JP2018163363A - Imaging System - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide an optimal imaging system that has a lens surface projected from a housing body.SOLUTION: An imaging system 10 according to the present embodiment comprises: an imaging body 12 that combines a plurality of optical systems 20A and 20B for capturing an image in a different direction and a plurality of solid state image pick-up elements 24A and 24B corresponding to the plurality of optical systems 20A and 20B; electric power supply means 14 that supplies electric power to the plurality of solid state image pick-up elements 24A and 24B; and a housing 18 that has a holding part for holding the imaging body 12 and a main body part holding the electric power supply means 14. The imaging system is configured to project, in a different direction, optical elements LA1 and LB1 positioned on at least a most subject side respectively owned by the plurality of optical systems 20A and 20B further than a housing surface where the main body part of the housing 18 is positioned.SELECTED DRAWING: Figure 1

Description

  The present invention relates to an imaging system, and more particularly to an imaging system having a lens surface protruding from a casing.

  As an imaging system for imaging the entire sky at once, a system using a plurality of wide-angle lenses such as fish-eye lenses and super-wide-angle lenses is known. In the imaging system, an image from each lens is projected onto the same or corresponding sensor and combined by image processing, thereby generating an all-sky image.

  In an imaging system using a plurality of lenses, when an imaging system is constructed with a configuration with few optical components, the angle of view assigned to each lens tends to increase. For example, when an all-sky image is captured using two fisheye lenses, each fisheye lens requires an angle of view of 180 ° or more.

  However, a lens with a wide angle of view tends to protrude from the housing because the radius of curvature of the lens on the incident side is small. In the imaging system in which the lens surface protrudes from the housing, there is a problem that the lens is easily damaged when the imaging system is dropped.

  As a technique for protecting a lens from damage, for example, Japanese Patent Laid-Open No. 62-191838 (Patent Document 1) is known. Patent Document 1 discloses a camera with a lens cover, characterized in that a push button-shaped lens cover opening / closing operation member is provided on the side surface of the lens barrel cover on the grip side. In the prior art of Patent Document 1, a push button-shaped lens cover opening / closing operation member is newly required, which increases the cost.

  Further, in the imaging system as described above, especially in the case of an imaging system having a linear housing shape, the optical system, the shutter button, and the power supply unit are often designed to be arranged in a straight line. In such an imaging system, the photographer holds between the position of the center of gravity of the imaging system and the position of the shutter button. When the shutter button is pressed, if the arrangement of the optical system and the power supply means that occupy a large proportion of the weight of the imaging system is inappropriate, camera shake tends to occur, and the photographer can shoot stably. It becomes difficult.

  The present invention has been made in view of the above problems in the prior art, and an object of the present invention is to provide an imaging system in which the balance of the center of gravity is improved in an imaging system in which a lens surface protrudes from a casing.

  Another object of the present invention is that, in an imaging system in which the lens surface protrudes from the housing, the lens surface may be damaged if the imaging system falls without adding new components. An object of the present invention is to provide an imaging system that can be suitably reduced.

In the present invention, in order to solve the above-described problems, an imaging body having an optical system and a solid-state imaging device, a power supply unit that supplies power to the solid-state imaging device, and a housing that holds the imaging body and the power supply unit are provided. An imaging system having the following features is provided. In the present imaging system, the optical system includes at least one optical element protruding from the housing. In this imaging system, the center of gravity of the part including the optical system is A, the center of gravity of the power supply means is B, the center of gravity of the entire imaging system is P, and the center of gravity A of the part including the optical system and the whole The distance AP of the center of gravity P and the distance BP of the center of gravity B of the power supply means and the entire center of gravity P are expressed by the following relational expression AP> BP
Meet.

  By adopting the above configuration, in an imaging system in which a lens surface protrudes from a casing, an imaging system in which an optical system and a power supply unit that occupy a large proportion of the weight of the imaging system are balanced can be provided. it can. In addition, when the imaging system is dropped without adding new parts, the possibility that the lens surface is damaged can be reduced.

1 is an overall view of an all-sky imaging system according to an embodiment. 2 is a detailed configuration diagram of two imaging optical systems in an imaging body of the omnidirectional imaging system according to the embodiment. The figure explaining the amount of sag in 1st lens LA1, LA2. The whole figure of the omnidirectional imaging system by other embodiments. The whole figure of the omnidirectional imaging system by other embodiments. The hexahedral view of the all-sky imaging system by other embodiment.

  Hereinafter, although embodiment of this application is described, embodiment of this invention is not limited to embodiment described below. In the embodiment described below, an example of an imaging system will be described using an all-sky imaging system 10 that includes an imaging body including two fisheye lenses in an optical system and a battery as power supply means.

