Abstract: A cam structure for a zoom lens barrel assembly which includes a first lens group including first and second sub-lens groups, and a second lens group; and a sub-lens group switching mechanism for moving one of the first and second sub-lens groups away from the other in a short focal length photographing range, and toward the other in a long focal length photographing range. The cam structure includes a zoom cam ring having front and rear lens group cam grooves for moving the first and second lens groups toward and away from each other. The front and rear lens group cam grooves are determined according to the following equation: C=B+(A−B)*K  (1); wherein 0<K<1; A designates the other sub-lens group position; B designates the second lens group position; and C designates an imaginary point position between positions A and B.

Abstract: A zoom lens barrel assembly includes a plurality of lens barrels including a rearmost lens barrel, secured to a camera body, and a frontmost lens barrel. At least one adjacent pair of lens barrels are connected to each other via a helicoid structure. The frontmost lens barrel and a first adjacent lens barrel are connected to each other via a cam structure. The helicoid structure allows the adjacent pair of the lens barrels to rotate and move in an optical axis direction relative to each other while the zoom lens barrel assembly moves from a retracted position to a minimally extended position for a photographing operation. At least a portion of the helicoid structure includes a slip region which allows the pair of adjacent lens barrels to rotate without relatively moving along the optical axis.

Abstract: A multi-stage-extension zoom lens barrel assembly includes an inner peripheral helicoid ring having a first helicoid formed on the outer periphery thereof which is engaged with a second helicoid formed on an inner periphery of an outer peripheral helicoid ring; a first linear guide ring provided in the inner peripheral helicoid ring and is relatively rotatable and integrally movable therewith in the optical axis direction; and a first outer barrel for covering the first linear guide ring, the first outer barrel being supported on the first linear guide ring so as to relatively rotate and move together in the optical axis direction therewith, wherein the first outer barrel is detachably attached to the inner peripheral helicoid ring, the first outer barrel being integrally rotatable about the optical axis and integrally movable along the optical axis with the inner peripheral helicoid ring.

Abstract: A rib structure for a display device includes a light-transmissive rib structure containing therein a material absorbent of visible light so that a visible light absorption distance is 40 to 1200 &mgr;m (the visible light absorption distance L (&mgr;m) means a distance such that visible light decreases to exp(−T/L) times less in connection to the travel distance T (&mgr;m), that is, visible light is absorbed by 1-exp(−T/L)).

Abstract: A stopper structure for use in a lens barrel assembly, the lens barrel assembly having a helicoid ring which includes a male helicoid, on the outer periphery of the helicoid ring, for engaging with a female helicoid on an inner periphery of a fixed barrel secured to a camera body; and gear teeth formed along the male helicoids to extend between the male helicoids and arranged in a circumferential direction about an optical axis, the helicoid ring moving along the optical axis while been driven by a pinion which is engaged with the gear teeth; wherein the stopper structure includes a stopper member which engages with at least one tooth of the gear teeth in order to prevent rotation of the helicoid ring.

Abstract: A multi-stage-extension zoom lens barrel assembly includes an inner peripheral helicoid ring having a first helicoid formed on the outer periphery thereof which is engaged with a second helicoid formed on an inner periphery of an outer peripheral helicoid ring; a first linear guide ring provided in the inner peripheral helicoid ring and is relatively rotatable and integrally movable therewith in the optical axis direction; and a first outer barrel for covering the first linear guide ring, the first outer barrel being supported on the first linear guide ring so as to relatively rotate and move together in the optical axis direction therewith, wherein the first outer barrel is detachably attached to the inner peripheral helicoid ring, the first outer barrel being integrally rotatable about the optical axis and integrally movable along the optical axis with the inner peripheral helicoid ring.

Abstract: A camera includes a lens support frame which supports a photographing lens group; an outer lens barrel which is provided on the front end thereof with a photographing aperture through which the lens support frame is moved; a lens barrier mechanism which opens and closes the photographing aperture of the outer lens barrel; a lens drive mechanism which moves the lens support frame in the outer lens barrel between a forward movement extremity in which the front end of the lens support frame is located in front of the photographing opening in an optical axis direction, and a rearward movement extremity in which the front end of the lens support frame is located behind the photographing aperture; and a barrier detection device for detecting the opening state of the lens barrier mechanism, based on an amount of movement of the lens support frame in the optical axis direction via the lens drive mechanism.

