JP2009015313A - Camera system - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide a camera system capable of easily and surely switching a plurality of photographing modes and acquiring an image corresponding to each mode. <P>SOLUTION: A camera 1 has a posture detecting switch 121 (122) installed and put into an ON state when pressed by a switch pressing protrusion 332 (331) formed at a support shaft 3. The camera 1 is detachably installed by a holding member 2, and the holding member 2 and the camera 1 are turnably installed with respect to the support shaft 3. Since the contact between the posture detecting switch 121 (122) and the switch pressing protrusion 332 (331), i.e., the ON/OFF combination of the posture detecting switch 121 (122), differs according to each of a plurality of turning positions of the camera 1 and the detached state from the holding member 2, the camera 1 detects the combination to determine the posture of the local device, and makes an image correction in the photographing mode corresponding to the posture to output. <P>COPYRIGHT: (C)2009,JPO&INPIT

Description

  The present invention relates to a camera system, and more particularly to a camera system capable of a plurality of usage modes.

  2. Description of the Related Art Conventionally, various cameras having two functions of a document image capturing function for capturing a document and a person image capturing function for capturing a person like a normal still camera have been devised as cameras capable of using a plurality of usage modes.

  For example, Patent Document 1 discloses a document camera that can switch a photographing direction between a vertical downward direction and a horizontal direction where a document to be photographed is placed.

  Patent Document 2 discloses a videophone system that includes a document / person camera and switches the shooting direction to the person direction when an incoming call is detected.

Patent Document 3 is a normal digital still camera, which has a document mode and a normal mode, and performs image processing dedicated to document shooting in the document mode.
JP 2003-348385 A JP-A-8-265716 JP 2005-311925 A

  However, the above-described conventional camera system can deal with only two modes of use: the document mode and the portrait mode. Moreover, in the camera systems shown in Patent Document 1 and Patent Document 2, the camera is mounted on a large-scale device, and it is not easy to carry around freely. On the other hand, the camera shown in Patent Document 3 is a normal digital still camera, and has a document shooting mode, but does not have a mechanism for shooting fixedly for a document, and the camera is used for document shooting. It was not easy to fix to.

  Accordingly, an object of the present invention is to easily and surely switch between a document shooting mode for shooting a close document or the like and a plurality of other versatile shooting modes, and acquire images and videos according to each mode. It is to provide a camera system that can do this.

The present invention relates to a camera that acquires an image, a camera holding member that detachably holds the camera, and a camera that is held by the camera holding member in a mode that is set in advance with respect to an installation location. The present invention relates to a camera system including a support shaft member that supports the member.
In the present invention, each of the camera holding member, the support shaft member, and the camera has the following characteristics.

  The camera holding member is installed so as to be rotatable with respect to the support shaft member. At this time, the camera is held such that the surface of the camera facing the camera holding member is separated from the support shaft member.

  The support shaft member is formed with a plurality of protrusions having a shape that substantially contacts the camera. The plurality of protrusions are formed on a circumference of a predetermined radius from the rotation center of the camera holding member on the surface of the support shaft member facing the camera holding member.

  The camera includes a plurality of posture detection switches at positions corresponding to the circumference of the surface facing the camera holding member. The plurality of posture detection switches have different combinations of contact with the plurality of protrusions according to the rotation of the camera.

  Further, the camera detects a plurality of postures by rotation or a detached state from the camera holding member by a combination of contact methods of the plurality of posture detection switches with the plurality of protrusions. And a camera acquires the image | video of a different image | video specification by each attitude | position or a desorption state.

  In this configuration, the camera can be fixed at a fixed position by being mounted on the camera holding member. For example, the document can be photographed by being fixed at a position above a predetermined distance from the table on which the document is placed. Further, when the camera is mounted on the camera holding member, the camera is rotated by the camera holding member, so that a plurality of postures can be realized while the position is fixed, and a plurality of directions can be photographed from the fixed position. . For example, the document on the table, the situation around the table, and the upper side from the table can be photographed at a fixed position with respect to the table. Further, the camera can be freely carried by being detached from the camera holding member. For example, the user can freely take a picture while holding the camera by hand.

