KR101466684B1 - Control Method for optical correction of penetration ratio of liquid crystal display of sunglass or goggle - Google Patents

Abstract

The present invention relates to a method of controlling optical transmittance correction of left and right LCD panels of sunglasses or goggles, and more particularly, to a method of controlling optical transmittance correction of left and right LCD panels of sunglasses or goggles, The present invention provides a method for controlling optical transmittance correction of a left or right LCD panel of a sunglass or a goggle capable of correcting an optical transmittance deviation of an LCD panel by adjusting an electrical signal supplied to the sunglass or the goggles. A method of controlling optical transmittance correction of left and right LCD panels, the method comprising: supplying the same electrical signal to left and right LCD panels; Measuring the optical transmittance of the left and right LCD panels; Determining whether an optical transmittance deviation occurs; Adjusting an optical signal supplied to the LCD panel in which optical transmittance deviation occurs, when the optical transmittance deviation occurs in the left and right LCD panels, thereby correcting the optical transmittance of the LCD panel in which the deviation occurs; Measuring an optical transmittance of the calibrated LCD panel and the normally operating LCD panel; Determining whether an optical transmittance deviation occurs; And storing the corrected electrical signal of the LCD panel as a reference value when the optical transmittances of the calibrated LCD panel and the normally operating LCD panel are uniform; And a control unit.

Description

BACKGROUND OF THE INVENTION 1. Field of the Invention [0001] The present invention relates to a method of controlling optical transmittance correction of an LCD panel of a sunglass or a goggle,

The present invention relates to a sunglass and a goggle, and more particularly, to a sunglass and a goggle capable of correcting an optical transmittance of an LCD panel in which optical transmittance deviations occur in an inspection process of left and right LCD panels applied to left and right lenses of sunglasses or goggles And a method of controlling the optical transmittance correction of left and right LCD panels of goggles.

In general, sunglasses are used to protect the eyes from intense sunlight and ultraviolet rays. In general, colored glasses colored with oxides such as nickel, chromium, and cadmium are used, or polarized glass is used.

Here, sunglasses do not have dioptric power according to the household goods quality indication method. Generally, the lens has no significant deformation and the parallelism is stable. However, the sunglasses have some degree of shading performance Performance) is required by law.

The shading performance is measured and displayed by an absorption curve and a spectral transmission state (transmissive state). The larger the number is, the lower the rate at which light is transmitted. In recent years, there have been used diopters for myopia (nearsightedness) and polarized filters.

Goggles, on the other hand, are glasses used to protect the eyes from dust and strong light. They are used when riding a motorcycle, performing outdoor exercise such as mountain climbing or skiing.

Recently, a technique has been proposed in which a discoloration-type lens that acts in response to ultraviolet rays or a liquid crystal for simply changing the transmittance is used to improve the optical characteristics of sunglasses or goggles.

Here, the automatic control type LCD panel is applied to the lens of the sunglasses or the goggles, and the voltage applied to the LCD panel is controlled according to the detection value of the wear sensor and the illuminance sensor installed on the sunglasses or the goggles, And a structure for switching and maintaining the concentration of the lens.

When wearing the sunglasses or the goggles having the structure as described above, the wear sensor senses the wearing of the wearer and sensors such as the illuminance sensor detect the illuminance and the condition of the surrounding environment in real time, Adjust the voltage to switch the LCD panel density of sunglasses or goggles lenses.

On the other hand, LCD panels applied to the left and right eye lenses of sunglasses or goggles manufactured and manufactured may have different optical transmittances of the respective LCD panels even if the same electrical signals are supplied.

That is, when the left and right LCD panels of the left LCD panel and the right LCD panel are applied as the left and right eye lenses, variations in the optical transmittance uniformity may occur during the manufacturing process, There is a problem that the deviation of the optical transmittance of each LCD panel used as the left and right lens causes a problem that the degree of fatigue of the user's eye increases or increases and it is difficult to precisely read out the sunglasses or goggles there was.