  FIG. 1 is an overall view showing an omnidirectional imaging system 10 according to the present embodiment. The omnidirectional imaging system 10 shown in FIG. 1 includes an imaging body 12, a battery 14, controller boards 16A and 16B, and a housing 18 that holds these components 12, 14, 16A, and 16B. In the embodiment shown in FIG. 1, the image pickup body 12 includes two imaging optical systems 20A and 20B and two solid-state image pickup devices 24A and 24B. A combination of the imaging optical system 20 and the solid-state imaging device 24 one by one is referred to as an imaging optical system.

  Each of the imaging optical systems 20 illustrated in FIG. 1 is configured as 6 groups of 7 fisheye lenses. In the embodiment shown in FIG. 1, the fisheye lens that the imaging optical system 20 configures has an angle of view larger than 180 degrees (= 360 degrees / n; n = 2). The fisheye lens preferably has an angle of view of 185 degrees or more, and preferably has an angle of view of 190 degrees or more. By having such an angle of view, composition is performed in the image processing based on the overlapping areas.

  FIG. 2 is a diagram showing a detailed configuration of the two imaging optical systems 20A and 20B in the imaging body 12 shown in FIG. As shown in FIG. 1, the imaging optical systems are joined with the prisms as axes, but in FIG. 2, the two imaging optical systems 20A and 20B are drawn apart for convenience. Please note that there are. As shown in FIG. 2, the first imaging optical system 20A includes a front group composed of lenses LA1 to LA3, a right-angle prism PA that is a reflecting member, and a rear group composed of lenses LA4 to LA7. Including. An aperture stop SA is disposed on the object side of the fourth lens LA4. In the first imaging optical system 20A, a filter F and an aperture stop SA are disposed on the image side of the seventh lens LA7.

  Similarly, the imaging optical system 20B includes a front group composed of lenses LB1 to LB3, a right angle prism PB, and a rear group composed of lenses LB4 to LB7. An aperture stop SB is disposed on the object side of the fourth lens LB4. A filter F and an aperture stop SB are disposed on the image side of the seventh lens LB7.

  In a specific embodiment, the lenses LA1 to LA3 constituting the front group of the first imaging optical system 20A are, in order from the object side, a negative meniscus lens (LA1) made of an optical glass material, and a negative lens made of a plastic resin material. (LA2) and a negative meniscus lens (LA3) made of an optical glass material. The lenses LA4 to LA7 constituting the rear group are, in order from the object side, a biconvex lens (LA4) made of an optical glass material, a laminated lens of a biconvex lens (LA5) and a biconcave lens (LA6) made of an optical glass material, and a plastic resin material. This is a biconvex lens (LA7).

  In the specific embodiment described above, the lenses LB1 to LB3 constituting the front group of the second imaging optical system 20B are similarly made in order from the object side, the negative meniscus lens (LB1) made of an optical glass material, and a plastic resin material. A negative lens (LB2) and a negative meniscus lens (LB3) made of an optical glass material. The lenses LB4 to LB7 constituting the rear group are also, in order from the object side, a biconvex lens (LB4) made of an optical glass material, a laminated lens of a biconvex lens (LB5) and a biconcave lens (LB6) made of an optical glass material, and a plastic resin material. This is a biconvex lens (LB7).

  In these first and second imaging optical systems 20A and 20B, the negative lenses LA2 and LB2 made of the front group plastic resin material and the biconvex lenses LA7 and LB7 made of the rear group plastic resin material have both aspheric surfaces. is there. On the other hand, each lens made of the remaining optical glass material is a spherical lens.

  The right-angle prisms PA and PB disposed between the front group and the rear group are preferably made of a material having a refractive index of d-line (λ = 587.6 nm) larger than 1.8. The right-angle prisms PA and PB respectively internally reflect light from the front group toward the rear group. Accordingly, in each of the imaging optical systems 20A and 20B, the optical path of the imaging light beam passes through the right-angle prisms PA and PB. By constructing a right-angle prism with the high refractive index material, the optical path lengths in the right-angle prisms PA and PB are increased, and the optical path length between the front group and the rear group in the front group, the right-angle prism and the rear group is determined by the machine. Can be longer than the typical length. As a result, a fisheye lens can be comprised compactly.

  Further, by arranging the right-angle prisms PA and PB in the vicinity of the aperture stops SA and SB, it becomes possible to use a right-angle prism having a small outer shape, and the distance between the fisheye lenses can be reduced. Further, by adopting the arrangement of the right-angle prisms PA and PB as shown in FIG. 2, the parallax between the two optical systems can be reduced. Furthermore, as shown in FIGS. 1 and 2, by arranging the two imaging optical systems 20A and 20B so as to face each other, a more compact structure can be obtained, and a space area that is not imaged can be reduced.

