Optical apparatus

An optical apparatus is provided with a main operation member arranged to permit both a rectilinear operation and a rotational operation, a subordinate operation member arranged to be operated to vary an operating force required for operating the main operation member to a greater extent for the rectilinear operation than for the rotational operation, a first optical adjustment mechanism arranged to perform a first optical adjusting action in association with the rectilinear operation of the main operation member, and a second optical adjustment mechanism arranged to perform a second optical adjusting action in association with the rotational operation of the main operation member.

BACKGROUND OF THE INVENTION 
1. Field of the Invention 
This invention relates to an optical apparatus arranged to permit both a 
rotational operation and a rectilinear operation with one operation 
member. 
2. Description of the Related Art 
Optical apparatuses of the kind having a relatively heavy weight imposed on 
an operation member have heretofore been arranged as follows: 
(i) A rectilinear operating force required for operating the operation 
member is set at a large value for the purpose of preventing the operation 
member from slipping down even in cases where the optical axis of the 
optical apparatus is in the direction of gravity. 
(ii) In the case of a macro lens or the like, the lens is to be 
rotationally operated by a helicoid arrangement or the like, by omitting 
the rectilinear operation of the operation member. 
However, with the rectilinear operating force required for operating the 
operation member set at the large value as mentioned in Para. (i) above, a 
larger operating force is necessary in operating the optical apparatus in 
a horizontal posture. Further, the helicoid arrangement mentioned in Para. 
(ii) makes the operation troublesome in cases where the operation member 
must be drawn out to a great extent. 
Any excessively poor operability necessitating a correction of an operating 
force has seldom been noted among optical apparatuses such as lens 
barrels. However, some of zoom lens barrels of today consist of many lens 
groups, which are required to make complex movements within the lens 
barrels. Therefore, it has become desirable for a zoom lens barrel of this 
type to have the operating force to be finely adjustable so as to 
eliminate the fluctuations of the operating force. 
Further, in a case where it is preferable to have the telephoto lens or the 
like focused slowly on an object located at a far distance and focused 
quickly on an object located at a near distance, it is also desirous to 
finely adjust the operating force by increasing the operating force for 
the far distance. 
SUMMARY OF THE INVENTION 
It is one aspect of this invention to provide an optical apparatus having a 
main operation member arranged to permit a rectilinear operation for 
giving a first adjusting action and a rotational operation for giving a 
second adjusting action and a subordinate operation member arranged to 
vary an operating force required for the rectilinear operation on the main 
operation member. 
The above and other aspects and features of this invention will become 
apparent from the following detailed description of embodiments thereof 
taken in connection with the accompanying drawings.

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS 
A first embodiment of this invention is arranged as shown in FIGS. 1 to 10. 
FIG. 1 is a sectional view showing a telephoto end state of a lens barrel 
which is arranged as the first embodiment. FIG. 2 is a sectional view 
showing a wide-angle end state of the same lens barrel. FIG. 3 is a 
development view of a cam tube. FIG. 4 is a development view of a fixed 
tube. FIG. 5 is a development view of a fitting engagement part of a 
fifth-lens-group tube. FIG. 6 is a development view of a first-lens-group 
tube. FIG. 7 is a development view of a cam tube for a hood. FIG. 8 is a 
development view of a focus interlocking tube. FIG. 9 is a detailed view 
of an operating force adjustment mechanism. FIG. 10 is a diagram showing 
the zooming movement of each lens group. 
Referring to FIGS. 1 to 10, the lens barrel includes a first lens group I, 
a second lens group II, a third lens group III, a fourth lens group IV, a 
fifth lens group V and a sixth lens group VI. In FIG. 1, reference symbol 
A denotes a filter which is detachably attached to the lens barrel. 
In these figures, reference numeral 1 denotes a fixed tube. As shown in 
FIG. 4, the fixed tube 1 has three outer rectilinear grooves 1a, three 
inner rectilinear grooves 1b and three second-lens-group holding holes 1c. 
These three grooves or holes are equally spaced. A small diameter part 1h 
of the fixed tube 1 has a circumferential hole 1i. 
Reference numeral 2 denotes a mount. The mount 2 is secured to the fixed 
tube 1 with screws 2a and is arranged to hold a back cover 3. A stopper 
pin 2b for mounting and demounting is provided on the mount 2. 