In the case of manufacturing the LCD panels used as the left and right lenses of the sunglasses or the goggles, the same electrical signals are supplied to the left LCD panel and the right LCD panel, that is, the same voltage is applied to measure the optical transmittance of each LCD panel The optical transmittance deviation occurs when the optical transmittance uniformity of the left LCD panel and the right LCD panel deviates or is measured differently, thereby collecting and discarding the LCD panel which is inspected for defects or abnormalities.

In other words, when inspecting each LCD panel for defects and abnormalities when inspecting each LCD panel used for the left and right lenses of sunglasses or goggles, the same voltage is applied to the left LCD panel and right LCD panel In the case of supplying the same voltage to the left LCD panel and the right LCD panel, the uniformity of the optical transmittance of the left LCD panel and the right LCD panel corresponds to the supplied voltage. When measured, it is judged as a normal operation and commercialized. However, a deviation in optical transmittance different from the voltage supplied to the left LCD panel occurs, or a deviation in optical transmittance different from the voltage supplied to the right LCD panel occurs, If the panel is deviated from the supplied voltage and different optical transmittance deviation, it is judged to be defective or abnormal and collected and discarded.

For example, when each LCD panel used as a left or right eye lens of sunglasses or goggles has been manufactured, the same voltage of 10 is applied to the left LCD panel and the right LCD panel when each LCD panel is defective, If the same optical transmittance of 10 is measured on each LCD panel and the uniformity is maintained, it is determined that the LCD panel is normal operation and commercialized. However, if the measured optical transmittance is less than 10 or more than 10 , It is judged that the left LCD panel is defective or abnormality. If the right LCD panel is supplied with a voltage of 10 and the measured optical transmittance is measured as less than 10 or more than 10, it is judged that the right LDC panel is defective or abnormal. If both the LCD panel and the right LCD panel are measured to be less than 10 or more than 10, it is determined that each LCD panel is defective or abnormal, do.

As a result, manufacturing cost, collection and disposal costs of sunglasses or goggles in the manufacture of left and right lenses are generated, which causes a problem of increase in product unit cost and the like.

SUMMARY OF THE INVENTION The present invention has been made in order to solve the problems described above, and it is an object of the present invention to provide an LCD panel in which an unevenness in optical transmittance uniformity among left and right LCD panels applied to left and right eye lenses of sunglasses or goggles And an optical transmittance correction control method of a left and right LCD panel of a sunglass or a goggle capable of correcting and controlling an optical transmittance deviation of an LCD panel by controlling the optical transmittance deviation of the LCD panel.

The present invention also relates to a liquid crystal display device for use in a liquid crystal display, which is capable of correcting an optical transmittance deviation of left and right LCD panels and storing data corresponding to the corrected optical transmittance as default values, It is an object of the present invention to provide a method for controlling optical transmittance correction of left and right LCD panels of sunglasses or goggles which can be applied.

According to an aspect of the present invention, there is provided an optical transmittance correction control method for left and right LCD panels, which is applied to left and right eye lenses of sunglasses or goggles, step; Measuring the optical transmittance of the left and right LCD panels; Determining whether an optical transmittance deviation occurs; Adjusting an optical signal supplied to the LCD panel in which optical transmittance deviation occurs, when the optical transmittance deviation occurs in the left and right LCD panels, thereby correcting the optical transmittance of the LCD panel in which the deviation occurs; Measuring an optical transmittance of the calibrated LCD panel and the normally operating LCD panel; Determining whether an optical transmittance deviation occurs; And storing the corrected electrical signal of the LCD panel as a reference value when the optical transmittances of the calibrated LCD panel and the normally operating LCD panel are uniform; And a control unit.