  Here, FIG. 1 will be referred to again. The optical elements (lens, prism, filter, and aperture stop) of the two imaging optical systems 20A and 20B are positioned so that their optical axes are orthogonal to the center of the light receiving region of the corresponding solid-state imaging device 24, and The positional relationship is determined and held with respect to the solid-state imaging devices 24A and 24B by the lens barrel 26 so that the light receiving area becomes the imaging surface of the corresponding fisheye lens. That is, each of the imaging optical systems 20 is positioned so as to form an image to be imaged in the light receiving region of the solid-state imaging device 24 to be combined.

  Each of the solid-state imaging devices 24 is a two-dimensional solid-state imaging device in which a light receiving region forms an area area, and converts the light collected by the combined imaging optical system 20 into an image signal. The solid-state imaging devices 24A and 24B have a structure in which extremely small light receiving regions are separated from each other and arranged two-dimensionally on the light receiving surfaces. Information that is photoelectrically converted in each minute light receiving region constitutes each pixel.

  In the embodiment shown in FIG. 1, the imaging optical systems 20A and 20B have the same specifications, and are combined in opposite directions so that their optical axes match. The omnidirectional imaging system 10 is configured to capture the image of the omnidirectional image by combining the two imaging optical systems 20A and 20B and the two solid-state imaging devices 24A and 24B. In addition, by adopting the configuration shown in FIG. 1, it is possible to take an image of an object on the top of the housing 18.

  An image picked up by the first image pickup optical system is formed on the light receiving region of the two-dimensional solid-state image pickup device 24A. Similarly, the image picked up by the second image pickup optical system is formed on the light receiving region of the two-dimensional solid-state image pickup device 24B. The solid-state imaging devices 24A and 24B convert the received light distribution into image signals and input them to the controller boards 16A and 16B.

  An image processing unit and an output unit (not shown) are provided on the controller boards 16A and 16B. Image signals output from the solid-state imaging devices 24A and 24B are input to the image processing unit on the controller board 16. The image processing unit combines the image signals respectively input from the solid-state imaging device 24A and the solid-state imaging device 24B into one image to obtain an image with a solid angle of 4π radians (hereinafter referred to as “all-sky image”). And output to the output unit. Here, in the embodiment shown in FIG. 1, the omnidirectional image is generated, but a so-called panoramic image obtained by photographing 360 degrees only on the horizontal plane may be used.

  As described above, since the fisheye lens has an angle of view of 180 degrees or more, when composing the whole sky image by synthesizing the image signals output from the solid-state imaging devices 24A and 24B, overlapping images are used. The portion is used as a reference for joining images as reference data representing the same image. The output unit is configured as, for example, an external storage medium such as a display device, a printing device, an SD card, or a compact flash (registered trademark), and outputs a synthesized omnidirectional image.

  The battery 14 is power supply means for supplying power to the chips and components on the solid-state imaging devices 24A and 24B and the controller boards 16A and 16B. The battery 14 is configured using a primary battery such as an alkaline manganese primary battery or an oxyride primary battery, or a secondary battery such as a lithium ion secondary battery, a lithium ion polymer secondary battery, or a nickel hydride secondary battery.

  The all-sky imaging system 10 shown in FIG. 1 has a rod shape in which an imaging optical system is provided at one end. The housing 18 includes a main body unit that holds the modules including the controller boards 16A and 16B and the battery 14, and a lens holding unit that holds the imaging body 12 and is provided with openings that expose the first lenses LA1 and LB1. Become. The casing 18 has flat casing surfaces 18A and 18B of the main body.

  In the imaging optical systems 20 </ b> A and 20 </ b> B shown in FIG. 1, the first lenses LA <b> 1 and LB <b> 1 that are located closest to the object side protrude from the housing surfaces 18 </ b> A and 18 </ b> B of the main body in the housing 18. In a specific embodiment, the first lenses LA1 and LB1 are exposed to the outside of the housing 18.

  When a drop test of the imaging optical system 20A alone is performed, if the first lenses LA1 and LB1 are made of an optical glass material, the lens surface cracks under the condition of dropping from a height of about 1.5 m. There is a case. If the first lenses LA1 and LB1 are made of a plastic resin material, the lens surface may be scratched under the same conditions as described above. That is, if the photographer holds the omnidirectional imaging system 10 and accidentally slips off the hand, the first lens may be damaged. If the first lenses LA1 and LB1 are damaged, it is not possible to properly form an image on the light receiving surface of the solid-state imaging device 24, and it becomes difficult to obtain a good image.

