JPH05191686A - Video camera - Google Patents

Abstract

PURPOSE:To extend the life of a battery or the like by providing an eyepiece part with a detecting switch means which detects the contact state of photographer's face. CONSTITUTION:When a face 10 representing the part of an eyeball 201 of the photographer is separated from an eyecup 105, electricity is not supplied from a power supply circuit 107 to a signal processing circuit 109 because a detecting switch 106 it turned off, and a gaze detecting system and a view finder 101 are not operated. When the face 10 of the photographer closely comes into contact with the eyecup 105, the detecting switch 106 is turned on, and the power supply circuit 107 is started to supply the electricity to the signal processing circuit 109 and the view finder 101. When the face 10 of the photographer is separated from the eyecup 105 in this state, the detecting switch 106 is turned off, and the power supply circuit 107 is shut off, and the signal processing circuit 109 and the view finder 101 stop the operation.

Description

Detailed Description of the Invention

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a video camera, and more particularly to a video camera having an electronic viewfinder for a monitor.

[0002]

2. Description of the Related Art For example, in a camera of this type, various devices have been proposed in the past for detecting what position on an observation surface an observer observes, that is, a so-called line of sight (visual axis). For example, in Japanese Unexamined Patent Publication No. 61-172552, a parallel light flux from a light source is projected onto the anterior eye part of an eyeball of an observer, and a corneal reflection image due to reflected light from the cornea and an image formation position of a pupil are used for viewing. Seeking the axis. 11
(A) and (B) are explanatory views of the principle of this visual axis detection method, FIG. (A) is a schematic diagram of the visual axis detection optical system, and FIG.
FIG. 6A is an intensity diagram of an output signal from the photoelectric element array 6 in FIG. In FIG. 1A, reference numeral 5 denotes a light source such as a light emitting diode that emits infrared light insensitive to the observer, and is arranged on the focal plane of the light projecting lens 3. The infrared light emitted from the light source 5 becomes parallel light by the light projecting lens 3 and is reflected by the half mirror 2 to illuminate the cornea 21 of the eyeball 201. At this time, the corneal reflection image d by a part of the infrared light reflected on the surface of the cornea 21 is transmitted through the half mirror 2, condensed by the light receiving lens 4, and re-imaged at the position Zd ′ on the photoelectric element array 6. . In addition, 24 shows a pupil.

The luminous fluxes from the ends a and b of the iris 23 are
Photoelectric element array 6 via half mirror 2 and light receiving lens 4
The images of the end portions a and b are formed at the upper positions Za ′ and Zb ′. When the rotation angle θ of the optical axis a of the eyeball with respect to the optical axis of the light receiving lens 4 (optical axis a) is small, Z of the ends a and b of the iris 23 is set.
If the coordinates are Za and Zb, the coordinate Zc of the center position C of the iris 23 is expressed as Zc = (Za + Zb) / 2. Further, when the Z coordinate of the generation position d of the corneal reflection image is Zd and the distance between the center of curvature O of the cornea 21 and the center C of the iris 23 is OC, the rotation angle θ of the eyeball optical axis a is OC × sin θ = Zc− Zd ... (1) The relational expression is almost satisfied.

Here, the Z coordinate Zd of the position d of the corneal reflection image
And the Z coordinate Z of the center of curvature O of the cornea 21 match.
Therefore, the computing means 9 detects the position of each singular point (corneal reflection image d and the edges a and b of the iris) projected on the surface of the photoelectric element array 6 as shown in FIG. The rotation angle θ of the axis a can be obtained. At this time (1)
The formula can be rewritten as β × OC × sin θ = (Za ′ + Zb ′) / 2−Zd ′ (2). However, β is a magnification determined by the distance L1 between the corneal reflection image generation position and the light receiving lens 4 and the distance L0 between the light receiving lens 4 and the photoelectric element array 6, and is usually a substantially constant value.

On the other hand, in the conventional camera-integrated VTR, when the photographer tries to input various functions during photographing, he or she has to look through the viewfinder and perform the operation. Further, in order to operate while checking the switches of various functions, it is necessary to once look away from the viewfinder, and the shooting screen may be disturbed or the subject may be lost. Furthermore, in recent years, camera integrated VTRs have been diversified due to diversified user applications.
There is a tendency for various functions associated with to increase. In view of such a background, for example, applying the above-described line-of-sight detection device,
By detecting the line of sight in the viewfinder and applying it to the function input, it becomes possible to easily perform the function input without taking the eyes off the viewfinder.