Abstract: A lens shutter mechanism includes a support frame having a photographing aperture; at least three shutter sectors which open and close the photographing aperture via rotating axes which extend parallel to the optical axis; and at least three diaphragm sectors which vary an aperture diameter formed by the diaphragm sectors to restrict the diameter of the photographing aperture, independently from the shutter sectors, via rotating axes which extend parallel to the optical axis. The support frame is provided with rotational center portions spaced from each other at equi-angular intervals about the optical axis, the number of the rotational center portions being same as each of the number of the shutter sectors and the number of the diaphragm sectors. Each of the rotational center portions rotatably and coaxially supports a one of the shutter sectors and one of the diaphragm sectors.

Abstract: A cam structure for a zoom lens barrel assembly which includes a first lens group including first and second sub-lens groups, and a second lens group; and a sub-lens group switching mechanism for moving one of the first and second sub-lens groups away from the other in a short focal length photographing range, and toward the other in a long focal length photographing range. The cam structure includes a zoom cam ring having front and rear lens group cam grooves for moving the first and second lens groups toward and away from each other.

Abstract: A lens shutter mechanism includes, between front and rear support frames having photographing apertures, shutter sectors which open and close the photographing apertures; a shutter drive ring which is rotatable about the optical axis to drive the shutter sectors; diaphragm sectors which change an aperture diameter of the photographing apertures independently of the shutter sectors; and a diaphragm drive ring which is rotatable about the optical axis to drive the diaphragm sectors. The shutter drive ring and the diaphragm drive ring are located at different radial positions and at the same optical axis position. One and the other of the shutter drive ring and the diaphragm drive ring is provided with an inner flange and an outer flange respectively, which radically project toward each other so as to overlap in the axial direction, and engage so as to be relatively slidable in the circumferential direction.

Abstract: A light intercepting member driving mechanism includes light intercepting members which are each rotatable about a rotational axis parallel with an optical axis to open and close a photographing aperture; a drive ring which engages with the light intercepting member to open and close the light intercepting member in accordance with the angular displacement of the drive ring in forward and reverse directions about a rotational axis coincident with the optical axis; a motor which rotates the drive ring in the forward and reverse directions; a position indication portion provided on the drive ring to indicate the angular position of the drive ring; and a stationary detector which detects a passing of the position indication portion when the drive ring is rotated. The opening state of the light intercepting members is detected by the stationary detector and the position indication portion.

Abstract: A lens guide mechanism includes a lens frame which supports a photographing lens group, the lens frame including a plurality of guide holes extending in a direction parallel with an optical axis; a support barrel in which the lens frame is provided; a gear holding member which is provided at a front end of the support barrel; a gear train which is held between the support barrel and the gear holding member, the gear train constituting a drive mechanism for the lens frame; and a plurality of linear movement guide rods provided in the gear holding member, which extend through the guide holes of the lens frame and support the lens frame to move linearly in the optical axis direction relative to the support barrel.

Abstract: An FPC mounting structure for a lens shutter having a lens-shutter unit having therein a photographing lens and a shutter, and an FPC which is adapted to connect the lens-shutter unit to a control circuit, includes a circumferentially extending FPC which is supported along an outer surface of the lens-shutter unit, and an axially extending FPC which extends in the optical axis direction and which is connected to the control circuit. The circumferentially extending FPC and the axially extending FPC are constructed separately and are connected to each other in a press-contact state.

Abstract: A zoom lens barrel assembly includes a plurality of lens barrels including a rearmost lens barrel, secured to a camera body, and a frontmost lens barrel. At least one adjacent pair of lens barrels are connected to each other via a helicoid structure. The frontmost lens barrel and a first adjacent lens barrel are connected to each other via a cam structure. The helicoid structure allows the adjacent pair of the lens barrels to rotate and move in an optical axis direction relative to each other while the zoom lens barrel assembly moves from a retracted position to a minimally extended position for a photographing operation. At least a portion of the helicoid structure includes a slip region which allows the pair of adjacent lens barrels to rotate without relatively moving along the optical axis.