The fixed tube 1 has a large diameter part 1e. The large diameter part 1e 
has a distance window part 4. A stepped part 1f and a fitting engagement 
part 1g are formed inside the peripheral part of the large diameter part 
1e. A rotary tube 5 is rotatably carried by the stepped part 1f and the 
fitting engagement part 1g. 
Pins 5a are screwed into the fore end of the rotary tube 5 from outside at 
two opposite points. Three protruding parts 5b protrude toward a rear end 
inner circumferential part of the rotary tube 5. Reference numeral 6 
denotes a focusing unit. A body 6a of the focusing unit 6 is secured to 
the fixed tube 1 with screws 6b. Reference numeral 6c denotes a known 
ultrasonic motor. 
Reference numeral 6d denotes an output member. Roller members 6e are 
rotatably carried by shaft screws 6f at three evenly spaced parts of the 
outer circumference of a roller ring 6g. The roller ring 6g is fitted into 
the body 6a of the focusing unit 6 on its inner diameter side in such a 
way as to be rotatably carried by the body 6a of the focusing unit 6. A 
distance graduation 6i is provided along the outer circumference of the 
roller ring 6g. 
An intermediate member 6h is fitted in and held by the body 6a of the 
focusing unit 6. The intermediate member 6h has three fitting longitudinal 
groove parts 6j on its outer circumferential side and is arranged to be 
rotatable together with the above-stated rotary tube 5 with the protruding 
parts 5b which are formed on the rear end inner circumferential part of 
the rotary tube 5 fitted into the fitting longitudinal groove parts 6j. 
A pressing member 6k which is provided for pressing the ultrasonic motor 6c 
is arranged within the body 6a of the focusing unit 6 to press the 
ultrasonic motor 6c, the output member 6d, the roller member 6e and the 
intermediate member 6h in turn at the same time. 
A focus key 7 is secured with a screw 7a to the roller ring 6g within the 
focusing unit 6. The focus key 7 has a fitting longitudinal groove part 
7b. A focus interlocking tube 8 is fitted into the fixed tube 1 and, as 
shown in FIG. 8, is provided with a longitudinal groove 8b formed in its 
inner circumferential face. A pin 8a is screwed into the outer 
circumferential face of the focus interlocking tube 8 and is arranged to 
have its thrust restricted by the circumferential hole 1i of the small 
diameter part 1h of the fixed tube 1 and to have its rotation restricted 
by the fitting longitudinal groove part 7b of the above-stated focus key 
7. 
A first lens group tube 9 is arranged to carry the first lens group I and 
to fittingly engage the fixed tube 1 at its fitting engagement part 9a 
which is located at the rear end inner part of the first-lens-group tube 
9. Three rectilinear keys 9b are secured to the rear end inner part of the 
first-lens-group tube 9 with screws 9c as shown in FIG. 6. The 
first-lens-group tube 9 is carried in such a way as to be rectilinearly 
movable relative to the fixed tube 1 with the three rectilinear keys 9b 
respectively fitted into the three rectilinear grooves 1a formed in the 
outer side of the fixed tube 1. 
Three cam slots 9d are formed and evenly spaced in the front half part of 
the first-lens-group tube 9. A peripheral fitting part of the 
first-lens-group tube 9 fittingly engages and carries a cam tube 10 which 
is provided for a hood. The first-lens-group tube 9 is thus arranged to 
carry the cam tube 10 for the hood in such a way as to allow the cam tube 
10 to rotate in a set position relative to the first-lens-group tube 9 by 
restricting the thrust of the cam tube 10. 
Three dowels 9e are evenly spaced and disposed on the front peripheral part 
of the first-lens-group tube 9. A flange part 9f extends from the 
first-lens-group tube 9 toward its outer circumferential side. The flange 
part 9f has a fitting engagement part 9g which is formed in the peripheral 
part of the flange part 9f. 
As shown in FIG. 7, the cam tube 10 for the hood is provided with three 
rectilinear slots 10a and three cam slots 10b which are evenly spaced. 
An operation ring 11 has a fitting engagement receiving part 11a which is 
formed in the middle part on the inner side of the operation ring 11. The 
fitting engagement receiving part 11a is arranged to fittingly engage the 
fitting engagement part 9g of the flange part 9f extending toward the 
outer circumferential side of the first-lens-group tube 9 and to restrict 
the thrust of the first-lens-group tube 9. The first-lens-group tube 9 
thus can be moved back and forth by the operation ring 11. 