  Each posture including such a detached state of the camera is detected by a combination of whether or not a plurality of protrusions attached to the support shaft member are in contact with a plurality of posture detection switches attached to the camera. . For example, in a state where the camera is detached, all of the plurality of posture detection switches do not come into contact with the protrusions, so that all the posture detection switches are turned off. In addition, the combinations in which the plurality of posture detection switches respectively contact the plurality of protrusions are different depending on the rotation position, and the combination of the on / off states of the plurality of posture detection switches varies depending on the combination. The detachment state and posture are detected by such a combination of on / off of the posture detection switch. And a camera detects an attitude | position, selects the usage condition according to each attitude | position, and performs an appropriate | suitable video process for every aspect.

  The camera of the camera system of the present invention includes a fisheye lens. And a camera acquires an image | video via a fisheye lens, and performs different image | video correction | amendment with respect to the acquired image | video according to an attitude | position or a removal | desorption state.

  In this configuration, the image is captured using the fisheye lens, and the captured image is corrected according to the posture or the detached state. By using a fisheye lens, for example, the shooting range is widened so that the entire circumference of the area on the front side from the camera is the shooting range, but the image is larger than when using a lens used for a normal video camera or still camera. Is distorted. However, since the distortion is eliminated by performing the image correction according to the posture or the detachment state, it is possible to handle a wider variety of images due to the wide shooting range. Therefore, it is easy to acquire images suitable for each posture and detached state.

  Further, the support shaft member of the camera system of the present invention has recesses formed at a plurality of positions corresponding to a plurality of postures on the circumference of the surface facing the camera holding member. On the other hand, the camera holding member is formed with a protrusion that fits into one of the recesses in each of a plurality of postures at a position corresponding to the circumference on the support shaft member side.

  In this configuration, positioning is performed by fitting the protrusions of the camera holding member into the plurality of recesses of the support shaft member. At this time, since each recess is provided for each posture that the camera can take, the camera is fixed in a posture corresponding to the fitted recess by fitting the projection into any of the recesses. Accordingly, the camera can be set in a desired posture easily and reliably.

  In addition, the camera system of the present invention includes a biasing unit that biases the support shaft member and the camera holding member in a state in which the support shaft member and the camera holding member can be separated from each other.

  In this configuration, since the camera holding member and the support shaft member are always urged, if the protrusion of the camera holding member is fitted in the recess of the support shaft member as described above, the protrusion can be easily obtained. Will not come out of the recess and the camera will not rotate. On the other hand, when the support shaft member and the camera holding member are urged to such an extent that they can be separated by an external force, when the user wants to change the posture of the camera, the user holds the camera fixed to the camera holding member. By turning away from the member, the camera can be easily turned.

  Further, the support shaft member of the camera system of the present invention is provided with a rotation restraining protrusion that contacts the camera holding member and inhibits the rotation when the camera holding member exceeds the range of rotation by a plurality of postures. ing.

  In this configuration, even if the user tries to rotate the camera, the rotation of the camera is prevented by the rotation suppression protrusion at the boundary position of the rotation range, thereby preventing unnecessary rotation, Furthermore, damage and failure can be prevented by this unnecessary rotation.

  According to this invention, the camera is fixed at a fixed position, and a plurality of modes in which a plurality of directions can be photographed respectively and a mode in which the camera can be freely carried are easily realized. Thus, a camera system capable of acquiring an optimal video can be realized with a simple and easy configuration and usage method.

The camera system of this embodiment will be described with reference to the drawings.
1 to 3 are external views showing the structure of each aspect in a state where the camera 1 is fixed to the holding member 2 in the camera system of the present embodiment, where (A) is a side view and (B) is a front view. It is.
4A is an external perspective view of the support shaft 3, and FIG. 4B is a front view (a view seen from the holding member 2 side).
5A and 5B are external perspective views of the holding member 2 viewed from the front side and the back side, respectively. FIG. 5C is a front view of the holding member 2 (viewed from the support member 3 side).
FIG. 6 is an external perspective view of the camera 1.
FIGS. 7A and 7B are views showing the fitted state of the support shaft 3 and the holding member 2, wherein FIG. 7A is an external perspective view seen from the holding member 2 side, and FIG. 7B is an assembly seen from the support shaft 3 side. It is a perspective view, and (C) is an assembly cross-sectional conceptual diagram seen from a direction perpendicular to the fitting direction.
FIG. 8 is a view showing each fitting state of the support shaft 3, the holding member 2, and the camera 1, (A) is an assembled perspective view seen from the support shaft 3 side, and (B) is the fitting direction. It is an assembly section conceptual diagram seen from the perpendicular direction.

