JP5181416B2 - Projection device - Google Patents

Description

  The present invention relates to a projection apparatus that projects an optical image.

  An electronic camera equipped with a projector is known (Patent Document 1). According to Patent Document 1, projection by a projector is started by operating a projection mode switch or a video playback button.

JP-A-8-146512

  It is desirable to add a projector function to an electronic device that does not have a projector.

According to another aspect of the present invention, there is provided a projection device between a projection unit that projects an optical image, a mounting member that fits into an accessory mounting member of an electronic camera that can switch between a reproduction mode and a photographing mode, and the electronic camera. Communication means for communicating, and control means for receiving a control signal transmitted from the electronic camera via the communication means, and controlling the projection means in accordance with the received control signal, the control means comprising: Determining whether the electronic camera is in the playback mode or the shooting mode, and when the playback mode is determined , an operation member for adjusting a shooting condition of the electronic camera or an operation member for shooting the electronic camera; The projection unit is controlled according to the control signal transmitted when operated.
The projection apparatus according to claim 2 is the projection apparatus according to claim 1, wherein the control unit is in the reproduction mode when a signal indicating that the electronic camera is in a reproduction mode is transmitted from the electronic camera. When the determination is made, the projection means starts projection, and a signal indicating that the electronic camera is in the photographing mode is transmitted from the electronic camera. When it is determined that the electronic camera is in the photographing mode, the projection means projects the projection. It is characterized by terminating .
According to a third aspect of the present invention, there is provided the projection device according to the first or second aspect , wherein the operation member for taking an image of the electronic camera is a release button of the camera, and the control means is the release unit. When the button is operated, the projection unit adjusts the focus according to a focus adjustment signal transmitted from the electronic camera .
According to a fourth aspect of the present invention, in the projection apparatus according to the first or second aspect , the operation member that adjusts the photographing condition of the electronic camera is a zoom operation member that adjusts the zoom of the camera. The control unit causes the projection unit to adjust the zoom according to a zoom adjustment signal transmitted from the electronic camera when the zoom operation member is operated .
The projection device according to claim 5 is the projection device according to any one of claims 1 to 4 , wherein the control unit projects a reproduced image based on data transmitted from the electronic camera onto the projection unit. It is characterized by that.
The projection apparatus according to claim 6 is the projection apparatus according to claim 5 , wherein the control unit causes the projection unit to end projection when data from the electronic camera is not received by the communication unit for a predetermined time. It is characterized by that.

The projection apparatus according to the present invention can be easily mounted and projected on an electronic apparatus having no projection function.
According to the electronic camera system of the present invention, it is possible to easily attach and project the projection apparatus to an electronic camera having no projection function.

  The best mode for carrying out the present invention will be described below with reference to the drawings. FIG. 1 is a perspective view of an electronic camera system according to an embodiment of the present invention as viewed from the front. The electronic camera system includes a projector 20 and an electronic camera 10.

(Electronic camera)
In FIG. 1, a photographing lens 11 is provided in front of the electronic camera 10. On the upper surface of the electronic camera 10, a release button 14, a zoom switch 16, a mode switching dial 15, a main switch 22, and an accessory shoe 110 are provided. A projector 20 or the like is attached to the accessory shoe 110.

  The mode switching dial 15 is a mode switching operation member for switching the operation mode of the electronic camera 10 such as a shooting mode and a reproduction mode. The shooting mode is an operation mode in which a subject image is shot and the shot image data is saved as a shot image file in a recording medium including a memory card. In the case of still image shooting, a still image file is generated, and in the case of moving image shooting, a moving image file is generated. The shooting start instruction corresponds to an operation signal output in response to the pressing operation of the release button 14. In the shooting mode, audio data collected by a microphone built in the electronic camera 10 can be stored in a recording medium.

  In the playback mode, the captured image data is read from a recording medium (for example, a memory card 200 described later or an internal memory (not shown)), and a playback image based on the image data is arranged on the back of the electronic camera 10. This is an operation mode in which reproduction display (projection) is performed by the liquid crystal display or the projector 20 attached to the accessory shoe 110. In the reproduction mode, it is also possible to reproduce sound based on the sound data from a speaker built in the electronic camera 10. In the playback mode, image data (sound data) read from other than the recording medium, and playback images and sounds based on image data (sound data) supplied from the outside of the electronic camera 10 are also displayed (projected) and played back, respectively. Is possible.

  The electronic camera 10 is also provided with a retracting mechanism that retracts the lens barrel P into the camera housing.

  FIG. 2 is a block diagram illustrating the configuration of the electronic camera system. In FIG. 2, an electronic camera 10 includes an imaging unit 220, a CPU 101, a memory 102, an operation member 103, a liquid crystal display 104, a speaker 105, a microphone 106, an external interface (I / F) 107, a power source. A circuit 108 and an accessory shoe 110 are provided, and a battery 109 and a memory card 200 are mounted. The memory card 200 is detachable.

