JPH0934631A - Computer input device - Google Patents

Abstract

PROBLEM TO BE SOLVED: To eliminate a need of manual alignment work between a pointer on the display picture and the gaze point of an operator. SOLUTION: A computer input device 10 is provided with electrodes A1 ,... stuck in the vicinity of operator's eyeballs ER and EL, a detection part 12 which detects not only EOGV1 generated by inclination of optical axes of eyeballs ER and EL through electrodes A1 ,... but also EOGV2 which is included in EOGV1 and is generated by the jumping eyeball motion, and a control part 14 which moves a pointer P on a display picture D based on EOGV1 detected by the detection part 12 and decides coincidence between a symbol C for calibration and the gaze point of the operator to calibrate the position of the pointer P at the time of detecting EOGV2 in the detection part 12 a prescribed time after generation of the symbol C for calibration on the display picture D.

Description

Detailed Description of the Invention

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a computer input device, such as a keyboard or a mouse, for an operator of a computer to specify a position on a display screen, and more specifically, it utilizes an eye movement of the operator. Related to computer input devices.

[0002]

2. Description of the Related Art An eyeball of a vertebrate has a lens side that is positively charged and a retina side that is negatively charged. Therefore, when an electrode is attached to the skin surface around the orbit of the human body and the potential is measured, a potential difference in the vertical and horizontal directions proportional to the inclination of the eyeball is observed. This potential difference is called Electro-ocurgram (hereinafter, abbreviated as "EOG"). Conventionally, a computer input device using an EOG has been known (for example, Japanese Patent Laid-Open No. 4-3589).
No. 98 gazette, Jitsukaihei 4-90244 gazette, etc.). In this computer input device, when the operator gazes at the pointer on the display screen and moves his or her line of sight, the pointer moves following this. In such a conventional computer input device, since the EOG is a weak electric signal and contains various noises, the positions of the gazing point and the pointer gradually shift during the operation. As a result, alignment work (calibration) between the gazing point and the pointer is required.

[0003]

However, if the positions of the gaze point and the pointer are misaligned, it becomes difficult to make a computer input using the EOG. Therefore, this alignment work requires a manual operation of, for example, a keyboard, which is very complicated. As a result, such a conventional computer input device has a problem that it cannot be applied to a physically handicapped person with limited limbs, work with both hands, etc., because manual alignment work is required.

[0004]

SUMMARY OF THE INVENTION Therefore, an object of the present invention is to provide a computer input device which can move a pointer on a display screen accurately at any time and which eliminates the need for a manual positioning operation between the gazing point and the pointer. .

[0005]

A computer input device according to the present invention comprises a plurality of electrodes attached near an operator's eyeball and a first potential difference generated by the inclination of the optical axis of the eyeball. And a detection unit for detecting a second potential difference generated by the jumping eye movement included in the first potential difference and a display unit on the display screen based on the first potential difference detected by the detection unit. When the second potential difference is detected by the detection unit within a predetermined time after the pointer is moved and the calibration symbol is generated on the display screen, the calibration symbol and the operator's gaze point are separated from each other. And a controller for calibrating the position of the pointer when it is determined that they match. Further, the detection unit may detect the second potential difference by separating it from the first potential difference by a high-pass filter. Further, the calibration symbol may be a flashing high-luminance light emitting point.

[0006]

The first electric potential difference generated by the inclination of the optical axis of the eyeball is derived from the plurality of electrodes attached near the eyeball of the operator. The first potential difference is EOG, which is a DC level potential change caused by eyeball charging. The second potential difference is EOG during jumping eye movement. Jumping eye movement is a phenomenon in which the line of sight moves rapidly from the stop point to the next stop point, and is seen in the movement of the line of sight during reading. Jump eye movement speed is 100-500 ° / sec
Therefore, the second potential difference can be detected by signal processing using a high-pass filter, for example.

The control unit generates a calibration symbol on the display screen if necessary. The calibration symbol is, for example, a flashing high-intensity light emitting point. When this calibration symbol is generated and the operator gazes at it, the detection unit detects the second potential difference. Then, the control unit determines whether or not the second potential difference is detected within a predetermined time after the generation of the calibration symbol. If it is detected within a predetermined time, it is determined that the second potential difference is based on the calibration symbol,
It is determined that the calibration symbol and the gaze point of the operator match.