The camera system of this embodiment includes a camera 1, a holding member 2, a support shaft 3, and a table 4.
The table 4 includes a base unit 40 installed on the top surface of a table on which a camera system such as a conference table is arranged, and a connection unit 41 connected to the support shaft 3. The connecting portion 41 rotatably supports the main body 30 of the support shaft 3 and supports the extending direction of the main body 30 of the support shaft 3 at a predetermined angle with respect to the top surface installation surface of the base member 40. Consists of structure. With such a structure, the support shaft 3 is installed at a predetermined angle with respect to the base member 40, and the end of the support shaft 3 facing the base 4 of the main body 30, that is, the end connected to the holding member 2. The portion is at a predetermined height with respect to the top surface of the table. In addition, the support shaft 3 can be folded to a state in which the support shaft 3 is in contact with the base member 40 by rotating in the direction of the base member 40 around the connection portion 41. Thereby, space can be saved at the time of conveyance or storage.

  Details of the structure and configuration of the support shaft 3, the holding member 2, and the camera 1 will be described later. Here, the connection relationship and operation of the support shaft 3, the holding member 2, and the camera 1 will be schematically described.

  The main body 30 of the support shaft 3 has a substantially elliptical cross section perpendicular to the extending direction. At the end of the main body 30 on the side facing the base 4, the holding member 2 is installed so as to be rotatable with respect to the support shaft 3. The holding member 2 is installed with respect to the main body 30 having a substantially elliptical cross section so that a plane including the extending direction and the vertical direction is a rotation surface. The camera 1 is detachably installed on the holding member 2, and the position of the camera 1 is fixed with respect to the holding member 2 in a mounted state. At this time, the camera 1 is installed so that the shooting direction of the camera 1 is in a direction parallel to the above-described rotation plane. As a result, the camera 1 is installed so as to be rotatable with respect to the support shaft 3, and the shooting direction of the camera 1 also changes as the camera 1 rotates.

  Such rotation is fitted to any of the plurality of holder positioning recesses 321 to 323 installed on the support shaft 3 according to the angle at which the positioning projection 23 installed on the holding member 2 rotates. And fixed at a plurality of positions. For example, as shown in FIGS. 1 to 3, the front surface of the camera 1 is fixed so as to be vertically downward, horizontally, and vertically upward. Thereby, the camera 1 can acquire the image | video from the direction according to each position. At this time, the camera 1 is provided with posture detection switches 121 and 122, and the shooting direction depends on the contact state between the posture detection switches 121 and 122 and the switch pressing protrusions 331 and 332 formed on the support shaft 3. Is detected. The camera 1 sets a shooting mode for each detected shooting direction, and performs an image correction specific to each shooting mode and outputs the result.

  Specifically, as shown in FIG. 8, the attitude detection switch 121 and the switch pressing protrusion 332 are in contact with each other, the attitude detection switch 122 and the switch pressing protrusion 331 are in contact with each other, and the attitude detection switches 121 and 122 are both turned on. In such a case (the state shown in FIG. 1), the camera 1 detects the horizontal shooting mode (person shooting mode). When the camera 1 is rotated from this state, the posture detection switch 121 and the switch pressing protrusion 331 are in contact with each other, and only the posture detection switch 121 is turned on (the state in FIG. 2), the camera 1 is moved vertically downward. Detects the shooting mode (document shooting horizontal mode). Further, when the camera 1 is rotated from this state, the posture detection switch 122 and the switch pressing protrusion 332 are in contact with each other, and only the posture detection switch 122 is turned on (the state in FIG. 3), the camera 1 is moved vertically upward. Direction shooting mode (all-around shooting mode) is detected. Further, since the camera 1 can be detached from the holding member 2, that is, the support shaft 3, when the camera 1 is detached, both the two posture detection switches 121 and 122 are turned off. In this case, the camera 1 detects the free shooting mode.