  The CPU 101 which is a controller sends out a control signal to each part of the electronic camera 10 by performing a predetermined calculation using a signal input from each part constituting the electronic camera 10 based on a control program. Controls shooting and playback operations. The CPU 101 is further configured to be able to communicate with the projector 20 via the accessory shoe 110 and control the projection operation by the projector 20. The control program is stored in a nonvolatile memory (not shown) in the CPU 101.

  The memory 102 is used as a working memory for the CPU 101. The operation member 103 corresponds to the main switch 22, the release button 14, the zoom switch 16, and the mode switching dial 15 in FIG. Includes switch. The half-push switch is turned on when the amount of depression of the release button 14 reaches the half-push operation amount, and the full-push switch is turned on when the amount of depression of the release button 14 reaches a full-push operation amount greater than the half-push operation amount. To do. The operation member 103 sends an operation signal corresponding to the operation content to the CPU 101.

  The memory card 200 is configured by a non-volatile memory such as a flash memory, and can write, save, and read data such as image data photographed by the imaging unit 220 according to a command from the CPU 101.

  The liquid crystal display 104 displays information such as images and texts according to instructions from the CPU 101. The text information is an operation state of the electronic camera 10, an operation menu, and the like. The speaker 105 reproduces sound based on sound data output from the CPU 101.

  The microphone 106 converts the collected sound into an electrical signal and sends it to the CPU 101. The audio signal data is recorded on the memory card 200 in the shooting mode.

  The external interface (I / F) 107 converts the video signal into image data and displays the converted image data in order to display a playback image based on the video signal transmitted from an external device such as a video camera on the liquid crystal display 104. Is sent to the CPU 101. Also, the external interface (I / F) 107 converts the sound based on the sound signal transmitted from the external device into sound data to be played back by the speaker 105, and sends the converted sound data to the CPU 101.

  The battery 109 supplies power to each part in the electronic camera 10. The power supply circuit 108 is constituted by a DC / DC conversion circuit or the like, and converts the voltage of the battery 109 into a voltage required for each part in the electronic camera 10. The power supply circuit 108 is further configured to be able to supply power to the projector 20 via the accessory shoe 110.

  When the attachment portion 160 of the projector 20 is attached to the accessory shoe 110 of the electronic camera 10, the accessory shoe 110 and the terminals in the attachment portion 160 are connected to each other. The terminals include at least a control signal terminal (Control I / F), a data signal terminal (Data I / F), and a power supply line terminal. The electronic camera 10 and the projector 20 perform communication and power supply via these terminals.

(Imaging part)
The imaging unit 220 includes a photographing lens 221 (11 in FIG. 1), an image sensor 222, a lens driving circuit 223, a photographing control circuit 224, and a lens barrel retracting mechanism 225. As the image sensor 222, a CCD, a CMOS image sensor, or the like is used. The imaging control circuit 224 controls driving of the image sensor 222 and the lens driving circuit 223 according to a command from the CPU 101, and performs predetermined image processing on an imaging signal (accumulated charge signal) output from the image sensor 222. Image processing includes white balance processing and gamma processing.

  The photographing lens 221 forms a subject image on the imaging surface of the image sensor 222. The imaging control circuit 224 causes the image sensor 222 to start imaging in response to an imaging start instruction, reads the accumulated charge signal from the image sensor 222 after the imaging is completed, sends the image processing to the CPU 101 as image data.

  The lens driving circuit 223 drives a focus lens (not shown) constituting the photographing lens 221 forward and backward in the optical axis direction based on the focus adjustment signal output from the photographing control circuit 224. The lens driving circuit 223 drives a zoom lens (not shown) constituting the photographing lens 221 to advance and retreat in the optical axis direction (tele side or wide side) based on the zoom adjustment signal output from the photographing control circuit 224. . The focus adjustment amount and the zoom adjustment amount are instructed from the CPU 101 to the photographing control circuit 224.

(Camera focus adjustment)
The imaging unit 220 adjusts the focus of the photographing lens 221 by shifting the focus lens constituting the photographing lens 221 in the optical axis direction. When performing autofocus adjustment, the CPU 101 integrates high frequency components (so-called focus evaluation value) for an image signal corresponding to a focus detection area (for example, the center of the shooting screen) among image signals captured by the image sensor 222. A focus adjustment signal is sent to the imaging control circuit 224 so as to maximize. The position of the focus lens that maximizes the focus evaluation value is a focus position that eliminates blurring of the edge of the subject image captured by the image sensor 222 and maximizes the contrast of the image.

(Camera zoom adjustment)
The imaging unit 220 adjusts the optical zoom of the photographing lens 221 by shifting the zoom lens constituting the projection lens 121 in the optical axis direction. The CPU 101 sends a zoom adjustment signal to the imaging control circuit 224 in response to an operation signal from the zoom switch 16. The CPU 101 sends a zoom adjustment signal so as to zoom up when an operation signal is input clockwise from the zoom switch 16, and adjusts the zoom so as to zoom down when an operation signal is input counterclockwise from the zoom switch 16. Send a signal. The zoom switch 16 is configured to alternatively output two different operation signals.