  In the omnidirectional imaging system 10 shown in FIG. 1, the imaging body 12 and the battery 14 described above are main members that occupy a large proportion of weight. Therefore, the omnidirectional imaging system 10 according to the present embodiment has the following characteristics with respect to the arrangement of the imaging body 12 and the battery 14 that are the main members occupying the weight, based on the moment of the omnidirectional imaging system 10 as a whole. .

  In the omnidirectional imaging system 10 according to the present embodiment, the center of gravity of the imaging body 12 is A, the center of gravity of the battery 14 is B, the center of gravity of the entire celestial imaging system 10 is P, and the imaging body 12 The distance AP between the gravity center position A and the gravity center P and the gravity center position B and the distance BP between the gravity centers P of the battery 14 satisfy the following relational expression (1).

(Equation 1)
AP> BP (1)

  When the relational expression (1) is satisfied, the center of gravity of the entire omnidirectional imaging system 10 is biased toward the battery 14. Thereby, for example, when the all-sky imaging system 10 slips and falls from the hand, it is less likely to fall from the imaging body 12 side having the protruding optical element.

  In a preferred embodiment, a shutter button can be arranged at a position S between the center of gravity A of the image pickup body 12 and the entire center of gravity P in FIG. The shutter button is an imaging start input unit that is pressed by the photographer to input an instruction to start imaging by the imaging body 12. In the omnidirectional imaging system 10 according to the embodiment shown in FIG. 1, the imaging body 12, the shutter button, and the battery 14 are arranged on the same straight line x in the drawing, and the gravity center position A of the imaging body 12, the shutter button. It arrange | positions so that it may arrange in order of the position S and the gravity center P of the omnidirectional imaging system 10 whole. The shutter button is arranged on the front side of the housing 18 in FIG.

  The arrangement of the shutter button is not limited to the arrangement shown in FIG. FIG. 5 is an overall view showing an omnidirectional imaging system 10 according to another embodiment. In the omnidirectional imaging system 10 shown in FIG. 5, the shutter button 22 is positioned on the left side of the straight line x, that is, below the imaging optical system 20 </ b> A on the paper surface of FIG. 5, and the light of the imaging optical systems 20 </ b> A and 20 </ b> B. It is installed so as to be pressed in the direction along the axis. 5 is the same as FIG. 1 in that the center of gravity position A of the image pickup body 12, the shutter button position S, and the center of gravity P of the entire omnidirectional imaging system 10 are arranged in this order. FIG. 6 is a hexahedral view of the omnidirectional imaging system 10 shown in FIG. 5 according to another embodiment.

  In order for the photographer to hold the omnidirectional imaging system 10 stably, it is desirable to hold the vicinity of the center N of the shape of the omnidirectional imaging system 10, that is, between the position S and the position P. The photographer presses the shutter button disposed on the image pickup body 12 side from the center of gravity P in the holding state as described above. At this time, by adopting an arrangement configuration in which the center of gravity is biased toward the battery 14 side farther from the image pickup body 12 than the image pickup body 12, even if the shutter button is pressed, the moment on the battery 14 side is large, so The camera shake that causes the deterioration is suppressed. As a result, the photographer can stably shoot using the omnidirectional imaging system 10.

  The center of gravity of each of the members 12 and 14 can be determined by measuring the center of gravity of each member in the two-dimensional direction multiple times using a load cell (mass measuring instrument). it can. In the embodiment to be described, the center of gravity position A is the center of gravity of the entire imaging body 12 including the two imaging optical systems 20A and 20B, the lens barrel 26, and the solid-state imaging devices 24A and 24B. However, in another embodiment, the solid-state imaging device 24A may be excluded, and the center of gravity of the portion including the two imaging optical systems 20A and 20B and the lens barrel 26 may be set as the center of gravity position A. The center-of-gravity position B is the center of gravity of the battery 14, and in this embodiment, the cable that connects the battery 14 to the solid-state image sensor 24 is not included.

  In the all-sky imaging system 10, the mass of the imaging body 12 is m, the mass of the battery 14 is M, and the weight m of the imaging body 12 and the weight M of the battery 14 satisfy the following relational expression (2). Is preferred.

(Equation 2)
m <M (2)

  Further, in the omnidirectional imaging system 10, the center position of the shape of the entire omnidirectional imaging system 10 is N, and the weight m of the imaging body 12, the weight M of the battery 14, the gravity center position A of the imaging body 12, and the above-described center. It is preferable that the N distance AN and the center-of-gravity position B and the center N distance BN of the battery 14 satisfy the following relational expression (3).