  When the camera 1 detects each shooting mode, the camera 1 corrects the acquired video according to the mode. For example, the camera 1 corrects and outputs distortion of the image of the document acquired through the fisheye lens 100 in the document shooting mode, and outputs the image of each person acquired through the fisheye lens 100 in the person shooting horizontal mode. Correct video distortion and output. Further, the camera 1 projects and outputs an image of the entire periphery acquired through the fisheye lens 100 on a plane in the all-around shooting mode, and the image acquired through the fisheye lens 100 in the free shooting mode. Are corrected and output as if taken with a normal digital video camera or still camera.

  With this configuration, in the camera system of the present embodiment, a plurality of postures of the camera 1 in a state where the camera 1 is rotatably installed with respect to the support shaft 3 and a state where the camera 1 is detached from the support shaft 3 are obtained. It can be detected by a simple switch structure. Furthermore, by performing appropriate image correction according to the detected plurality of postures and detachment states, an optimal image can be output without the user being aware of the camera posture or detachment state.

  Since the camera system of the present embodiment can be realized with a simple structure as described above, the longest outer shape of the camera 1 is 100 mm or less, the support shaft 3 is about 250 mm, and the longest outer shape of the table 4 is 200 mm or less. It is possible to form in the shape which becomes. Therefore, it is easy to install, does not take up space, and is excellent in portability. As a result, it is not simply used in a single place but can be carried and used where necessary. That is, a camera system that can acquire an optimal video in each of various modes can be used for a wide range of purposes.

  Next, the detailed configuration of each unit will be described.

(A) Support shaft 3 (see FIG. 4)
A substantially circular disc part 39 is formed at the end of the main body 30 of the support shaft 3 facing the base 4 in the extending direction, as viewed from the installation side of the holding member 2. A fitting recess 31 having a predetermined radius and a circular cross section of the inner wall surface is formed at the center viewed from the member 2 side (referred to as “disc view side center” for the sake of simplicity).

  On the outer peripheral side of the fitting recess 31 in the disc part 39, a holder positioning part 32 is formed which spreads in a fan shape at approximately 180 degrees and has a predetermined width in the radial direction with the center on the disc view side as a central point of formation. The holder positioning portion 32 is formed so as to protrude from the surface of the disc portion 39 on the holding member 2 side and to have a flat surface.

  Holder positioning recesses 321 and 323 are provided at both ends in the circumferential direction of the holder positioning portion 32 so as to be recessed from the flattened surface, and the holder positioning recesses are also provided at substantially midpoints along the circumferential direction. 322 is provided. That is, on the surface of the holder positioning portion 32, three holder positioning recesses 321, 322, and 323 are provided at intervals of about 90 degrees with reference to the center on the disc view side. These recesses are provided in a shape whose cross section is an arc shape.

  On substantially the same circumference as the holder positioning portion 32 of the disc portion 39, stoppers 34 protruding from the disc portion 39 toward the holding member 2 are formed in the vicinity of both ends of the holder positioning portion 32 in the circumferential direction. ing. When the holding member 2 to be described later rotates, these stoppers 34 are moved to a predetermined rotation amount when the fan-shaped portion 202 formed with the positioning projections 23 to be fitted to any of the holder positioning recesses 321 to 323 is reached. The fan-shaped portion 202 is installed so as to abut against the circumferential end surface of the sector 202, and unnecessary rotation is prevented by this abutment.

