JP2006135894A - Digital camera with built-in projector - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To make a digital camera small-sized and to reduce costs while including a projector function. <P>SOLUTION: There are provided a light source for emitting light; a first optical system including a projecting and photographing lens 3; a second optical system for returning the light from the light source on mirrors 6b and 6c and guiding the light to the first optical system; and an imaging device 8 capable of entering and leaving the second optical system. If the imaging device 8 is located inside the second optical system, the imaging device 8 receives light flux from an object via the first optical system. <P>COPYRIGHT: (C)2006,JPO&NCIPI

Description

  The present invention relates to a digital camera, and more particularly to a digital camera with a built-in projector function.

  In recent years, in cameras, digital cameras, and video cameras, proposals have been made to add various functions in addition to the imaging function. For example, in a digital camera, there has been proposed a function of allowing a photographed image to be immediately viewed on a liquid crystal display (LCD) or a projector function.

  According to both of the above functions, it is possible to display an image at a place where a computer device or an image reproduction device cannot be used or is inconvenient to use. In addition, it is possible to save the trouble of connecting, setting, and operating computer equipment and image playback equipment.

  The following technologies are disclosed as technologies related to a camera having a projector function.

  For example, Patent Document 1 discloses a technique of an electronic camera that allows a large number of people to view an image without using a projection device such as a projector. In this technique, a photographing lens that is also used as a projection lens for a camera is also used as a projection lens for a projector.

  Patent Document 2 also discloses a technique of a camera having a projector function. In this technique, switching between a function as an imaging device and a function as a projector is performed mainly by mirror switching.

  Patent Document 3 discloses a technique of a photographic camera capable of observing an image formed on a developed film. In this technique, when the projector mode is switched, an image of a desired frame of the developed film sent from the film cartridge can be projected at the photographing position on the front surface of the camera body by the illumination light from the illumination unit.

Patent Document 4 discloses a technique of an electronic viewfinder having a projection function. In this technique, an image displayed on a liquid crystal display unit of an electronic viewfinder is projected onto an external screen of the viewfinder through an eyepiece lens by illumination from a light source. Further, an amplifying unit for amplifying the audio signal and a speaker are incorporated, and audio reproduction is also possible.
Japanese Patent Laid-Open No. 5-137039 JP 2002-369050 A JP 2001-42415 A JP-A-6-86108

  However, it is difficult for a digital camera having a function that allows a photographed image to be immediately viewed on a liquid crystal display device (LCD) because of the small area of the display portion of the liquid crystal display device. It was. Moreover, this problem becomes more serious as the camera becomes smaller.

  As for the projector function, if the camera is provided with the projector function using the techniques described in Patent Document 1 and Patent Document 2, the portability of the device itself is inevitably deteriorated and the cost is increased.

  The technique described in Patent Document 3 is a technique related to a photographic camera, and is not a proposal of a technique related to a digital camera.

  The technique described in Patent Document 4 is a technique related to an electronic viewfinder provided with a liquid crystal display unit mounted on a video camera, and it can be said that it is difficult to apply the technique to a digital camera as it is.

  The present invention has been made in view of the above circumstances, and an object of the present invention is to provide a digital camera with a built-in projector that realizes miniaturization and cost reduction while being a digital camera having a projector function.

  To achieve the above object, a digital camera with built-in projector according to a first aspect of the present invention includes a light source that emits light, a first optical system that includes a photographing lens, and light from the light source by a plurality of mirrors. A second optical system that is folded back and led to the first optical system; and an image pickup device capable of entering into the second optical system and retracting from the second optical system. When the image pickup device is located in the second optical system, the image pickup device receives a subject light beam through the first optical system.

  In order to achieve the above object, a projector built-in digital camera according to a second aspect of the present invention includes a light source that emits light and a function of guiding light from outside the housing of the projector built-in digital camera into the housing. And a first optical system having a function of guiding light from the inside of the casing to the outside of the casing, and the first optical system disposed in the casing, and the light from the light source is folded back by a plurality of mirrors. A second optical system that leads to the optical system; and a second optical system that is disposed in the housing and is capable of moving back and forth in the second optical system and is located in the second optical system. An image sensor that receives a subject light beam from outside the housing via an optical system, and at least one of the plurality of mirrors constituting the second optical system is arranged two-dimensionally A plurality of micromirrors, and the plurality of micromirrors Generating a projection image by changing the inclination for each color, the generated projection image is characterized in that it is projected on the projection surface of the housing outside the body through the first optical system.