[0008]

1 is a block diagram showing an embodiment of a computer input device according to the present invention. Less than,
A description will be given based on this drawing.

Computer input device 10 according to the present invention
Is an electrode A attached near the operator's eyes E _R , E _L
1, and A _2, B _1, B _2, eye E _R, EOGV ₁ (first potential) to electrodes A ₁ generated by the inclination of the optical axis of the E _L, and detects through a ..., to EOGV ₁ The detection unit 12 that detects EOGV ₂ (second potential difference) generated by the included jumping eye movement, and the pointer P on the display screen D is moved based on the EOGV ₁ detected by the detection unit 12 and the display screen D After the calibration symbol C is generated on the upper side, E
When OGV ₂ is detected, it is provided with a control unit 14 for calibrating the position of the pointer P by determining that the calibration symbol C and the operator's gaze point match. Also, the detecting unit 1
2 is EO by the high pass filters 122 _A and 122 _B.
GV ₂ is detected separately from EOGV ₁ . Further, the calibration symbol C is a flashing high-intensity light emitting point.

The electrodes A ₁ and A ₂ are attached on the left and right sides of the eyeballs E _R and E _L respectively, and the electrodes B ₁ and B ₂ are on the left eyeball E.
It is affixed to the top and bottom with _L in between.

The detection unit 12 includes differential amplifiers 121 _A and 12 _A.
1 _B , high pass filters 122 _A and 122 _{B, and the} like. The differential amplifier 121 _A derives EOGV ₁ from the electrodes A ₁ and A _2, and the differential amplifier 121 _B derives EOGV ₁ from the electrodes B ₁ and B ₂ . High pass filter 122 _A ,
122 _B has a cutoff frequency of about 0.05 to 0.1 Hz, and E
EOGV ₂ is separated and detected by removing low-frequency baseline wobbling noise from OGV ₁ .

The control unit 14 comprises a potential difference comparator 141, a variable resistor 142, potentiometers 143 _A and 143 _B , a computer 144, a video controller 145, a calibration symbol generator 146, a unit time signal generator 147 and the like. ing. The potential difference comparator 141 is composed of a so-called comparator or the like, and has a threshold value Vth of the change amount of EOGV _2.
Only EOGV ₂ having a reference potential corresponding to 1 and the threshold Vth2 of the absolute amount and exceeding the thresholds Vth1 and Vth2 is recognized as a true EOGV ₂ . The variable resistor 142 is for adjusting the threshold values Vth1 and Vth2. Potentiometer 143 _A ,
143 _B outputs to the computer 144 a pulse X _P indicating the amount of movement in the X-axis direction and a pulse Y _P indicating the amount of movement in the Y-axis direction, according to the value of EOGV ₁ . The computer 144 includes a CPU, an input / output interface, a ROM,
It is a general type composed of RAM and the like, and operates according to a stored computer program. The video controller 145 displays the pointer P on the display screen D.
And a video signal S _V for displaying the calibration symbol C to the display device.

FIG. 2 is an explanatory diagram showing a concrete example of use of the computer input device 10. FIG. 3 is a waveform diagram showing an example of EOGV ₂ in the computer input device 10. The operation of the computer input device 10 will be described below with reference to FIGS. 1 to 3.

First, the computer 144 outputs a signal S ₁ for starting the alignment to the calibration symbol generator 146, if necessary. Then, the calibration symbol generator 146 outputs the signal S ₂ for displaying the calibration symbol C on the display screen D to the video controller 145 and the signal S ₃ for starting the operation to the unit time signal generator 147. To do.

As a result, the calibration symbol C is displayed on the display screen D (FIG. 2A). On the other hand, at the same time t ₀ (FIG. 3) as this, the unit time signal generator 14
7 starts operation and outputs a signal S ₄ for detecting EOGV ₂ to the potential difference comparator 141 until time t ₂ after the time t _{1 has} elapsed (FIG. 3). That is, the detection time t _M of EOGV ₂ is limited to the time t ₁ to the time t ₂ . For example, if the time t ₀ is “0”, the time t ₁ is about 150 msec and the time t ₂ is about 250 msec.