  Further, switch pressing protrusions 331 and 332 that protrude from the disk portion 39 toward the holding member 2 are formed on substantially the same circumference as the holder positioning portion 32 and the stopper 34 of the disk portion 39. The switch pressing protrusions 331 and 332 are adjacent to the stoppers 34 and are disposed on the opposite side of the holder positioning portion 32 with respect to the stoppers 34. At this time, the switch pressing projection 331 is formed on the holder positioning recess 323 side, and the switch pressing projection 332 is formed on the holder positioning recess 321 side. The switch pressing protrusions 331 and 332 are formed at an interval of approximately 90 degrees with respect to the center on the disk view side, and the switch pressing protrusion 331 and the holder positioning recess 323 are approximately 45 degrees apart, and the switch pressing protrusions 332 and the holder positioning recess 321 are formed at an interval of approximately 45 degrees. The switch pressing protrusions 331 and 332 have a central portion having a flat top surface having a constant height in the center along the circumferential direction, and both end portions gradually increasing in height toward the central portion. It consists of an integrally formed shape. The height of the central part of the switch pressing protrusions 331 and 332 is set to a height that is surely turned on when posture detection switches 121 and 122 of the camera 1 described later reach the central part. That is, it is set by the stroke from when the attitude detection switches 121 and 122 are pushed in until the switch is turned on, and the distance from the attitude detection switches 121 and 122 of the camera 1 to the surface of the disk portion 39 of the support shaft 3. . Further, since the switch pressing protrusions 331 and 332 have a structure in which the height gradually increases, becomes constant, and gradually decreases along the circumferential direction, posture detection switches 121 and 122 of the camera 1 described later are circular. When moving in the circumferential direction, the top surfaces of the switch pressing protrusions 331 and 332 are continuously and smoothly moved. This prevents the discontinuity of the rotation of the camera 1 caused by the posture detection switches 121, 122 of the camera 1 hitting the switch pressing protrusions 331, 332 of the support shaft 3, and the user can turn the camera 1 quickly and easily. Can be moved.

(B) Holding member (see FIG. 5)
The holding member 2 includes a casing 20 including a circular casing 201 having a predetermined thickness and a fan-shaped casing 202.
Have The fan-shaped housing 202 has a shape protruding from the circumferential surface of the circular housing 201 in a direction perpendicular to the circumferential surface, and the circular housing 201 side is formed in a shape having a sector-shaped center.

  On one circular surface of the circular housing 201 (the surface on the support shaft 3 side in the assembled state), a cylindrical fitting protruding from the one circular surface with the center viewed from the disk view side as the center of formation. The joint convex part 22 is formed. The fitting convex portion 22 has a shape that fits into the fitting concave portion 31 of the support shaft 3 described above. A concave fitting flange portion 21 is formed on the other circular surface of the circular casing 201 (the surface on the camera 1 side in the assembled state) based on the center of the formation. The fitting flange portion 21 is formed in a shape that fits with a fitting flange 11 of the camera 1 described later.

  A semi-cylindrical positioning protrusion 23 is formed on the same surface as the one circular surface of the circular housing 201 in the fan-shaped housing 202 (the surface on the support shaft 3 side in the assembled state). The projections 23 are formed so that the semicircular surfaces are respectively positioned in the direction in which the sector housing 202 extends (radial direction from the center of the sector shape) The positioning projections 23 correspond to the holding member 2 and the support shaft. 3 is formed at a position that fits into the holder positioning recesses 321 to 323 of the support shaft 3. Specifically, the holder is a holder for the center of the disc portion 39 of the support shaft 3 with respect to the disk view side. The installation distance of the positioning recesses 321 to 323 and the installation distance of the positioning projection 23 with respect to the center viewed from the circular surface of the circular housing 201 of the holding member 2 are formed to coincide with each other.

A camera fixing recess 24 is formed on the same surface as the other circular surface of the circular housing 201 in the fan-shaped housing 202 (surface on the camera 1 side in the assembled state).
In addition, the fan-shaped housing 202 is formed thin so that the end portion on the widened side has a predetermined length from the end portion on the widened side toward the center.

(C) Assembly structure of the support shaft 3 and the holding member 2 (see FIG. 7)
The fitting convex portion 22 of the holding member 2 is fitted into the fitting concave portion 31 of the support shaft 3. A spring 27 is installed inside the support shaft 3 on the outer peripheral side of the wall surface of the fitting recess 31. In addition, a cap 25 that covers the spring 27 is provided on the end surface of the fitting convex portion 22 inside the support shaft 3, and the cap 25 is fixed to the end surface of the fitting convex portion 22 with a screw 26. ing. At this time, the cap 25 is installed so as to compress the spring 27 by the inner wall surface on the holding member 2 side of the disc portion 39 of the support shaft 3 and the cap 25. Further, the height of the inner wall in the direction in which the fitting convex portion 22 is inserted in the fitting concave portion 31 of the support shaft 3 is such that the inner wall does not reach the cap 25 when the fitting convex portion 22 is completely fitted. It is formed at a height. With this structure, the holding member 2 is applied with an urging force from the spring 27 so as to always contact the support shaft 3, but due to an external force from the user or the like, the holding member 2 has an amount corresponding to the distance between the cap 25 and the inner wall of the fitting recess 31. It becomes a structure which can move only to a fitting direction.

