Motor built-in lens mounting

A mechanical mounting for a lens system having a component axially movable to perform optical functions. Movement of the component is controlled by a motor in a form of a hollow cylindrical field magnet rotatably fitted in a hollow cylindrical field coil which is fixedly fitted on a body tube of the lens mounting. Thus, the motor is snugly assembled with members of the lens mounting.

BACKGROUND OF THE INVENTION 
1. Field of the Invention 
This invention relates to lens mountings having incorporated therein a 
motor by which movement of a movable lens system is controlled. 
2. Description of the Prior Art 
There have been known many techniques of employing the reactive force of 
electromagnetic induction for moving some members or units within the lens 
mounting. As examples of prior art relating to the technique of 
controlling the operation of a diaphragm unit in the lens mounting by an 
electromagnetic induction mechanism, mention may be made of U.S. Pat. Nos. 
3,687,042 and 4,113,359. 
Further, in relation to a motorized focusing technique it has been the 
common practice in the art of motion picture cameras to incorporate a 
small-sized D.C. motor in the lens mounting with the driving torque of 
said motor being transmitted through a gear train to the holder for the 
focusing lens. The use of such a motor driven focusing mechanism produces 
a problem in that as the motor is positioned on a lens barrel, for 
example, in a space between the body tube and the casing of the lens 
mounting, the outer appearance becomes awkward with a large outward 
projection only at that portion which contains the motor. Up to now, the 
portion comprising the lens barrel has been perfectly round over its 
entire length. Thus such an awkward appearance cause in users a feeling of 
discomfort. This is not only undesirable from the standpoint of industrial 
design but also because it involves an objectionably large increase in the 
complexity of the structure of the lens mounting mechanism. 
Another prior art proposal involves the use of a linear motor in 
controlling the movement of the focusing lens as disclosed in U.S. patent 
application Ser. No. 396,030 filed July 7, 1982 (corresponding to Japanese 
Laid-Open Patent Application No. Sho 58-10706 published Jan. 21, 1983). In 
this case, however, the stator of the motor must be as elongated axially 
as much as the range of movement of the focusing lens, and the rigorous 
requirement for the control of adjustment in position of the focusing lens 
is also difficult to fulfill. 
Another type of lens focus adjusting mechanism using an epicyclic motor is 
known in U.S. Pat. No. 4,152,060. This motor is constructed with a stator 
concentric to the optical axis of the focusing lens and a tubular armature 
arranged in eccentric relation to the optical axis upon energization to 
rotate epicyclically relative to the stator. A lens holder for the 
focusing lens has a central axis substantially coincident with the optical 
axis and is rotatably mounted in the interior of the armature through an 
intermediary of which the center of rotation is in coincidence with the 
optical axis and of which rotative motion causes axial movement of the 
lens holder. The mechanism further includes a drive connection for 
transmitting epicyclic motion of the armature to rotative motion of the 
lens holder. From this description it seems that the structure of a lens 
mounting adapted for use of such focusing mechanism will be very 
complicated and therefore the assembling and adjusting operations will be 
very difficult to carry out. 
Since it is conventional for a lens mechanism to be called lens is round in 
crossection, the parts of the lens mounting are designed on the basis of 
this form, and constituent parts such as the lens holder, fixed body, 
focusing actuator, zoom actuator, helicoid member and cam member are 
necessarily of a round shape. Therefore it has been sought to construct 
the motor usable with the operating mechanism for the focusing lens or 
zoom lens from only such tubular constituent parts as are compatible with 
the parts constituting the lens mounting with the advantage that the outer 
appearance will not have an awkward projection, and the use of the motor 
will not call for an unduly large increase in the complexity of the 
structure of the lens mounting mechanism. A device seeking to achieve this 
object is disclosed in Japanese Laid-Open Patent Application No. Sho 
57-186738 published Nov. 17, 1982. This prior art device concerns a lens 
mounting provided with a space near a holder containing a lens group to be 
axially moved, wherein a motor is positioned in this space and is fixedly 
secured to the lens holder. When the motor is energized, the lens holder 
is driven along with this motor to move axially to effect focusing or 
zooming. A practical example of this motor is shown in an annular form. 
It is also known to provide a stepping motor incorporated in a lens 
mounting wherein the movable lens is driven to move by the stepping motor 
as disclosed in Japanese Laid-Open Patent Application No. Sho 56-147132. 
This stepping motor is of the variable reluctance (VR) type and is 
arranged between the lens holder and the lens case. Rotative movement of 
the motor is converted to axial movement of the lens holder by a drive 
connection. 