  According to the present invention, an optical path required for image projection is turned back by using a reflecting mirror, and further, an image pickup system is arranged in the optical system, so that the housing of the digital camera can be effectively used as a projector device. Therefore, it is possible to provide a digital camera with a built-in projector that can efficiently reduce the size and cost of a digital camera having a projector function by efficiently storing various optical systems and configurations.

  A projector built-in digital camera according to an embodiment of the present invention will be described below with reference to the drawings.

  First, FIG. 1A is a schematic external view of a projector built-in digital camera 1 according to this embodiment. FIG. 4B is a cross-sectional view of the digital camera with built-in projector according to the present embodiment taken along the cutting plane 2, and includes a projection lens / shooting lens 3 as a first optical system, and a second lens. Schematic representation of the mutual positional relationship (when used as a projector) between the imaging device 8 and the digital mirror device (hereinafter referred to as DMD element) 4 and the irradiation optical systems 6b to 6c, which are components of the optical system of FIG. FIG.

  The DMD element 4 is a member as described below. The DMD element is a micro mirror (hereinafter referred to as a pixel mirror) for resolution that is physically arranged on the device, and is ON or OFF, for example, +10 degrees at the ON position and −10 degrees at the OFF position. This is an element having a structure in which the tilt is changed. Therefore, by switching the ON / OFF position according to the pixel value of 1, 0, the pixel mirror changes the direction of the light beam incident from the light source to the projection lens (in this embodiment, the projection lens / photographing lens 3 as well). , And so on), or can be deflected in a different direction from the projection lens. ON / OFF of these pixel mirrors is individually controlled in accordance with display data by a pixel control circuit.

  First, a projection lens / shooting lens 3 is provided on the front surface of the projector built-in digital camera 1. The projection lens / shooting lens 3 is used as a projection lens when the built-in projector digital camera 1 is used as a projector. On the other hand, when used as a camera, it is used as a photographing lens. The arithmetic control means 20 (see FIG. 2) controls the projection lens / photographing lens 3 shown in FIG. 1 through the lens control means 12a (see FIG. 2) to perform focusing.

  Further, a release button 14a is provided on the upper side surface of the digital camera 1 with a built-in projector as shown in FIG. By operating the release button 14a, a subject image is formed on the image sensor 8 inside the projector built-in digital camera 1 via the projection lens / shooting lens 3.

  A liquid crystal monitor 16 is provided on the back of the projector built-in digital camera 1 as shown in FIG. The liquid crystal monitor 16 is a small display that is an LCD (Liquid Crystal Display). By providing the liquid crystal monitor 16, a captured image can be displayed. In FIG. 1A, reference numeral 18 denotes a strobe light emitting unit. Reference numeral 18a denotes a dial, which will be described with reference to FIG.

  FIG. 2 is a block diagram of a circuit for controlling the projector built-in digital camera according to the present embodiment.

  As shown in the figure, the strobe light emitting unit 18 and the dial 18a are provided at positions close to each other. The strobe light emitting unit 18 includes a xenon (Xe) tube 18 b that is a xenon tube filled with xenon (Xe) gas and a reflector 17. The xenon (Xe) tube 18b is a light source, and emits a very short flash of tens of thousands to one millions of seconds when the xenon (Xe) gas in the tube is ionized and discharged. Based on this principle, the strobe light emitting unit 18 provides auxiliary light at the time of shooting (especially necessary when the amount of light irradiating the subject is small). The light emitted from the xenon (Xe) tube 18b can be rotated by rotating the reflector 17 by operating the dial 18a.

  When the reflector 17 is rotated as described above to emit light downward when the projector built-in digital camera 1 is set up (see FIG. 2B), the interlock mechanism 19 causes the dial 18a to rotate. In conjunction with the operation, the image sensor 8 retreats from the optical path. Thereby, the light from the strobe light emitting unit 18 emitted from the light guide 21 can be projected toward the DMD element 4 through the irradiation optical system without being blocked by the imaging element 8.