  Further, the photographing control circuit 224 sends a command to the lens barrel retracting mechanism 225 in response to a command from the CPU 101, and the lens barrel P (FIG. 1) of the photographing lens 221 is retracted into the casing of the electronic camera 10, or within the casing. The lens barrel P that is retracted into the position is extended to the state at the time of photographing (FIG. 1).

(projector)
The projector 20 that is a projection device is attached to the electronic camera 10 by fitting the attachment portion 160 (FIG. 1) to the accessory shoe 110 of the electronic camera 10. The projector 20 attached to the electronic camera 10 emits a projected light beam through a projection lens 121 toward a screen or the like disposed in front of the electronic camera 10 and projects information such as an image on the screen.

  2, the projector 20 includes a projection unit 120, a CPU 151, a memory 152, an operation member 153, an external interface (I / F) 155, a power circuit 156, a speaker 159, and a detection switch 1000. A battery 157 and a memory card 154 are mounted.

  The CPU 151, which is a controller, sends a control signal to each part of the projector 20 by performing a predetermined calculation using a signal input from each part constituting the projector 20 based on the control program, and thereby the projector 20. Controls the projection operation. The control program is stored in a nonvolatile memory (not shown) in the CPU 151. The CPU 151 performs trapezoidal distortion correction (keystone correction) on image data projected by the projector 20 by image processing.

  Further, when the projector 20 is mounted on the electronic camera 10, the CPU 151 communicates with the CPU 101 of the electronic camera 10 via the attachment unit 160 and the terminal in the accessory shoe 110.

  The memory 152 is used as a working memory for the CPU 151. The operation member 153 includes a main switch, a light source on / off switch, and the like, and sends an operation signal corresponding to each operation switch to the CPU 151.

  The memory card 154 is configured by a non-volatile memory, and is configured to be detachable from a card slot (not shown). The external interface 155 transmits / receives data to / from an external device via a cable (not shown) or the like according to a command from the CPU 151. Data to be transmitted and received is video / audio data and control data for the projector 20.

  The speaker 159 reproduces sound based on the sound signal output from the CPU 151. The battery 157 supplies power to each unit in the projector 20. The power supply circuit 156 is constituted by a DC / DC conversion circuit or the like, and converts the voltage of the battery 157 into a voltage required for each part in the projector 20. The power supply circuit 156 is configured to be able to use electric power supplied from the electronic camera 10 via a terminal in the attachment unit 160.

  The detection switch 1000 detects that the attachment portion 160 is attached to the accessory shoe 110 and sends a detection signal to the CPU 151. When the attachment portion 160 is not attached to the accessory shoe 110, no detection signal is output.

(Projection part)
The projection unit 120 includes a projection lens 121, a liquid crystal panel 122, an LED light source 123, a projection control circuit 124, and a lens driving circuit 125. The projection control circuit 124 supplies a drive current to the LED light source 123 according to the projection command output from the CPU 151. The LED light source 123 illuminates the liquid crystal panel 122 with brightness according to the supplied current. The LED light source 123 is also used as an illumination light source during photographing.

  The projection control circuit 124 further generates a liquid crystal panel drive signal in accordance with the image data sent from the CPU 151, and drives the liquid crystal panel 122 with the generated drive signal. Specifically, a voltage corresponding to the image signal is applied to the liquid crystal layer for each pixel. In the liquid crystal layer to which a voltage is applied, the arrangement of liquid crystal molecules changes, and the light transmittance of the liquid crystal layer changes. Thus, the liquid crystal panel 122 generates an optical image by modulating the light from the LED light source 123 according to the image signal.

  The projection lens 121 projects the light image emitted from the liquid crystal panel 122 onto a screen or the like. The lens driving circuit 125 drives the projection lens 121 forward and backward in a direction orthogonal to the optical axis based on the offset adjustment signal output from the projection control circuit 124. The lens driving circuit 125 drives a focus lens (not shown) constituting the projection lens 121 forward and backward in the optical axis direction based on the focus adjustment signal output from the projection control circuit 124. The lens drive circuit 125 further drives a zoom lens (not shown) constituting the projection lens 121 forward and backward in the optical axis direction based on the zoom adjustment signal output from the projection control circuit 124. The CPU 151 instructs the projection control circuit 124 to set the offset adjustment amount, the focus adjustment amount, and the zoom adjustment amount.

(Projected image offset)
By shifting the projection lens 121 in a direction orthogonal to the optical axis, the emission direction of the light beam emitted from the projection unit 120 changes, and the projection image is offset. In addition to shifting the projection lens 121, the projection image may be offset by shifting the liquid crystal panel 122 and the LED light source 123 in the direction perpendicular to the optical axis. That is, the offset of the projected image can be realized by changing the relative positional relationship between the projection lens 121 and the liquid crystal panel 122 in a direction perpendicular to the optical axis.