SUMMARY OF THE INVENTION 
It is an object of the present invention to provide a mechanical mounting 
for a lens system having a focusing component or zoom components driven to 
move by a motor, while still permitting the motor to be built into the 
interior of the lens mounting without involving any unduly large increase 
in the bulk and size of the outer lens barrel and without causing 
deformation of the outer appearance. 
Another object is to make use of a stepping motor as the drive source for 
the movable lens component together with a drive connection for converting 
motion of the rotor to axial movement of the lens holder which connection 
is formed in the rotor itself, thereby providing an advantage in that the 
number of parts is reduced, and that a further reduction in the thickness 
of the motor is achieved, thereby contributing to achievement of a minimum 
diameter for the outer lens barrel.

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS 
In FIGS. 1 to 3 there is shown a first embodiment of the invention where 1 
denotes a body tube of a lens mounting L having a built-in motor. Lens 
elements G1 to G5 are fixedly mounted to the body tube 1. A bayonet 
coupling portion 1a is formed in the rear end of the body tube 1. A lens 
holder 2 containing a focusing lens element G6 is movably fitted in the 
inner diameter of the body tube 1. A drive connection pin 4 extends 
radially outwardly of the outer peripheral surface of the lens holder 2 
through a longitudinal slot 1b formed through the wall of the body tube 1 
into a camming groove 6a of a rotor 6. The rotor 6 is made of 
magnetoplastic material and is formed to a hollow cylindrical shape with N 
and S poles alternating about the optical axis as shown in FIG. 2. The 
camming groove 6a formed in the inner surface of the rotor 6 constitutes 
together with the drive connection pin 4, a mechanism for transmitting 
rotative movement of the rotor 6 into axial movement of the lens holder 2. 
Two circumferential grooves 6b for accommodating ball bearings 8A and 8B 
are formed in either end of the axial length of the inner surface of the 
rotor 6 with only one of the grooves 6b being visible in FIG. 2. 
A first field yoke 10 holding a field coil 12 is constructed with two 
members 10A and 10B having letter L-shaped portions to enclose the coil 12 
and having pole teeth 10a1, 10a2, . . . and 10b1, 10b2, . . . respectively 
extending rearwardly of the L-shaped portions to cover the front half of 
the rotor 6. The pole teeth 10a and 10b alternate each with the other. A 
second field yoke 14 holding a second field coil 16 is constructed with 
two members 14A and 14B in a similar form to that of the first field yoke 
10. Their pole teeth 14a1, 14a2, . . . and 14b1, 14b2, . . . are displaced 
from those of the first field yoke 10 by a 1/2 pitch in the tangential 
direction. 
The first and second field yokes 10 and 14 and the first and second field 
coils 12 and 16 constitute a stepping motor M. 
It is desirable that the body tube 1 which lies inside the magnet rotor 6 
be made of magnetic material with a view toward providing good 
permeability of magnetic flux and increase efficiency of the motor. In 
order to minimize the weight of the body tube 1, that portion of the body 
tube which lies near the rotor 6 is made of ferrous material, and the 
other portion may be made of aluminum alloy or plastic material. 
A diaphragm 20 is housed in a case 18 fixedly mounted to the body tube 1, 
and has a presetting ring 22 operatively connected to a control ring for 
the diaphragm blades through a presetting mechanism of prior known 
construction (not shown). 
In operating the lens mounting mechanism of such construction, with the 
lens components G1 to G6 constituting a photographic objective optical 
system, when motion of the motor is imparted into the component G6, 
automatic focus adjustment is formed. The reflected light from a target 
object is received by a range finder 24. The output signal representing 
the object distance from the range finder 24 is applied to a signal 
processor 26 where the number of steps through which the rotor 6 of the 
motor M must be rotated to move the focusing lens component into the 
in-focus position is computed. The output signal from the signal processor 
26 is applied to a motor drive circuit 28, whereby the field coil 12 or 16 
is supplied with current in the form of the required number of pulses. As 
the rotor 6 rotates, the lens holder 2 is moved axially by a distance 
depending upon the track of the camming groove 6a. The aforesaid range 
finder, signal processor and motor drive circuit may be of known design. 
Responsive to the signal from the processor 26, the motor drive circuit 28 
provides pulsated current to the first to fourth coils L1 to L4 of the 
field coil 12 or 16 successively. By this current, each of the pole teeth 
10a1, 10a2, . . . , 10b1, 10b2, . . . , 14a1, 14a2, . . . and 14b1, 14b2, 
. . . generates an electromagnetic field and attracts or repels the 
magnetic poles of the rotor 6 so that the rotor 6 is driven to rotate 
about the axis of the body tube 1. 