  Further, the CPU in the figure represents an arithmetic control means 20 comprising a microcomputer or the like. The arithmetic control means 20 detects the operating state of the switch 14 that is turned on by operating the release button 14a, and controls the image processing circuit 22 according to the operating state. Through this control, the subject image formed on the image sensor 8 is recorded in the memory 22a (see FIG. 3), or the DMD element 4 and the liquid crystal monitor 16 (see FIG. 1 (b) through the reproduction circuit 16a (see FIG. 3). ))). The lens control means 3a shown in the figure is a member that moves the position of the projection lens / shooting lens 3 under the control of the arithmetic control means 20.

  The lens 6a is a member used when the projector built-in digital camera according to the present embodiment is used as a projector, and will be described in detail with reference to FIG.

  Next, the configuration of a circuit (hereinafter referred to as a strobe controller) for controlling the strobe light emitting unit 18 in the projector built-in digital camera according to the present embodiment will be described with reference to FIG.

  First, when the projector built-in digital camera 1 is used as a camera, a secondary battery 26 is used as a power source to be supplied to the arithmetic control means 20. That is, the arithmetic control unit 20 receives supply of electric energy from the secondary battery 26.

  In addition, regardless of whether it is used as a camera or a projector, the AC voltage supplied from the AC power supply 28 is converted into a DC voltage by the AC / DC converter circuit 30. In this way, the charge control circuit 32 controls the charging of the secondary battery 26 by the power supplied by applying the DC voltage. In FIG. 3, the inside of the broken line portion including the AC / DC converter circuit 30 is the charger 31 of the projector built-in digital camera 1 according to this embodiment. Further, when the secondary battery 26 is charged, the arithmetic control means 20 monitors the charging status of the secondary battery. According to the monitoring result, the voltage and current supplied to the secondary battery 26 by the charge control circuit 32 are controlled by the control of the arithmetic control means 20.

  The energy stored in the secondary battery 26 in this way is supplied to the main capacitor 40 through the booster circuit 34, the diode 36 and the diode 38 under the control of the arithmetic control means 20. Here, although the battery voltage of the secondary battery 26 is several V level, the charging voltage of the main capacitor 40 is about 300V. That is, boost charging is performed.

  In the step-up charging, the voltage determination unit 46 monitors the voltage generated during charging between the diode 36 and the diode 38 under the control of the arithmetic control unit 20. Based on the monitoring result, the calculation control means 20 determines whether or not to continue the charging operation, and controls the booster circuit 34 according to the determination result, whereby the boosting charging operation described above is performed.

  When the main capacitor 40 is charged as described above, the arithmetic control unit 20 controls the trigger circuit 48 to apply the voltage of the main capacitor 40 to the xenon (Xe) tube 18b. Then, the xenon gas in the xenon (Xe) tube 18b is ionized, and the xenon (Xe) tube 18b is in a state where it can be energized. In this state, when the IGBT 50 is turned on, the xenon (Xe) tube 18b is discharged and flashes. That is, the discharge control of the xenon (Xe) tube 18b is performed by turning on / off the IGBT 50. Hereinafter, the current flowing through the xenon (Xe) tube 18b when the xenon (Xe) tube 18b is discharged is referred to as strobe current (ST).

  Here, the strobe current and the timing of the exposure operation are shown in the graphs of FIGS. Hereinafter, each graph will be described with reference to FIG.

  When used as a camera, as shown in the graph of (a), the xenon (Xe) tube 18b is pulse-emitted only once in synchronization with the exposure of the digital camera 1 with a built-in projector. Thereby, the flash generated at that time is used as auxiliary light for illuminating the subject at the time of photographing.

  Note that the light emission amount at this time can be switched according to the distance between the projector built-in digital camera 1 and the subject by using the distance detection circuit 52 (known technology) shown in FIG. Further, if the photometry circuit 54 (known technique) shown in FIG. 3 is used, the arithmetic control means 20 determines whether or not to perform the strobe irradiation as described above from the output of the photometry circuit 54, and performs control according to it. It can be carried out.