  As a result, when the positioning projection 23 of the holding member 2 is fitted to any of the holder positioning recesses 321 to 323 of the support shaft 3, the fitting state is maintained unless a new external force is applied. Is maintained. On the other hand, when a force is applied by the user so as to separate the holding member 2 from the support shaft 3, the holding member 2 is separated from the support shaft 3 by an interval between the cap 25 and the inner wall of the fitting recess 31. The holding member 2 can be rotated with respect to the support shaft 3. Since the holder positioning recesses 321 to 323 are installed at intervals of approximately 90 degrees, the holding member 2 is fixed in three postures that differ from each other by approximately 90 degrees with respect to the support shaft 3 by the rotation of the holding member 2. Can be made. Further, when the holding member 2 reaches both ends of the rotation range including these postures, the side surface of the fan-shaped housing 202 abuts against the stopper 34 formed on the support shaft 3, and thus further rotation is suppressed. Thereby, the unnecessary rotation of the holding member 2 can be prevented.

(D) Camera 1 (see FIGS. 6, 8 and 9)
FIG. 9 is a functional block diagram of the camera 1.
(D-1) Assembly Structure of Camera 1 and Camera 1 The housing 10 of the camera 1 is formed by protruding from one of the flat plate portion 102 and the main surface (surface having a large area) facing the flat plate portion. The elliptical spherical optical system holding unit 101 is integrally formed. In the optical system holding unit 101, a functional unit of an optical system including the fisheye lens 100 is formed inside. The fisheye lens 100 is installed so that the axis of the optical system is set parallel to the main surface of the flat plate portion 102.

  On the other main surface of the flat plate portion 102, a fitting flange 11 protruding in a substantially columnar shape is formed. The fitting flange 11 has a shape that fits into the fitting flange 21 of the holding member 2, and a tap that has a shape that can be attached to a general-purpose tripod is formed at the center thereof.

  Further, posture detection switches 121 and 122 are installed on the other main surface of the flat plate portion 102 with the center of the fitting flange 11 as the center of installation. The posture detection switches 121 and 122 are pressing switches, and are switches that are turned on when a portion protruding from the flat plate portion 102 is pressed by a predetermined amount. These posture detection switches 121 and 122 are installed on the circumference at a constant distance from the center of the installation at an interval of about 90 degrees, and the combination of contact with the switch pressing protrusions 331 and 332 of the support shaft 3 described above. Therefore, it is installed at a position where the above-mentioned three postures can be detected.

  A fixing button 13 having a fixing protrusion 131 is provided on the other main surface of the flat plate portion 102. The fixing protrusion 131 is formed at a position where the fixing protrusion 131 is fitted to the camera fixing recess 24 of the holding member 2 in a state where the holding member 2 and the camera 1 are assembled by fitting the fitting flanges 11 and 21 together. . The fixing button 13 is provided with an urging force from the inside of the flat plate portion 102 to the outside in the direction of the other main surface by a spring 132 installed in the flat plate portion 102, and when pressed by the user or the like from the outside. The structure is pushed into the flat plate portion 102.

The camera 1 and the holding member 2 having such a structure are mounted in the following procedure.
First, the user holds the camera 1 and brings the camera 1 close to the holding member 2. At this time, the claws of the fitting flange 11 of the camera 1 and the claws of the fitting flange 21 of the holding member 2 are brought close to each other so as not to contact each other. At this time, neither the fixing button 13 of the camera 1 nor the fan-shaped housing 202 of the holding member 2 is in contact. Next, the user rotates the camera 1 with the fixing button 13 of the camera 1 pushed into the flat plate portion 102 side of the camera 1 to fit the fitting flange 11 and the fitting flange 21 together. In this state, the fixing protrusion 131 of the fixing button 13 and the camera fixing concave portion 24 of the holding member 2 are substantially opposed to each other. The user releases the pressing of the fixing button 13. By this release, the fixing button 13 protrudes outward from the inside of the flat plate portion 102, and the fixing protrusion 131 and the camera fixing recess 24 are fitted. Thereby, the camera 1 and the holding member 2 are fixed, and the camera 1 is installed so as to be rotatable with respect to the support shaft 3.