Further, longitudinal grooves 11b are formed in two opposite parts on the 
inner side of the operation ring 11. The two longitudinal grooves 11b 
fittingly engage two pins 5a which are screwed from outside into the fore 
end of the rotary tube 5. By virtue of this fitting engagement, the 
operating force of the operation ring 11 can be always stably transmitted 
through the rotary tube 5 to the intermediate member 6h included in the 
focusing unit 6 even when the operation ring 11 is moved back and forth by 
a rotational operation performed on the operation ring 11. 
A filter frame 12 is provided with a filter thread 12a in its fore end 
inner circumferential part for screwing a filter A into the filter frame 
12. The filter frame 12 is provided further with a fitting engagement part 
12b in its rear end inner circumferential part. The fitting engagement 
part 12b has three dowels 12c evenly spaced on the inner side thereof. 
Three longitudinal grooves 12d are formed in three evenly spaced 
intermediate parts on the inner side of the filter frame 12. The position 
of the filter frame 12 is restricted with the longitudinal grooves 12d 
fitted on the dowels 9e provided on the front peripheral part of the 
first-lens-group tube 9. A fitting engagement part 12b which is located in 
the rear end inner circumferential part of the filter frame 12 is fitted 
on the periphery of the cam tube 10 for the hood. In addition to that, the 
three dowels 12c which are on the inner side of the fitting engagement 
part 12b in the rear end inner circumferential part of the filter frame 12 
are fitted in the cam slots 10b of the cam tube 10 for the hood. 
Therefore, when the cam tube 10 for the hood is rotated, the filter frame 
12 is rectilinearly drawn out relative to the first lens group I which is 
carried by the first-lens-group tube 9. 
As shown in FIG. 3, a cam tube 13 has a large diameter part 13a. The large 
diameter part 13a is fitted into the inner side of the fixed tube 1 and is 
carried by the fixed tube 1. Further, as shown in FIG. 3, the large 
diameter part 13a is provided with three fixed-pin cams 13c, three 
third-lens-group cams 13d, three fourth-lens-group cams 13e and three 
fifth-lens-group cams 13f. The three cams of each of the cam groups are 
evenly spaced. 
A small diameter part 13b of the cam tube 13 is provided with a focus cam 
13g. The diameter of the cam tube 13 is increased by one step for its 
front end peripheral part. A fitting engagement part 13h is arranged at 
the front end peripheral part of the cam tube 13 to have fitting 
engagement pins 13i screwed into three parts which are evenly spaced. 
The fitting engagement pins 13i engage the cam slots 9d of the 
first-lens-group tube 9 by piercing them and, at the same time, engage the 
rectilinear slots 10a of the cam tube 10 for the hood. Therefore, the 
amount of rotation of the cam tube 13 restricts the amount of rotation of 
the cam tube 10 for the hood and thus determines the drawn out amount of 
the filter frame 12. 
A second-lens-group tube 14 carries the second lens group II and has a 
fitting engagement part 14a on its periphery. The fitting engagement part 
14a has three fixed pins 14b which are evenly spaced. 
The three fixed pins 14b on the fitting engagement part 14a respectively 
engage three fixed-pin cams 13c which are formed in the large diameter 
part 13a of the cam tube 13 and, at the same time, also engage the 
second-lens-group holding holes 1c provided in the fixed tube 1. The 
second-lens-group tube 14 is, therefore, stationary relative to the fixed 
tube 1. 
The rotating position and the thrust (rectilinear) position of the cam tube 
13 are determined by two position determining factors including the shapes 
of the fixed-pin cams 13c formed in the large diameter part 13a of the cam 
tube 13 and the shapes of the cam slots 9d formed in the front half of the 
first-lens-group tube 9. The cam tube 13 can be drawn out, with a 
rotational motion, from its wide-angle end state (position) shown in FIG. 
2 to its telephoto end state shown in FIG. 1 by moving the operation ring 
11 forward. 
A moving diaphragm 13j is secured to the fore end face of the cam tube 13. 