(Keystone correction of projected image)
When a part of the projection lens 121, the liquid crystal panel 122, and the LED light source 123 is shifted in the direction perpendicular to the optical axis, keystone correction is performed on the data to be projected according to the shift amount. Since the projection image changes to a trapezoidal shape only by giving the offset to the projection image, the CPU 151 performs electrical keystone correction by image processing to correct the projection image from the trapezoidal shape to the rectangular shape. The memory in the CPU 151 stores an initial correction value for correcting the projected image into a square shape in advance. The CPU 151 reads the initial correction value corresponding to the offset adjustment amount, performs keystone correction processing on the image data to be projected based on the read initial correction value on the memory 152, and controls projection of the image data after the keystone correction processing. Send to circuit 124.

(Focus adjustment of projected image)
The projection unit 120 adjusts the focus of the projected image by shifting the focus lens constituting the projection lens 121 in the optical axis direction. When performing manual focus adjustment, the CPU 151 sends a focus adjustment signal to the projection control circuit 124 in accordance with an operation signal from the operation member 153.

(Zoom adjustment of projected image)
By shifting the zoom lens constituting the projection lens 121 in the optical axis direction, the projection unit 120 performs zoom adjustment of the projection image. The CPU 151 sends a zoom adjustment signal to the projection control circuit 124 in accordance with an operation signal from the operation member 153 (or an operation signal transmitted from the electronic camera 10).

(Projection source: source)
The projection unit 120 receives the following source 1. ~ Source 4. Project and play back content based on either Whenever a source switching operation signal is input from the operation member 153 (or the electronic camera 10), the CPU 151 causes the source 1. ~ Source 3. Projected image of source 1. → 2. → 3. → 1. Image data corresponding to each image is sent to the projection unit 120 so as to be cyclically switched in the order of. However, when the memory card 154 is not attached to the projector 20, the source 1. Is skipped. When the projector 20 is not attached to the accessory shoe 110 of the electronic camera 10 or when the main switch of the electronic camera 10 is turned off even if the projector 20 is attached to the accessory shoe 110 of the electronic camera 10. Source 2. Is skipped. If no external device is connected to the external interface (I / F) 155, the source 3. Is skipped.

  When the switching instruction signal to the chart projection is input from the mounted electronic camera 10, the CPU 151 receives the following source 4. Is sent to the projection unit 120.

Source 1. 1. Reproduced image source based on data read from the memory card 154 2. Reproduced image source based on data transmitted from the electronic camera 10 3. Reproduced image source based on data input from the external interface (I / F) 155 A chart for focus adjustment, for example, an image composed of a striped pattern with black lines on a white background

  The CPU 151 receives the source 1. When the image corresponding to is projected, the image data having the latest recording date and time (the last recorded image data captured) is sequentially read from the memory card 154, and the read image data is sent to the projection unit 120. Send it out.

  In the electronic camera system according to the present embodiment, the projector 20 attached to the electronic camera 10 performs a projection operation while communicating with the electronic camera 10.

(Projector-side processing)
FIG. 3 is a flowchart for explaining the flow of processing by a program executed by the CPU 151 of the projector 20. 3 starts when the main switch of the projector 20 is turned on and a detection signal from the detection switch 1000 is input to the CPU 151.

  In step S1 of FIG. 3, the CPU 151 determines whether or not communication is established. The CPU 151 communicates with the CPU 101 on the electronic camera 10 side using a predetermined communication protocol. If communication is established, an affirmative determination is made in step S1 and the process proceeds to step S2. If communication is not established, CPU 151 makes a negative determination in step S1 and proceeds to step S13.

  The CPU 151 that has proceeded to step S13 performs normal processing. The normal processing includes a function of communicating with the projector 20 when the projector 20 is used without being attached to the electronic camera 10, when the main switch of the electronic camera 10 to which the projector 20 is attached is turned off. This is processing when the projector 20 is mounted on an electronic camera or the like that is not provided.

  The CPU 151 that performs normal processing instructs the projection control circuit 124 to perform projection on / off, projection source switching, manual focus adjustment, and zoom adjustment processing according to an operation signal input from the operation unit 153. Specifically, when an operation signal is input from the light source on / off switch, the LED light source 123 is instructed to be turned on / off according to the operation signal. When the source switching operation signal is input, the image data to be sent to the projection unit 120 is switched as described above. The initial image projected by the projector 20 when communication with the electronic camera 10 is not established is the source 1. The reproduced image is the image data read from the memory card 154.

  Further, when an operation signal for manually adjusting the focus is input, the CPU 151 sends a focus adjustment signal corresponding to the operation signal to the projection control circuit 124 as described above. When an operation signal for zoom adjustment is input, the CPU 151 sends a zoom adjustment signal corresponding to the operation signal to the projection control circuit 124 as described above. When the CPU 151 performs the normal process in this way, the process proceeds to step S11.