[0006]

However, in the case of using the above-described line-of-sight detection device, the power of the line-of-sight detection mechanism incorporated in the viewfinder during the photographing mode is always on, so that, for example, the view Even when the photographer's eyes are not aimed at the viewfinder, power is flowing to the electric circuit of the visual axis detection system, which causes a problem of shortening the life of the power source such as a battery.

The present invention has been made in view of the above problems, and is configured to supply a visual axis detection system and power to the viewfinder only when the photographer is gazing at the viewfinder. The purpose is to

[0008]

Therefore, according to the present invention, there is provided a video camera having a visual axis detecting mechanism in a viewfinder, wherein it is detected that a photographer's face is in close contact with an eyepiece portion of the viewfinder. By providing a detection switch means for controlling the power supply of the line-of-sight detection mechanism and the viewfinder according to the output of the detection switch means, or alternatively, in the eyepiece of the viewfinder After the face of the photographer who was in close contact with the viewfinder moves away from the ON state to the OFF state,
While the line-of-sight detection mechanism detects the line of sight of the photographer,
The power source of the line-of-sight detection mechanism and the viewfinder is continuously maintained in the ON state, and when the line-of-sight cannot be detected, the power source is turned off.
When the face of the photographer who is in close contact with the viewfinder eyepiece is separated from the viewfinder, the detection switch means is turned off, and the face of the photographer is far away from the viewfinder and After the detection mechanism cannot detect the line-of-sight of the photographer, the line-of-sight detection mechanism does not detect the line-of-sight again within a predetermined time, or the line-of-sight detection mechanism is detected only when the detection switch means remains off. And by configuring the viewfinder to turn off, or even
A video camera having line-of-sight detection means for detecting the line-of-sight of the photographer, the detection switch means for detecting that the face of the photographer approaches the video camera, and the output of the line-of-sight detection means and the detection switch means. Accordingly, it is intended to achieve the above object by including a power supply control means for controlling power supply to each device constituting the video camera.

[0009]

With the above-described structure of the present invention, power is supplied to the line-of-sight detection system and this viewfinder only when the photographer is gazing at the viewfinder. Can be improved.

[0010]

EXAMPLES The present invention will be described below based on examples. (Structure) FIG. 1, FIG. 2 and FIG. 3 are schematic diagrams of respective main parts when the eyes of the photographer of the electronic viewfinder unit incorporating the visual line detection mechanism according to the present invention are at different positions. The same (corresponding) constituent elements as in FIG. 11A are represented by the same reference numerals.

In each figure, reference numeral 1 denotes an eyepiece lens, and a dichroic mirror 2 for transmitting visible light and reflecting infrared light is obliquely provided inside the eyepiece lens, which also serves as an optical path splitter. Reference numeral 4 is a light receiving lens, and 5 is an illuminating means, which is composed of, for example, three infrared light emitting diodes 5a and 5c and 5b (not shown) arranged at respective positions described later. Reference numeral 6 is a photoelectric element array. The light-receiving lens 4 and the photoelectric element array 6 form an element of light-receiving means. The photoelectric element array 6 usually uses a device in which a plurality of photoelectric elements are arranged one-dimensionally in the direction perpendicular to the drawing, but a device in which photoelectric elements are arranged two-dimensionally is used as necessary.
The eyeball 201 is formed by these respective constituent elements 1, 2, 4, 5, and 6.
Constitutes the eye gaze detection system. 10 is the photographer's eyeball 20
The face part which represents one copy is shown.

Further, 101 is an electronic viewfinder, 1
Reference numeral 02 indicates a finder screen. In this embodiment, the image displayed on the viewfinder screen 102 is guided to the eyepoint E via the eyepiece lens 1. Reference numeral 105 denotes an eyecup arranged in the eyepiece of the electronic viewfinder 101, and reference numeral 106 denotes a face 10 incorporated in the eyecup 105.
Is a detection switch as a detection means for detecting the close contact state with the eyecup 105. 1, FIG. 2, and FIG. 3, FIG. 1 shows the photographer's face 10 far from the eyecup 105, and FIG. 2 shows the photographer's face 10.
Is in close contact with the eyecup 105 and the detection switch 106 is turned on. In FIG. 3, the detection switch 106 is turned off, but since the photographer's face 10 is not too far from the eyecup 105, The state where the eyeball 201 is within the line-of-sight detectable range is shown.

The line-of-sight detection apparatus according to the present embodiment includes the line-of-sight detection system composed of the members represented by the respective constituent elements 1, 2, 4, 5, 6 and the signal processing circuit 109 which is a calculation means. It includes an eyeball optical axis detection circuit, an eyeball discrimination circuit, a visual axis correction circuit, a gazing point detection circuit and a signal processing circuit 109, and a power supply circuit 107 such as a battery for supplying electricity to the viewfinder 101.