  On the other hand, when used as a projector, the main capacitor 40 needs to be charged in advance. Note that AC voltage is supplied from the AC power source 28, but is converted into a DC voltage of 100 V by the AC / DC converter circuit 30. Further, the arithmetic control means 20 controls the switch circuit 42 so that the DC voltage is applied to the main capacitor 40 via the diode 44 and charging is performed.

  When the main capacitor 40 is charged as described above, it can be used as a projector. When used as a projector, the strobe current is continuously turned ON / OFF as shown in the graph of FIG. By continuing this operation, light emission can be continued for a desired viewing time and image projection can be performed.

  At this time, it is possible to perform screen projection more preferably by shortening the pulse interval of the strobe current shown in the graph of (b) sufficiently to the extent that the projection screen does not flicker.

  The optical path setting employed in the projector built-in digital camera according to this embodiment will be described below.

First, as shown in FIG. 5, it is assumed that light emitted from a small uniform light source such as the light guide 21 is uniformly irradiated to a large surface such as the DMD element 24 through the lens 6a. For this purpose, L ₂ must be longer than L ₁ as shown in FIG. Under such circumstances, the apparatus becomes large due to the optical path. Further, if the surface of the DMD element 24 is made smaller, resolution degradation, enlargement ratio degradation, and the like occur, and image quality deteriorates. For this reason, it is not possible to shorten the optical path by reducing the surface of the DMD element 24.

  In this embodiment, as shown in FIG. 6, by using the reflecting mirrors 6b and 6c, the light from the light guide 21 is irradiated to the DMD element 24 through the lens 6a. By using the reflecting mirror in this way, it is possible to take an optical path of the same distance in a smaller space than in the case of taking an optical path at a linear distance. That is, the device can be miniaturized by effectively using the space by turning the optical path. As described above, switching between the camera function and the projector function is performed by moving the image sensor 8 into or away from the optical path as shown in FIG.

  Here, an actual use scene example when using the projector built-in digital camera 1 according to the present embodiment will be described with reference to FIG. (A) shows a scene used as a camera, and (b) shows a scene used as a projector.

  (A) shows a state in which the user 56 holds the projector built-in digital camera 1 and photographs the subject 58. This is a scene where the projector built-in digital camera 1 according to the present embodiment is used as a normal camera.

  On the other hand, (b) shows a state in which the projector built-in digital camera 1 according to the present embodiment is used as a projector. Here, the AC power supply 28 is connected to the digital camera 1 with a built-in projector, and further leans against the charger stand 60. The above-described charger 31 is stored in the casing of the charger stand 60. The user (viewer) 56a and the user (viewer) 56b are viewing the projection screen projected by the projector built-in digital camera 1. As described above, when the projector built-in digital camera 1 according to this embodiment is used as a projector, the strobe light emitting unit 18 is used as a light source for image projection.

  As described above, the circuit of the strobe control unit (see FIG. 3) in the camera has a high voltage capacitor and a light emitting unit with a large amount of light. By diverting the light emitting unit and the strobe control unit to a function to be newly added, the cost performance of the product can be improved. In the present invention, by using these as light sources in the projector function, a camera having both photographing and projection functions can be realized with high cost performance.

  Hereinafter, operation control of the projector built-in digital camera 1 according to the present embodiment will be described with reference to a flowchart shown in FIG.

  First, in S1, the arithmetic control unit 20 determines whether or not the release button 14a of the projector built-in digital camera 1 has been pressed, and determines whether or not to perform shooting. Here, if the release button is pressed, it is determined that photographing is to be performed and the Y branch is made and the process proceeds to S2.

  In S2, the arithmetic control unit 20 determines whether or not the luminance is low from the output of the above-mentioned photometric circuit 54 (see FIG. 3). If it is determined in this step that the brightness is low, the Y branch is taken and the process proceeds to S3.

  In S3, strobe emission as auxiliary light is performed under the control of the arithmetic control means 20 in order to more accurately detect the subject distance (S4). At the same time, in S4, the distance detection circuit 52 (see FIG. 3) detects the distance between the projector built-in digital camera 1 and the subject under the control of the arithmetic control means 20.