Abstract: A lens assembly includes an exposure control unit having an exposure control member; a lens drive unit including a lens drive mechanism which moves a photographing lens group in an optical axis direction; center apertures which are formed in the exposure control unit and the lens drive unit, respectively, at the center portions thereof, which define a lens movement opening when the exposure control unit and the lens drive unit are connected to each other; and a lens support frame which supports the photographing lens group, the lens support frame being provided in the lens movement openings so as to move in the optical axis direction and driven via the lens drive mechanism.

Abstract: A zoom lens barrel assembly includes a first lens group including first and second sub-lens groups; a second lens group; a sub-lens group switching mechanism for moving the first or second sub-lens group away from the other in a short focal length photographing range, and toward the other in a long focal length photographing range; and a zoom cam mechanism having front and rear lens group cam grooves. The rear lens group cam groove includes first and second portions corresponding to the short and long focal length photographing ranges, respectively, the first and the second portions connected to each other via a discontinuous portion. The front lens group cam groove includes a non-linear portion which corresponds to the short focal length photographing range and provides a non-linear path, and a linear portion which corresponds to the long focal length photographing range and provides a linear path.

Abstract: A zoom lens barrel includes a cylindrical member which is provided with a female helicoid; a split helicoid cylinder having a rear helicoid ring portion which is provided with a male helicoid which is screw-engaged with the female helicoid, and a front cylindrical portion which is detachably connected to the rear helicoid ring portion so as not to relatively rotate; a linear movement cylinder provided in the split helicoid cylinder so as to move in the optical axis direction; and a connecting structure for connecting the linear movement cylinder to the split helicoid cylinder so as to relatively rotate and so as not to relatively move in the optical axis direction, so that the rear helicoid ring portion and the front cylindrical portion of the split helicoid cylinder maintain connected by the connecting structure without being disconnected in the optical axis direction.

Abstract: A zoom lens barrel includes a rotary feed cylinder which is moved in an optical axis direction while being rotated; a linear movement cylinder which is provided within the rotary feed cylinder; and a connecting structure for connecting the linear movement cylinder to the rotary feed cylinder. The connecting structure includes at least two circumferential grooves centered about the optical axis, provided on the inner peripheral surface of the rotary feed cylinder or the outer peripheral surface of the linear movement cylinder, at different positions in the optical axis direction; and at least two radially extending engagement pawls which correspond to the at least two circumferential grooves, the engagement pawls being engaged in the circumferential grooves so as to slide in the circumferential direction and so as not to relatively move in the optical axis direction.

Abstract: A zoom lens barrel includes a first cylindrical member having first and second bottomed grooves, which intersect each other, on an inner peripheral surface thereof; a first moving member which is provided with a first radial projection which is fitted in the first bottomed groove, the first moving member being movable relative to the first cylindrical member; and a second moving member which is provided with a second radial projection which is fitted in the second bottomed groove, the second moving member being movable relative to the first cylindrical member. The shapes of the first bottomed groove and the first radial projection and the shapes of the second bottomed groove and the second radial projection are such that the second radial projection cannot be fitted in the first bottomed groove and that the first radial projection cannot be fitted in the second bottomed groove.

Abstract: An eccentricity-prevention mechanism includes a pair of lens-supporting rings for supporting a pair of lens groups, respectively; and a pair of positioning recesses and a follower projection formed on one and the other of opposed surfaces of the pair of lens-supporting rings, such that the follower projection engages with one of the pair of positioning recess to define a relative position of the pair of lens-supporting rings with respect to the optical axis, at a mutually close position and at a mutually distant position. At least three pairs of the positioning recesses and at least three follower projections are provided at different positions in a circumferential direction, so that eccentricity between the pair of lens-supporting rings is eliminated when all of the follower projections are concurrently brought into engagement with corresponding positioning recesses.