In this line-of-sight detection system, the infrared light emitted from the infrared light-emitting diode 5 illuminates the eyeball 201 of the observer located near the eye point E in the figure. In addition, the infrared light reflected by the eyeball 201 is reflected by the dichroic mirror 2.
And is converged by the light receiving lens 4 to form an image on the photoelectric element array 6. In addition, the signal processing circuit 109
Is executed by the software of the microcomputer. The detection switch 106 is always supplied with power from the power supply circuit 107 unless the main switch (not shown) is turned off.

(Operation) FIG. 4 shows an operation sequence flowchart of the first embodiment in the states shown in FIGS. 1 and 2 will be described below with reference to FIG. In FIG. 1, the photographer's face 10 is an eyecup 10.
5 is separated from the detection switch 106 in step S1.
Is off, no electricity is supplied from the power supply circuit 107 to the signal processing circuit 109, and the line-of-sight detection system and the viewfinder 101 are not operating.

In FIG. 2, the face 10 of the photographer is in close contact with the eyecup 105, the detection switch 106 is turned on, the power supply circuit 107 is activated, and step S2 is performed.
In S3, the signal circuit 109 and the viewfinder 1
01 is supplied with electricity. The face 10 of the photographer is separated from the eyecup 105 from the state of FIG.
When 6 is turned off, the power supply circuit 107 is also stopped and the signal processing circuit 109 and the viewfinder 101 are also stopped in steps S4 and S5.

(Embodiment 2) FIG. 5 is a flow chart for explaining the operation sequence of the second embodiment of the present invention.
1 to 3 will be described below with reference to FIG. In step S11, when the detection switch 106 is turned on in the state of FIG. 2, the process proceeds to step S12, and when the state 10 of FIG. 1, that is, the photographer's face 10 is separated from the eyecup 105 and the detection switch 106 is turned off, the process proceeds to step S16. ..

In step S12, power is supplied to the sight line detecting mechanism. Furthermore, in step S13, the viewfinder 1
Power is also supplied to 01. Next, in step S14,
Here, it is determined again whether the detection switch 106 is turned on. If the detection switch 106 is turned on, the process returns to step S12, and if not turned on, step S
Proceed to 15.

In step S15, even if the face 10 of the photographer is separated from the eyecup 105 and the detection switch 106 is turned off in step S15, as shown in FIG. If the line-of-sight detection system is not far from 105 and the line-of-sight of the photographer is detected (Yes), it is determined that the photographer is taking another image, and the process returns to step S12.

On the other hand, if the line-of-sight detection is not possible (No) in step S15, the process proceeds to step S16 to turn off the power supply to the line-of-sight detection mechanism, and further to step S17 to turn off the power supply to the viewfinder 101. And returns to step S11.

(Embodiment 3) FIG. 6 is a flow chart for explaining an operation sequence showing a third embodiment of the present invention. Hereinafter, FIGS. 1 to 3 will be explained based on FIG. In step S21, the detection switch 10 in the state of FIG.
When 6 is turned on, the process proceeds to step S22, and when the state of FIG. 1, that is, the face 10 of the photographer is separated from the eyecup 105 and the detection switch 106 is turned off, the process proceeds to step S28. In step S22, power is supplied to the line-of-sight detection mechanism.
Further, power is supplied to the viewfinder 101 in step S23.

Next, in step S24, it is again determined whether the detection switch 106 is turned on. If the detection switch 106 is turned on, step S2
Returning to step 2, if not turned on, the process proceeds to step S25. In step S25, the state of FIG. 1, that is, the face 10 of the photographer is separated from the eyecup 105 and the detection switch 106
Even when is turned off, as shown in FIG. 3, the face 10 of the photographer is not too far from the eyecup 105, and the line-of-sight detection system detects the line of sight of the photographer (Yes). Judges that the photographer is still photographing, and returns to step S22.

On the other hand, if it is impossible to detect the line of sight (No) in step S25, the process proceeds to step S26, the power supply circuit 107 is waited for a certain time without being stopped, and is stopped after a predetermined time has elapsed. It is a thing. If the predetermined time has not elapsed, the process returns to step S25, and if the predetermined time has elapsed, the process proceeds to the next step S27. In step S27, the power supply to the line-of-sight detection mechanism is turned off, the process proceeds to step S28, the power supply to the viewfinder 101 is also turned off, and the process returns to step S21.