  In S5, the arithmetic control unit 20 performs focus control according to the distance detection result in S4. In step S6, flash photography is performed under the control of the arithmetic control unit 20.

  The operation control in the case of using the projector built-in digital camera 1 as a camera and performing strobe shooting because of low brightness has been described above. If the main capacitor 40 required for strobe emission is not sufficiently charged, at least one of light, sound and vibration is used to warn the user to that effect. Of course, you may be prompted to charge.

  On the other hand, the case where it is used as a camera and the brightness is not low at the time of shooting will be described. In this case, after branching S1 to Y, branching into N is performed in S2 because the brightness is not low, and the process proceeds to S10. In S10, the arithmetic control unit 20 performs focus control. In subsequent S11, normal shooting without flash emission is performed.

  The focus control in S10 may be performed simply using the output of the distance detection circuit 52, or the arithmetic control unit 20 performs the focus control so that the output of the image sensor 8 becomes a high contrast signal. You may take the method of doing.

  After performing strobe shooting in S6 described above and after performing normal shooting in S11 described above, the process proceeds to S7. In S <b> 7, the image processing circuit 22 performs image processing such as color correction, edge processing, and compression on the image data acquired by photographing under the control of the arithmetic control unit 20. In subsequent S8, the image data subjected to the image processing in S7 is recorded in the memory 22a under the control of the arithmetic control means 20.

  The operation control when the projector built-in digital camera 1 according to this embodiment is used as a camera has been described above with reference to the flowchart of FIG.

  Hereinafter, operation control when the digital camera 1 with a built-in projector is used as a projector and when a charging operation is performed will be described in the flowchart of FIG. In the present embodiment, when the projector built-in digital camera 1 is used as a projector, the state shown in FIG. 2A is changed to the state shown in FIG. 2B by operating the dial 18a as described above. Then, the projection direction of the light by the strobe light emitting unit 18 is switched, and in conjunction with this switching operation, the arithmetic control means 20 switches to the projector mode in which the projector built-in digital camera 1 is used as a projector.

  Therefore, in the above-described S1, when it is determined that shooting is not performed in N, branching of the light projection direction by the strobe light emitting unit 18 is first performed, that is, the projector mode is set. The arithmetic and control unit 20 determines whether or not it has been switched (S19). If it is determined by the arithmetic control means 20 that the projector mode has not been switched, the process proceeds to S30, which is a strobe charging step, after N branches from S19. Hereinafter, the case of proceeding to the strobe charging step will be described first.

  In S <b> 30, the arithmetic control unit 20 performs a check as to whether or not charging of the strobe (charging of the main capacitor 40 in FIG. 4) has been completed via the voltage determination unit 46. If it is determined in S30 that charging has not yet been completed, the process branches to N31 and proceeds to S31. In S31, the charging operation is performed, and the process proceeds to S30 again. During charging, the user is notified by using at least one of light and sound.

  In S30, if the calculation control means 20 determines that charging of the strobe (charging of the main capacitor 40 in FIG. 3) has been completed by the above-described control, the process proceeds to S32. In S32, the charging step is terminated and the process returns to S1 again.

  The strobe charging step described above makes it possible to charge the strobe in preparation for shooting and projection.

  On the other hand, when switching to the projector mode, the above S19 is branched to Y.

  In subsequent S20, the lens focus position control is performed by moving the projection lens / shooting lens 3 as well. By this lens focus position control, the projection lens / shooting lens 3 is moved, and the distance between the projection lens / shooting lens 3 and the image sensor 8 at the time of shooting is set at the distance between the projection lens / shooting lens 3 and the DMD element 24 at the time of projection. The lens position is corrected so that the distances are equal. By performing this lens position correction in advance, it becomes possible to perform the focusing more smoothly when switching between shooting and projection. Here, this control will be described in detail with reference to FIG.

FIG. 9A shows a relative positional relationship among the projection lens / shooting lens 3, the DMD element 4, and the imaging element 8 when the projector built-in digital camera according to the present embodiment is used as a camera. First, as shown in the figure, the distance between the projection lens also serves photographing lens 3 and the image sensor 8 and Z _0. The distance between the imaging device 8 and the DMD element 4 at this time is the _{Z 1.} In the above positional relationship, it is assumed that the camera is in focus when used as a camera.