When the calibration symbol C is displayed on the display screen D, the operator quickly moves the line of sight L toward the calibration symbol C to perform the jumping eye movement (FIG. 2B). As a result, the EOGV ₂ waveform shown in FIG. 3 is observed. Here, if the EOGV ₂ exceeds the threshold values Vth1 and Vth2 within the detection time t _M , the potential difference comparator 141 determines that the jumping eye movement is performed based on the calibration symbol C, and the signal S for executing the calibration is determined. ₅ is output to the potentiometers 143 _A and 143 _B. Then, the computer 144 outputs a signal S _P for displaying the pointer P on the display screen D to the video controller 145. At this time, since the line of sight L is still at the position of the calibration symbol C, the pointer P is also displayed at this position. That is, the alignment of the line of sight L and the pointer P is automatically performed. From this point on, potentiometer 143 _A , 1
43 _B outputs to the computer 144 a pulse X _P indicating the amount of movement in the X-axis direction and a pulse Y _P indicating the amount of movement in the Y-axis direction according to the value of EOGV ₁ . Therefore,
As shown in FIG. 2D, when the operator moves the line of sight L, the pointer P moves according to the EOGV ₁ generated thereby.

By the way, if the EOGV ₂ does not exceed the threshold values Vth1 and Vth2 within the detection time t _M , the potential difference comparator 141 determines that the jumping eyeball movement is not performed based on the calibration symbol C, and performs the alignment. The signal S ₆ to start again is output to the calibration symbol generator 146.

Needless to say, the present invention is not limited to the above embodiment. For example, on the display screen D, the movement sensitivity of the pointer P may be set by displaying the calibration symbol C at a certain position and then displaying the calibration symbol C at another position. The moving sensitivity of the pointer P is the moving distance of the pointer P with respect to the moving angle of the line of sight L. In addition, by linking the start of alignment between the gaze point and the pointer with the voluntary movements of the operator's blink, voice, exhalation, etc., the operator can control the linkage / non-linkage between the line of sight and the pointer. You may do it.

[0019]

According to the computer input device of the present invention, the pointer on the display screen is moved based on the first potential difference, and at the predetermined time after the calibration symbol is generated on the display screen. When the second potential difference is detected, the position of the pointer is calibrated by determining that the calibration symbol and the operator's gaze point match, so that the pointer can be moved accurately at any time and No manual alignment work with the pointer is required. Therefore, it can be suitably used especially for physically handicapped persons with limited limbs and for work with both hands.

According to the computer input device of the second aspect, the second potential difference is detected separately from the first potential difference by the high-pass filter. The potential difference between the two can be detected easily and accurately.

According to the computer input device of the third aspect, since the blinking high-luminance light emitting point is used as the calibration symbol, the operator can accurately recognize the generation and position of the calibration symbol. The accuracy of alignment between the gazing point and the pointer can be improved.

[Brief description of drawings]

FIG. 1 is a block diagram showing an embodiment of a computer input device according to the present invention.

FIG. 2 is an explanatory diagram showing a specific example of use in the computer input device of FIG. 1, in which time elapses in the order of FIGS.

FIG. 3 is a waveform diagram showing an example of EOG in the computer input device of FIG.

[Explanation of symbols]

10 computer input device 12 detection unit 14 control unit 122 _A , 122 _B high-pass filter E _R , E _L operator's eye A ₁ , A ₂ , B ₁ , B ₂ electrode V ₁ EOG (first potential difference) V ₂ EOG (second potential difference) D Display screen P Pointer C Calibration symbol

Claims (3)

[Claims] 1. A plurality of electrodes attached in the vicinity of an operator's eyeball and a first potential difference caused by the inclination of the optical axis of the eyeball are detected via the electrodes, and the first potential difference is detected. A detection unit for detecting a second potential difference generated by the included jumping eye movement, and moving a pointer on the display screen based on the first potential difference detected by this detection unit, and for calibration on the display screen. When the second potential difference is detected by the detection unit within a predetermined time after the symbol is generated, the position of the pointer is calibrated by determining that the calibration symbol matches the gazing point of the operator. A computer input device including a control unit. 2. The computer input device according to claim 1, wherein the detection unit separates and detects the second potential difference from the first potential difference by a high-pass filter. 3. The computer input device according to claim 2, wherein the calibration symbol is a flashing high-intensity light emitting point.