  In step S2, the CPU 151 determines whether or not the electronic camera 10 is set to the playback mode. When the CPU 151 receives a signal indicating that the electronic camera 10 is in the reproduction mode through communication, the CPU 151 makes an affirmative decision in step S2 and proceeds to step S3. On the other hand, when the CPU 151 receives a signal indicating that the electronic camera is in the shooting mode, the CPU 151 makes a negative determination in step S2 and proceeds to step S14.

(When the electronic camera is in playback mode)
When proceeding to step S3, the LED light source 123 is used as a projection light source. In step S3, the CPU 151 determines whether or not a projection instruction has been given. The CPU 151 makes an affirmative determination in step S3 when a signal instructing projection is input and proceeds to step S4. If a signal instructing the projection is not input, the CPU 151 makes a negative determination in step S3 and proceeds to step S5. The signal for instructing the projection is a control signal transmitted from the electronic camera 10 or an operation signal from the operation member 153.

  In step S4, the CPU 151 instructs the projection control circuit 124 to start or end the projection according to the input signal, and proceeds to step S5. The initial image projected by the projector 20 onto the screen (not shown) when communication with the electronic camera 10 is established is the source 2. The reproduced image is the data transmitted from the electronic camera 10.

  In step S5, the CPU 151 determines whether or not source switching is instructed. If a signal instructing switching of the projection source is input, the CPU 151 makes an affirmative determination in step S5 and proceeds to step S6. If a signal instructing switching of the projection source is not input, the CPU 151 makes a negative determination in step S5. Proceed to S7. The signal for instructing source switching is a control signal transmitted from the electronic camera 10 or an operation signal from the operation member 153.

  In step S6, the CPU 151 switches image data to be sent to the projection unit 120 according to the input signal, and proceeds to step S7. The image data to be sent is source 1. ~ Source 3. Corresponds to one of the following. Further, the CPU 151 causes the speaker 159 to reproduce an audio signal corresponding to the image data sent to the projection unit 120.

  In step S7, the CPU 151 determines whether zoom adjustment is instructed. If a signal for instructing zoom adjustment is input, CPU 151 makes a positive determination in step S7 and proceeds to step S8. If a signal for instructing zoom adjustment is not input, the CPU 151 makes a negative determination in step S7 and proceeds to step S9. The signal for instructing the zoom adjustment is a control signal transmitted from the electronic camera 10 or an operation signal from the operation member 153.

  In step S8, the CPU 151 performs zoom adjustment processing. As described above, the CPU 151 sends a zoom adjustment signal corresponding to the input signal to the projection control circuit 124, and proceeds to step S9.

  In step S9, the CPU 151 determines whether autofocus (AF) adjustment is instructed. When a signal instructing AF adjustment is input, CPU 151 makes a positive determination in step S9 and proceeds to step S10. When a signal instructing AF adjustment is not input, the CPU 151 makes a negative determination in step S9 and proceeds to step S11. A signal instructing AF adjustment is a control signal transmitted from the electronic camera 10. Note that the focus adjustment of the imaging unit 220 in the electronic camera 10 is performed in advance so as to focus on a screen (not shown).

  In step S10, the CPU 151 performs AF adjustment processing. The CPU 151 receives the source 1. ~ Source 3. The above source 4. The chart image data is sent to the projection control circuit 124 to project the chart image. Further, the CPU 151 further integrates the high-frequency component (for the image signal corresponding to the focus detection area (for example, the center of the shooting screen) among the image signals obtained by the imaging unit 220 of the electronic camera 10 that captures the projected chart image). A focus adjustment signal is sent to the projection control circuit 124 so as to maximize the so-called focus evaluation value. A signal indicating the magnitude of the focus evaluation value is configured to be transmitted from the electronic camera 10 to the projector 20 via the data signal terminal (Data I / F) during the AF adjustment process.

  As described above, the position of the focus lens that maximizes the focus evaluation value is a focus adjustment position that eliminates blurring of the edge of the chart projection image that is the subject of the electronic camera 10 and maximizes the contrast of the projection image. When the CPU 151 finishes the AF adjustment process, the CPU 151. The original reproduced image is projected instead of the chart image and the process proceeds to step S11.

  In step S11, the CPU 151 determines whether an off instruction has been issued. When an operation signal for instructing power off is input from the operation member 153, the CPU 151 makes an affirmative determination in step S11 and proceeds to step S12. When an operation signal instructing power off is not input, the CPU 151 makes a negative determination in step S11. Return to step S1.

  In step S12, the CPU 151 instructs the projection control circuit 124 to end projection, performs a predetermined power-off process, and ends the process shown in FIG.

(When the electronic camera is in shooting mode)
When the process proceeds to step S14, the LED light source 123 is used as an illumination light source at the time of photographing. In this case, the CPU 151 sends a command to the projection control circuit 124 to maximize the light transmittance for all the pixels of the liquid crystal panel 122.

  In step S14, the CPU 151 determines whether or not a light emission instruction has been issued. When the CPU 151 receives the light emission instruction (control signal) transmitted from the electronic camera 10, the CPU 151 makes an affirmative determination in step S14 and proceeds to step S15. When the light emission instruction is not received, the CPU 151 negates step S14 and proceeds to step S11. The light emission instruction corresponds to a known X contact signal.

  In step S15, the CPU 151 sends a command to the projection control circuit 124, causes the LED light source 123 to emit a predetermined amount of light, and proceeds to step S11. Thereby, illumination light for illuminating the subject is emitted from the projection lens 121 toward the front of the electronic camera 10.

  Although the above example has been described as illumination with maximum transmission of all pixels, illumination with an arbitrary light distribution pattern is possible based on a command from the camera. For example, only a very small area may be illuminated or the illumination color may be changed.

(Processing on the electronic camera side)
FIG. 4 is a flowchart for explaining the flow of processing by a program executed by the CPU 101 of the electronic camera 10. 4 is started when the main switch of the electronic camera 10 is turned on and an operation signal instructing the CPU 101 to switch to the projection mode is input from the mode switching dial 15.

  In step S51 of FIG. 4, the CPU 101 instructs the imaging control circuit 224 to turn off the imaging unit, and the process proceeds to step S52. Thereby, the imaging operation in the imaging unit 220 is stopped.

  In step S52, the CPU 101 determines whether or not the lens barrel P is in the retracted state. When the CPU 101 receives a signal indicating the collapsed state from the imaging control circuit 224, the CPU 101 makes a positive determination in step S52 and proceeds to step S54. When the CPU 101 receives a signal indicating the non-collapsed state, the CPU 101 makes a negative determination in step S52 and proceeds to step S53. move on.

  In step S53, the CPU 101 sends a collapsible command (instruction) to the photographing control circuit 224, and proceeds to step S54. In step S54, the CPU 101 determines whether communication has been established. The CPU 101 communicates with the CPU 151 on the projector 20 side using a predetermined communication protocol. If communication is established, an affirmative determination is made in step S54 and the process proceeds to step S56. If communication is not established, CPU 101 makes a negative determination in step S54 and proceeds to step S55.

  In the case of proceeding to step S55, the CPU 101 displays the reproduced image on the liquid crystal display 104. In step S55, the CPU 101 causes the liquid crystal display 104 to start reproduction display, and proceeds to step S57. When proceeding to step S57, the CPU 101 does not transmit a control signal, data, or the like to the projector 20.

  When proceeding to step S56, the CPU 101 causes the projector 20 to project the reproduced image. In step S56, the CPU 101 transmits a projection start instruction (control signal) to the projector 20, and turns off the display by the liquid crystal display 104, and proceeds to step S57.

  In step S57, the CPU 101 reads the image data with the newest recording date from the memory card 200, and sets the read image data as image data for reproduction. The CPU 101 transmits the reproduction image data to the liquid crystal display 104 when displaying the reproduction image on the liquid crystal display 104, and transmits the reproduction image data to the projector 20 when projecting the reproduction image on the projector 20. As a result, a reproduced image based on the image data sent out by the CPU 101 is reproduced and displayed (projected) by the liquid crystal display 104 or the projector 20. Note that, when audio data is stored in association with the data file of the image being projected, the CPU 101 reproduces audio from the audio data from the speaker 105 during display on the liquid crystal display 104. Further, during the projection by the projector 20, the sound data is transmitted to the projector 20, and the sound is reproduced from the speaker 159 on the projector 20 side.

  In step S58, the CPU 101 determines whether or not a frame advance / frame return operation has been performed. When an operation signal instructing frame advance or frame return is input from the operation member 103, the CPU 101 makes an affirmative decision in step S58 and returns to step S57 to read out and read the image data corresponding to the operation signal from the memory card 200. The image data is set as image data for reproduction. On the other hand, if neither of the operation signals instructing frame advance and frame return is input from the operation member 103, the CPU 101 makes a negative determination in step S58 and proceeds to step S59.

  In step S59, the CPU 101 determines whether a source switching operation has been performed. When an operation signal instructing source switching is input from the operation member 103, the CPU 101 makes an affirmative determination in step S59 and proceeds to step S63. When an operation signal instructing source switching is not input, the CPU 101 makes a negative determination in step S59. Then, the process proceeds to step S60.

  In step S60, the CPU 101 determines whether or not a mode switching operation has been performed. When the operation signal for switching to the photographing mode is input from the mode switching dial 15, the CPU 101 makes a positive determination in step S <b> 60 and proceeds to step S <b> 61. If the operation signal for switching to the shooting mode is not input, the CPU 101 makes a negative determination in step S60 and proceeds to step S62.