When the computed number of pulses by the signal processor 26 have been 
produced and the rotor 6 has rotated by the required angular distance, the 
focusing lens component G6 is stopped in an in-focus position after it has 
moved by a distance depending upon the shift of the camming groove. 
This embodiment has an advantage that because the rotor 6 is formed to a 
hollow cylindrical shape so that it can be arranged on the body tube and 
also because the rotor 6 itself is made to serve as a control member for 
the movement of the focusing lens component G6 by forming therein the 
camming groove 6a, the radial thickness of the lens mounting can be 
reduced. The arrangement of the field coils and field yokes which 
constitute the stator of the motor M adjacent either end of the axial 
length of the rotor 6 and the limitation of what lies above the outer 
periphery of the rotor 6 only to the pole teeth 10a, 10b, . . . , 14a and 
14b . . . also contribute to the valuable decrease in the diameter of the 
lens mounting. 
FIG. 5 and FIGS. 6(a) and 6(b) illustrate an example of variation of the 
above-described first embodiment, wherein the bearings for the rotor 6 are 
positioned between either of the field yokes and either end of the rotor 6 
to achieve a further reduction of the radial thickness of the lens 
mounting. The lens mounting of FIG. 5 is similar in construction to that 
of FIG. 1 except for the positioning of the bearing portion of the rotor 
6. Therefore, only the bearing portion will next be described. 
As shown in FIG. 5, the rotor 6 is provided with ball bearings 30A and 30B 
at either end of the axial length thereof. In one example of FIG. 6(a), as 
each ball bearing has a number of balls, each ball is located in the one 
portion of a groove 6c in the end of the rotor 6 which is divided by 
successive radial projections 6d1, 6d2, . . . . Thus a range of movement 
of the ball is defined. 
In another example of FIG. 6(b), a number of semi-spherical recesses 6e1, 
6e2, . . . , to corresponding the number of balls in the bearings 30A and 
30B are formed in the end of the rotor 6 to accommodate the respective 
balls. 
FIGS. 7 and 8 illustrate another embodiment of the invention, where a body 
tube 32 fixedly carries lens components Gl to G5. A hollow cylindrical 
magnet rotor 34 is made of magneto-plastic material and has N and S poles 
alternating with each other. Formed in the inner surface of the rotor 34 
is a camming groove 34a for controlling the axial movement of the focusing 
lens component G6. The magnet rotor 34 is rotatably fitted on the outer 
diameter of the body tube 32 through a pair of ball bearings 36A and 36B. 
A first field yoke 38 is constructed with two members 38A and 38B having 
radial flanges at the front and rear ends thereof respectively and axially 
elongated pole teeth 38a1, 38a 2, . . . and 38b1, 38b2, . . . at the 
opposite ends thereof. These two members 38A and 38B are assembled so that 
there are provided pole teeth 38a.sub.n and 38b.sub.n where n is equal to 
1, 2 or 3 which alternate with each other as shown in FIG. 8. A first 
field coil 42 is positioned in a space defined by the front and rear 
flanges and pole teeth of the yoke members 38A and 38B. A second field 
yoke 40 and a second field coil 46 are similar in construction and 
arrangement to the first ones. 
The first and second field yokes 38 and 40 are arranged on the outer 
periphery of the magnet rotor 34, covered with an outer barrel yoke 44 of 
FIG. 8, and fixedly secured to the body tube 32. 
The yoke members 38A, 38B, 40A and 40B each are provided with a radial 
extension 38a0, 38b0, 40a0, 40b0 (not shown) on the outer periphery of the 
flange thereof, while the outer sleeve yoke 44 is provided with holes 
44a1, 44a2 and 44a3 for engagement with the extensions to determine the 
relative position of the two members. 
As the control system for the lens mounting of FIGS. 7 and 8 use may be 
made of that of FIG. 4. The pulsated signal from the drive circuit 28 is 
applied to the field coils 42 and 46 so that the rotor 34 rotates 
stepwise, thereby adjustment in axial position of the focusing lens G6 is 
automatically formed in a similar manner to that described in connection 
with the foregoing embodiment. 
The lens mounting of FIGS. 7 and 8 has an advantage in the axial length of 
the coils 42 and 46 is increased with increase in the number of turns of 
the coils crossing the magnetic flux of the magnet rotor 34, whereby the 
number of layers of turns of the coils can be reduced and the driving 
torque can be increased. 
Another advantage is that the radial thickness of the motor is limited to a 
minimum, thus facilitating a minimization of the bulk and size of the lens 
mounting. 
While specific embodiments of the invention have been shown and described 
in detail to illustrate the application of the inventive principles, it 
will be understood that the invention may be embodied otherwise without 
departing from such principles.