(D-2) Function of Camera 1 In addition, the camera 1 includes a light receiving element 111, a video acquisition unit 112, a video data control unit 113, and an input / output unit 114 by using an optical system and an electronic circuit as functional units.
The light receiving element 111 receives light via an optical system including the fisheye lens 100, generates a photoelectric signal, and outputs it to the video acquisition unit 112. The video acquisition unit 112 generates video data based on the acquired photoelectric signal and supplies the video data to the video data control unit 113. The video data control unit 113 detects an on / off combination of the posture detection switches 121 and 122 and selects a shooting mode according to the combination. The shooting mode and the video correction are stored in advance in a storage unit (not shown), and when the video data control unit 113 detects the shooting mode, it reads out and executes the corresponding video correction process. The video data control unit 113 outputs the corrected video data to the input / output unit 114.

Specific examples of correction include the following.
10 to 12 are diagrams showing the concept of correction in each mode. FIG. 10 shows the document shooting mode, FIG. 11 shows the person shooting horizontal mode, and FIG. 12 shows the all-around shooting mode.

  When the document shooting mode is detected, as shown in FIG. 10, the video data control unit 113 corrects the circular video 680 acquired through the fisheye lens 100 into a square video 680 '. As a result, the original image 660 distorted in a circular shape is corrected to a rectangular original image 660 'and output. As a result, an easy-to-read original image in which the written characters are not distorted is output. In such a document photographing mode, for example, as shown by a two-dot chain line in FIG. 2, a document table 50 that covers the table 4 is installed, and a document 500 is installed on the top surface of the document table 50. It is. For example, it is useful when projecting a document on a larger screen or the like at a meeting or lecture.

  When the person photographing horizontal mode is detected, as shown in FIG. 11, the video data control unit 113 performs correction for converting the circular video 610 acquired through the fisheye lens 100 into a square video 610 '. At this time, the video data control unit 113 corrects and outputs a video 610 ′ having a predetermined width in the vertical direction from the center in the vertical direction and along the circumferential direction as video 610 ′. Thereby, the person images 611 to 615 distorted in the image 610 are output as the person images 611 ′ to 615 ′ whose distortion has been corrected. As a result, an image in which each person is not distorted is output. Such a person photographing horizontal mode is useful, for example, for acquiring a conference video during a conference. Furthermore, since it is the above-mentioned dimension, since it is comparatively small and unnoticeable, it can also be used as a security camera. Furthermore, since the camera can be separated, it is excellent in portability, so that it can be used as a portable security camera that can be used anywhere as long as a PC (personal computer) to be connected can be prepared.

  When the all-around shooting mode is detected, the video data control unit 113 performs correction to convert the circular video 640 acquired through the fisheye lens 100 into a square video 640 'as shown in FIG. At this time, the video data control unit 113 removes only the peripheral part except for the central part of the video 640 and corrects and outputs the result as a video 640 ′. As a result, the person images 641 to 644 distorted in the image 640 are output as the person images 641 ′ to 644 ′ whose distortion has been corrected. As a result, an image in which each person is not distorted is output.

  Further, when the free shooting mode is detected, the image distorted through the fisheye lens 100 is corrected by a known method to an image shot with a normal wide-angle lens or the like and output.

  The input / output unit 114 includes a USB port 141, a V-OUT 142, and a MIC-IN 143. When receiving output control from an information processing apparatus such as a PC via the USB port 141, the input / output unit 114 outputs the corrected video data via the USB port 141. On the other hand, if an external information processing apparatus is not connected to the USB port 141 or the output from the V-OUT 142 is selected, the input / output unit 114 converts the corrected video data into the NTSC format or the PAL format. The analog video signal is output via the V-OUT 142. The MIC-IN 143 outputs audio data to the video data control unit 113 when an audio cable is connected and an audio signal is supplied from an external microphone or the like.

  With such a configuration and processing, the camera 1 can output an optimal video according to the detected shooting mode. At this time, since the shooting mode is automatically detected by the posture detection switches 121 and 122 of the camera 1, an optimal image can be obtained without the user having to worry about the use state of the camera 1.