(Equation 3)
m × AN <M × BN (3)

  When the relational expressions (2) and (3) are satisfied, the center of gravity of the entire omnidirectional imaging system 10 is biased toward the battery 14 side. Thereby, for example, when the all-sky imaging system 10 slips and falls from the hand, it is less likely to fall from the imaging body 12 side having the protruding optical element.

  The arrangement configuration described above is particularly effective for an imaging system in which the first lenses LA1 and LB1 have shapes protruding from the housing surfaces 18A and 18B. This is particularly effective for an imaging system in which the sag amount of the first lenses LA1 and LB1 is 3 mm or more. This is because, when the sag amount of the first lenses LA1 and LB1 is 3 mm or more, in the drop test from 1.5 m, the lens formed of the optical glass material is cracked, but the lens formed of the plastic resin material is scratched. , By becoming prominent. Here, the sag amount indicates the sag amount at the effective diameter, and does not include the sag amount at the ineffective diameter.

  The sag amount h is defined as shown in FIG. 3, where r is the radius of curvature of the convex lenses of the first lenses LA1 and LB1, R is the effective diameter (diameter) of the first lenses LA1 and LB1, and the radius of curvature r is It is suitable when normalized and the following relational expression (4) is satisfied.

(Equation 4)
1-1 cos {sin ⁻¹ (R / 2r)} ≧ 0.17 (4)

  For example, if the radius of curvature r of the first lens LA1, LB1 is 18 mm and the effective diameter R is 20 mm, the sag amount h of the first lens is about 3.03 mm, and the sag amount h The value (h / r) normalized by the curvature radius r is about 0.17, which satisfies the above-mentioned relation (4).

  For example, if the radius of curvature r of the first lens LA1, LB1 is 17 mm and the effective diameter R is 20 mm, the sag amount h of the first lens is about 3.25 mm. A value (h / r) obtained by normalizing the quantity h by the radius of curvature r is about 0.19, and the above-mentioned relation (4) is satisfied.

  Further, if the radius of curvature r of the first lens LA1, LB1 is 10 mm and the effective diameter R is 20 mm, the sag amount h of this first lens is about 10.00 mm, and the sag amount h The value (h / r) obtained by normalizing with the radius of curvature r is about 1, which satisfies the above relation (4). Since the upper limit of the normalized value (h / r) is 1, this value is the upper limit.

  Hereinafter, a material configuration for realizing the arrangement configuration of the imaging body 12 and the battery 14 that satisfy the relational expressions (1) to (3) will be described.

  In order to make the weight m of the imaging body 12 lighter than the weight M of the battery 14, that is, in order to satisfy the relational expression (3), the specific gravity of the lens used in the imaging optical system 20 of the imaging body 12 is small. Material may be adopted. As described above, in the specific embodiment, the imaging optical system 20 has a six-group, seven-lens configuration, and of these, the second lenses LA2, LB2 and the seventh lenses LA7, LB7 from the object side. Is formed of a plastic resin material. In other embodiments, the lenses are not limited to the second lenses LA2 and LB2 and the seventh lenses LA7 and LB7, and all or any part of the lenses LA1 to LA7 and LB1 to LB7 may be formed of a plastic resin material. Good.

As a material for forming the lens, a plastic resin material having a specific gravity smaller than 2.5 g / cm ³ (hereinafter, units are omitted) can be preferably used. As such plastic resin materials, cycloolefin resin (specific gravity 1.1), episulfide resin (specific gravity 1.46), thiourethane resin (specific gravity 1.35), (polyester) methacrylate (specific gravity 1.37) Polycarbonate (specific gravity 1.20), (urethane) methacrylate (specific gravity 1.17), (epoxy) methacrylate (specific gravity 1.19), diallyl carbonate (1.23), diallyl phthalate resin (specific gravity 1.27), Examples thereof include urethane-based resin (specific gravity 1.1), polymethyl methacrylate (specific gravity 1.18), and allyl diglycol carbonate (specific gravity 1.32). As the plastic resin material for forming the lens, it is more preferable to use a plastic resin material having a specific gravity of 1.1 or more and less than 1.25 so that the specific gravity is 2 times or more smaller than that of glass (specific gravity 2.5). Can do.

In order to satisfy the relational expression (3), it is preferable to employ a material having a small specific gravity not only for the lens but also for the lens barrel 26 that holds the lens. As a material for forming the lens barrel, a plastic resin material having a specific gravity smaller than 2.7 g / cm ³ can be preferably used. The plastic resin material that forms the lens barrel includes polycarbonate resin (PC), polyphenylene sulfide resin (PPS), acrylonitrile butadiene styrene resin (ABS), polybutylene terephthalate resin (PBT), polyethylene terephthalate resin (PET), and polystyrene resin. (PS), a polyphenylene ether resin (PPE), a polyamide resin (PA), and a composite material made of a filler such as glass fiber, carbon fiber, pitch-based, or PAN (Polyacrylonitrile) -based carbon fiber. it can.