A fifth-lens-group tube 15 carries the fifth lens group V and has a 
fitting engagement part 15a. The fifth-lens-group tube 15 is thus arranged 
to be carried by the cam tube 13 with the fitting engagement part 15a 
engaging the large diameter part 13a of the cam tube 13. Further, as shown 
in FIG. 5, the fifth-lens-group tube 15 is provided with three 
fifth-lens-group pins 15b which are screwed into the fitting engagement 
part 15a, three third-lens-group slots 15c and three fourth-lens-group 
slots 15d, which are evenly spaced. Since the fifth-lens-group pins 15b 
which are screwed into the fitting engagement part 15a are engaging the 
fifth-lens-group cams 13f formed in the large diameter part 13a of the cam 
tube 13 and are also engaging, at the same time, the rectilinear grooves 
1b provided in the inner face of the fixed tube 1, the fifth-lens-group 
tube 15 is movable for zooming as desired by the rotational drawing-out 
action of the cam tube 13. 
Reference numeral 16 denotes a known electromagnetic diaphragm unit. 
A third-lens-group tube 17 carries the third lens group III and the 
electromagnetic diaphragm unit 16. The third-lens-group tube 17 fittingly 
engages the fifth-lens-group tube 15 to be carried thereby. 
Third-lens-group pins 17a which are screwed into the fitting engagement 
face of the third-lens-group tube 17 engage the third-lens-group slots 15c 
provided in the fitting engagement part 15a of the fifth-lens-group tube 
15 and also engage third-lens-group cams 13d formed in the large diameter 
part 13a of the cam tube 13. This arrangement permits zooming to be 
carried out as desired by rectilinearly moving the third-lens-group tube 
17 through the rotational drawing-out action of the cam tube 13. 
A fourth-lens-group tube 18 carries the fourth lens group IV and fittingly 
engages the fifth-lens-group tube 15 to be carried thereby. 
Fourth-lens-group pins 18a are screwed into the fitting engagement face of 
the fourth-lens-group tube 18. The fourth-lens-group pins 18a engage the 
fourth-lens-group slots 15d which are formed in the fitting engagement 
part 15a of the fifth-lens-group tube 15 and, at the same time, also 
engage the fourth-lens-group cams 13e which are formed in the large 
diameter part 13a of the cam tube 13. Therefore, the fourth-lens-group 
tube 18 is movable at the same time as the third-lens-group tube 17 for 
zooming as desired by the rotational drawing-out action of the cam tube 
13. 
A sixth-lens-group tube 19 carries the sixth lens group VI and fittingly 
engages the inner face of the small diameter part 13b of the cam tube 13 
to be carried thereby. A sixth-lens-group pin 19a is screwed into the 
fitting engagement part of the sixth-lens-group tube 19. The 
sixth-lens-group pin 19a engages the focus cam 13g formed in the small 
diameter part 13b of the cam tube 13 and also engages the longitudinal 
groove 8b formed in the inner circumferential face of the focus 
interlocking tube 8 mentioned in the foregoing. The sixth-lens-group tube 
19 is thus positioned through the sixth-lens-group pin 19a. 
Referring to FIG. 9, a female thread 20a formed in the fore end part of a 
subordinate operation ring 20 engages a male thread 11c formed in the rear 
end outer circumferential part of the operation ring 11 which serves as a 
main operation ring. The subordinate operation ring 20 has an inner flange 
part 20b at its rear end part. Between the rear end part 11d of the 
operation ring 11 and the inner flange part 20b of the subordinate 
operation ring 20, there are provided, in order from the front side of the 
optical axis, balls 21a, a tapered block 22 which has a pressed contact 
face 22a for pressed contact with the balls 21a and a conical slanting 
face 22b, a C band 23 which has a conical slanting face 23a for pressed 
contact with the conical slanting face 22b, a conical slanting face 23a' 
located on the rear end side of the C band 23, an elastic sliding member 
24 applied to the inner diameter side of the C band 23 and a cutout part 
in the direction of circumference, a tapered block 22' which has a conical 
slanting face 22b' for pressed contact with the conical slanting face 23a' 
of the C band 23 and a pressed contact face 22a', and balls 21a' arranged 
to be in pressed contact with the pressed contact face 22a' of the tapered 
block 22'. When the subordinate operation ring 20 is screwed into the 
operation ring 11, pressure is applied simultaneously to these parts in 
the direction of the optical axis. 
As apparent from the arrangement shown in FIG. 9, the C band 23 which has 
the front and rear conical slanting faces 23a and 23a' is arranged to be 
contractive on the inner diameter side. Therefore, the elastic sliding 
member 24, which is applied to the inner diameter side of the C band 23, 
tightly pushes the large diameter part 1e of the fixed tube 1. As a 
result, the operation ring 11 becomes not readily movable relative to the 
fixed tube 1. An operating force required for a rectilinear operation on 
the operation ring 11 thus comes to increase. On the other hand, the balls 
21a and 21a' act to allow the operation ring 11 to be always rotatable 
relative to the fixed tube 1. Therefore, an operating force required for a 
rotational operation on the operation ring 11 does not vary much. 
FIG. 10 is a diagram showing the movement of each lens group taking place 
at the time of zooming. The first lens group I is drawn out in a nonlinear 
manner. The second lens group II is stationary. The third lens group III 
to the sixth lens group VI are respectively drawn out in nonlinear 
manners. 
FIGS. 11 to 15 show a second embodiment of this invention. FIG. 11 is a 
sectional view showing a lens barrel in a telephoto end state. FIG. 12 is 
a sectional view showing the lens barrel in a wide-angle end state. FIG. 
13 is a development view showing a first-lens-group tube and a cam tube. 
FIG. 14 is a diagram showing the movement of each lens group taking place 
at the time of zooming. FIG. 15 is an enlarged view showing a key and a 
spring part. 
In FIGS. 11 to 15, reference numeral I denotes a first lens group. 
Reference numeral II denotes a second lens group. Reference numeral III 
denotes a third lens group. Reference numeral IV denotes a fourth lens 
group. Reference numeral V denotes a fifth lens group. 
Referring to these figures, a fixed tube 101 has three outer rectilinear 
grooves 101a which are evenly spaced, three rectilinear slots 101b which 
are evenly spaced and three second-lens-group holding holes 101c which are 
also evenly spaced. The width of each of the outer rectilinear grooves 
101a varies with its position. The fixed tube 101 is provided further with 
an outer fitting engagement part 101d and an inner fitting engagement part 
101e. A mount 102 which is secured to the fixed tube 101 with screws 102a 
is arranged to carry a back cover 103 and is provided with a stopper pin 
102b for mounting and demounting. A first-lens-group tube 104 has three 
keys 104a which are disposed in a rear end part and are evenly spaced. The 
first-lens-group tube 104 further has, on its inner side, a fitting 
engagement part 104b and three cam grooves 104d which are evenly spaced. 
As shown in FIG. 15, each of the keys 104a fittingly engages the outer 
rectilinear groove 101a of the fixed tube 101 and, at the same time, has 
leaf springs 106 fitted therein in such a manner that the pressed contact 
force of the key 104a varies according to a change of the groove width of 
the outer rectilinear groove 101a. Therefore, fluctuations in the force of 
a zooming operation, etc., can be absorbed by suitably setting the groove 
width of the outer rectilinear grooves 101a of the fixed tube 101. The 
operating force also can be controlled in such a way as to intentionally 
change it. 
Further, the inner fitting engagement part 104b of the first-lens-group 
tube 104 fittingly engages the outer fitting engagement part 110d of the 
fixed tube 101. A mail helicoid 104c is formed in a fore end outer 
diameter part of the first-lens-group tube 104. 
An operation ring 105 carries the first lens group I at its fore end part 
and is provided with a female helicoid 105a which is formed in its inner 
face. The female helicoid 105a engages the male helicoid 104c formed in 
the fore end outer part of the first-lens-group tube 104. The 
first-lens-group tube 104 thus can be moved back and forth between the 
telephoto end state as shown in FIG. 11 and the wide-angle end state as 
shown in FIG. 12 by rotating the operation ring 105. 
A cam tube 107 has a large diameter part 107a. The large diameter part 107a 
fittingly engages an inner diameter part of the fixed tube 101 to be 
carried thereby. Further, referring to FIG. 13, the large diameter part 
107a of the cam tube 107 is provided with three fixed-pin cams 107c and 
three third-lens-group cams 107d, which are evenly spaced. The small 
diameter part 107b of the cam tube 107 carries the fifth lens group V. 
The diameter of the fore end peripheral part of the cam tube 107 is 
increased by one step and includes a fitting engagement part 107h, which 
fittingly engages the fitting engagement part 104b on the inner side of 
the first-lens-group tube 104. Fitting engagement pins 107i are screwed 
into the fitting engagement part 107h at three evenly spaced parts. The 
fitting engagement pins 107i engage the cam grooves 104d of the 
first-lens-group tube 104. The cam tube 107 further has a cutout part 
107k. 
