JP2013174898A - Imaging display device, and imaging display method - Google Patents

Abstract

PROBLEM TO BE SOLVED: To realize assistance and enhancement of visual ability of a user, and precise operation control according to external conditions (surrounding condition, condition of imaging object, present time and date, condition of present position).SOLUTION: When a user wears an attachment unit of spectacles type or a head-mounting type, the user can visually recognize display means located in front of the user's eyes. When an image photographed by imaging means is displayed by the display means, the user can visually recognize a photographed image of a scene in a direction where the user normally visually recognizes on the display means. When a mode of the image displayed on the display means is changed according to external conditions, visual ability of the user can be assisted and enhanced.

Description

  The present invention captures an image in which the direction visually recognized by the user is taken as a subject direction and is displayed in front of the user's eyes while being worn on the user by, for example, a spectacle-type or head-mounted type mounting unit. The present invention relates to a display device and an imaging display method.

JP-A-8-126031 JP-A-9-27970 Japanese Patent Laid-Open No. 9-185009

  For example, as in each of the above patent documents, various devices have been proposed in which a display unit is arranged in front of the user's eyes and displayed by a spectacle-type or head-mounted mounting unit.

However, there is no known device that performs control related to imaging and display particularly from the viewpoint of assisting the user's vision and expanding visual ability.
Therefore, an object of the present invention is to realize user assistance and expansion. Furthermore, regarding the control of the display operation and the imaging operation for realizing visual assistance and expansion, accurate operation control is performed according to the external environment (ambient environment, subject, date, place, etc.).

  An imaging display device according to the present invention includes an imaging unit configured to image a direction visually recognized by a user as a subject direction, and a transparent or translucent through-hole that is disposed so as to be positioned in front of the user's eyes. At least two of a display unit that can switch between a state and an image display state in which an image captured by the imaging unit is displayed, and an ambient environment sensor, a photographing target sensor, an image analysis unit, a position information acquisition unit, or a communication unit The external state information acquisition means for acquiring external world information from each of the above and the through state and the image display for the display means based on two or more external world information acquired by the external world information acquisition means Control means for performing state switching control.

The outside world information acquired by the outside world information acquisition means is ambient brightness information, temperature information, humidity information, atmospheric pressure information, or weather information.
The outside world information acquired by the outside world information acquiring unit is information on a distance to the imaging target of the imaging unit.
The outside world information acquired by the outside world information acquiring unit is information on the movement of the imaging target of the imaging unit.
The outside world information acquired by the outside world information acquisition means is information on a point corresponding to the current position.

The control means controls the display means to switch between the through state and the image display state.
In addition, illumination means for illuminating the subject direction is further provided, and the control means controls the illumination operation by the illumination means based on the information acquired by the outside world information acquisition means.
The outside world information acquisition unit can perform image analysis on the image captured by the imaging unit by the image analysis unit, and can acquire outside world information for determining whether or not the imaging target is a character. The captured image Voice synthesis means for synthesizing speech contained in the text as a read-out voice, and voice output means for outputting the voice generated by the voice synthesis means, wherein the control means is acquired by the outside world information acquisition means Based on the information, the synthesized speech output operation by the speech synthesizer is controlled.

  An imaging display method according to the present invention includes an imaging unit configured to image a direction visually recognized by a user as a subject direction, and a transparent or translucent through-hole that is disposed in front of the user's eyes. As an imaging display method of an imaging display device comprising display means capable of switching between an image display state for displaying an image captured by the imaging means provided with a state, an ambient environment sensor, an imaging target sensor, an image The display based on the outside world information acquisition step of acquiring outside world information from at least two of the analysis unit, the position information acquisition unit or the communication unit, and the two or more outside world information acquired in the outside world information acquisition step A control step for performing switching control between the through state and the image display state with respect to the means.

In the present invention described above, the user (user) visually recognizes the display means located in front of the eyes by wearing the imaging display device of the present invention with, for example, a spectacle-type or head-mounted type mounting unit. It becomes. Then, by displaying the image picked up by the image pickup means on the display means, the picked-up image of the scene in the direction normally viewed by the user can be visually recognized by the display means.
This means that the user sees the scene that is normally viewed through the imaging display device of the present invention. In this case, the user views the image displayed on the display means as a normal visual landscape. It will be. Here, if the mode of the image displayed on the display means is changed according to the external environment such as the ambient environment state or the subject state, the user's visual ability can be assisted or expanded.
For example, when a telephoto image is displayed, a distant view that the user cannot normally see can be seen. In addition, when a book or newspaper is being viewed, if the display means enlarges the display of the characters and adjusts the brightness and contrast, the display can be easily read even in a dark situation.
That is, it is possible to create a visual situation that is comfortable or interesting for the user by controlling the operation of the imaging means and the display means in accordance with external information and controlling the mode of the displayed captured image.

According to the present invention, an image picked up by the image pickup means, that is, a picked-up image with the direction viewed by the user as the subject direction is displayed on the display means in front of the user's eyes. By controlling the operation of the imaging means or the display means, it is possible to create a situation in which the user's visual ability is assisted or expanded in a pseudo manner.
In addition, the change of the display mode by the control of the imaging unit or the display unit is performed based on the surrounding environment determined from the external world information, the subject classification, the subject situation, etc. Since the control is executed, usability is improved.
In addition, the display means can be in a transparent or semi-transparent through state without displaying an image captured by the imaging means, so that there is no hindrance to normal life even in the mounted state. For this reason, the advantage of the imaging display device of the present invention can be obtained effectively in the normal life of the user.

It is explanatory drawing of the example of an external appearance of the imaging display apparatus of embodiment of this invention. It is a block diagram of the imaging display device of an embodiment. It is explanatory drawing of the through state of embodiment, a normal captured image display state, and a telephoto image display state. It is explanatory drawing of the display state of the wide-angle zoom image of embodiment. It is explanatory drawing of the display state of the enlarged image of embodiment. It is explanatory drawing of the display state of the adjustment image of embodiment. It is explanatory drawing of the display state of the infrared sensitivity raise captured image of embodiment. It is explanatory drawing of the display state of the ultraviolet-ray sensitivity raise captured image of embodiment. It is explanatory drawing of the division | segmentation display of embodiment. It is explanatory drawing of the display state of the adjustment image of embodiment. It is explanatory drawing of the display state of the highlight image of embodiment. It is a flowchart of the control processing of an embodiment. 6 is a flowchart of image control trigger discrimination processing according to the embodiment. 6 is a flowchart of image control trigger discrimination processing according to the embodiment. 6 is a flowchart of image control trigger discrimination processing according to the embodiment. 6 is a flowchart of image control trigger discrimination processing according to the embodiment. 6 is a flowchart of image control trigger discrimination processing according to the embodiment. 6 is a flowchart of image control trigger discrimination processing according to the embodiment. 6 is a flowchart of image control trigger discrimination processing according to the embodiment. 6 is a flowchart of image control trigger discrimination processing according to the embodiment.

Hereinafter, embodiments of the imaging display device and imaging display method of the present invention will be described in the following order.

[1. Appearance example of imaging display device]
[2. Configuration example of imaging display device]
[3. Display example]
[4. Detection of external information]
[5. Examples of various operations]
[6. Effect, modification and extension of embodiment]

[1. Appearance example of imaging display device]

As an embodiment, FIG. 1 shows an appearance example of an imaging display device 1 that is a glasses-type display camera. The imaging display device 1 has a mounting unit having a frame structure that, for example, makes a half turn from both sides of the head to the back of the head, and is mounted on the user by being put on both ear shells as illustrated.
The imaging display device 1 has a pair of display units 2 for the left eye and the right eye in the wearing state as shown in FIG. 2 is arranged. For example, a liquid crystal panel is used for the display unit 2, and by controlling the transmittance, a through state as shown in the figure, that is, a transparent or translucent state can be obtained. Since the display unit 2 is in the through state, there is no hindrance to normal life even if the user always wears it like glasses.

In addition, the imaging lens 3a is arranged facing forward so that the direction viewed by the user is taken as the subject direction in the state worn by the user.
Moreover, the light emission part 4a which performs illumination with respect to the imaging direction by the imaging lens 3a is provided. The light emitting unit 4a is formed by, for example, an LED (Light Emitting Diode).
Although only the left ear side is shown in the figure, a pair of earphone speakers 5a that can be inserted into the user's right ear hole and left ear hole in the mounted state are provided.
Microphones 6a and 6b for collecting external sound are arranged on the right side of the display unit 2 for the right eye and on the left side of the display unit 2 for the left eye.

FIG. 1 is an example, and various structures for the user to wear the imaging display device 1 can be considered. Generally, it may be formed of a mounting unit that is a spectacle type or a head mounting type. At least in the present embodiment, the display unit 2 is provided in front of the user's eyes, and is based on the imaging lens 3a. It suffices if the imaging direction is the direction visually recognized by the user, that is, the front of the user. In addition, a pair of display units 2 may be provided corresponding to both eyes, or one display unit 2 may be provided corresponding to one eye.
Further, the earphone speaker 5a may not be a left and right stereo speaker, but only one earphone speaker 5a may be provided to be worn only on one ear. The microphone may be one of the microphones 6a and 6b. Further, a configuration in which the microphone and the earphone speaker are not provided as the imaging display device 1 is also conceivable.
A configuration in which the light emitting unit 4a is not provided is also conceivable.