  As the plastic resin material forming the lens barrel, it is more preferable to use a plastic resin material having a specific gravity of 1.3 or more and less than 1.35, which has a specific gravity that is twice or more smaller than that of aluminum (specific gravity 2.7). it can. As a material for forming the lens barrel, for example, a glass-containing polycarbonate material can be used.

  Referring again to FIG. 1, the entire sky imaging system 10 can preferably include a shock absorber 30 disposed on the exterior of the housing 18 in the vicinity of where the battery 14 is disposed. As the impact absorbing material, a low elastic rubber material such as a low resilience urethane rubber, an impact absorbing gel molded product, or the like can be used.

  In the arrangement configuration described above, for example, even when the all-sky imaging system 10 has dropped from the hand, it is easy to drop from the battery 14 side. With the configuration including the shock absorber 30, the housing 18 and the module to be accommodated can be suitably protected when dropped.

  In the above-described embodiments, the omnidirectional imaging system capable of photographing the whole sky using two imaging optical systems has been described. However, the present invention is not limited to a state in which two imaging optical systems are combined. In addition, the present invention can be applied to a monocular rod-like camera. In the above description, a fish-eye lens in which distortion is not corrected has been described as an example. However, an all-sky imaging system can be configured using an ultra-wide-angle lens in which distortion is corrected.

  Furthermore, the present invention may be applied to an imaging system in general that can capture the entire sky using an imaging optical system having a natural number n greater than 2. For example, three wide-angle lenses (imaging optical systems) having an angle of view larger than 360 degrees / 3 = 120 degrees are arranged radially in the same plane, and an image pickup system is configured by combining solid-state image pickup elements with each. be able to. Although the image obtained in this case is not an all-sky image, a 360-degree horizontal panoramic image can be captured, which is excellent as an in-vehicle camera or a security camera. The image to be captured may be a still image or a moving image.

  Further, in the embodiments described above, the omnidirectional imaging system having a linear shape has been described. However, the above arrangement configuration can also be suitably applied to an omnidirectional imaging system having other shapes. FIG. 4 is a diagram illustrating an entire omnidirectional imaging system according to another embodiment. Since the omnidirectional imaging system 50 according to the embodiment shown in FIG. 4 has a configuration similar to the omnidirectional imaging system 10 of the embodiment shown in FIG.

  An all-sky imaging system 50 according to another embodiment shown in FIG. 4 includes an imaging body 52, a battery 54, a controller board (not shown), and a housing 58 that holds these components. In the embodiment shown in FIG. 4, the imaging body 52 includes two imaging optical systems configured as seven fisheye lenses in six groups, and two solid-state imaging devices, as in the embodiment shown in FIG. 1. It is configured. The imaging optical system shown in FIG. 4 has the same configuration as that of the embodiment shown in FIGS. 1 and 2, but a right-angle prism is not provided between the front group and the rear group, and the optical axis is mutually connected. Are matched in opposite directions while matching.

  The all-sky imaging system 50 shown in FIG. 4 has a spherical shape in which imaging optical systems are provided on both sides. The housing 58 has a structure in which openings for exposing the first lenses LA1 and LB1 are provided in a main body portion that holds the imaging body 52, the controller board, and the battery 54. In the imaging optical system shown in FIG. 4, the first lenses LA <b> 1 and LB <b> 1 located closest to the object side protrude from the surface of the housing 58 and are exposed to the outside of the housing 58.

  Similarly, in the all-sky imaging system 50 shown in FIG. 4, the imaging body 52 and the battery 54 described above are main members that occupy a large proportion of weight. Therefore, the omnidirectional imaging system 50 according to the embodiment shown in FIG. 4 has the following features with respect to the arrangement of the imaging body 52 and the battery 54 which are the main members occupying the weight.

  In the omnidirectional imaging system 50 according to the embodiment shown in FIG. 4, the imaging center 52 is set to A, the center of gravity of the battery 54 is set to B, and the centroid of the entire imaging system 50 is set to P. The distance AP between the center of gravity position A and the center of gravity P of the body 52 and the distance BP between the center of gravity B and the center of gravity P of the battery 54 satisfy the relational expression (1).

  When the relational expression (1) is satisfied, the entire center of gravity is biased toward the battery 54 in the spherical all-sky imaging system as shown in FIG. Further, by providing the shock absorber 70 on the exterior of the casing 58 near the battery 54, the casing can be suitably protected when dropped.