On the other hand, FIG. 9B shows the relative positional relationship among the projection lens / shooting lens 3, the DMD element 4, and the image sensor 8 when the projector built-in digital camera according to the present embodiment is used as a projector. As can be seen from the figure, at this time, the image sensor 8 is retracted from the optical path. Here, as shown in the figure, the distance between the projection lens also serves photographing lens 3 and the DMD element 4 to the same distance as the Z _0, the position of the photographing lens combined projection lens 3, when used as a camera from convolving the direction toward the distance _{Z 2} only DMD element 4 corresponding to _{Z 1.} In the figure, the distance convolving by the following reasons are denoted as Z _2. When position movement of the taking lens combined projection lens 3 as described above, further and Z ₂ by adding the fine adjustment amount to Z ₁ as a fine adjustment of the position, by a distance Z ₂ a projection lens combined imaging lens Move the lens to correct the lens position. Note that Z ₁ ≈Z ₂ .

  After switching to the projector mode by branching Y in S19, and after performing lens focus position control in S20, the process proceeds to S21. S21 is a step in which the user operates the operation means (not shown) to display the captured images stored in the memory 22a sequentially or as thumbnails on the liquid crystal monitor 16 and select images to be projected with reference to them. is there.

  In S22, the arithmetic control unit 20 determines whether or not the projector built-in digital camera 1 is installed in the charger stand 60 and electric energy is continuously supplied from the AC power supply 28. Here, when it is determined that the electric energy is continuously supplied from the AC power source 28, the Y branch is made to S23. In S23, the strobe is continuously emitted under the control of the arithmetic control unit 20, and the projection of the image selected by the user is continued until the end operation is performed by the user.

  On the other hand, when it is determined in S22 that the electric energy is not continuously supplied from the AC power source 28 by the arithmetic control means 20, the process branches to N26 and proceeds to S26. In S26, light emission projection for 3 seconds is performed. The process proceeds to S31 through the subsequent light emission end step in S27. In S31, strobe charging is performed. Here, as described above, when the main capacitor is not charged, the main capacitor charging step is performed after boosting the voltage from the secondary battery. During charging, the user is notified of this by means of light or sound. The steps after S31 are as described above.

  In a state where AC charging is not performed, the use of electric energy is avoided by emitting light and projecting for such a limited time (3 seconds). In addition, when AC charging is performed, there is no need to take such an energy saving measure, and thus projection is performed by continuous light emission of a strobe as described above.

  In subsequent S24, whether or not to end the projection is determined by the operation of the switch 14 by the user. Here, when not ending, it branches N and returns to S21. Then, the steps after the above-described projection image selection step are followed again. On the other hand, if it is determined in S24 that the projection is to be terminated, the process proceeds to S25 to terminate the flash emission. In this step, the lens position is controlled in preparation for the upcoming shooting, and the projection lens / shooting lens is returned to the lens position before the projector mode.

  As described above, according to an embodiment of the present invention, the optical path necessary for image projection is turned back by using a reflecting mirror, and an image pickup system is further disposed in the optical system, thereby providing a digital camera housing. It is possible to efficiently store the optical system and configuration necessary for the projector apparatus by effectively using the projector. As a result, it is possible to provide a digital camera with a built-in projector that achieves miniaturization and cost reduction while being a digital camera having a projector function.

  As mentioned above, although embodiment of this invention was described, in the range which does not deviate from the summary of this invention other than embodiment mentioned above, this invention can be variously modified.

(A) shows the outline appearance figure of the digital camera with a built-in projector concerning one embodiment of the present invention. (B) is sectional drawing of the digital camera with a built-in projector which concerns on one Embodiment of this invention. It is a figure which shows the block diagram of the circuit which controls the digital camera with a built-in projector which concerns on one Embodiment of this invention. It is a figure which shows the circuit (strobe control part) which controls the strobe in the digital camera with a built-in projector according to an embodiment of the present invention. It is the graph which showed the strobe current and the timing of the exposure operation. It is a figure which shows the distance between DMD required for an appropriate image projection, a lens, and a light guide. It is a figure which shows the reflective optical system and imaging optical system of the digital camera with a built-in projector which concerns on one Embodiment of this invention. FIG. 2 is a diagram showing an actual use situation of a projector built-in digital camera according to an embodiment of the present invention, where (a) is a diagram showing a scene used as a camera, and (b) is used as a projector. FIG. It is a flowchart which shows operation control of the digital camera with a built-in projector which concerns on one Embodiment of this invention. FIG. 5 is a diagram illustrating a relative positional relationship among a projection lens / photographing lens, an image sensor, and a DMD when performing lens position correction by lens focus position control.