(Gaze position detecting method) Next, details of the gaze position detecting method briefly described above will be supplementarily described with reference to FIGS. 7 to 10. FIG. 7 is a perspective view of a main part of the line-of-sight detection system in FIG. 1, and FIGS. 8A and 8B are optical principle diagrams of the line-of-sight detection system. Infrared light emitting diodes 5a, 5 for illumination
b and 5c are used as a pair to detect the distance between the camera and the eyeball of the observer, and the infrared light emitting diodes 5a and 5b are positioned laterally according to the posture of the camera. The vertical position is detected at 5c. 7 and 8, the attitude detecting means of the camera is not shown, but the attitude detecting means using a mercury switch or the like is effective. The infrared light emitting diodes 5a and 5b are arranged in the row direction (Z axis direction) of the photoelectric element row 6 with respect to the optical axis (X axis) of the light receiving lens 4.
And are arranged at positions shifted in a direction orthogonal to the column direction.

In FIG. 8A, the luminous fluxes from the infrared light emitting diodes 5a and 5b which are separately arranged in the row direction (Z-axis direction) of the photoelectric element row 6 are reflected by the cornea at positions separated in the Z-axis direction. Images e and d are formed, respectively. At this time, the Z coordinate of the midpoint of the corneal reflection images e and d is the Z of the curvature center O of the cornea 21.
It matches the coordinates. Further, since the interval between the corneal reflection images e and d changes according to the distance between the infrared light emitting diode and the observer's eyeball, the positions e ′ and d ′ of the corneal reflection images re-imaged on the photoelectric element array 6 are formed. It is possible to obtain the imaging magnification β of the reflected image from the eyeball by detecting See also FIG.
In (B), the infrared light emitting diodes 5a and 5b (not shown) arranged in the direction orthogonal to the row direction of the photoelectric element rows 6 illuminate the eyeball of the observer obliquely from above, and therefore the eyeball of the observer's eyeball. Is not rotated in the vertical direction (in the XY plane), the corneal reflection image e (d is not shown) is formed in the + Y direction in the figure with respect to the center of curvature of the cornea and the center of the pupil.

FIG. 9A is an explanatory view showing reflection images from the eyeball projected on the plurality of photoelectric element array surfaces of the photoelectric element array 6 in this embodiment, and is projected on the photoelectric element array 6. It shows a reflection image from the eyeball. In the figure, the corneal reflection images e'and d'are re-imaged on the photoelectric element array Yp '. The output signal obtained from the photoelectric element array Yp 'at this time is shown in FIG. 9 (B).

Next, the visual axis detection method in this embodiment will be described with reference to the sequence flowchart of FIG. First, the rotation angle of the eyeball optical axis is detected by the eyeball optical axis detection circuit included in the signal processing circuit 109. Next, the image signals of the photoelectric element array 6 are sequentially read out in the -Y direction shown in FIG. 9 (A), and the photoelectric element array (line) Yp 'on which the corneal reflection images e', d'are formed is detected (step). S1). At the same time, in step S2, the generation positions Zd 'and Ze' of the corneal reflection images e'and d'in the column direction are detected, and in step S3.
Then, the imaging magnification β of the optical system is obtained from the interval | Zd′−Ze ′ | of the corneal reflection image. Further, in step S4, boundary points Z2a 'and Z2b' between the iris 23 and the pupil 24 are detected on the photoelectric element array (line) Yp ', and step S5 is performed.
Then, the pupil length on this photoelectric element array Yp '| Z2a'-Z2
Calculate b '|

As shown in FIG. 9A, the photoelectric element array Yp 'on which a corneal reflection image is formed is usually generated in the -Y direction in the figure from the photoelectric element array Y0' in which the pupil center C'is present. Another photoelectric element array Y1 ′ from which signals should be read is calculated from the values of the imaging magnification β and the pupil length (step S).
6). At this time, the photoelectric element array Y1 'is the photoelectric element array Y1.
It is set so that it has a sufficient distance to p '. Similarly, when boundary points Z1a 'and Z1b' between the iris 23 and the pupil 24 on the photoelectric element array Y1 'are detected in step S7, these boundary points (Z1a', Y1 '), (Z1b',
Y1 ') and the boundary points (Z2a', Y2 '), (Z2
The center position C '(Zc', Yc ') of the pupil is obtained by using at least three points of b', Y2 '). Further, the positions (Zd ', Yp'), (Ze ', Y) of the corneal reflection image are
When the above equation (2) is transformed using p ′), the rotation angles θz and θy of the optical axis of the eyeball are β × OC × SIN θz≈Zc ′ − (Zd ′ + Ze ′) / 2 (3) β × OC × SIN θy≈Yc′−Yp ′ + δY ′ (4) is satisfied (step S8). However, δY ′ is because the infrared light emitting diode is arranged in the direction orthogonal to the row direction of the photoelectric element row 6 with respect to the light receiving lens 4, so that the re-imaging positions e ′ and d ′ of the corneal reflection image are the photoelectric elements. Cornea 2 on row 6
This is a value for correcting the amount of shift in the Y axis direction with respect to the Y coordinate of the center of curvature of 1.

Further, in the eyeball discrimination circuit included in the signal processing circuit 109, it is determined in step S9 whether the eye of the observer looking into the viewfinder 101 is the right eye or the left eye based on the distribution of the calculated rotation angles of the eyeball optical axis. In step S10, the visual axis correction circuit corrects the visual axis based on the eyeball discrimination information and the rotation angle of the optical axis of the eyeball. In the gazing point detection circuit, step S1
At 1, the gazing point is calculated based on the optical constants of the finder optical system.

[0030]

As described above, according to the present invention, the detection switch means for detecting the close contact state of the photographer's face is provided in the eyepiece of the viewfinder device of the VTR with a built-in camera. The power is supplied to the eye gaze detection system and the viewfinder only while the photographer is gazing at the pure finder, so that a power saving effect can be obtained and the life of the battery or the like can be extended.

Further, if the line of sight is detected even if the detection switch means is turned off, or if the line of sight can be detected again within a predetermined time even if the line of sight is not detected, the power source is turned on. Since it is configured not to stop, it is possible to prevent large current consumption and circuit fatigue at startup due to frequent power on / off and improve usability.

[Brief description of drawings]

FIG. 1 is a schematic view of an essential part of an embodiment of an electronic viewfinder unit (No. 1)

FIG. 2 is a schematic view of a main part of an embodiment of an electronic viewfinder unit (No. 2)

FIG. 3 is a schematic view of an essential part of an embodiment of an electronic viewfinder unit (Part 3).

FIG. 4 is an operation sequence flowchart of FIGS. 1 and 2.

FIG. 5 is an operation sequence flowchart of the second embodiment.

FIG. 6 is an operation sequence flowchart of the third embodiment.

7 is a perspective view of a main part of the line-of-sight detection system of FIG.

FIG. 8 is an optical principle diagram of FIG.

FIG. 9: Reflected image on photoelectric element array

FIG. 10 is a gaze detection method sequence flowchart

FIG. 11 is an explanatory diagram of a gaze detection method.

[Explanation of symbols]

 10 Face of photographer 101 Electronic viewfinder 102 Viewfinder screen 105 Eyecup 106 Detection switch 107 Power supply circuit 109 Signal processing circuit 201 Eyeball

─────────────────────────────────────────────────── ─── Continuation of the front page (51) Int.Cl. ⁵ Identification code Office reference number FI technical display location H04N 5/225 F 7205-5C

Claims (4)

[Claims] 1. A video camera having a line-of-sight detection mechanism in a viewfinder, wherein detection switch means for detecting that a photographer's face is in close contact is provided at an eyepiece part of the viewfinder, and the detection is performed. A video camera characterized in that power supply to the visual axis detection mechanism and the viewfinder can be controlled according to the output of the switch means. 2. The line-of-sight detection mechanism is operated by the photographer after the detection switch means shifts from an on state to an off state when the photographer's face that is in close contact with the eyepiece of the viewfinder moves away from the viewfinder. While detecting the line of sight of, the power of the line-of-sight detection mechanism and the viewfinder is continuously held in the ON state, and when the line of sight cannot be detected, the power is turned off. The video camera according to claim 1. 3. When the face of the photographer who is in close contact with the eyepiece of the viewfinder moves away from the viewfinder, the detection switch means is turned off, and the face of the photographer comes out of the viewfinder. When the line-of-sight detection mechanism cannot detect the line of sight of the photographer after a long distance and the line-of-sight detection mechanism cannot detect the line of sight of the photographer, or when the detection switch means remains off. 2. The video camera according to claim 1, wherein the visual axis detection mechanism and the viewfinder are configured to be turned off for the first time. 4. A video camera having line-of-sight detection means for detecting the line-of-sight of the photographer, wherein the detection switch means detects that the face of the photographer approaches the video camera.
A video camera comprising: a power supply control means for controlling power supply to each device constituting the video camera according to outputs of the line-of-sight detection means and the detection switch means.