  The conditions for defining other arrangement configurations are the same as those in the embodiment described with reference to FIG. 1, and thus detailed description thereof is omitted.

  As described above, according to the embodiment of the present invention, it is possible to provide an imaging system in which the lens surface protrudes from the housing, and the balance of the center of gravity is improved. Further, in the above imaging system, it is possible to suitably reduce the possibility that the lens surface is damaged when the imaging system is dropped without adding new parts.

  Hereinafter, the imaging system according to the embodiment of the present invention will be described more specifically with reference to examples. However, the present invention is not limited to the examples described later.

  An omnidirectional imaging system 10 having a linear shape shown in FIG. 1 was configured. The imaging optical systems 20A and 20B have a 6-group, 7-lens configuration, and the second lens LA2, LB2 and the seventh lens LA7, LB7 from the object side are plastic lenses. The plastic lens was formed using Zeonex (registered trademark) E48R plastic resin material (specific gravity 1.1). The lens barrel 26 was formed using a glass-filled polycarbonate (PC + GF) material having a specific gravity of 1.3.

  The curvature radii r of the first lenses LA1 and LB1 were 17 mm, the effective diameter R was 20 mm, and the sag amount h was about 3.25 mm. Further, the protruding amounts of the first lenses LA1 and LB1 from the housing surfaces 18A and 18A were about 5 mm. Therefore, the relational expression (4) is satisfied.

  The center of gravity position A of the image pickup body 12 combining the lenses LA1 to 7 and LB1 to 7, the right-angle prisms PA and PB, the lens barrel 26, and the solid-state imaging devices 24A and 24B, the center of gravity P of the whole, and the center of gravity position B of the battery 14 Was measured, the distance AP was 38 mm, and the distance BP was 26 mm. The weight m of the image pickup body 12 was 17 g, and the weight M of the battery 14 was 25 g. Further, when the center of gravity position A of the imaging body 12, the center of gravity B of the battery 14, and the distance AN and BN of the center N of the shape of the all-sky imaging system 10 were measured, the distance AN was 35 mm, and the distance BN was It was 29 mm. Therefore, the above relational expressions (1) to (3) are satisfied.

  A shutter button was provided at a position S where the distance PS was 10 mm. Even when the shutter button at point S was pressed with a pressure of 10 g, stable shooting could be performed.

  An omnidirectional imaging system 50 having a spherical shape shown in FIG. 4 was configured. Each of the imaging optical systems has a 6-group, 7-lens configuration, and the second lens LA2, LB2 and the seventh lens LA7, LB7 from the object side are made of Zeonex (registered trademark) E48R plastic. A lens was used. The lens barrel 26 was made of glass-containing polycarbonate (PC + GF).

  The curvature radius r of the first lens LA1, LB1 was 17 mm, the effective diameter R was 20 mm, and the sag amount h was about 3.5 mm. Therefore, the relational expression (4) is satisfied.

  When the center of gravity position A of the image pickup body 52 combining the lenses LA1 to 7 and LB1 to 7, the right angle prisms PA and PB, the lens barrel, and the solid-state image sensor, the entire center of gravity P, and the center of gravity position B of the battery 54 are measured. The distance AP was 15 mm, and the distance BP was 10 mm. The weight m of the image pickup body 52 was 17 g, and the weight M of the battery 54 was 25 g. The distance AN was 0 mm, and the distance BN was 25 mm. Therefore, the above relational expressions (1) to (3) are satisfied.

  Using the same imaging optical systems 20A and 20B and the lens barrel 26 as in the first embodiment, the omnidirectional imaging system 10 having the linear shape shown in FIGS. 5 and 6 was configured. The curvature radii r of the first lenses LA1 and LB1 were 17 mm, the effective diameter R was 20 mm, and the sag amount h was about 3.25 mm. Further, the protruding amounts of the first lenses LA1 and LB1 from the housing surfaces 18A and 18A were about 5 mm. Therefore, the relational expression (4) is satisfied.

  The center of gravity position A of the image pickup body 12 combining the lenses LA1 to 7 and LB1 to 7, the right-angle prisms PA and PB, the lens barrel 26, and the solid-state imaging devices 24A and 24B, the center of gravity P of the whole, and the center of gravity position B of the battery 14 Was measured, the distance AP was 47 mm, and the distance BP was 32 mm. The weight m of the image pickup body 12 was 17 g, and the weight M of the battery 14 was 25 g. Further, when the center of gravity position A of the image pickup body 12, the center of gravity position B of the battery 14, and the distance AN and BN of the center N of the shape of the omnidirectional imaging system 10 were measured, the distance AN was 42 mm, and the distance BN was It was 37 mm. Therefore, the above relational expressions (1) to (3) are satisfied. The shutter button 22 is provided at a position S on the lens surface on the lens forming side where the distance PS is 7.5 mm. Even when the shutter button at point S was pressed with a pressure of 10 g, stable shooting could be performed.