Explanation of symbols

    DESCRIPTION OF SYMBOLS 1 ... Digital camera with a built-in projector, 2 ... Cut surface, 3 ... Shooting lens used as a projection lens, 3a ... Lens control means, 4 ... DMD element, 6a ... Lens, 6b, 6c ... Reflector, 8 ... Imaging element, 14 ... Switch 14a ... Release button, 16 ... LCD monitor, 16a ... Playback circuit, 17 ... Reflector, 18 ... Strobe light emitting part, 18a ... Dial, 18b ... Xenon tube, 19 ... Interlocking mechanism, 20 ... Calculation control means, 21 ... Light guide 22 ... Image processing circuit, 22a ... Memory, 24 ... DMD element, 26 ... Secondary battery, 28 ... AC power supply, 30 ... DC converter circuit, 31 ... Charger, 32 ... Charge control circuit, 34 ... Booster circuit, 36 , 38 ... Diode, 40 ... Main capacitor, 42 ... Switch circuit, 44 ... Diode, 46: Voltage determination means, 48: Trigger circuit, 50: IGBT, 52: Distance detection circuit, 54: Photometry circuit, 56, 56a, 56b ... User, 58 ... Subject, 60 ... Charger stand.

Claims (9)

A light source that emits light;
A first optical system including a taking lens;
A second optical system that returns light from the light source by a plurality of mirrors and guides the light to the first optical system;
An image pickup device capable of entering into the second optical system and retracting from the second optical system;
A digital camera with a built-in projector, wherein the image sensor receives a subject light beam through the first optical system when the image sensor is located in the second optical system. At least one of the plurality of mirrors constituting the second optical system is composed of a plurality of micromirrors arranged two-dimensionally, and the inclination of each of the plurality of micromirrors is changed. Generate projected images,
2. The projector built-in digital camera according to claim 1, wherein the generated projection image is projected onto a projection surface via the first optical system.   2. The projector built-in digital camera according to claim 1, wherein the light source is a strobe device for photographing assistance.   4. The digital camera with built-in projector according to claim 3, wherein when performing image projection, the light emitting unit of the strobe device emits light toward the optical path of the second optical system. 5.   5. The projector built-in digital camera according to claim 4, wherein the second optical system further includes an optical element for condensing and uniformizing irradiation light from the strobe device.   6. The optical system according to claim 1, wherein the first optical system is configured to be capable of adjusting a focal position, and the focal position is changed between when an image is taken and when an image is projected. A digital camera with a built-in projector.   7. The digital camera with a built-in projector according to claim 6, further comprising control means for adjusting a focal position of the first optical system. A light source that emits light;
A first optical system having a function of guiding light from outside the housing of the projector built-in digital camera into the housing, and a function of guiding light from inside the housing to the outside of the housing;
A second optical system disposed in the housing and configured to fold light from the light source by a plurality of mirrors and guide the light to the first optical system;
An object from outside the casing through the first optical system, when the optical system is disposed in the casing and can be moved back and forth in the second optical system and is positioned in the second optical system; An image sensor for receiving a light beam;
And at least one of the plurality of mirrors constituting the second optical system is composed of a plurality of micromirrors arranged two-dimensionally, and each of the plurality of micromirrors is inclined. A digital camera with a built-in projector, wherein a projection image is generated by changing the projection image, and the generated projection image is projected onto a projection surface outside the housing via the first optical system. Switching means for switching the light emission direction of the light source to the outside of the housing or the inside of the housing;
An interlocking mechanism for retracting the image sensor from the second optical system in conjunction with the switching of the light irradiation direction of the light source into the housing by the switching means;
The digital camera with a built-in projector according to claim 8, further comprising:

Images