[2. Configuration example of imaging display device]

FIG. 2 shows an internal configuration example of the imaging display device 1.
The system controller 10 includes, for example, a microcomputer including a CPU (Central Processing Unit), a ROM (Read Only Memory), a RAM (Random Access Memory), a nonvolatile memory unit, and an interface unit. It is a control unit for controlling.
The system controller 10 controls each unit in the imaging display device 1 based on the external environment. That is, it operates in accordance with an operation program adapted to detect and determine the situation of the outside world and to control the operation of each unit accordingly. For this reason, from a functional point of view, as shown in the figure, an outside world situation determining function 10a for judging the outside world situation and an operation control function 10b for giving a control instruction to each part according to the judgment result of the outside world situation judging function 10a are provided.

In the imaging display device 1, an imaging unit 3, an imaging control unit 11, and an imaging signal processing unit 15 are provided as a configuration for imaging a scene in front of the user.
The imaging unit 3 includes a lens system including the imaging lens 3a illustrated in FIG. 1, an aperture, a zoom lens, a focus lens, and the like, and a drive system for causing the lens system to perform a focus operation and a zoom operation. In addition, a solid-state imaging device array that detects imaging light obtained by the lens system and generates an imaging signal by performing photoelectric conversion is provided. The solid-state imaging device array is, for example, a CCD (Charge Coupled Device) sensor array or a CMOS (Complementary Metal Oxide Semiconductor) sensor array.

  The imaging signal processing unit 15 includes a sample hold / AGC (Automatic Gain Control) circuit that performs gain adjustment and waveform shaping on a signal obtained by the solid-state imaging device of the imaging unit 3, and a video A / D converter. An imaging signal is obtained. The imaging signal processing unit 15 also performs white balance processing, luminance processing, color signal processing, blur correction processing, and the like on the imaging signal.

The imaging control unit 11 controls the operations of the imaging unit 3 and the imaging signal processing unit 15 based on instructions from the system controller 10. For example, the imaging control unit 11 controls on / off of operations of the imaging unit 3 and the imaging signal processing unit 15. The imaging control unit 11 performs control (motor control) for causing the imaging unit 3 to perform operations such as auto focus, automatic exposure adjustment, aperture adjustment, and zoom.
In addition, the imaging control unit 11 includes a timing generator. For the sample hold / AGC circuit and the video A / D converter of the solid-state imaging device and the imaging signal processing unit 11, a signal processing operation is performed by a timing signal generated by the timing generator. To control. In addition, the imaging frame rate can be variably controlled by this timing control.
Further, the imaging control unit 11 controls imaging sensitivity and signal processing in the solid-state imaging device and the imaging signal processing unit 15. For example, gain control of a signal read from a solid-state image sensor can be performed as imaging sensitivity control, black level setting control, various coefficient control of imaging signal processing in a digital data stage, correction amount control in blur correction processing, and the like can be performed. . As for imaging sensitivity, overall sensitivity adjustment that does not specifically consider the wavelength band, and sensitivity adjustment that adjusts the imaging sensitivity in a specific wavelength band such as the infrared region and the ultraviolet region (for example, imaging that cuts a specific wavelength band) Etc. are also possible. Sensitivity adjustment according to the wavelength can be performed by inserting a wavelength filter in the imaging lens system or wavelength filter calculation processing on the imaging signal. In these cases, the imaging control unit 11 can perform sensitivity control by insertion control of a wavelength filter, designation of a filter calculation coefficient, or the like.

The imaging display device 1 includes a display unit 2, a display image processing unit 12, a display driving unit 13, and a display control unit 14 that perform display for the user.
The imaging signal imaged by the imaging unit 3 and processed by the imaging signal processing unit 15 is supplied to the display image processing unit 12. The display image processing unit 12 is a so-called video processor, for example, and is a part capable of executing various display processes on the supplied imaging signal. For example, brightness level adjustment, color correction, contrast adjustment, sharpness (outline emphasis) adjustment, and the like of the imaging signal can be performed. The display image processing unit 12 generates an enlarged image obtained by enlarging a part of the imaging signal, or generates a reduced image, image processing for highlighting (highlighting) a part of the image, and divided display of the captured image. For example, image separation and synthesis, generation of a character image or image image, and processing of combining the generated image with a captured image can be performed. That is, various processes can be performed on the digital video signal as the imaging signal.

The display driving unit 13 includes a pixel driving circuit for displaying the video signal supplied from the display image processing unit 12 on the display unit 2 which is a liquid crystal display, for example. That is, a drive signal based on the video signal is applied to each pixel arranged in a matrix in the display unit 2 at a predetermined horizontal / vertical drive timing, and display is executed. Further, the display driving unit 13 can control the transmittance of each pixel of the display unit 2 to enter the through state.
The display control unit 14 controls the processing operation of the display image processing unit 12 and the operation of the display driving unit 13 based on an instruction from the system controller 10. That is, the display image processing unit 12 is caused to execute the various processes described above. In addition, the display drive unit 13 is controlled to be switched between the through state and the image display state.
In the following, for the “through state” in which the display unit 2 is transparent or translucent, the operation (and the state) in which the display unit 2 performs image display is “monitor display” (“monitor display state”). I will say.

The imaging display device 1 is provided with an audio input unit 6, an audio signal processing unit 16, and an audio output unit 5.
The voice input unit 6 includes microphones 6a and 6b shown in FIG. 1 and a microphone amplifier unit that processes voice signals obtained by the microphones 6a and 6b.
The audio signal processing unit 16 includes, for example, an A / D converter, a digital signal processor, a D / A converter, and the like, converts an audio signal supplied from the audio input unit 6 into digital data, and controls the system controller 10. Depending on the process, volume adjustment, sound quality adjustment, acoustic effects, etc. are performed. The processed audio signal is converted into an analog signal and supplied to the audio output unit 5. Note that the audio signal processing unit 16 is not limited to a configuration that performs digital signal processing, and may perform signal processing using an analog amplifier or an analog filter.
The audio output unit 5 includes a pair of earphone speakers 5a shown in FIG. 1 and an amplifier circuit for the earphone speakers 5a.
With the audio input unit 6, the audio signal processing unit 16, and the audio output unit 5, the user can hear external audio via the imaging display device 1.
Note that the audio output unit 5 may be configured as a so-called bone conduction speaker.

The imaging display device 1 is provided with a speech synthesizer 27. The voice synthesizer 27 performs voice synthesis in response to an instruction from the system controller 10 and outputs a voice signal.
The audio signal output from the audio synthesizing unit 27 is processed by the audio signal processing unit 16 and supplied to the audio output unit 5 to be output as audio to the user.
For example, the voice synthesizer 27 generates a voice signal of a reading voice to be described later.

An illumination unit 4 and an illumination control unit 18 are provided. The illumination unit 4 includes a light emitting unit 4a shown in FIG. 1 and a light emitting circuit that emits light from the light emitting unit 4 (for example, an LED). The illumination control unit 18 causes the illumination unit 4 to perform a light emission operation based on an instruction from the system controller 10.
Since the light emitting unit 4a in the illuminating unit 4 is attached to illuminate the front as shown in FIG. 1, the illuminating unit 4 performs an illuminating operation with respect to the user's visual field direction.

  The imaging display device 1 includes an ambient environment sensor 19, an imaging target sensor 20, a GPS reception unit 21, a date and time counting unit 22, an image analysis unit 17, and a communication unit 26 as a configuration for acquiring outside world information.

Specifically, as the ambient environment sensor 19, for example, an illuminance sensor, a temperature sensor, a humidity sensor, an atmospheric pressure sensor, or the like is assumed. As the ambient environment of the imaging display device 1, ambient brightness, temperature, humidity, weather, or the like is used. The sensor obtains information for detection.
The imaging target sensor 20 is a sensor that detects information about the imaging target that is the subject of the imaging operation in the imaging unit 3. For example, a distance measuring sensor that detects information on the distance from the imaging display device 1 to the imaging target is assumed.
Also, a sensor that detects information and energy such as a specific wavelength of infrared rays emitted from an imaging target, such as an infrared sensor such as a pyroelectric sensor, is also assumed. In this case, for example, it is possible to detect whether the imaging target is a living body such as a person or an animal.
Further, sensors such as various UV (Ultra Violet) sensors that detect information and energy such as a specific wavelength of ultraviolet rays emitted from an imaging target are also assumed. In this case, for example, it is possible to detect whether or not the imaging target is a fluorescent material or a phosphor, and to detect the amount of external ultraviolet rays necessary for sunburn countermeasures.

The GPS receiving unit 21 receives radio waves from a GPS (Global Positioning System) satellite and outputs latitude / longitude information as a current position.
As a so-called clock unit, the date / time counting unit 22 counts date / time (year / month / day / hour / minute / second) and outputs current date / time information.
The image analysis unit 17 performs image analysis on the captured image obtained by the imaging unit 3 and the imaging signal processing unit 15. That is, an image as a subject is analyzed, and information on the subject included in the captured image is obtained.