  The embodiments and examples of the present invention have been described above. However, the embodiments and examples of the present invention are not limited to the above-described embodiments and examples, and other embodiments, examples, Additions, changes, deletions, and the like can be made within the scope that can be conceived by those skilled in the art, and any embodiment is included in the scope of the present invention as long as the effects and advantages of the present invention are exhibited.

The present invention also discloses the following.
(Appendix 1)
An imaging system comprising: an imaging body having an optical system and a solid-state imaging element; power supply means for supplying power to the solid-state imaging element; and a housing for holding the imaging body and the power supply means.
The optical system includes at least one optical element protruding from the housing,
The center of gravity position of the part including the optical system is A, the center of gravity position of the power supply means is B, the center of gravity of the entire imaging system is P, and the center of gravity position A of the part including the optical system and the center of gravity P And the distance BP between the center of gravity position B of the power supply means and the entire center of gravity P are expressed by the following relational expression AP> BP
An imaging system that meets the requirements.
(Appendix 2)
The imaging system further includes imaging start input means for inputting an instruction to start imaging by the imaging body,
The optical system, the imaging start input unit, and the power supply unit have a position of the imaging start input unit as S, a gravity center position A of a portion including the optical system, a position S of the imaging start input unit, and the whole The imaging system according to appendix 1, wherein the imaging system is arranged in the order of the center of gravity P.
(Appendix 3)
At least one optical element protruding from the housing is a convex lens, and the convex lens has a radius of curvature of the convex lens as r and an effective diameter as R.
1-1 cos {sin ⁻¹ (R / 2r)} ≧ 0.17
The imaging system according to appendix 1 or 2, wherein
(Appendix 4)
The weight of the portion including the optical system is m, the weight of the power supply means is M, and the weight m of the portion including the optical system and the weight M of the power supply means are expressed by the following relational expression m <M
The imaging system according to any one of supplementary notes 1 to 3, wherein
(Appendix 5)
The center position of the shape of the entire imaging system is N, the weight m of the portion including the optical system, the weight M of the power supply means, the center of gravity position A of the portion including the optical system, and the distance AN of the center N And the distance BN between the center of gravity B of the power supply means and the center N is expressed by the following relational expression m × AN <M × BN
The imaging system according to appendix 4, wherein
(Appendix 6)
The imaging system according to any one of appendices 1 to 5, wherein the optical system includes, as the optical element, one or more lenses made of a material having a specific gravity smaller than 2.5 g / cm ³ .
(Appendix 7)
The optical system includes one or more lenses made of a resin material as the optical element, and an optical element holding member that is made of a resin material and fixes the optical element. The imaging system described in 1.
(Appendix 8)
The imaging system according to any one of appendices 1 to 7, further comprising an impact absorbing material disposed in an exterior of the housing in the vicinity of where the power supply unit is disposed.
(Appendix 9)
The imaging system according to any one of appendices 1 to 8, wherein the optical system includes n imaging optical systems each having an angle of view of 360 degrees / n or more.

DESCRIPTION OF SYMBOLS 10 ... All-sky imaging system, 12 ... Imaging body, 14 ... Battery, 16 ... Controller board, 18 ... Housing, 20A ... Imaging optical system, 20B ... Imaging optical system, 22 ... Shutter button, 24A, 24B DESCRIPTION OF SYMBOLS ... Solid-state image sensor, 26 ... Lens barrel, 30, 70 ... Shock absorber, 50 ... All-round imaging system, 52 ... Imaging body, 54 ... Battery, 58 ... Housing, F ... Filter, LA, LB ... Lens, PA, PB ... right angle prism, SA, SB ... aperture stop

JP-A-62-191838

Claims (3)

An imaging system,
Optical system,
Shutter button,
A housing for holding the optical system,
The lens located on the most object side in the optical system protrudes from a part of the housing between the shutter button and the lens,
The center of the imaging system is located between the center of gravity of the imaging system and the lens. The imaging system includes:
An imaging body including the optical system and an imaging device;
The image pickup system according to claim 1, further comprising: a power supply unit that supplies power to the image pickup device, wherein the center of the image pickup system exists between the center of gravity of the power supply unit and the lens. . The weight of the imaging body is m, the weight of the power supply means is M, and the weight m of the imaging body and the weight M of the power supply means are expressed by the following relationship m <M
The imaging system according to claim 2, wherein: