JP6999530B2 - Imaging device - Google Patents

Description

The present invention relates to an image pickup device, and more particularly to an image pickup device capable of detecting the tilt of the image pickup device and accurately displaying a tilt guide display corresponding to the tilt information on the screen of the image display device.

In recent years, image pickup devices such as digital cameras have become smaller and lighter, and can be more easily carried and used in various places. Furthermore, the functions of digital cameras are incorporated into mobile phones and the like. It became so.
An image pickup device including such a digital camera is designed to be smaller and lighter, and is held by a person, so that it is not always taken in a stable posture. In addition, the image tends to have a tilt that is hard to notice.
On the other hand, as an imaging method of an image pickup device, there is a case where an image is taken with an intentionally tilted composition. Further, as for the imaging posture, not only the horizontally long, so-called horizontal position, but also the vertically long, so-called vertical position composition may be used.
In any case, the image pickup device shall be equipped with a function to detect the tilt of the main body of the device at the time of shooting and display the angle of the tilt on the monitor screen so that the photographer can recognize the tilt of the screen. Is desirable.
According to Patent Document 1 (Japanese Unexamined Patent Publication No. 2004-343476), when a still image is acquired, the inclination of the still image is detected, and information indicating the detected inclination is recorded on a recording medium together with the still image. Accordingly, there is disclosed an imaging device capable of correcting the tilt of a still image by post-processing, thereby correctly reflecting the user's intention and appropriately correcting the tilt of the imaging result.

Further, Patent Document 2 (Japanese Unexamined Patent Publication No. 2007-174156) provides a shooting mode corresponding to a moving image or a still image, and is detected only in the still image shooting mode and when the display of tilt is required. An imaging device that generates a tilt guide display signal from tilt information and sends it to a display processing circuit to display a tilt guide display on a screen for displaying an captured image is disclosed.
Further, in Patent Document 3 (Patent No. 3896505), the posture of the camera is detected by the posture detecting means provided in the camera, and the horizontal reference line of the camera itself and the posture of the camera depend on the screen of the image display means. Disclosed is an imaging device that displays the changing tilt information at the same time as the captured image, and allows the photographer to correct the tilt of the camera by referring to these displays.
It should be noted that, in order to confirm the posture, a spirit level using bubbles in the liquid, a so-called level, which can be installed by using a hot shoe of an image pickup device including a digital camera is also commercially available.

However, in such an image pickup apparatus, for example, Patent Document 1 (Japanese Patent Laid-Open No. 2004-3)
In the case of the image pickup apparatus disclosed in No. 43476), the tilt is displayed using a bar-shaped display unit on the display screen, but the accuracy of tilt detection is fixed, and even if the accuracy of tilt detection is increased, There is a drawback that it is not possible to display according to it.
Further, Patent Document 2 (Japanese Patent Laid-Open No. 2007-174156) and Patent Document 3 (Patent No. 389).
In the case of the image pickup device disclosed in No. 6505), the posture of the image pickup device is recognized by recognizing the inclination of the captured image or the composite image, which is convenient for intuitive grasping. There is a drawback that the magnitude of the tilt of the image pickup device cannot be displayed with high accuracy.
The present invention has been made in view of the above-mentioned circumstances. Based on the inclination of the image pickup apparatus, the present invention emphasizes accuracy according to the range in which accuracy is required and the range in which accuracy is not required, and is easy to use. It is an object of the present invention to provide an image pickup apparatus capable of realizing a user interface for improving operability by properly using it according to a request.
Another object of the present invention is to provide an image pickup device that can easily grasp the tilt guide display corresponding to the tilt information of the image pickup device both intuitively and quantitatively.

The image pickup apparatus according to the present invention according to claim 1 is used to achieve the above-mentioned object.
It ’s an image pickup device.
Image sensor and
An image display unit that displays an image captured by the image sensor, and an image display unit.
The image pickup apparatus is provided with a tilt detection unit for detecting the tilt in the roll direction and the tilt in the pitch direction .
The tilt information of the image pickup device is displayed on the image display unit according to the tilt of the image pickup device detected by the tilt detection unit.
In an image pickup device including a display control means for switching a display position of tilt information of the image pickup device when the tilt in the roll direction of the image pickup device exceeds a predetermined range.
When the tilt in the pitch direction of the image pickup device is within a predetermined range and the tilt in the roll direction exceeds the predetermined range, the display control means switches the display position of the tilt information of the image pickup device.
When the tilt in the pitch direction of the image pickup device exceeds a predetermined range and the tilt in the roll direction exceeds a predetermined range, the display position of the tilt information of the image pickup device is not switched.
The image pickup apparatus according to the present invention according to claim 2 is the image pickup apparatus according to claim 1.
The display control means is characterized in that the display position of the tilt information of the image pickup apparatus is switched to a position along an end portion in the longitudinal direction or the lateral direction of the image display unit.

The image pickup apparatus according to the present invention according to claim 3 is the image pickup apparatus according to claim 1 or 2.
The tilt information of the image pickup device is tilt information in the roll direction indicating the tilt of the image pickup device in the roll direction.
The display control means is characterized in that a tilt guide, which is a display corresponding to the tilt information in the roll direction, and a marker that moves along the display scale are displayed.
The image pickup apparatus according to the present invention according to claim 4 is the image pickup apparatus according to claim 3.
The tilt guide is characterized in that the color of the display scale is changed when the tilt amount in the roll direction of the image pickup apparatus increases from a small state.
The image pickup apparatus according to the present invention according to claim 5 is the image pickup apparatus according to claim 3 or 4.
The display control means is characterized in that, when the amount of tilt in the pitch direction of the image pickup device exceeds a predetermined range, the display position of the tilt information of the image pickup device is not switched and the marker is erased .

The image pickup apparatus according to the present invention according to claim 6 is the image pickup apparatus according to any one of claims 3 to 5.
The display control means is characterized in that when the amount of inclination in the pitch direction exceeds a predetermined range, the display form of the inclination guide is changed .
The imaging apparatus according to the present invention according to claim 7 is characterized in that the inclination in the roll direction according to claim 1 is 60 degrees.

According to the present invention, it is possible to provide an image pickup device capable of improving operability by changing the display position of tilt information to an easy-to-see position according to the tilt of the image pickup device.
That is, according to the image pickup device of claim 1 of the present invention, the image pickup device, the image pickup element, the image display unit for displaying the image captured by the image pickup element, and the inclination of the image pickup device in the roll direction. A tilt detection unit for detecting tilt in the pitch direction is provided, and tilt information of the image pickup device is displayed on the image display unit according to the tilt of the image pickup device detected by the tilt detection unit, and the image pickup device is displayed. In an image pickup device including a display control means for switching a display position of tilt information of the image pickup device when the tilt in the roll direction exceeds a predetermined range, the display control means has a tilt in the pitch direction of the image pickup device. If it is within a predetermined range and the tilt in the roll direction exceeds the predetermined range, the display position of the tilt information of the image pickup device is switched, the tilt in the pitch direction of the image pickup device exceeds the predetermined range, and the roll When the tilt in the direction exceeds a predetermined range, the display position of the tilt information of the image pickup device is not switched.
When the image pickup device is held, the tilt information in the image display unit can be easily seen according to the tilt of the image pickup device, and can be accurately grasped, which in turn can improve the operability.

According to the image pickup device of claim 2 of the present invention, the display control means switches the display position of the tilt information of the image pickup device to a position along the end portion in the longitudinal direction or the lateral direction of the image display unit. As a result, the tilt guide information can be easily grasped.
According to the image pickup apparatus of claim 3, the inclination information of the image pickup apparatus is the inclination information of the roll direction indicating the inclination of the image pickup apparatus in the roll direction.
The display control means intuitively and easily grasps the tilt in the roll direction by displaying a tilt guide, which is a display corresponding to the tilt information in the roll direction, and a marker that moves along the display scale. be able to.

According to the image pickup apparatus of claim 4, the tilt guide includes a marker that moves according to the tilt amount of the image pickup device, and the marker is a marker whose color changes according to the tilt amount in the roll direction. By doing so, it is possible to intuitively grasp the amount of inclination in the roll direction by the movement of the marker or the change in the color of the marker.

According to the fifth aspect of the present invention, the display control means does not switch the display position of the tilt information of the image pickup device when the tilt amount in the pitch direction of the image pickup device exceeds a predetermined range. Moreover, by erasing the marker , the user can easily and accurately grasp the roll angle detection accuracy so as not to decrease the roll angle detection accuracy due to the inclination amount in the pitch direction exceeding a predetermined range.
According to the image pickup apparatus of claim 6, the display control means improves the accuracy of tilt detection by changing the display form of the tilt guide when the tilt amount in the pitch direction exceeds a predetermined range. When the pitch angle is out of the range that can be maintained, it can be surely grasped by the tilt guide display, and it can be used within the range of the pitch angle that can easily maintain the accuracy of tilt detection.

According to the image pickup apparatus of claim 7, the inclination in the roll direction according to claim 1 is 60 degrees, so that the image pickup apparatus is provided in the horizontal position or the vertical position to be 60 degrees in the roll direction. When tilted until it exceeds, the display position of the tilt information is switched, so that the tilt in the roll direction can be accurately grasped.

The appearance of a digital camera as an image pickup apparatus which concerns on embodiment of this invention is shown, (a) is a front view, (b) is a rear view, and (c) is a plan view. It is a block diagram which shows typically the system structure of the image pickup apparatus which concerns on embodiment of this invention. It is a figure which shows the change of the display form of a monitor display when the image pickup apparatus which concerns on 1st Embodiment of this invention returns from the tilted state to the vicinity of 0 degree. It is a figure which shows the change of the display form of a monitor display when the image pickup apparatus which concerns on 1st Embodiment of this invention is tilted from the tilted state to nearly 90 degrees. It is a figure which shows the change of the display form of a monitor display when the image pickup apparatus which concerns on 1st Embodiment of this invention reaches close to 90 degrees from the tilted state. It is a figure which shows the display form of the tilt guide display of a monitor display in the image pickup apparatus which concerns on 2nd Embodiment of this invention. It is a figure which shows the display form of the pitch angle of the tilt guide display of the monitor display in the image pickup apparatus which concerns on 3rd Embodiment of this invention. It is a figure which shows the display form of the pitch angle of the tilt guide display of a monitor display in the image pickup apparatus which concerns on 4th Embodiment of this invention. It is a figure which shows the display form of the tilt guide display of a monitor display when it is tilted until it becomes a large pitch angle in the image pickup apparatus which concerns on 4th Embodiment of this invention. It is a figure which shows the tilt guide display of both the roll angle and the pitch angle of the monitor display in the image pickup apparatus which concerns on 8th Embodiment of this invention. It is a figure for demonstrating the example of the tilt guide display of both the roll angle and the pitch angle of the monitor display in the image pickup apparatus which concerns on 9th Embodiment of this invention. It is a figure for demonstrating another example of the tilt guide display of both the roll angle and the pitch angle of the monitor display in the image pickup apparatus which concerns on 9th Embodiment of this invention. It is a figure which shows the display form of the tilt guide display of both the roll angle and the pitch angle of the monitor display in the image pickup apparatus which concerns on 9th Embodiment of this invention. It is a figure which shows the display form of the tilt guide display of both the roll angle and the pitch angle of the monitor display in the image pickup apparatus which concerns on 10th Embodiment of this invention. It is a figure which shows the display form of the tilt guide display of the monitor display in the case of the horizontal position in the image pickup apparatus which concerns on 11th Embodiment of this invention. It is a figure which shows the display form of the tilt guide display of the monitor display in the case of the horizontal position in the image pickup apparatus which concerns on 11th Embodiment of this invention. It is a figure which shows the display form of the tilt guide display of the monitor display in the case of the horizontal position in the image pickup apparatus which concerns on 11th Embodiment of this invention. It is a figure which shows the display form of the tilt guide display of the monitor display in the case of the vertical position in the image pickup apparatus which concerns on 11th Embodiment of this invention. It is a figure which shows the display form of the tilt guide display of the monitor display in the case of the vertical position in the image pickup apparatus which concerns on 11th Embodiment of this invention. It is a figure which shows the display form of the tilt guide display of the monitor display in the case of the vertical position in the image pickup apparatus which concerns on 11th Embodiment of this invention. It is a figure which shows the display form of the tilt guide display of a monitor display in the image pickup apparatus which concerns on 13th Embodiment of this invention. It is a flowchart for demonstrating the control of the display form of the tilt guide display of a monitor display in the image pickup apparatus which concerns on 13th Embodiment of this invention.

Hereinafter, the imaging apparatus of the present invention will be described in detail with reference to the drawings based on the embodiments.
1A and 1B show the appearance of an image pickup apparatus configured as a digital camera according to an embodiment of the present invention, in which FIG. 1A is a front view, FIG. 1B is a rear view, and FIG. 1C is a plan view. Further, FIG. 2 is a block diagram schematically showing the system configuration inside the image pickup apparatus.
As shown in FIGS. 1A and 1C, a release switch (shutter release button) SW1, a mode dial switch SW2, and a first jog dial switch SW3 are arranged on the upper surface of the image pickup apparatus. Further, on the front side of the image pickup apparatus, a strobe light emitting unit 1, a distance measuring unit 2, an optical finder 3, and a lens barrel unit 4 are provided. The lens barrel unit 4 is
Includes shooting lens.
On the back of the image pickup device, as shown in FIG. 1 (b), an LCD monitor 5, a second jog dial switch SW4, a zoom switch [TELE] SW5, a zoom switch [WIDE] SW6, and an upper switch SW7. , Right switch SW8, OK switch SW9, left switch SW10, down / macro switch SW11, display switch SW12, delete switch SW13, menu switch SW14, and power switch SW15. Further, a battery lid 6 is provided on the side surface of the image pickup apparatus.

Each switch SW1 to SW15 is a switch operated by the user and constitutes an operation key unit. The appearance of the digital camera as the image pickup apparatus according to the present invention is not necessarily limited to the appearance shown in FIG. 1, and may have an appearance different from that shown in FIG.
Since the functions and operations of each part of the digital camera as an image pickup device are known, detailed description thereof will be omitted, and then the system configuration inside the image pickup device will be described with reference to FIG. 1 with reference to FIG. ..
In FIG. 2, the solid-state image pickup device (CCD) 101 is an image pickup device configured by using, for example, a CCD (charge-coupled device) or a CMOS (complementary metal oxide semiconductor) for photoelectric conversion of an optical image. .. Front-end IC (F / E-IC) 10 as an image pickup processing means
2 is a correlated double sampling unit (C) that performs correlated double sampling for image noise removal.
DS) 1021, a gain control unit (AGC) 1022 that adjusts the gain, an A / D (analog-digital) conversion unit 1023 that performs analog-to-digital conversion, and a timing signal generation unit (TG) that generates a drive timing signal. It is configured as an IC (integrated circuit) having 1024. Here, the TG1024 is supplied with the vertical sync signal VD and the horizontal sync signal HD from the first CCD signal processing block 1041, and the drive timing is driven to the CCD 101 and the F / E-IC 102 by the signal output from the CPU block 1043. Output a signal.

The digital still camera processor 104 (hereinafter referred to as “processor 104”) sets the white balance and gamma to the output image data from the CCD 101 via the F / E-IC 102, and sets the TG1024 of the F / E-IC 102. Vertical sync signal VD
The first CCD signal processing block 1041 that supplies the horizontal synchronization signal HD, the second CCD signal processing block 1042 that converts image data into brightness data and color difference data by filtering processing, and central processing that controls the operation of each part of the device. Unit (CPU) block 1043, local SRAM (static random access memory) 1044 for temporarily storing data required for control, and USB for USB communication with external devices such as PC (personal computer). The block 1045, the serial block 1046 for serial communication with an external device such as a PC, the PEG codec (JPEG-CODEC) block 1047 for PEG compression / decompression, and the size of the image data are enlarged / reduced by interpolation processing. Resize (RESIZE) block 1048 and liquid crystal of image data (
Controls a TV signal display block 1049 that converts to a video signal for display on an external display device such as an LCD) monitor 5 or a TV (television) receiver, and a memory card for recording captured image data. It has a memory card controller block 10410 and. Each of these blocks is connected to each other via a bus line.

Further, outside the processor 104, RAW-RGB image data (RGB image data in which white balance adjustment and γ adjustment have only been performed) and YUV image data (brightness data / color difference data conversion have been performed). An SDRAM (synchronous dynamic random access memory) 103 that stores image data) and PEG image data (image data in a PEG-compressed state) is arranged, and the SDRAM 103 has a memory controller (not shown) and a bus in the processor 104. It is connected via a line.
The SDRAM 103 temporarily stores the image data when the processor 104 performs various processes on the image data. The image data to be saved is, for example, from CCD101, F /
RAW-RGB image data in a state where white balance adjustment and gamma adjustment have been performed in the first CCD signal processing block 1041 after being captured via the E-IC102, and the second CC.
YUV image data in a state where brightness data / color difference data has been converted in the D signal processing block 1042, JPEG image data compressed in JPEG in the JPEG / CODEC block 1047, and the like.
A built-in memory such as a RAM (a built-in memory for storing captured image data even when a memory card is not installed in the memory card slot) 107, a control program, parameters, and the like are further stored outside the processor 104. ROMs (not shown) are provided, which are also connected to the processor 104 by a bus line.

When the power switch SW15 of the digital camera is turned on, the control program stored in the ROM is loaded into the main memory (not shown) of the processor 104, and the processor 10 is loaded.
4 controls the operation of each part according to the control program, and temporarily stores the control data, parameters, and the like in the built-in memory 107 and the like.
The lens barrel unit 4 is from a zoom optical system 41 having a zoom lens 41a for capturing an optical image of a subject, a focus optical system 42 having a focus lens 42a, an aperture unit 43 having an aperture 43a, and a mechanical shutter unit 44 having a mechanical shutter 44a. It is equipped with a lens barrel. The zoom lens 41a and the focus lens 4
The 2a and the aperture 43a constitute a photographing optical system. Further, the optical axis of the photographing optical system is defined as the Z axis, and the plane orthogonal to the Z axis is defined as the XY plane.
The zoom optical system 41, the focus optical system 42, the aperture unit 43, and the mechanical shutter unit 44 are driven by the zoom motor 41b, the focus motor 42b, the aperture motor 43b, and the mechanical shutter motor 44b, respectively.

The motors 41b to 44b of the lens barrel unit 4 are driven by the motor driver 45, and the motor driver 45 is controlled by the CPU block 1043 of the processor 104.
Further, a subject optical image is formed on the light receiving surface of the CCD 101, which is a solid-state image sensor that photoelectrically converts an optical image obtained by each lens system of the lens barrel unit 4, and the CCD 101 electrically images the subject optical image. It is converted into information and an image signal is output to the F / E-IC 102.
These signal control processes are performed via the TG1024 by the VD (vertical synchronization) -HD (horizontal synchronization) signal output from the first CCD signal processing block 1041 of the processor 104. The TG1024 generates a drive timing signal based on the VD-HD signal.
The processor 104 supplies a vertical sync signal VD and a horizontal sync signal HD by the first CCD signal processing block 1041 in order to perform white balance adjustment and gamma adjustment on the output data obtained from the CCD 101 via the F / E-IC 102. Then, the second CCD signal processing block 1042 converts the data into brightness data and color difference data by filtering processing.

Further, the CPU block 1043 controls the operation of each part of the device, and temporarily stores data and the like necessary for control in the local SRAM 1044. Further, the processor 104 calculates data indicating the tilt of the image pickup device based on the angle data transmitted from the acceleration sensor 111, and displays the tilt information on the liquid crystal display (LCD) monitor 5 via the LCD driver 108. Details will be described later).
The CPU block 1043 further controls the strobe circuit 114 to emit illumination light from the strobe light emitting unit 1. In addition to this, the CPU block 1043 also controls the ranging unit 2.
The CPU block 1043 is connected to the sub CPU 112 of the processor 104 and is connected to the sub C.
The PU 112 is connected to an operation key unit including operation switches SW1 to SW15. The operation key units (SW1 to SW15) are operation units including a group of key switches operated by the user. Further, the sub CPU 112 is a CPU having a ROM / RAM built in one chip, and outputs output signals of operation key units (SW1 to SW15) to the CPU block 1043 as user operation information.

The USB block 1045 communicates with an external device such as a personal computer via a USB connector (not shown), and the serial block 1046 is a serial communication connector such as an RS-232C connector from a serial driver circuit (not shown). It is connected to an external device via USB and performs serial communication. The TV signal display block 1049 is the LCD driver 108.
It is connected to the LCD monitor 5 via a video amplifier (video AMP) [amplifier (amplifier-amplifier) for converting a video signal output from the TV signal display block 1049 into a 75Ω impedance] 109. Video jack (camera T
It is connected to a jack) 110 for connecting to an external display device such as V. The memory card controller block 10410 is connected to a card contact in a memory card slot (not shown). ^The I2C (Inter Integrated Circuit to I2C) block 10411 is connected to an acceleration sensor 111 as a tilt detecting means.
The LCD driver 108 is a drive circuit that drives the LCD monitor 5 and converts the video signal output from the TV signal display block 1049 into a signal to be displayed on the LCD monitor 5. The LCD monitor 5 is a display device for a monitor, and is intended to monitor the state of the subject before shooting, to check the shot image, and to display the tilt of the image pickup device described later, and is a memory card or built-in. It is used to display the image data recorded in the memory 107 and the tilt information of the image pickup apparatus.

The video AMP 109 displays the video signal output from the TV signal display block 1049.
It is an amplifier for 75Ω impedance conversion, and the video jack 110 is a connection jack for connecting to an external display device such as a TV receiver.
The sub CPU 112 is a CPU having a ROM / RAM built into one chip, and outputs output signals of the above-mentioned operation key units (SW1 to SW15) to the above-mentioned CPU block 1043 as user operation information. The built-in memory 107 is a memory for storing captured image data.
The acceleration sensor 111 as the tilt detecting means is mounted on the printed circuit board (PCB) constituting each of the above-mentioned parts, and detects the 2-axis X, Y data (X, Y) and the temperature T data to be a processor. It is sent to the I2C block 10411 of 104. Processor 104 is I2
Based on the data given from the acceleration sensor 111 via the C block 10411, the tilt information such as the roll angle to be displayed is calculated by, for example, the CPU block 1043 (tilt calculation means), and the size of the display scale of this roll angle is large. The display image corresponding to the above is selected (display processing means), and the image obtained by synthesizing the image of the marker M as a mark at the position indicating the roll angle on this display image is displayed on the LCD monitor 5 or the like (image display). Display on the device).

When X0 and Y0 are the output data of the data (X, Y) of the two axes X and Y at zero gravity, the roll angle θ with respect to the horizontal of the acceleration sensor 111 is expressed by the following equation (1).
θ [deg] = 180 / π * arctan {(Y-Y0) / (X-X0)} ... (1)
Similarly, another accelerometer 111 installed so as to be able to detect the tilt of the image pickup device in the pitching direction detects the pitch angle to be displayed and sends the data to the processor 104. Based on the data transmitted from the acceleration sensor 111, the processor 104 calculates the tilt (pitch angle) of the image pickup device to be displayed by, for example, the CPU block 1043 (tilt angle calculation means), and takes a picture on a part of the LCD monitor 5. It can be displayed superimposed on the image (however, this function is optional and optional, but if this function is provided, only the roll angle or only the pitch angle, or both the roll angle and the pitch angle are provided. It is preferable to provide a selection button for instructing the user to select and display.).
The processor 104 determines the size of the calculated roll angle and / or pitch angle when displaying the roll angle and / or pitch angle on the LCD monitor 5, and displays this angle according to the size of this angle. Change the range of the display scale. This display scale has
A display of marker M, which is a pseudo bubble image like a bubble in a level using a liquid, a so-called level, is added, and the angle is recognized by looking at the scale of the scale on which this marker M is located. do. Therefore, the processor 104 synthesizes an image of the marker M indicating the angle on the display scale in which the range is selected and displays it on the LCD monitor 5. Further, the angle shall be recorded in the built-in memory 107 or the like.

In the processor 104, the roll angle (which does not directly indicate the inclination of the image pickup device) obtained by the equation (1) is in a state where the image pickup device is as shown in FIG. 3 (a), that is, the image pickup device is horizontal. On the other hand, if it is in the range of 0 degrees ± 5 degrees to ± 60 degrees, the display scale B1 indicating the roll angle is displayed.
Sideways with respect to the display screen of the LCD monitor 5 (direction along the longitudinal direction of the display screen of the image pickup device)
It can be configured to be displayed on the screen in the state. On the other hand, when the roll angle in the left-right direction with respect to the horizontal of the image pickup device is within a predetermined small range, for example, 0 degrees ± 5 degrees and is close to the horizontal, the roll angle can be accurately measured in FIG. 3 (b). ) Display scale B2
Automatically expands the range of. Further, the roll angle is ± 6 as shown in FIG. 4 (b).
It can be configured to switch the screen display to the portrait orientation (vertical position) when it exceeds 0 degrees.
Further, the image pickup apparatus enlarges the display scale B2 to improve the accuracy when the roll angle reaches the region of 90 degrees ± 5 degrees (near the vertical direction). In general, when the image pickup device is greatly tilted from the horizontal to the left and right, the user can recognize that the image pickup device is tilted with almost no visual inspection. However, when the image pickup device is in a horizontal state considered to be a shooting posture, it is desired to strictly confirm whether or not the image pickup device is correctly horizontal. Therefore, the image pickup device according to this embodiment. Then, as described above, when the roll angle is near the horizontal (0 degree ± 5 degrees), the range of the display scale B2 can be expanded, so that the position of the marker M can be read accurately. It is possible to accurately respond to such user's request.

The vertical neighborhood is not necessarily limited to 0 degrees ± 5 degrees, and is, for example, 0 degrees ±.
It may be 4 to 7 degrees.
Further, as shown in FIG. 6, the processor 104 is configured to always display only one display scale, and the scale interval (scale) of the display scale B3 is displayed at equal intervals, that is, linearly. If the roll angle is close to horizontal (center if marker M is near the center), the part is displayed in a fine range, and if the roll angle is not close to horizontal, for example, 0 degrees ± 5
In the case of 60 degrees ± 5 degrees from degrees, the part where the marker M is located is displayed in a coarse range.
It can also be configured to provide a non-linear display.
As a result, the roll angle can be displayed with high accuracy at the timing when only one display scale is used and accuracy is required without switching the display scale B3 itself. For example, the scale interval of the display scale can be arbitrarily changed non-linearly by displaying the logarithmic display or the exponentiation display when the roll angle is ± 1 degree or more.

Further, the display processing means included in a part of the processor 104 is a state where the roll angle is close to horizontal (0 degree ± 5 degrees) and a normal state where the roll angle is not close to horizontal (0 degree ± 5 degrees) in the above-mentioned roll angle display method. It can be configured to change the number of samplings and the number of average processes of the acceleration sensor 111 depending on the case (0 degree ± 5 degrees to 0 degree ± 60 degrees). That is, in the normal state where the image pickup device is not close to horizontal, the number of samplings and average processing of the roll angle in the accelerometer 111 is controlled to be small so that the approximate inclination of the image pickup device can be displayed instantly. It is possible to cope with a sudden change in the tilt of the image pickup device. On the other hand, in the case of being close to the horizontal state (0 degree ± 5 degrees), the display processing means controls the number of samplings and the average number of processing of the roll angle acceleration sensor 111 in the acceleration sensor 111 so as to increase the inclination. The value can be configured to be displayed with high accuracy. Also, in the normal state and the horizontal state,
It can be configured to change the moving speed of the marker M that moves along the display scale. That is, in the normal state, it is possible to give priority to speeding up the response by increasing the response speed, and in the horizontal state, it is possible to give priority to slowing down the response speed to make it easier for the user to align the image pickup device horizontally.

Further, when the pitch angle (so-called tilt angle in the front-back direction) falls within the range of 0 degree ± 5 degrees to 0 degree ± 60 degrees, the processor 104 has a pitch angle having a wide range as shown in FIG. The display scale B4 can be configured to be displayed on the screen in a portrait orientation with respect to the display screen of the LCD monitor 5.
Further, in the range of this display scale B4, when the pitch angle approaches 0 degree (0 degree ± 5 degree) and the vertical vicinity (90 degree ± 5 degree), the inclination of the image pickup apparatus can be accurately measured. That is, as shown in FIG. 7, the display scale B5 can be configured to automatically expand the range and enable highly accurate reading.
Further, in the above-mentioned pitch angle display method, the processor 104 (display processing means) has a case where the pitch angle is close to vertical (90 degrees ± 5 degrees) and a normal state where the pitch angle is not close to vertical (0 degrees ± 5 degrees). The number of samplings and the number of average processes of the accelerometer 111 can be changed depending on whether the degree is from 0 degree to 0 degree ± 30 degree). That is, the normal state (0 degree ± 5) that is not close to vertical
In the case of 0 degrees ± 30 degrees from degrees), the number of samplings and average processing of the pitch angle in the accelerometer 111 is controlled to be small so that the approximate inclination of the image pickup device can be displayed instantly. It is possible to cope with a sudden change in the tilt of the image pickup device.

On the other hand, in the case of being close to vertical (near vertical) (90 degrees ± 5 degrees), the processor 104 controls so that the number of samples and the average number of processes of the acceleration sensor 111 of the pitch angle in the acceleration sensor 111 increases. It can be configured to display the tilt value with high accuracy. Further, it can be configured to change the moving speed of the marker M that moves along the display scale between a normal state (a state deviating from the vicinity of the horizontal) and a state close to the horizontal. That is, in the normal state, it is possible to give priority to speeding up the response by increasing the response speed, and in the horizontal state, it is possible to give priority to slowing down the response speed to make it easier for the user to align the image pickup device horizontally.
Hereinafter, the processing of the processor 104 that functions as the display processing means when displaying both the roll angle and the pitch angle in combination will be described.
When the roll angle is 0 degrees ± 60 degrees or less, the processor 104 sets the roll angle to LC.
The display scale B1 and the marker M in the landscape orientation are displayed on the display screen of the D monitor 5, and the pitch angle is displayed by the display scale B5 and the marker M in the portrait orientation as shown in FIG. Can be configured. Also, when the roll angle exceeds 0 degrees ± 60 degrees (not shown).
Can be configured to switch the roll angle display to the portrait display scale and the pitch angle display to the landscape display scale.

Further, the processor 104 can be configured so that the display scale for displaying the width of the display range is wide and the display scale for displaying the width of the display range are different in coloring. For example, from a state where the roll angle and / or pitch angle is 0 degrees ± 5 degrees to 0 degrees ± 6
When the inclination becomes large to the state of 0 degrees, the coloring of the display scale is changed. Further, the display scale is colored even when the inclination increases from the state where the roll angle and / or the pitch angle is 90 degrees ± 5 degrees to the state where the roll angle and / or the pitch angle is 90 degrees ± 30 degrees. As a change form of this coloring, for example, switching from a black display scale to a red display scale can be considered.
Further, a selection button (not shown) is provided on the operation surface of the image pickup apparatus to instruct the user to select and display only the roll angle, only the pitch angle, or both the roll angle and the pitch angle as a tilt guide display. It can be configured.
3 to 10 are explanatory views showing a display method for displaying an inclination in the image pickup apparatus according to the embodiment of the present invention.
Hereinafter, a specific display method for displaying the inclination of the image pickup apparatus according to the first to eighth embodiments will be described with reference to FIGS. 3 to 9.
The processing in each of the following embodiments is mainly performed by the acceleration sensor 111, the processor 104, the LCD monitor 5, and the like.

[First Embodiment]
In this first embodiment, when the roll angle obtained by the above-mentioned equation (1) is in the range of 0 degrees ± 5 degrees to ± 60 degrees (generally, the longitudinal direction of the screen is substantially horizontal). (It is considered to be a horizontal position), as shown in FIG. 3A, the display scale B1 indicating the roll angle is displayed, and the display scale B1 indicating the roll angle is displayed. It is configured to be displayed near the bottom edge of the screen. The range of this display scale B1 is automatically expanded so that the roll angle can be accurately measured when the roll angle reaches a region approaching horizontal with 0 degrees ± 5 degrees, that is, a region near the horizontal. Let me. (The scale of the display scale B2 shown in FIG. 3B has a larger scale than the range of the display scale B1 shown in FIG. 3A, and the accuracy is higher). Further, as shown in FIG. 4 (b), when the roll angle exceeds ± 60 degrees (
The vertical direction of the screen is considered to be a vertical position that is almost vertical), and the display is automatically switched to the vertical position like the display scale B1. Further, as shown in FIG. 5A,
When the roll angle is in the range of 90 degrees ± 5 degrees to 90 degrees ± 30 degrees, the display scale B1 in the reduced range is displayed, and the roll angle is vertical as shown in FIG. 5 (b). In the case of a close 90 degrees ± 5 degrees, the range is expanded and the angle can be obtained with high accuracy. Display scale B2
Will be displayed.

[Second Embodiment]
In this second embodiment, as shown in FIG. 6, only one display scale B3 is displayed as the display scale, and the scale intervals (scales) of the display scale B3 are not displayed at linear equal intervals. In addition, the scale in the area where the roll angle is close to horizontal is displayed in a fine range, and the scale scale in the area where the roll angle is not close to horizontal (roll angle is 0 degrees ± 30 degrees) is displayed in a coarse range. It is configured. With this configuration, the roll angle can be reasonably displayed without switching the display scale itself. As a display method, for example
It is possible to arbitrarily change the scale interval of the display scale B3 by displaying a logarithmic display or a power display when the roll angle is ± 1 degree or later.

[Third Embodiment]
In the third embodiment, the display method of the roll angle or the pitch angle is the same as the display method shown in the first and second embodiments, but the processor 104 has a horizontal roll angle or pitch angle. The number of samplings and the average number of processes of the accelerometer 111 are changed depending on whether the state is close to (0 degrees ± 5 degrees) or not horizontal (0 degrees ± 5 degrees to 0 degrees ± 60 degrees). It is configured as follows. That is, in the case of a non-horizontal normal state, the number of samplings and the number of average processing of the roll angle or pitch angle in the acceleration sensor 111 are configured to be small so that the approximate inclination of the image pickup apparatus can be displayed instantly. On the other hand, when the roll angle or the pitch angle is close to the horizontal state, the processor 104 is configured to increase the sampling number and the average processing number of the roll angle acceleration sensor 111 in the acceleration sensor 111 to increase the inclination value. To be able to display with accuracy. Further, in this embodiment, the marker M that moves along the display scales (B1, B2) in the normal state and the horizontal state.
It can also be configured to change the movement speed of. In the normal state, the response speed is increased and it becomes possible to respond quickly, and in the horizontal state, the response speed becomes slower, but it is possible for the user to easily align the image pickup device horizontally.

[Fourth Embodiment]
In this fourth embodiment, when the pitch angle falls within the range of 0 degrees ± 5 degrees to 0 degrees ± 60 degrees, as shown in FIG. 9, the pitch angle has a wide range (coarse range). The display scale B4 is displayed on the screen in a portrait orientation with respect to the display screen of the LCD monitor 5.
Further, the range of the display scale B4 is the display scale shown in FIGS. 7 and 8 so that the inclination of the image pickup apparatus can be accurately measured as the pitch angle approaches horizontal with 0 degree ± 5 degrees. Like B5, the range is automatically enlarged and displayed.

[Fifth Embodiment]
In the fifth embodiment, the pitch angle display method is the same as the display method shown in the fourth embodiment, but the processor 104 has a state in which the pitch angle is close to a right angle (90 degrees ± 5 degrees). ) And the non-vertical state (90 degrees ± 5 degrees to 90 degrees ± 60 degrees), the difference is that the number of samples and the average number of processes of the acceleration sensor 111 are changed. That is, in the normal state, the number of samplings and average processing of the pitch angle in the accelerometer 111 is configured to be small so that the approximate inclination of the image pickup apparatus can be displayed instantly, while the pitch angle is horizontal. When close to the state, the processor 104 is the accelerometer 11.
The number of samplings and the number of average processes of 1 are configured to be large, and the inclination value is configured to be displayed with high accuracy. Further, in this embodiment, the moving speed of the marker M for moving the display scales (B1 and B2) is changed between the normal state and the horizontal state. With this configuration, the response speed is increased in the normal state to enable quick response, and the response speed is slower in the horizontal state, making it easier for the user to align the image pickup device horizontally.

[Sixth Embodiment]
Hereinafter, the sixth embodiment in which the roll angle and the pitch angle are combined will be described with reference to FIG. 10.
In the sixth embodiment, as shown in FIG. 10, when the roll angle is 0 degrees ± 5 degrees or less, this roll angle is displayed on the display scale B2 in a landscape orientation with respect to the display screen of the LCD monitor 5. However, the pitch angle is displayed on the display scale B5 in the vertical orientation state. Also, the roll angle is 0.
When the degree exceeds ± 60 degrees, the roll angle display is switched to the vertical display scale and the pitch angle display is switched to the horizontal display scale, although not shown.

[7th Embodiment]
In the seventh embodiment, the coloring is different between the display scale that displays the width of the display range wide and the display scale that displays the width of the display range narrowly. For example, when the roll angle and / or the pitch angle is 0 degrees ± 5 degrees, what was displayed in black is changed to 0.
When the inclination becomes large to the state of degree ± 60 degrees, the color of the display scale is changed to red. Also, from the state where the roll angle and / or pitch angle is 90 degrees ± 5 degrees, 90 degrees ± 30
The color of the display scale is changed from black to red, for example, even when the inclination becomes large to the state of degree. The colors of the display scale are not limited to black and red, but blue, green, and so on.
A combination such as yellow may be used.

[Eighth Embodiment]
In the eighth embodiment, a selection button (FIG.) for instructing the user to display only the roll angle, only the pitch angle, or both the roll angle and the pitch angle on the operation surface of the image pickup apparatus. Not shown) is provided.
For the user, it is possible to perform accurate shooting by appropriately operating the selection button according to the shooting target, which improves convenience.

[9th embodiment]
Next, in the above-mentioned imaging device, a ninth embodiment of the present invention is based on the premise that both the roll angle and the pitch angle of the imaging device are displayed by using an orthogonal three-axis acceleration sensor as the acceleration sensor 111. Will be explained.
If an acceleration sensor 111 having outputs of three axes orthogonal to each other is used and the direction in which the acceleration sensor 111 is incorporated in the image pickup apparatus is known, the magnitude of the acceleration applied to each axis is the gravitational acceleration in the axial direction. Since it is disassembled into two parts, it is possible to accurately know the tilt of the image pickup device in all directions.
In this case, as shown in FIG. 10, when the image pickup device is held in the horizontal position, the rotation around the Z axis is in the roll direction, the rotation around the X axis is in the pitch direction, and the rotation around the Y axis is in the yaw direction. Will be. When the image pickup device is held horizontally and substantially horizontally, the acceleration detected by the Y-axis is substantially equal to the gravitational acceleration, and the values detected by the X-axis and the Z-axis are almost zero. In this way, by detecting which axis mainly detects the gravitational acceleration, it is possible to know the approximate orientation of the image pickup apparatus.
The tilt data detected by the accelerometer 111 is CP via the I2C block 10411.
Received by the U block 1043, the main detection axis of the gravitational acceleration and the magnitude of the inclination are calculated by software or hardware, and the result is displayed on the display device.

At this time, as shown in FIG. 11, the roll angle and the pitch angle, which are inclinations in the roll direction and the pitch direction, are displayed on the LCD monitor 5 of the image pickup apparatus.
In the case of FIG. 11, the display modes of the tilt guide display G1 indicating the roll angle and the tilt guide display G2 indicating the pitch angle are almost the same, but the gauge of the tilt guide display G1 along the longitudinal direction of the display screen is tilted in the roll direction. , And the gauge of the tilt guide display G2 along the lateral direction of the display screen indicates the tilt in the pitch direction. In each gauge, it means that the angle of the square mark is tilted when it is in the center as shown, that is, the roll angle and pitch angle are zero, and the tilt angle, that is, the roll angle and pitch angle, increases as the distance from the center increases. ..
FIG. 12 shows a display example when the image pickup apparatus is held in a vertical position. In this case, the display form of the tilt guide display in the roll direction and the pitch direction is apparently almost the same as that in FIG. 11, but the difference from FIG. 11 is that the display device has a gauge in the lateral direction. The tilt guide display G3 shows the roll angle which is the tilt in the roll direction, and the tilt guide display G4 having the gauge in the longitudinal direction shows the pitch angle which is the tilt in the pitch direction.

However, when the tilt guide display in the roll direction and the pitch direction is switched when the holding direction is changed in this way, it becomes difficult to distinguish between the two. In order to deal with this, in this embodiment, as shown in FIG. 13, the display colors of the tilt guide display in the roll direction and the pitch direction are different, and the display color of the marker of the tilt guide display Gr1 in the roll direction is changed. For example, red is used, and the display color of the marker of the tilt guide display Gp1 in the pitch direction is, for example, blue. In this case, for example, even when the orientation of the image pickup apparatus is changed from the horizontal position to the vertical position in FIG. 13, the red color is the tilt guide display Gr1 in the roll direction, and the blue color is the tilt guide display Gp1 in the pitch direction. By making the display colors different in this way, the relationship between the gauge of each tilt guide display and the roll angle and pitch angle can be intuitively understood even when the vertical and horizontal directions are switched.

[10th Embodiment]
In the tenth embodiment, for the same purpose, as shown in FIG. 14, the display form of the tilt guide display in the roll direction and the pitch direction is different, for example, the tilt guide display G in the roll direction.
The gauge of r2 has the lowest height in the center and is narrow, and the height gradually increases and widens toward both ends. And. In this case as well, for example, even when the orientation of the image pickup apparatus is changed from the horizontal position to the vertical position in FIG. 14, the wider the width at both ends is the tilt guide display Gr2 in the roll direction, and the uniform width is the tilt in the pitch direction. The guide display is Gp2. By changing the display form in this way, the relationship between the gauge of each tilt guide display and the roll angle and pitch angle can be intuitively understood even when the vertical and horizontal directions are switched.
In the ninth and tenth embodiments, when the display of the tilt guide display in the pitch direction is not always required, a means for hiding the tilt guide display in the pitch direction is provided by setting the program. Is also feasible in the configurations shown in FIGS. 1 and 2. That is, the screen for setting the display presence / absence of each gauge is displayed on the display means such as the LCD monitor 5, and the result of the setting using the operation buttons (not shown) is stored in the EEPROM or the main memory and displayed. It may be displayed according to the setting contents called at times.

[Eleventh Embodiment]
Next, in the above-mentioned image pickup device, it is premised that an orthogonal two-axis acceleration sensor is used as the acceleration sensor 111 and the tilt guide display of the roll angle is displayed only when the pitch angle of the image pickup device is within a predetermined range. The eleventh embodiment of the present invention will be described.
The acceleration sensor 111 is mounted vertically on the main PCB (printed circuit board) on which the processor 104 or the like is mounted, that is, on the main board with respect to the image pickup device, and outputs orthogonal two-axis X and Y and temperature T data. do. The tilt of the image pickup device is calculated from the data, and the corresponding tilt guide display is displayed on the LCD monitor 5 or the like.
The roll angle θ with respect to the horizontal of the acceleration sensor 111 is expressed by the above-mentioned equation (1).
The pitch angle φ is expressed by the following equation (2).
φ [deg] = 180 / π * arctan (Gz / Gxy)
Gz = sqrt (Gxyz ² -Gxy ² )
Gxy = sqrt {(X-X0) ² + (Y-Y0) ² } ... (2)
Here, Gxyz is an output value at 1 G, and X0 and Y0 are outputs at zero gravity, respectively.

Then, the acceleration sensor 111 is mounted perpendicularly to the image pickup apparatus. More specifically, the accelerometer 111 is mounted vertically on the main board in a portion closer to the right end and closer to the lower end when viewed from the back side of the image pickup device, but is not necessarily limited to this position. is not it. If the pitch angle is increased in this state, the output values of the X-axis and the Y-axis output from the acceleration sensor 111 gradually become smaller, and are easily affected by noise and offset deviation. In other words, the more the pitch angle is added, the lower the display accuracy of the roll angle will be. Therefore, when the pitch angle becomes a certain angle as shown in FIGS. 15 to 17 and 18 to 20, for example, blinking the display, turning off the marker indicating the angle displayed on the bar, and warning sound. Warn by ringing. 15 to 17 show a case of a horizontal position, where (a) is a perspective view and (b) is a side view. FIG. 15 shows a state in which the image pickup apparatus is almost vertical, FIG. 16 shows a state in which a pitch angle is slightly added, and FIG. 17 shows a state in which a large pitch angle is added, and rolls for warning. The tilt guide display G of the corner is blinking. 18 to 20 show the case of the vertical position, where FIG. 18A is a perspective view and FIG. 20B is a side view. FIG. 18 shows a state in which the image pickup apparatus is almost vertical in a vertical position, FIG. 19 shows a state in which a slightly pitch angle is added, and FIG. 20 shows a state in which a large pitch angle is added, which is a warning. Therefore, the tilt guide display G of the roll angle is blinking.

[Twelfth Embodiment]
Next, a twelfth embodiment of the present invention will be described on the premise that the tilt guide display of the roll angle is displayed only when the temperature of the image pickup device is within a predetermined range in the above-mentioned image pickup device.
When the temperature is changed, the output values of the X-axis and the Y-axis of the acceleration sensor 111 change accordingly. For example, if the output values of the X-axis and the Y-axis become smaller by raising the temperature, in such a case, it becomes more susceptible to noise and offset deviation. Therefore, when the output T of the acceleration sensor 111 reaches an output value that is outside the standard range, the pitch angle or roll angle display that has been displayed up to that point is blinked, and the angle that was displayed on the bar. A warning is given by turning off the marker M indicating the above, sounding a warning sound, or the like.
Also in this case, the display form is substantially the same as in the cases of, for example, FIGS. 17 and 20.

[13th Embodiment]
Next, a thirteenth embodiment of the image pickup apparatus of the present invention will be described.
In the above-mentioned image pickup apparatus, when the pitch angle is increased and the image pickup apparatus is placed in a flattened state, both X and Y become 0 G, and the roll angle cannot be calculated. Even in the vicinity of 0G, the output values of X and Y decrease, so that the accuracy deteriorates. Therefore, assuming that the position of the display bar of the tilt guide display G is changed depending on the angle of the image pickup device as shown in FIG. 21, the display bar of the tilt guide display G is displayed when X and Y are near 0 G (for example, the threshold value is 0.1 G or less). It is possible to determine whether the position of is to be arranged along the longitudinal direction as shown in FIG. 21 (a) or along the lateral direction as shown in FIG. 21 (b). Can not. The display method in such a case is shown in the flowchart of FIG.
It is determined whether or not the output values Xt = n and Yt = n at the time of t = n are 0.1 G or less (step S11), and if both are not 0.1 G or less, the output value Xt = as it is. Calculate θ using n and Yt = n (step S12) and display it on the monitor (step S1).
3).

However, when both the output values of Xt = n and Yt = n are 0.1 G or less, X and Y
It is determined whether or not the output values of the above are both 0.1 G or less before m seconds (step S14).
), The angle θ is determined from the output values Xt = nm and Yt = nm m seconds before both are not 0.1 G or less, the position of the display bar is determined (step S15), and the process proceeds to step S13. And display it on the monitor. At that time, the position of the bar of the tilt guide display is fixed until either output value becomes 0.1 G or more, and the position of the bar is prevented from being unnecessarily changed and difficult to see. This is the same during playback, and when the display orientation is rotated depending on the angle of the image pickup device, it is not possible to determine in which direction the image should be rotated if the image pickup device is placed flat, but this is also the monitoring display bar. Change the display orientation by the same process as. In addition, no matter how many values of m are, m
When both Xt = nm and Yt = nm in the state before seconds are 0.1 G or less, a warning is displayed in substantially the same manner as in the eleventh embodiment (step S16).

[14th Embodiment]
Next, a fourteenth embodiment of the image pickup apparatus of the present invention will be described.
When the pitch angle is added and both X and Y are output values below the threshold value and the warning is displayed as described above, it is not necessary to obtain high accuracy, so the number of samplings is reduced. Therefore, it is possible to prevent a load from being applied to the processing system such as the processor 104 and reduce the power consumption.

1 Strobe light emitting unit 2 Distance measuring unit 3 Optical finder 4 Lens barrel unit 5 LCD monitor 6 Battery lid 104 Digital still camera processor 108 LCD driver 111 Accelerometer 112 Sub CPU
1041 First CCD signal processing block 1043 CPU block 10411 I2C block SW1 to SW15 Operation keys B1, B2, B3, B4, B5 Display scale M Marker G Tilt guide display Gp1, Gp2 Pitch angle tilt guide display Gr1, Gr2 Roll angle tilt Guide display

Japanese Unexamined Patent Publication No. 2004-343476 Japanese Unexamined Patent Publication No. 2007-174156 Japanese Patent No. 389655

Claims (7)

It ’s an image pickup device.
Image sensor and
An image display unit that displays an image captured by the image sensor, and an image display unit.
The image pickup apparatus is provided with a tilt detection unit for detecting the tilt in the roll direction and the tilt in the pitch direction .
The tilt information of the image pickup device is displayed on the image display unit according to the tilt of the image pickup device detected by the tilt detection unit.
In an image pickup device including a display control means for switching a display position of tilt information of the image pickup device when the tilt in the roll direction of the image pickup device exceeds a predetermined range.
When the tilt in the pitch direction of the image pickup device is within a predetermined range and the tilt in the roll direction exceeds the predetermined range, the display control means switches the display position of the tilt information of the image pickup device.
An imaging device characterized in that when the tilt in the pitch direction of the image pickup device exceeds a predetermined range and the tilt in the roll direction exceeds a predetermined range, the display position of the tilt information of the image pickup device is not switched. The image pickup device according to claim 1, wherein the display control means switches the display position of the tilt information of the image pickup device to a position along an end portion in the longitudinal direction or the lateral direction of the image display unit. .. The tilt information of the image pickup device is tilt information in the roll direction indicating the tilt of the image pickup device in the roll direction.
The first or second aspect of the present invention, wherein the display control means displays a tilt guide, which is a display corresponding to the tilt information in the roll direction, and a marker that moves along the display scale. Imaging device. The image pickup device according to claim 3, wherein the tilt guide is configured to change the color of the display scale when the tilt amount in the roll direction of the image pickup device increases from a small state. The display control means is characterized in that, when the amount of tilt in the pitch direction of the image pickup device exceeds a predetermined range, the display position of the tilt information of the image pickup device is not switched and the marker is erased . 3 or the image pickup apparatus according to claim 4. The imaging according to any one of claims 3 to 5, wherein the display control means changes the display form of the tilt guide when the tilt amount in the pitch direction exceeds a predetermined range. Device. The imaging device according to claim 1 or 2, wherein the inclination in the roll direction according to claim 1 is 60 degrees.

Images