The communication unit 26 performs data communication with an external device. As the external device, any device having information processing and communication functions such as a computer device, a PDA (Personal Digital Assistant), a mobile phone, a video device, an audio device, and a tuner device is assumed.
Also, terminal devices and server devices connected to a network such as the Internet are assumed as external devices to be communicated.
Furthermore, a non-contact communication IC card incorporating an IC chip, a two-dimensional barcode such as QR code (registered trademark), a hologram memory, and the like are external devices, and the communication unit 26 is configured to read information from these external devices. It is also possible.
Furthermore, the other imaging display device 1 is also assumed as an external device.
The communication unit 26 may be configured to perform network communication via short-range wireless communication with a network access point using a method such as wireless LAN or Bluetooth, or directly with an external device having a corresponding communication function. It may be one that performs wireless communication.

The ambient environment sensor 19, the imaging target sensor 20, the GPS receiving unit 21, the date and time counting unit 22, the image analysis unit 17, and the communication unit 26 acquire information on the outside world as viewed from the imaging display device 1, and the system controller 10. To be supplied.
The system controller 10 performs control related to the imaging operation and the display operation by the process of the operation control function 10b according to the acquired external environment information by the process of the external environment determination function 10a. That is, the system controller 10 instructs the imaging control unit 11 to control the operations of the imaging unit 3 and the imaging signal processing unit 15, and also instructs the display control unit 14 to operate the display image processing unit 12 and the display driving unit 13. Control.

In addition, although the surrounding environment sensor 19, the imaging target sensor 20, the GPS receiving unit 21, the date and time counting unit 22, the image analysis unit 17, and the communication unit 26 are shown as the configuration for acquiring the outside world information, these are not necessarily all. It is not necessary to have. In addition, other sensors such as a voice analysis unit that detects and analyzes surrounding voice may be provided.

[3. Display example]

It is recognized by the user as various display modes in the display unit 2 as a result that the system controller 10 performs control related to the imaging operation and the display operation in accordance with the acquired outside world information. 3 to 11 illustrate various display modes.
FIG. 3A shows a case where the display unit 2 is in a through state. That is, the display unit 2 is a simple transparent plate-like body, and the user is viewing the view scene through the transparent display unit 2.
FIG. 3B shows a state where an image captured by the imaging unit 3 is displayed on the display unit 2 as a monitor display state. For example, in the state of FIG. 3A, the imaging unit 3, the imaging signal processing unit 15, the display image processing unit 12, and the display driving unit 13 operate, and these parts normally display the captured image on the display unit 2. is there. The captured image (normal captured image) displayed on the display unit 2 in this case is almost the same as in the through state. In other words, for the user, the normal field of view is viewed as a captured image.

FIG. 3C shows a case where the system controller 10 causes the imaging unit 3 to perform telephoto imaging via the imaging control unit 11, and a telephoto image is displayed on the display unit 2.
Although not shown, conversely, if the system controller 10 causes the imaging unit 3 to perform wide-angle imaging via the imaging control unit 11, an image in which a short-distance scene is projected at a wide angle is displayed on the display unit 2. Become. The telephoto / wide-angle control can be performed not only by the zoom lens drive control in the imaging unit 3 but also by signal processing in the imaging signal processing unit 15.

FIG. 4A shows a case where the display unit 2 is in a through state. For example, the user is looking at a newspaper or the like.
FIG. 4B shows a so-called wide-angle zoom state. That is, zoom imaging is performed at a focal position at a short distance, and characters such as newspapers are displayed on the display unit 2 so as to be enlarged by the user.

FIG. 5A shows a case where a normal captured image is displayed on the display unit 2 or a case where the display unit 2 is in a through state.
At this time, the system controller 10 instructs the display image processing unit 12 to perform image enlargement processing via the display control unit 14, so that an enlarged image as shown in FIG. 5B is displayed on the display unit 2. It will be.

FIG. 6A shows a case where a normal captured image is displayed on the display unit 2 or a case where the display unit 2 is in a through state. In particular, the case where the user is reading a newspaper or a book is shown. Here, it is assumed that the surroundings are dim and it is difficult to see characters such as newspapers in a normal captured image or through state.
In such a case, the system controller 10 instructs the imaging control unit 11 (imaging unit 3, imaging signal processing unit 15) to increase imaging sensitivity, or the display control unit 14 (display image processing unit 12, display). By instructing the drive unit 13) to increase brightness, contrast, and sharpness, a clearer image can be displayed on the display unit 2 as shown in FIG. Note that it is also preferable to cause the illumination unit 4 to perform an illumination operation when performing such display.

FIG. 7A shows a case where a normal captured image is displayed on the display unit 2 or a case where the display unit 2 is in a through state. Here, a case where the user is in a dark bedroom where a child is sleeping is shown. Since it is in a dark room, a child's figure cannot be clearly seen in a normal captured image or a through state.
At this time, when the system controller 10 instructs the imaging control unit 11 (imaging unit 3, imaging signal processing unit 15) to increase the infrared imaging sensitivity, an infrared captured image is displayed as shown in FIG. 7B. It is displayed on part 2 and the sleeping face of a child can be confirmed in a dark room.

FIG. 8A shows a case where a normal captured image is displayed on the display unit 2 or a case where the display unit 2 is in a through state.
When the system controller 10 instructs the imaging control unit 11 (imaging unit 3, imaging signal processing unit 15) to increase the ultraviolet imaging sensitivity, the captured image representing the ultraviolet light component as shown in FIG. 8B. Is displayed on the display unit 2.

FIG. 9A shows a case where the display unit 2 is in a through state.
When the system controller 10 instructs the display control unit 14 (the display image processing unit 12 and the display driving unit 13) to perform divided display and enlarged display on a divided screen, an image as illustrated in FIG. 9B is displayed on the display unit. 2 can be displayed. That is, the screen of the display unit 2 is divided into areas AR1 and AR2, the area AR1 is a through state or normal image display, and the area AR2 is an enlarged image.
FIG. 9C shows another example of divided display. In this case, the screen of the display unit 2 is divided into areas AR1, AR2, AR3, and AR4, and each area has a predetermined time interval. One frame of the captured image is extracted and displayed. For example, the display image processing unit 12 extracts one frame from the captured image signal at intervals of 0.5 seconds, and displays the extracted image of the frame in the order of the areas AR1, AR2, AR3, AR4, AR1, AR2,. Go. This is an example in which an image called so-called strobe display is executed by split display on the display unit 2.

FIG. 10A shows a case where a normal captured image is displayed on the display unit 2 or a case where the display unit 2 is in a through state. In this image, for example, in a soccer stadium, a boundary between the shade and the sun occurs on the pitch, and it is difficult to see.
For example, the system controller 10 improves the imaging sensitivity for the pixels in the area corresponding to the shaded area on the CCD sensor or the CMOS sensor, and improves the display brightness, while increasing the imaging sensitivity for the pixels in the area corresponding to the shaded area. By lowering or lowering the display brightness, an image with reduced influence of the sun / shade is displayed as shown in FIG.

FIGS. 11A and 11B are display examples in which, for example, when a bird is included in an image as a specific target, highlighting is performed so that the bird is emphasized.
When a bird is detected in the image, the bird portion is highlighted so that a display that makes it difficult for the user to lose sight of the target can be realized.
As the highlight image processing, there are methods such as increasing the luminance of only the target portion in the image, decreasing the luminance other than the target portion, or displaying the target portion in color and displaying the portion other than the target portion in monochrome. Further, a specific portion in the image may be emphasized by displaying some character image such as a attention frame, a cursor, or a pointer mark on the attention portion.

Various display examples have been shown so far, but these are only examples. In this example, various display modes are realized by controlling the processes and operations of the imaging unit 3, the imaging signal processing unit 15, the display image processing unit 12, and the display driving unit 13.
For example, telephoto display, wide-angle display, zoom-in or zoom-out display from telephoto to wide-angle, enlarged display, reduced display, variable frame rate display (display of captured image at high frame rate or captured image at low frame rate) ), High brightness display, low brightness display, variable contrast display, sharpness variable display, imaging sensitivity increased state display, infrared imaging sensitivity increased state display, ultraviolet imaging sensitivity increased state display, image display with a specific wavelength band cut Image effect display such as mosaic image / inverted brightness image / soft focus / partial highlighting in the image / variable color atmosphere of the entire image, slow display, frame advance display, etc. Split display, through display combined with captured image and strobe display, 1 frame of captured image A still picture display to continue the view, very diverse display modes are contemplated.

[4. Detection of external information]

As described above, the imaging display device 1 of this example has a configuration for acquiring external environment information, the ambient environment sensor 19, the imaging target sensor 20, the GPS reception unit 21, the date and time counting unit 22, the image analysis unit 17, and the communication. Part 26.

As the ambient environment sensor 19, an illuminance sensor, a temperature sensor, a humidity sensor, an atmospheric pressure sensor, or the like is assumed.
Depending on the illuminance sensor, it is possible to detect the brightness information around the imaging display device 1.
Depending on the temperature sensor, the humidity sensor, and the atmospheric pressure sensor, information for determining the temperature, humidity, atmospheric pressure, or weather can be obtained.
These ambient environment sensors 19 allow the imaging display device 1 to determine ambient brightness and weather conditions when outdoors, so the system controller 10 uses these as external environment information and is suitable for ambient brightness and weather conditions. The image pickup operation and display operation can be controlled.