A second-lens-group tube 108 carries the second lens group II and has an 
outer circumferential part 108a. The outer circumferential part 108a has 
three fixed pins 108b which are evenly spaced. The fixed pins 108b engage 
the fixed-pin cams 107c formed in the large diameter part 107a of the cam 
tube 107 and, at the same time, engage also the second-lens-group holding 
holes 101c formed in the fixed tube 101. Therefore, the second-lens-group 
tube 108 is stationary relative to the fixed tube 101. 
The rotating position and the thrust position of the cam tube 107 are 
determined by two positional factors including the shape of the fixed-pin 
cams 107c formed in the large diameter part 107a of the cam tube 107 and 
the shape of the cam grooves 104d formed in the inner face of the 
first-lens-group tube 104. With the cam tube 107 arranged as described 
above and its rotating and thrust positions determined in this manner, the 
cam tube 107 can be drawn out, with a rotational motion, by moving the 
operation ring 105 back and forth. 
A moving diaphragm 107j is secured to the fore end face of the cam tube 
107. A third-lens-group tube 109 carries the third lens group III and has 
a peripheral part 109a, by which the third-lens-group tube 109 is carried 
within a void inside space of the large diameter part 107a of the cam tube 
107. Third-lens-group pins 109b are screwed into the peripheral part 109a 
of the third-lens-group tube 109. The third-lens-group pins 109b engage 
the third-lens-group cams 107d formed in the large diameter part 107a of 
the cam tube 107 and, at the same time, also engage the rectilinear slots 
101b of the fixed tube 101. Therefore, the third-lens-group tube 109 can 
be moved for zooming as desired by the rotational drawing-out action of 
the cam tube 107. 
A known electromagnetic diaphragm unit 110 is carried by the 
third-lens-group tube 109. 
A fourth-lens-group tube 111 carries the fourth lens group IV. The 
fourth-lens-group tube 111 has three connection parts 111b on its 
peripheral part. The three connection parts 111b are secured to the fixed 
tube 101 through the cutout part 107k of the cam tube 107. 
FIG. 14 is a diagram showing the movement of each lens group taking place 
at the time of zooming. In this instance, the first lens group I, the 
third lens group III and the fifth lens group V are drawn out in a 
nonlinear manner while the second lens group II and the fourth lens group 
IV remains stationary. 
In the second embodiment, the operation ring is arranged to be movable in 
the direction of thrust. In a case where the operation ring is of a 
rotating type, the operation ring moves in the direction of circumference. 
In that case, the operating force can be corrected in the same manner as 
the embodiment by replacing the longitudinal grooves (outer rectilinear 
grooves 101a) of the second embodiment with circumferential grooves and by 
varying the groove width of the circumferential grooves. This 
modification, therefore, makes the contents and the spirit of this 
invention applicable also to a lens barrel of the rotational operation 
ring type. 
Further, the correction of the operating force by means of the rectilinear 
or rotational grooves described in the foregoing may be replaced with use 
of a flange arranged to vary in part its thickness in the direction of 
rectilinear movement or rotation in combination with pressed contact 
members arranged to sandwich the flange between them. Such a modification 
falls within the spirit and scope of this invention. 
In the embodiment described, an operation ring arranged to permit both a 
rectilinear operation and a rotational operation is divided into main and 
subordinate operation rings. The embodiment is arranged such that, with 
the subordinate operation ring operated relative to the main operation 
ring, the operating force varies little for the rotational operation and 
varies to a great extent for the rectilinear operation. Even in a case 
where an optical apparatus is relatively heavy, the arrangement gives an 
operating force adjustment mechanism which excels in operability for 
operations on one and the same ring in every direction relative to 
gravity. 
Further, an optical apparatus which has a fixed part and an acting member 
and is arranged according to this invention as another embodiment thereof 
is provided with a protruding or recessed guide part which determines the 
operating direction of an operation member and an elastic sliding member 
which is arranged to be in pressed contact with the protruding or recessed 
part. The embodiment is arranged to make the pressed contact force of the 
elastic sliding member variable by partly varying the pressed contact part 
of the protruding or recessed part. This arrangement enables the optical 
apparatus to have an operating force adjustment mechanism which ensures 
excellent operability and gives an operating force apposite to each of 
different areas of operation.