focal distance. Of course, even 
one of the position of the minimum focal length or the position of the 
maximum focal length is set as above, the explained effects can be 
obtained. 
By the settings explained above, the official indication of the focal 
length is shifted from W to T.sub.F, the cam barrel can be configured to 
move in the range identical to that of the focal lengths of the official 
indication. If the range finder is designed to have a magnification 
variation between a and b, the range of the magnification variation can be 
set narrower for .alpha. and .beta. portions than that corresponding to 
the officially-written range of focal lengths. 
According to the zoom lens barrel of the camera according to the present 
invention, even if the number of zooming steps is increased by using a 
high magnification ratio zoom lens, the angle of cam can be designed 
smooth so that mechanical load can be decreased without increasing the 
diameter of the lens barrel under the condition that the magnification 
ratio, the number of zooming steps, and the diameter of the lens barrel 
are the same as those of the lens barrel according to the conventional 
step zooming method. 
Further, the magnification ratio of the range finder can be small, a range 
finder performance can be assured easily, and the movement of 
magnification mechanisms of the range finder can be minimized; therefore, 
the mechanical load of the magnification mechanisms can be minimized, and 
the size of the zoom lens barrel can be minimized. 
Furthermore, focusing control can be simple and backlashes of cams and 
driving gears can be absorbed; therefore, the focusing precision can be 
enhanced.