The imaging target sensor 20 detects information about the imaging target. For example, a distance measuring sensor, a pyroelectric sensor, or the like can be considered, and information for determining the distance to the imaging target or the imaging target itself can be obtained.
By detecting the distance to the imaging target, the system controller 10 can execute and control the imaging operation and the display operation according to the distance. Further, by detecting that the imaging target is a living body such as a person, it is possible to execute and control an imaging operation and a display operation corresponding to the imaging target.

The GPS receiving unit 21 acquires latitude / longitude information as the current position. When the latitude / longitude is detected, it is possible to obtain information on a point (near the point) at the current position by referring to a map database or the like. Although not particularly described in the configuration of FIG. 2, for example, as a recording medium that can be referred to by the system controller 10, a relatively large capacity recording medium such as an HDD (Hard Disk Drive) or a flash memory is mounted. By storing the map database in the medium, information related to the current position can be acquired.
Even if the image display device 1 does not have a built-in map database, it accesses, for example, a network server or a map database built-in device via the communication unit 26 and transmits latitude / longitude to request information according to the current position. Information may be received.
Information related to the current position includes name information such as a place name, a building name, a facility name, a shop name, and a station name near the current position.
Information related to the current position includes information indicating the type of building such as a park, a theme park, a concert hall, a theater, a movie theater, and a sports facility.
Information relating to the current position includes information on the types and names of natural objects such as coasts, seas, rivers, mountains, mountain peaks, forests, lakes, and plains.
In addition, as information about the current position, for example, information on the location in the theme park, the area of the spectator seat in the baseball stadium, the soccer field, the information on the seat area in the concert hall, etc. Can be acquired.
By acquiring the information on the current position, the system controller 10 can execute and control the imaging operation and the display operation according to the current position, the geographical conditions near the current point, the facility, and the like.

  The date / time counting unit 22 counts year / month / day / hour / minute / second, for example. The date / time counting unit 22 allows the system controller 10 to recognize the current time, day / night distinction, month, season, and the like. Therefore, for example, it is possible to execute and control an imaging operation and a display operation according to day and night (time), an imaging operation and a display operation suitable for the current season, and the like.

According to the image analysis unit 17, various types of information about the imaging target as described below can be detected from the captured image.
First, a person, animal, natural object, building, device, or the like included in the captured image can be identified as the type of the imaging target. For example, as an animal, it is possible to determine a situation where a bird is imaged as a subject, a situation where a cat is imaged, and the like. As natural objects, the sea, mountains, trees, rivers, lakes, sky, sun, moon, etc. can be distinguished. As buildings, houses, buildings, and stadiums can be identified. As a device, it is possible to determine a situation in which a personal computer, an AV (Audio-Visual) device, a mobile phone, a PDA, an IC card, a two-dimensional barcode, or the like is an imaging target.
These types of imaging targets can be determined by setting characteristics of various shapes in advance and determining whether or not a subject corresponding to the shape is included in the captured image.

Further, according to the image analysis by the image analysis unit 17, it is possible to detect the movement of the subject, for example, a quick movement within the image by a method such as detection of a difference between frames before and after the image. For example, it is possible to detect a situation in which a fast-moving subject is being imaged, for example, when a player is imaged during a sporting event or when a moving automobile is being imaged.
Further, according to the image analysis by the image analysis unit 17, it is also possible to determine the surrounding situation. For example, it is possible to determine the brightness situation due to day and night or weather, and it is also possible to recognize the intensity of rain.

Moreover, according to the image analysis by the image analysis part 17, it can discriminate | determine that it is the situation which is imaging a book, a newspaper, etc., for example. For example, character recognition in an image or shape recognition such as a book or a newspaper may be performed.
When character recognition is performed by the image analysis unit 17, the system controller 10 can supply the recognized character to the speech synthesis unit 27 as text data.

Further, according to the image analysis performed by the image analysis unit 17, when a person is a subject, it is also possible to identify the person from the person's face. As already known, a person's face can be converted into personal feature data as relative position information of the constituent elements of the face. For example, the ratio between the distance EN between the center of the eye and the nose and the distance Ed between the eyes (Ed / EN) and the ratio between the distance EM between the center of the eye and the mouth and the distance Ed between the eyes (Ed / EM) This information is unique to each individual and is not affected by changes in appearance due to an attachment such as a hairstyle or glasses. Furthermore, it is known that it does not change with aging.
Therefore, the image analysis unit 17 can detect the personal feature data as described above by analyzing the image when a certain person's face is included in the captured image.
When personal feature data is detected from a captured image, for example, an HDD (Hard Disk Drive), a flash memory, or the like is installed as a recording medium that can be referred to by the system controller 10, and a person database is stored in these recording media. , Information about the individual who is the subject can be acquired. Alternatively, even if the image display device 1 does not have a person database, it accesses, for example, a network server or a person database built-in device via the communication unit 26, transmits personal characteristic data, requests information, and sends a specific person. The information may be received.
For example, if the user himself / herself registers personal information such as the name and affiliation of a person who has met in the past in the person database together with the personal characteristic data, the system controller 10 can be used when a certain person is met (when captured). Can search for the person's information.
Further, if a person database in which celebrity information is registered together with personal characteristic data is prepared, information on the person can be retrieved when the user meets the celebrity.

According to the communication part 26, various information can be acquired as external information.
For example, as described above, information retrieved by an external device can be acquired according to latitude / longitude transmitted from the imaging display device 1 or personal characteristic data.
In addition, weather information such as weather information, temperature information, and humidity information can be acquired from an external device.
In addition, facility usage information, in-facility imaging prohibition / permission information, guidance information, and the like can be acquired from an external device.
Further, identification information of the external device itself can be acquired. For example, the device type or device ID identified as a network device in a predetermined communication protocol.
Further, image data stored in the external device, image data reproduced or displayed on the external device, image data received on the external device, and the like can be acquired.

In the above, examples of information that can be acquired by the ambient environment sensor 19, the imaging target sensor 20, the GPS reception unit 21, the date and time counting unit 22, the image analysis unit 17, and the communication unit 26 have been described. The system may detect and determine certain external information.
For example, information such as humidity obtained by the ambient environment sensor 19 and weather information received by the communication unit 26 can be combined to determine the current weather more accurately.
Further, the current position and the state of the imaging target can be more accurately determined based on the information on the current location acquired by the operations of the GPS receiving unit 21 and the communication unit 26 and the information obtained by the image analysis unit 17.

[5. Examples of various operations]

As described above, the imaging display device 1 according to the present embodiment includes the ambient environment sensor 19, the imaging target sensor 20, the GPS receiving unit 21, the date and time counting unit 22, the image analysis unit 17, and the external environment information acquired by the communication unit 26. Thus, the system controller 10 discriminates the surrounding situation and the situation of the imaging target, and controls the imaging operation and the display operation accordingly, thereby realizing the user's visual assistance and expansion.
Various operation examples based on the control of the system controller 10 for this purpose will be described.

FIG. 12 shows a control process as the operation control function 10 b of the system controller 10.
Step F101 indicates a control process in which the system controller 10 causes the display control unit 14 to bring the display unit 2 into a through state. For example, at the initial stage when the imaging display device 1 is turned on, the system controller 10 controls the display unit 2 to the through state in step F101.
During the period in which the display unit 2 is in the through state, the system controller 10 confirms whether or not a trigger for starting the monitor display state has occurred in step F102. Although not shown in FIG. 2, for example, an operator that can be operated by the user may be provided, and it may be determined that a trigger for starting the monitor display state is generated when the user operates a predetermined operator. However, although an example will be described later, it can also be determined that a trigger for starting the monitor display state is generated according to external information.

If it is determined that a monitor display start trigger has occurred, the system controller 10 advances the process to step F103 to perform monitor display start control. That is, the imaging control unit 11 is instructed to start imaging, and the imaging unit 3 and the imaging signal processing unit 15 perform normal imaging operations, and the display control unit 14 is instructed to display the display image processing unit 12 and the display driving unit 13. Then, an operation for displaying the imaging signal on the display unit 2 in the form of a normal captured image is executed.
By this processing, for example, the through state of FIG. 3A changes to the monitor display state of the normal captured image of FIG. 3B, for example.

During a period in which a normal captured image, that is, a captured image similar to a sight seen in the through state is displayed on the display unit 2, the system controller 10 monitors whether or not an image control trigger has occurred in step F104. In step F105, it is monitored whether a monitor display end trigger has occurred.
The generation of the image control trigger in step F104 is a change in the display image mode of the monitor display according to the external environment conditions (the surroundings, the subject conditions, the current date and time, the current position conditions, etc.) determined by the external environment determination function 10a. This means that the system controller 10 itself makes a determination.
The generation of the monitor display end trigger in step F105 may be, for example, a case where the user performs an operation of ending the monitor display state with a predetermined operation element. Similarly, the trigger for the end of the monitor display may be determined to be a trigger according to the detected outside world information.

If it is determined that an image control trigger has occurred, the system controller 10 advances the process from step F104 to F106, and performs control related to the display operation of the captured image. That is, the imaging control unit 11 and the display control unit 14 are instructed to cause the display unit 2 to execute display in a mode according to the external environment at that time.
Even after the display mode is controlled in step F106, the generation of triggers in steps F104 and F105 is monitored.

  If it is determined that a monitor end trigger has occurred, the system controller 10 returns the process from step F105 to F101, instructs the imaging control unit 11 to end the imaging operation, and instructs the display control unit 14 to display the display unit 2. The instruction to pass through.

During a period when the user wears the imaging display device 1 and is turned on, the operation control function 10b of the system controller 10 performs control processing as shown in FIG. 12, for example.
In this process, display mode control is performed by determining the image control trigger in step F104. Specific examples of the trigger generation determination and control contents will be described with reference to FIG.

  FIG. 13 to FIG. 20 show processing examples as the external environment determination function 10a of the system controller 10, and these are executed in parallel with the processing of FIG. 12 by the operation control function 10b. Note that the parallel processing means that the detection processing as shown in FIG. 13 to FIG. 20 is periodically performed as interrupt processing during the period when the system controller 10 executes the processing of FIG. It is. These processing programs shown in FIGS. 13 to 20 may be incorporated in the program that executes the processing of FIG. 12 or may be other programs that are called periodically. That is, the form of the program is not limited.

13 to 20 are processing examples relating to the determination of the occurrence of the image control trigger as step F104 in FIG. 12. First, in FIG. 13, based on the information from the ambient environment sensor 19 or the image analysis unit 17, the image control is performed. An example of determining that a trigger has occurred is shown.
Step F201 in FIG. 13 shows processing in which the system controller 10 monitors information on one or both of the ambient environment sensor 19 and the image analysis unit 17. Here, it is assumed that the ambient environment sensor 19 is an illuminance sensor, and the image analysis unit 17 performs processing for analyzing ambient brightness from an image.
Based on information from one or both of the ambient environment sensor 19 and the image analysis unit 17, the system controller 10 determines whether or not the environment is currently dark or too bright. For example, the detected illuminance is digitized, and if the detected illuminance is less than x lux, it is determined that the situation is dark, and if the detected illuminance is greater than y lux, the situation is determined to be too bright.

If it is determined that the environment is dark, the system controller 10 advances the process from step F202 to F204, and determines that an image control trigger has occurred.
In step F205, an adjustment value corresponding to the current ambient illuminance (darkness) is calculated. For example, as adjustment values for display brightness, contrast, sharpness, imaging sensitivity, and the like, an adjustment value that allows the user to visually recognize the surroundings comfortably from the captured image is obtained.
Due to the processing of steps F204 and F205, the processing of FIG. 12 of the system controller 10 proceeds from step F104 to F106. In this case, adjustment of the imaging sensitivity of the imaging unit 13, the imaging signal processing unit 15 or the display image processing unit is performed. 12 is instructed to perform processing such as brightness adjustment, contrast adjustment, and sharpness adjustment. By this processing, the image quality of the display image on the display unit 2 is adjusted, and even if the surrounding is dark, the user can easily see the surrounding by the display image on the display unit 2. For example, the situation is switched from a situation where the surroundings are dark and the display image of the display unit 2 is as shown in FIG. 6A to an easily viewable state as shown in FIG.
When it is determined that the surroundings are dark as described above, the system controller 10 may perform control to cause the illumination unit 4 to perform illumination.

Also, when the system controller 10 determines that the surroundings are too bright, the process proceeds from step F203 to F206, and determines that an image control trigger has occurred.
In step F207, an adjustment value corresponding to the current ambient illuminance is calculated. For example, as adjustment values for display brightness, contrast, sharpness, imaging sensitivity, and the like, an adjustment value that allows the user to visually recognize the surroundings comfortably from the captured image is obtained. In this case, since the user feels dazzling in an excessively bright situation, an adjustment value that decreases the imaging sensitivity or decreases the display luminance is obtained.
Due to the processing in steps F206 and F207, the processing in FIG. 12 of the system controller 10 proceeds from step F104 to F106. In this case as well, adjustment of the imaging sensitivity of the imaging unit 13, the imaging signal processing unit 15 or the display image processing unit is performed. 12 is instructed to perform processing such as brightness adjustment, contrast adjustment, and sharpness adjustment. By this processing, the image quality of the display image on the display unit 2 is adjusted, and even if the surroundings are too bright, the user can visually recognize the surroundings without feeling glare by the display image on the display unit 2.

FIG. 14A shows an example of determining that an image control trigger has occurred based on information from the ambient environment sensor 19 or the communication unit 26.
Step F301 in FIG. 14A shows processing in which the system controller 10 monitors information of one or both of detection information from the ambient environment sensor 19 and reception information by the communication unit 26. As the ambient environment sensor 19, a temperature sensor, a humidity sensor, an atmospheric pressure sensor or the like is assumed. In addition, the communication unit 26 sequentially receives weather information from, for example, a network server.
For example, the system controller 10 can determine the surrounding weather conditions from the atmospheric pressure, humidity, and temperature obtained by the ambient environment sensor 19. The weather condition can also be determined from the weather information received by the communication unit 26. In order to receive the weather condition from the network server, the system controller 10 sequentially transmits the current position information obtained by the GPS receiver 21 to the network server, and the weather information of the area corresponding to the current position. May be received from the network server.
The system controller 10 can determine the ambient weather situation based on the detection information of the ambient environment sensor 19 or the reception information of the communication unit 26. However, if both information are used, the weather situation can be determined more accurately.

For example, the system controller 10 determines whether image adjustment is necessary according to changes in weather conditions such as sunny weather, cloudy weather, rainy weather, thunderstorms, typhoons, snowfall, and rainy weather, rain stops, or cloudy weather. To do. If it is determined that the situation requires adjustment, the system controller 10 advances the process from step F302 to F303, determines that an image control trigger has occurred, and calculates an adjustment value according to the current weather in step F304. For example, as an adjustment value for display brightness, contrast, sharpness, imaging sensitivity, etc., an adjustment value that makes it easier for the user to visually recognize the surroundings from the captured image is obtained.
Due to the processing of steps F303 and F304, the processing of FIG. 12 of the system controller 10 proceeds from step F104 to F106. In this case, the adjustment of the imaging sensitivity of the imaging unit 13, the imaging signal processing unit 15 or the display image processing unit 12 is instructed to perform processing such as brightness adjustment, contrast adjustment, and sharpness adjustment. By this processing, the image quality of the display image on the display unit 2 is adjusted to an image quality according to the weather condition, and the user can easily see the surroundings by the display image on the display unit 2.
Depending on the weather, the system controller 10 may perform control to cause the illumination unit 4 to perform illumination.
In addition, although the weather judgment is performed based on the reception information of the ambient environment sensor 19 or the communication unit 26 here, the image analysis unit 17 recognizes the rain image so that the rain has started or the rain has stopped. It becomes possible to accurately detect the occurrence of lightning.

Next, FIG. 14B shows an example in which it is determined that an image control trigger for causing the night vision function is generated based on information from the ambient environment sensor 19.
Step F310 in FIG. 14B shows a process in which the system controller 10 monitors information of the surrounding environment sensor 19. Here, it is assumed that the ambient environment sensor 19 is an illuminance sensor.
Based on the detection information of the ambient environment sensor 19, the system controller 10 determines whether or not the environment is currently dark. For example, the detected illuminance is digitized, and if the detected illuminance is less than x lux, it is determined that the situation is dark.

If it is determined that the environment is dark, the system controller 10 proceeds from step F311 to step F313, and determines that an image control trigger that turns on the night vision function is generated.
With the processing in step F313, the processing in FIG. 12 of the system controller 10 proceeds from step F104 to F106, and in this case, control for turning on the night vision function is performed. That is, the system controller 10 instructs the imaging control unit 11 to increase the infrared imaging sensitivity of the imaging unit 13.
By this processing, the night vision function is exhibited. For example, in a situation where the image is dark and cannot be seen as shown in FIG. 7A, an image of infrared sensitivity increased imaging as shown in FIG. The user can visually recognize the surroundings in a dark place.

  If the system controller 10 determines that the surroundings are not dark, the process proceeds from step F311 to F312. In this case, if the night vision function (infrared sensitivity-enhanced imaging) is turned on at that time, the process proceeds to step F314. At this time, it is determined that an image control trigger is generated to turn off the night vision function. With the processing in step F314, the processing in FIG. 12 of the system controller 10 proceeds from step F104 to F106. In this case, control for turning off the night vision function is performed. That is, the system controller 10 instructs the imaging control unit 11 to return the infrared imaging sensitivity of the imaging unit 13 to normal and to execute normal imaging.

14B, the night vision function is automatically turned on when the user enters a dark room or the like, so that the user can easily see the surroundings in the dark. Further, for example, when the user goes out of a dark room, the night vision function is automatically turned off. That is, processing that can expand the user's visual ability according to the surrounding situation is realized.
Note that whether or not the surroundings are dark can be detected by image analysis in the image analysis unit 17. For example, when the brightness of the entire captured image becomes very low, it may be determined that an image control trigger with the night vision function on is generated, assuming that the surroundings are in a dark state.

FIG. 15 is an example in which it is determined that an image control trigger has occurred based on information from the imaging target sensor 20 or the image analysis unit 17.
Step F401 in FIG. 15 illustrates processing in which the system controller 10 monitors one or both of detection information from the imaging target sensor 20 and information from the image analysis unit 17. As the imaging target sensor 20, for example, a distance measuring sensor is assumed. The image analysis unit 17 calculates the distance to the subject by analyzing the captured image.
That is, the system controller 10 determines whether the target (imaging target) that the user is viewing is far away or near the hand based on these pieces of information.

For example, when the user is looking at a distant landscape or watching a game at a distant seat in the stadium, and when it is determined that the imaging target is far away, the system controller 10 performs steps F402 to F404. Then, it is determined that an image control trigger for switching to the telephoto zoom display has occurred. In step F405, an appropriate zoom magnification is calculated according to the distance to the imaging target at that time.
In addition, for example, when the user is looking at a nearby landscape or when looking at a newspaper at hand and the like, and when it is determined that the imaging target is near, the system controller 10 moves from step F403 to F406. Then, it is determined that an image control trigger for switching to zoom-up (wide-angle zoom) display has occurred. In step F407, an appropriate zoom magnification is calculated according to the distance to the imaging target.

By performing the processing in steps F404 and F405 or the processing in steps F406 and F407, the processing in FIG. 12 of the system controller 10 proceeds from step F104 to F106. Instructs the zoom operation.
As a result, a telephoto image as shown in FIG. 3C or a wide-angle zoom image as shown in FIG. 4B is displayed on the display unit 2 according to the scene that the user wants to see.
In this example, the telephoto / wide-angle zoom operation control is performed. However, the control operation is performed to change the focal position or execute the image enlargement / reduction operation according to the distance to the imaging target. Is also possible.

FIG. 16 is an example in which it is determined that an image control trigger is generated based on information from the imaging target sensor 20 and the image analysis unit 17, and this indicates whether or not the imaging target includes characters such as newspapers and books. This is an example of discrimination.
Step F501 in FIG. 16 shows processing in which the system controller 10 monitors the detection information from the imaging target sensor 20 and the information from the image analysis unit 17. The imaging target sensor 20 is assumed to be a distance measuring sensor. The image analysis unit 17 detects whether or not characters are included in the subject by analyzing the captured image.
Based on these pieces of information, the system controller 10 determines whether or not the target (imaging target) that the user is viewing is near and includes characters such as newspapers and books. That is, it is determined whether or not the situation is such as reading a newspaper at hand.

If it is determined that the imaging target is near and includes characters, the system controller 10 advances the process from step F502 to F503, and determines that an image control trigger has occurred.
In step F504, an adjustment value suitable for reading the current newspaper or book is calculated. For example, as adjustment values for display brightness, contrast, sharpness, imaging sensitivity, and the like, adjustment values that allow the user to read newspapers and the like comfortably are obtained.
Due to the processing in steps F503 and F504, the processing in FIG. 12 of the system controller 10 proceeds from step F104 to F106. In this case, the adjustment of the imaging sensitivity of the imaging unit 13, the imaging signal processing unit 15 or the display image processing unit 12 is instructed to perform processing such as brightness adjustment, contrast adjustment, and sharpness adjustment. By this processing, the image quality of the display image on the display unit 2 is adjusted, and for example, a display that allows easy reading of characters as shown in FIG. 6B is executed.

In addition to detection of including characters, ambient brightness may also be detected, and ambient brightness may be reflected in the calculation of the adjustment value.
In addition, the recognition of the shape of a book or newspaper during image analysis may be added to the condition for proceeding to step F503.
Further, when it is determined that the imaging target is a newspaper or the like, the system controller 10 may perform control to cause the illumination unit 4 to perform illumination.
In addition, instead of adjusting the image quality, for example, the display image processing unit 12 may execute an enlargement process to display an enlarged image as shown in FIG.

In the case of an image including a character, the image analysis unit 17 may determine the character and supply the character to the system controller 10 as text data. In this case, the system controller 10 causes the speech synthesizer 27 to execute speech synthesis processing based on the text data detected from the image.
Then, the voice synthesizer 27 generates a voice signal as a reading voice of characters included in the captured image. The system controller 10 causes the voice output unit 5 to output this read-out voice.
If it does in this way, a user will be able to hear the reading sound only by looking at a newspaper etc. now.

FIG. 17 is an example in which it is determined that the image control trigger is generated based on the current time information by the date / time counting unit 22.
Step F601 in FIG. 17 shows a process in which the system controller 10 checks the current date and time counted by the date and time counting unit 22. The system controller 10 determines the time zone based on the current time. For example, time zones such as early morning, morning, daytime, evening, and night are determined. For example, it is assumed that 4:00 to 7:00 is early morning, 7:00 to 9:00 is morning, 9:00 to 17:00 is daytime, 17:00 to 19:00 is evening, and 19:00 to 4 is nighttime.
Moreover, it is preferable to change the reference for dividing the time for each time zone by judging the date. For example, considering the difference in sunrise time and sunset time depending on the month and day, the determination time as each time zone is changed. For example, the time zone for early morning is 4 to 7 in the summer, and 6 to 8 in the winter.

If it is determined that the time zone has changed as the time zone determined by the date and time check in step F601, the system controller 10 advances the process from step F602 to F603 and thereafter.
For example, when it is time for early morning, the process proceeds from step F603 to F607, where it is determined that an image control trigger for the imaging operation / display operation for early morning has occurred.
When it is time to be in the morning, the process proceeds from step F604 to F608, where it is determined that an image control trigger for the morning imaging / display operation has occurred.
When the daytime is reached, the process advances from step F605 to F609, where it is determined that the daytime image control trigger for the imaging / display operation is generated.
When it is the time for evening, the process proceeds from step F606 to F610, where it is determined that an image control trigger for the evening imaging / display operation has occurred.
When it is time to be nighttime, the process proceeds to step F611, where it is determined that an image control trigger for nighttime imaging operation / display operation has occurred.

If it is determined in any of steps F607, F608, F609, F610, and F611 that an image control trigger has occurred, the processing in FIG. 12 of the system controller 10 proceeds from step F104 to F106, and the imaging control unit 11 and The display control unit 14 is instructed to perform an imaging operation and a display operation corresponding to the time zone. For example, instructions such as adjustment of imaging sensitivity, brightness adjustment, contrast adjustment, sharpness adjustment are instructed. Alternatively, an image effect such as soft focus display may be instructed. ,
With this process, an image corresponding to the time zone is provided to the user. For example, an image with a soft image quality in the early morning, a clear image with a strong contrast during the day, an image with a sepia color in the evening, and a dull image at night. In this way, it is possible to provide an interesting image that matches the mood of the user for each time period.
Of course, image quality adjustment is also conceivable in which the image quality is adjusted according to the brightness of each time zone to improve the visibility.
Note that it is also conceivable that the image quality adjustment suitable for the situation is performed by judging whether the weather situation and indoor / outdoor as well as the time zone.
It is also conceivable to determine the season from the date and time information instead of the time zone and adjust the image quality according to the season. For example, in a displayed image, provide a seasonal image by highlighting the blue component in summer, the red component in autumn, the white component in winter, and the green / pink system in spring. Etc.

FIG. 18A is an example in which it is determined that an image control trigger has occurred based on the reception information of the GPS receiving unit 21 and the communication unit 26.
In step F701 of FIG. 18A, the system controller 10 transmits the latitude / longitude information of the current position obtained by the GPS receiving unit 21 from the communication unit 26 to the network server or the map database mounted device, and the current location at the transmission destination. The operation of receiving information on the current location and receiving information on the current location is shown. If the map database is held in the imaging display device 1, the system controller 10 can search the current location information from the map database based on the latitude and longitude from the GPS receiver 21.

Based on the acquired information on the current location, the system controller 10 determines whether or not the user is currently in a place where predetermined image control is executed. If it is determined that the current position is a place where the predetermined image control is to be executed, the process proceeds from step F702 to F703, where it is determined that an image control trigger for executing the predetermined image control has occurred.
When it is determined in step F703 that an image control trigger has occurred, the process of FIG. 12 of the system controller 10 proceeds from step F104 to F106, and a predetermined image is displayed to the imaging control unit 11 and the display control unit 14. Instruct processing.
The following examples are conceivable as image processing control in this case.

For example, when it is detected that the current position is a sports stadium, a circuit, or the like, the target (imaging target) that the user sees is a fast-moving person or car, so the system controller 10 instructs the imaging controller 11. The imaging frame rate is increased, and a display that can express fast motion well is executed.
If the current position is a concert venue, a party, a theater, a sports stadium, etc., the system controller 10 can instruct the imaging controller 11 to perform a telephoto imaging operation according to the distance to the stage to be imaged. Conceivable. If the distance to the imaging target such as the stage can be determined as the current position information, the telephoto magnification may be set accordingly, and the distance to the imaging target is detected by the imaging target sensor 20 (ranging sensor). What is necessary is just to set a magnification. Further, instead of the telephoto operation, the imaging signal processing unit 15 or the display image processing unit 12 may be instructed to perform image enlargement processing.
If the current position is a coast, a mountain or the like, the system controller 10 instructs the imaging control unit 11 to perform ultraviolet sensitivity improvement imaging, and displays an image as shown in FIG. It is conceivable to execute a display that recognizes.
In addition, based on the acquired information on the current location, the place name, the name of the facility / store being imaged, etc., can be superimposed with character images or characters, advertising information, facility guidance information, surrounding caution information, etc. It is also conceivable to perform control so that is displayed on the display unit 2.

FIG. 18B is also an example in which it is determined that an image control trigger has occurred based on the reception information of the GPS receiver 21 and the communication unit 26. In particular, this is a processing example during execution of infrared sensitivity improvement imaging.
The processing in FIG. 18B proceeds from step F710 to F711 when the imaging unit 3 is currently performing infrared sensitivity improvement imaging.
In step F711, the system controller 10 transmits the latitude / longitude information of the current position obtained by the GPS receiving unit 21 from the communication unit 26 to the network server or the map database-equipped device, and searches the current location information at the transmission destination. And receive information about the current location. If the map database is held in the imaging display device 1, the system controller 10 performs processing for searching the current location information from the map database based on the latitude and longitude from the GPS receiver 21.

After acquiring the current position information, the system controller 10 determines whether or not the current position is a place where infrared sensitivity-enhanced imaging should be prohibited.
If it is determined that the location is to be prohibited, the process proceeds from step F712 to F713, and the system controller 10 determines that an image control trigger for ending the infrared sensitivity improvement imaging has occurred.
When it is determined in step F713 that an image control trigger has occurred, the processing of FIG. 12 of the system controller 10 proceeds from step F104 to F106, and the imaging control unit 11 is instructed to end infrared sensitivity improvement imaging. I do.
In this way, by making it impossible to execute infrared sensitivity-enhanced imaging depending on the location, it is effective in preventing abuse of special imaging functions such as imaging with increased infrared sensitivity.

FIG. 19A is an example in which it is determined that an image control trigger has occurred based on information from the image analysis unit 17.
Step F801 in FIG. 19A shows processing in which the system controller 10 monitors information from the image analysis unit 17. It is assumed that the image analysis unit 17 detects whether or not the subject includes a specific target by analyzing the captured image.
If it is detected as a result of image analysis that a specific target is being imaged, the system controller 10 proceeds from step F802 to F803 and determines that an image control trigger has occurred.
When it is determined in step F803 that an image control trigger has occurred, the process of FIG. 12 of the system controller 10 proceeds from step F104 to F106, and a predetermined image is displayed to the imaging control unit 11 and the display control unit 14. Instruct processing.
The following examples are conceivable as image processing control in this case.

For example, when a specific target is a bird, a display image is displayed so that highlighting of a bird portion in the image is executed as shown in FIGS. 11A and 11B by detecting the bird in the captured image. It is conceivable to instruct the operation of the processing unit 12. In this case, for example, at the time of bird watching, it becomes easy for the user to find a bird and to follow the movement of the bird.
In addition, if a cat is a specific target, a user who likes a cat can recognize the cat by highlighting it on the display image when the cat enters the field of view during normal life. Easy to do.
In addition, when a specific target is a person, a person is detected in the captured image, so that the person's portion in the image is highlighted by highlighting or the like, or a display image is displayed so that enlarged display, zoom display, or the like is executed. It is conceivable to instruct the operation of the processing unit 12, the imaging signal processing unit 15, or the imaging unit 3.
In addition, in a specific target such as a person, an animal, or a building, only the specific target may be displayed, and an image may be displayed so that the scene around the specific target such as a person is completely filled.
On the contrary, if a person is detected as a specific target, it may be possible to execute image processing in which only that person is erased in the image. For example, an image obtained by removing (masking) an artificial thing such as a person or a car in a natural scene is displayed. In this case, processing for filling the pixel portion of the specific target may be performed by interpolation processing from pixels around the specific target to be masked.
It is also conceivable to add an image effect such as mosaic display to a specific target such as a person.

  In FIG. 19A, the example is based on information from the image analysis unit 17. However, for example, when a specific target is a living body such as a person or an animal, the pyroelectric sensor as the imaging target sensor 20 is used to specify the specific target. When an object is detected, it may be determined that an image control trigger has occurred.

FIG. 19B is also an example in which it is determined that an image control trigger has occurred based on information from the image analysis unit 17.
Step F810 in FIG. 19B shows processing in which the system controller 10 monitors information from the image analysis unit 17. The image analysis unit 17 detects whether or not a quick motion has occurred in the subject by analyzing the captured image. For example, the quickness of the motion is determined from the difference in each imaging frame.
If a quick movement of the subject is detected as an image analysis result, the system controller 10 proceeds from step F811 to F812 and determines that an image control trigger for strobe display has occurred.
When it is determined in step F812 that an image control trigger has occurred, the process of FIG. 12 of the system controller 10 proceeds from step F104 to F106, and the display control unit 14 is as shown in FIG. An instruction for image processing is given so that display is executed.
According to this processing, for example, when there is a quick movement of a player during sports watching, the user can check the movement with a strobe display.

  Here, the detection of the quick movement of the imaging target is used as a trigger for strobe display, but the trigger for switching to a high frame rate may be used, or the zoom display or highlight display for an imaging target that has performed a quick movement may be used. It is good also as a trigger of.

FIG. 20A is also an example in which it is determined that an image control trigger has occurred based on information from the image analysis unit 17. In particular, this is an example in which when a person is imaged, the person is identified.
Step F901 in FIG. 20A shows processing in which the system controller 10 monitors information from the image analysis unit 17. The image analysis unit 17 determines whether or not the subject includes a person's face by analyzing the captured image. If the person includes a face, the image analysis unit 17 generates personal feature data from the face image. For example, as described above, the personal feature data includes the ratio of the distance EN between the center of the eye and the nose to the distance Ed between the eyes (Ed / EN), the distance EM between the center of the eye and the mouth, and the distance between the eyes. The ratio of the distance Ed (Ed / EM).

When the personal feature data is extracted, the system controller 10 proceeds from step F902 to F903, and searches for personal information based on the personal feature data.
For example, the system controller 10 transmits the personal characteristic data from the communication unit 26 to the network server or the person database-equipped device, has the person search for the person information, and receives the search result. Alternatively, if a person database is held in the imaging display device 1, the system controller 10 can search the person database based on the personal feature data.
If personal information of a specific person can be searched as a search result by the external device or the system controller 10 itself, the process proceeds from step F904 to F905, and it is determined that an image control trigger for displaying personal information has occurred.
When it is determined in step F905 that an image control trigger has occurred, the processing of FIG. 12 of the system controller 10 proceeds from step F104 to F106, and for example, the retrieved personal information is sent to the display control unit 14. Instruct to superimpose.
According to this process, for example, when there is a person who has been registered in the person database, such as a person who has met in the past or a celebrity, among the people who go on the road, the display unit 2 displays information along with the image of the person. (Information registered in the person database, such as name, affiliation, and location that was met in the past) will be displayed, and the user can accurately recognize the person.

FIG. 20B is also an example in which it is determined that an image control trigger has occurred based on information from the image analysis unit 17. This is a processing example corresponding to the case where the image is difficult to see due to the influence of the sun and shade as shown in FIG.
Step F910 in FIG. 20B shows processing in which the system controller 10 monitors information from the image analysis unit 17. The image analysis unit 17 analyzes the captured image to detect whether a bright region or a dark region is generated in the captured image depending on the sunshine condition.
If it is determined as a result of image analysis that a difference due to the sun / shade has occurred on the image, the system controller 10 proceeds from step F911 to F912 and determines that an image control trigger has occurred.

When it is determined in step F912 that an image control trigger has occurred, the process of FIG. 12 of the system controller 10 proceeds from step F104 to F106. / Instructs partial change of image processing or imaging sensitivity to eliminate the difference in shade. Thereby, for example, as shown in FIG. 10B, it is possible to provide a user with an easy-to-view image that is less affected by the sun / shade.
In addition, when there is a large difference in brightness due to lighting, etc. in the house or facility, rather than the effect of sunshine, or when the image is partially blurred, It is also assumed that partial brightness adjustment, imaging sensitivity adjustment, contrast adjustment, and the like are executed.

  13 to 20 have been described as examples of the image control trigger generation determination in step F104 in FIG. 12, but these processing examples include the determination of the monitor display start trigger in step F102 in FIG. The present invention can also be applied to determination of the trigger for the end of monitor display in F105.

For example, when it is set to the through state in step F101 of FIG. 12, if it is detected that the surrounding is dark or too bright as in the processing example of FIG. May be switched to the monitor display state.
Further, as shown in FIG. 14A, when it is determined that the adjustment due to the weather is necessary, it may be determined that the trigger for starting the monitor display is generated. Then, the monitor display function is exhibited in the case of specific weather.
As shown in FIG. 14B, if it is determined that the monitor display start trigger is generated when the surrounding is determined to be in a dark state, the monitor display function can be automatically exhibited in the dark state.
As shown in FIG. 15, it may be determined that a monitor display start trigger has occurred when the imaging target is far away or near.
As shown in FIG. 16, it may be determined that a monitor display start trigger is generated when an image including characters is detected in the vicinity.
As shown in FIG. 17, it may be determined that the trigger for starting the monitor display is generated according to the time zone.
As shown in FIG. 18A, it may be determined that a monitor display start trigger has occurred when the current position is a predetermined location. Then, the monitor display function can be exhibited in a specific place or facility type.
As shown in FIG. 19A, when a specific target exists, it may be determined that a trigger for starting monitor display has occurred.
As shown in FIG. 19B, it may be determined that a monitor display start trigger is generated when a quick movement of the imaging target is detected.
When a specific person is detected as shown in FIG. 20A, it may be determined that a monitor display start trigger has occurred.
As shown in FIG. 20B, when a light and dark distribution occurs in the image, it may be determined that a monitor display start trigger has occurred.
If it is determined that the trigger for starting the monitor display is generated as described above and the process proceeds to step F103 in FIG. 12, if the user wears the imaging display device 1 in the through state, the user does not need to perform any operation. The monitor display is executed in response to this, and an image corresponding to the situation can be viewed.

Similarly, the monitor end trigger can be determined.
For example, in the processing example of FIG. 13, it is detected that the surrounding is dark or too bright, but it is determined that the trigger for the end of the monitor display has occurred in a situation where it is neither dark nor too bright. Then, it may be returned to the through state.
In FIG. 14 (a), it is determined whether or not adjustment due to weather is necessary. However, when it is determined that adjustment is not particularly necessary, it is determined that a monitor display end trigger has occurred and the state is returned to the through state. good.
As shown in FIG. 14B, it is determined whether or not the surrounding is in a dark state, and if it is not in a dark state, it may be determined that a monitor display end trigger has occurred, and the through state may be restored.
As shown in FIG. 15, when it is determined whether the imaging target is far away or near, if it is determined that the imaging target is neither far away nor near, it may be determined that a monitor display end trigger has occurred and may be returned to the through state. .
As shown in FIG. 16, when an image including characters is detected in the vicinity, if it is no longer detected, it may be determined that a monitor display end trigger has occurred, and the through state may be restored.
As shown in FIG. 17, it may be determined that a monitor display end trigger has occurred according to the time zone, month, day, season, or the like.
As shown in FIG. 18A, it may be determined that a monitor display end trigger has occurred when the current position becomes a predetermined location. Then, the imaging and monitor display functions can be stopped at a specific location or facility type.
In the case of stopping infrared sensitivity improvement imaging as shown in FIG. 18B, it may be determined in step F713 that a monitor display end trigger has occurred, and the through state may be restored.
As shown in FIG. 19 (a), when a specific target exists, it may be determined that a monitor display end trigger has occurred, and the through state may be restored. For example, it is a case where imaging / monitor display is prohibited for a specific target.
Alternatively, when it is determined that a specific target does not exist, it may be determined that a monitor display end trigger has occurred, and the through state may be restored.
When a quick movement of the imaging target is detected as shown in FIG. 19B, it may be determined that a monitor display end trigger has occurred and the through display is returned to the through state if the quick movement is not detected.
As shown in FIG. 20 (a), when a specific person is detected, it may be determined that a monitor display end trigger has occurred, and the through state may be restored. This is an example of prohibiting imaging / monitor display for a specific person.
Alternatively, when it is determined that a specific person no longer exists in the image, it may be determined that a monitor display end trigger has occurred, and the through state may be restored.
In the case where the light / dark distribution in the image is detected as shown in FIG. 20B, it may be determined that a monitor display end trigger has occurred when there is no light / dark difference in the imaging target, and the through state may be restored.
If it is determined that the trigger for the end of the monitor display is generated and the process returns to step F101 in FIG. 12, the necessity of the monitor display for the user is reduced or no longer required, and the monitor display function It is possible to automatically enter the through state in a situation where it is desired to prohibit the operation.

[6. Effect, modification and extension of embodiment]

Although the embodiment has been described above, according to the embodiment, an image captured by the imaging unit 3 arranged in the spectacle-type or head-mounted type mounting unit, that is, the direction visually recognized by the user is the subject direction. The captured image is displayed on the display unit 2 in front of the user's eyes. In this case, ambient brightness, weather, subject status, recognition of the subject itself, subject motion, location, date and time as the external environment By controlling the imaging operation or display operation based on such information, it is possible to create a situation in which the user's visual ability is assisted or expanded in a pseudo manner.
In addition, since the display mode is changed by controlling the imaging operation of the imaging unit 3 and the signal processing of the imaging signal processing unit 15 and the display image processing unit 12 based on the external environment, the user is not burdened with operation and is accurate. Since the control is executed, usability is improved.
Further, the display unit 2 can be in a transparent or translucent through state by controlling the transmittance, so that there is no problem in normal life even when the mounting unit is mounted. For this reason, the advantage of the imaging display apparatus 1 of this example can be effectively utilized in a user's normal life.

  In the embodiment, the control mainly related to the display mode realized by the imaging operation of the imaging unit 3 and the signal processing control of the imaging signal processing unit 15 and the display image processing unit 12 has been described. However, for example, power on / off / Switching of standby, control of sound volume and sound quality of sound output from the sound output unit 5, and the like may be performed based on the external environment. For example, the volume may be adjusted according to the time or place, or the surrounding volume may be detected and the speaker output volume adjusted according to the volume.

The appearance and configuration of the imaging display device 1 are not limited to the examples of FIGS. 1 and 2, and various modifications can be considered.
For example, a storage unit that records an image signal captured by the imaging unit 3 or a transmission unit that transmits the image signal to another device may be provided.
Furthermore, as a source of an image to be displayed on the display unit 2, in addition to the imaging unit 3, an input unit or a reception unit that inputs video from an external device may be provided.
Moreover, although the example which has a spectacles type or a head-mounted type mounting unit was described as the imaging display apparatus 1, the imaging display apparatus of this invention images a user's visual field direction, and displays it in front of a user's eyes. For example, a headphone type, a neckband type, an ear hook type, or any other mounting unit that can be worn by the user may be used. Furthermore, for example, it may be configured to be worn by the user by attaching to a normal eyeglass, visor, headphones, or the like with an attachment such as a clip.

  DESCRIPTION OF SYMBOLS 1 Imaging display apparatus, 2 Display part, 3 Imaging part, 4 Illumination part, 5 Voice output part, 6 Voice input part, 10 System controller, 11 Imaging control part, 12 Display image processing part, 13 Display drive part, 14 Display control , 15 Imaging signal processing unit, 16 Audio signal processing unit, 17 Image analysis unit, 19 Ambient environment sensor, 20 Imaging target sensor, 21 GPS reception unit, 22 Date / time counting unit, 26 Communication unit, 27 Speech synthesis unit

Claims (7)

An imaging means configured to image a direction viewed by a user as a subject direction;
A display unit arranged to be positioned in front of the user's eyes and capable of switching between a transparent state or a translucent state and an image display state for displaying an image captured by the imaging unit;
An external environment information acquisition unit that has at least two of an ambient environment sensor, an imaging target sensor, an image analysis unit, a position information acquisition unit, or a communication unit, and acquires external environment information from each;
Control means for controlling the display means to switch between the through state and the image display state based on two or more external world information acquired by the external world information acquisition means;
An imaging display device comprising:   The imaging display apparatus according to claim 1, wherein the outside world information acquired by the outside world information acquiring unit is information on ambient brightness, temperature, humidity, air pressure, or weather.   The imaging display apparatus according to claim 1, wherein the outside world information acquired by the outside world information acquisition unit is information on a distance to an imaging target of the imaging unit.   The imaging display apparatus according to claim 1, wherein the outside world information acquired by the outside world information acquisition unit is information on a motion of an imaging target of the imaging unit. Further comprising illumination means for illuminating the subject direction,
The imaging display device according to claim 1, wherein the control unit controls an illumination operation by the illumination unit based on the information acquired by the outside world information acquisition unit. The outside world information acquisition unit can perform image analysis on the image captured by the imaging unit by the image analysis unit and acquire outside world information for determining whether or not the imaging target is a character. Speech synthesis means for performing speech synthesis using the contained characters as speech,
Voice output means for outputting the voice generated by the voice synthesis means;
With
The imaging display device according to claim 1, wherein the control unit controls the output operation of the synthesized speech by the speech synthesis unit based on the information acquired by the external world information acquisition unit. The imaging means comprising: an imaging means configured to image a direction visually recognized by the user as a subject direction; and a through state that is disposed so as to be positioned in front of the user's eyes and is transparent or translucent As an imaging display method of an imaging display device comprising display means capable of switching between image display states for displaying an image captured in
An external environment information acquisition step of acquiring external environment information from at least two of an ambient environment sensor, an imaging target sensor, an image analysis unit, a position information acquisition unit, or a communication unit;
A control step for performing switching control between the through state and the image display state on the display means based on two or more external world information acquired in the external world information acquisition step;
An imaging display method comprising:

Images