  In step S61, the CPU 101 turns off the display by the liquid crystal display 104 when the reproduction image is displayed on the liquid crystal display 104, and displays the projection image by the projector 20 when the reproduction image is projected on the projector 20. The process shown in FIG. 4 is terminated after turning off. When the projector 20 turns off the projection image, a projection end instruction (control signal) is transmitted to the projector 20.

  In step S62, the CPU 101 determines whether or not the reproduction image data is a recorded image. If the reproduction image data is a recorded image recorded on the memory card 200, the CPU 101 makes an affirmative decision in step S62 and returns to step S58. The reproduction image data is input from the external interface (I / F) 107. If the received image is a negative image, a negative determination is made in step S62, and the process returns to step S59.

  In step S63, the CPU 101 switches the image data for reproduction and proceeds to step S64. Specifically, each time the source switching operation is performed, the image data read from the memory card 200 and the image data input from the external interface (I / F) 107 are switched, and the process proceeds to step S64.

  In step S64, the CPU 101 determines whether the reproduction image data is a recorded image. When the reproduction image data is switched to the recorded image recorded on the memory card 200, the CPU 101 makes an affirmative decision in step S64, returns to step S57, reads the image data from the memory card 200, and reads the read image data. It is set as image data for reproduction. On the other hand, when the reproduction image data is switched to the image data input from the external interface (I / F) 107, the CPU 101 makes a negative determination in step S64 and returns to step S59. In this case, determination of frame advance / return operation is unnecessary.

  The CPU 101 treats the release button 14 and the zoom switch 16 as operation members having functions different from those in the shooting mode until the mode switching operation is determined to be affirmative in step S60 after step S56 in the flowchart described above. In the case of the release button 14, it is not an operation member for instructing shooting, but instructs the autofocus adjustment of the projector 20, It is handled as an operation member for instructing switching to a chart projection image for focus adjustment. In the case of the zoom switch 16, it is handled as an operation member for zoom adjustment of the projection unit 120 of the projector 20, not zoom adjustment of the imaging unit 220.

According to the embodiment described above, the following operational effects can be obtained.
(1) Since the projector 20 is mounted on the accessory shoe 110 of the electronic camera 10 to constitute the electronic camera system, the posture of the projector 20 is stabilized and the table (not shown) on which the electronic camera 10 is placed. The height from the plane such as the projection lens 121 from which the projection image is emitted can be obtained. By raising the position of the projection lens 121, there is less possibility that a part of the projected light beam is scattered on the mounting plane.

(2) When the electronic camera 10 and the projector 20 are configured to be communicable and communication is established between the electronic camera 10 and the electronic camera 10 set in the reproduction mode, a projection start instruction (control signal) from the electronic camera 10 to the projector 20 ) And reproduction data are transmitted, and the reproduction image based on the reproduction data is automatically projected by the projector 20 (step S56 in FIG. 4 and step S4 in FIG. 3). As a result, the liquid crystal display 104 of the electronic camera 10 can be turned off, the projection lamp (LED light source 123) of the projector 20 can be turned off, and the projection image can be selected, thereby improving the usability of the electronic camera system.

(3) In addition to the above (2), when the electronic camera 10 is switched to the shooting mode, a projection end instruction (control signal) is transmitted from the electronic camera 10 to the projector 20, and the projector 20 automatically projects the projection. It is made to complete | finish (step S61 of FIG. 4, step S4 of FIG. 3). Thereby, the off operation of the projection lamp (LED light source 123) of the projector 20 can be omitted, and the usability of the electronic camera system is improved.

(4) After step S56, when the projector 20 starts the reproduction projection, the electronic camera with projector 10 does not use the release button 14 as an operation member for shooting instructions until the mode switching operation is positively determined in step S60. 20 auto-focus adjustment, or the projector 20 to the source 4. The function was changed so as to be handled as an operation member for instructing to switch to the chart projection image for focus adjustment, and the function was changed so that the zoom switch 16 was handled as an operation member for zoom adjustment of the projection image. Thereby, it is not necessary to add a new operation member related to projection.

(Modification 1)
The electronic camera 10 transmits a power-off instruction (control signal) to the projector 20 when the power of the electronic camera 10 is turned off (including when the timer is turned off) according to the contents set in advance by menu setting or the like. You may comprise as follows. In this case, when an operation signal for instructing power off is input from the operation member 103, the CPU 101 of the electronic camera 10 transmits a power off instruction to the projector 20 and performs a predetermined power off process for the electronic camera 10. Receiving the power-off instruction, the CPU 151 of the projector 20 instructs the projection control circuit 124 to end the projection and performs a predetermined power-off process for the projector 20.

(Modification 2)
Further, the electronic camera 10 supplies / does not supply power from the power supply circuit 108 of the electronic camera 10 to the power supply circuit 156 of the projector 20 according to the contents preset in the menu setting or the like, or the battery 157 of the projector 20. Switching such as supplying power from the power supply circuit 108 to the power supply circuit 156 may be performed only when the remaining capacity is insufficient. When the power supply from the power supply circuit 108 to the power supply circuit 156 is permitted, the CPU 151 sends a command to the projection control circuit 124 to increase the current value supplied to the LED light source 123 from the normal value so that the projected image becomes brighter. The projection unit 120 may be controlled.