  Note that the above-described video correction method in each shooting mode is an example, and another correction method may be assigned to each shooting mode. In this case, the correction method for each shooting mode can be rewritten by a USB-connected PC or the like, and video correction is performed according to the rewritten content.

It is an external view which shows the structure of each aspect (person photographing horizontal mode) in the state which fixed the camera 1 to the holding member 2 in the camera system of this embodiment. It is an external view which shows the structure of each aspect (document photography mode) in the state which fixed the camera 1 to the holding member 2 in the camera system of this embodiment. It is an external view which shows the structure of each aspect (all surrounding photography mode) in the state which fixed the camera 1 to the holding member 2 in the camera system of this embodiment. It is the external appearance perspective view of the support shaft 3, and the front view of the support shaft 3 (the figure seen from the holding member 2 side). They are the external appearance perspective view which looked at the holding member 2 from the front side and the back side, respectively, and the front view of the holding member 2 (the figure seen from the support member 3 side). 1 is an external perspective view of a camera 1. FIG. It is a figure which shows the fitting state of the support shaft 3 and the holding member 2. FIG. It is a figure which shows each fitting state of the support shaft 3, the holding member 2, and the camera 1. FIG. 2 is a functional block diagram of the camera 1. FIG. It is a figure showing the concept of the correction | amendment in document photography mode. It is a figure showing the concept of the correction | amendment in a person photography horizontal mode. It is a figure showing the concept of the correction | amendment in all the circumference | surroundings imaging | photography mode.

Explanation of symbols

1-camera, 10-camera 1 housing, 11-fitting flange, 13-fixing button, 131-fixing protrusion, 132-spring, 100-fisheye lens, 121,122-posture detection switch, 111- Light receiving element, 112-video acquisition unit, 113-video data control unit, 114-input / output unit, 141-USB port, 142-V-OUT terminal, 143-MIC-IN terminal,
2-holding member, 20-housing member 2 housing, 200-support shaft side surface, 201-circular housing, 202-fan-shaped portion, 21-fitting flange portion, 2-fitting convex portion, 23-positioning Projection, 24-Recess for fixing camera, 25-Cap, 26-Screw, 27-Spring,
3-support shaft, 30-main body, 31-concave recess, 32-holder positioning portion, 321,322,323-holder positioning recess, 331,332-switch pressing projection, 34-stopper

Claims (5)

A camera that captures video,
A camera holding member for detachably holding the camera;
A support shaft member that supports the camera holding member in a mode in which the camera held by the camera holding member is in a preset position with respect to an installation location;
A camera system comprising:
The camera holding member is rotatably installed with respect to the support shaft member, and holds the camera in a mode in which a camera holding member side surface of the camera is separated from the support shaft member,
A plurality of protrusions having a shape substantially in contact with the camera are formed on a circumference of a predetermined radius from the rotation center of the camera holding member of the support shaft member,
A plurality of posture detection switches that are in combinations corresponding to the plurality of protrusions according to the rotation of the camera at positions corresponding to the circumference of the camera holding member side surface of the camera;
The camera detects a plurality of postures due to rotation or a detached state from the camera holding member by a combination of contact manners of the plurality of posture detection switches with the plurality of protrusions, and is different in each posture or detached state. Acquire video specification video,
Camera system. The camera includes a fisheye lens, acquires an image through the fisheye lens, and performs different image correction on the acquired image depending on the posture or the detached state.
The camera system according to claim 1. On the circumference of the support shaft member on the camera holding member side, recesses are formed at a plurality of positions corresponding to the plurality of postures, respectively.
Projections that fit into any of the recesses in each of the plurality of postures are formed at positions corresponding to the circumference on the support shaft member side of the camera holding member.
The camera system according to claim 1 or 2. The support shaft member and the camera holding member include a biasing unit that biases the support shaft member and the camera holding member in a direction in which the support shaft member and the camera holding member are in close contact with each other.
The camera system according to claim 3. The support shaft member includes a rotation-suppressing protrusion that contacts the camera-holding member and inhibits rotation when the camera-holding member exceeds a range of rotation by the plurality of postures.
The camera system according to claim 1.

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