(Modification 3)
When the projection start instruction (control signal) and playback data are transmitted from the electronic camera 10 to the projector 20 and the projector 20 is projecting a playback image based on the data, the projector 20 does not receive data from the electronic camera 10. If the state continues for a predetermined time, the projector 20 may be configured to end the projection. In this case, the CPU 151 instructs the projection control circuit 124 to end projection, and turns off the LED light source 123.

(Modification 4)
The electronic camera 10 and the projector 20 communicate and supply power via the terminals in the accessory shoe 110 and the attachment unit 160. However, the electronic camera 10 and the projector 20 are connected by a connection cable, and the electronic camera 10 and the projector 20 are connected via the connection cable. Communication or power supply may be performed.

(Modification 5)
The projector can operate independently without being connected to an electronic camera. In this case, it is driven by a built-in battery, and the projection content is controlled by the CPU. The projection source may be stored in a memory card or may be a signal supplied through an external I / F. When operating alone, the rotatable mounting portion is rotated approximately 90 degrees. The attachment portion is stopped by clicking at a position rotated by 90 degrees. In this state, the end surface of the attachment portion and the lower surface of the projector housing are configured to substantially coincide with each other, and these constitute an installation surface. With this configuration, an electronic camera having an accessory shoe can be connected there, while an electronic camera that does not have an accessory shoe can also be connected through an external I / F, improving usability. . Further, it can function as a single small projector.

(Modification 6)
Furthermore, when connecting to an electronic camera and acquiring and projecting image data in the electronic camera by communication, the image data may be stored (COPY) in a memory card on the projector side during projection. As a result, when the same data is projected for the second time or later, it is not necessary to communicate the image itself. Further, even when the projector is detached from the electronic camera and operates as a single projector, there is an advantage that the image data can be used for projection.

  In the above description, the example in which the projector 20 is mounted on the accessory shoe 110 of the electronic camera 10 has been described. However, the projector 20 may be configured to be mounted on another electronic device including the accessory shoe.

  The above description is merely an example, and the interpretation of the invention is not limited to the correspondence between the components of the above-described embodiment and the components of the present invention. The projector unit may be a transmissive liquid crystal, a reflective liquid crystal (LCOS), or a DMD.

It is the perspective view which looked at the electronic camera system from the front. It is a block diagram explaining the structure of an electronic camera system. It is a flowchart explaining the flow of the process by the program which CPU of a projector performs. It is a flowchart explaining the flow of the process by the program which CPU of an electronic camera performs.

Explanation of symbols

DESCRIPTION OF SYMBOLS 10 ... Electronic camera 11 (221) ... Shooting lens 14 ... Release button 15 ... Mode switching dial 16 ... Zoom switch 20 ... Projector 101, 151 ... CPU
103, 153 ... operation member 104 ... liquid crystal display 110 ... accessory shoe 120 ... projection unit 121 ... projection lens 154, 200 ... memory card 160 ... mounting unit 220 ... imaging unit

Claims (6)

Projection means for projecting an optical image;
An attachment member that fits into an accessory mounting member of an electronic camera that can be switched between a reproduction mode and a shooting mode;
Communication means for communicating with the electronic camera;
Control means for receiving a control signal transmitted from the electronic camera via the communication means, and controlling the projection means according to the received control signal, and
The control means determines whether the electronic camera is in the playback mode or the shooting mode, and if it is determined to be in the playback mode , an operation member that adjusts shooting conditions of the electronic camera or shooting of the electronic camera. A projection apparatus that controls the projection unit according to the control signal transmitted when an operation member to be operated is operated. The projection device according to claim 1,
The control means, when a signal indicating that the electronic camera is in a playback mode is transmitted from the electronic camera and determines that the electronic camera is in the playback mode, causes the projection means to start projection, and the electronic camera A projection device that causes the projection means to terminate projection when it is determined that the photographing mode is transmitted from the electronic camera . The projection apparatus according to claim 1 or 2 ,
The operation member for photographing the electronic camera is a release button of the camera,
The control unit causes the projection unit to adjust the focus according to a focus adjustment signal transmitted from the electronic camera when the release button is operated . The projection apparatus according to claim 1 or 2 ,
The operation member that adjusts the shooting conditions of the electronic camera is a zoom operation member that adjusts the zoom of the camera,
The control device causes the projection unit to perform zoom adjustment in accordance with a zoom adjustment signal transmitted from the electronic camera when the zoom operation member is operated. In the projection device according to any one of claims 1 to 4 ,
The projection device characterized in that the control means causes the projection means to project a reproduced image based on data transmitted from the electronic camera. The projection device according to claim 5 ,
The control device causes the projection device to end projection when data from the electronic camera is not received by the communication device for a predetermined time.

Images