Measuring the optical transmittance of the left and right LCD panels using a spectrometer; Transmitting transmittance data according to the optical transmittance of the left and right LCD panels measured by the spectroscope to a spectroscopic data input unit; Transmitting the transmittance data transmitted to the spectroscopic data input unit to the microcomputer; And comparing and analyzing the measured transmittance data of the micom; .

Adjusting the optical transmittance of the LCD panel in which deviation occurs by adjusting the supply voltage supplied to the LCD panel in which the optical transmittance deviation is generated when the optical transmittance deviation occurs in the left and right LCD panels; .

In addition, when an optical transmittance deviation occurs in the left and right LCD panels, the microcomputer adjusts the pulse width (PWM) per unit time supplied to the LCD panel in which the optical transmittance deviation is generated to adjust the optical transmittance of the LCD panel ; .

Measuring the optical transmittance of the calibrated LCD panel and the normally operating LCD panel using a spectrometer; Transmitting transmittance data according to the optical transmittance of the calibrated LCD panel measured in the spectroscope and the normally operating LCD panel to a spectroscopic data input unit; Transmitting the transmittance data transmitted to the spectroscopic data input unit to the microcomputer; And comparing and analyzing the measured transmittance data of the micom; .

As described above, according to the present invention having the above-described structure, it is possible to provide a liquid crystal display device capable of improving the uniformity of the optical transmittance that can be generated in the left and right LCD panels during the inspection process of the left and right LCD panels applied to left and right lenses of sunglasses or goggles It is possible to use and apply all the LCD panels manufactured regardless of defects such as optical transmittance deviation or the like, and thus the collection and disposal processes of the left and right LCD panels are eliminated, and the sunglasses or goggles It is possible to reduce manufacturing cost and product cost, maintain the uniformity of the left and right LCD panels, and correct the uniformity of the optical transmittance of the left and right LCD panels to an appropriate level to reduce the fatigue of the wearer's eyes when worn. And the like.

1 is a perspective view schematically showing a sunglass according to the present invention,
2 is a block diagram of a sunglass or goggles according to the present invention,
3 is a block diagram showing a system of a method for controlling optical transmittance correction of left and right LCD panels of sunglasses or goggles according to the present invention,
4 is a flow chart showing a method of controlling the optical transmittance correction of left and right LCD panels of sunglasses or goggles according to the present invention,
FIG. 5 is a flowchart schematically illustrating a process of measuring optical transmittance of an LCD panel in a method of controlling optical transmittance correction of left and right LCD panels of sunglasses or goggles according to the present invention.
6 is a flow chart schematically illustrating a process of measuring optical transmittance of a calibrated LCD panel of a method of controlling optical transmittance correction of left and right LCD panels of sunglasses or goggles according to the present invention.

Hereinafter, preferred embodiments of the present invention will be described in detail with reference to the accompanying drawings. The present invention is not limited to the scope of the present invention, but is merely an example, and various modifications can be made without departing from the technical spirit of the present invention.

2 is a block diagram of a sunglass or a goggle according to the present invention. FIG. 3 is a graph showing the optical transmittance correction of left and right LCD panels of sunglasses or goggles according to the present invention. 4 is a flowchart showing a method of controlling optical transmittance correction of left and right LCD panels of sunglasses or goggles according to the present invention. FIG. 5 is a flowchart illustrating a method of controlling the optical transmittance correction of the left and right LCD panels of a sunglass or a goggle according to the present invention, FIG. 6 is a flowchart illustrating an optical transmittance measurement method of an LCD panel of a right LCD panel according to an embodiment of the present invention. FIG. 6 is a flowchart illustrating a method of controlling the optical transmittance of the LCD panel of FIG. FIG. 5 is a flowchart schematically showing a process of measuring the optical transmittance of the panel. FIG.

As shown in the figure, the optical transmittance correction control method of the left and right LCD panels according to the present invention is applied to sunglasses, goggles, glasses and the like having two or more left and right eye lenses. In the present invention, One embodiment will be described.

As described above, the sunglass 100 to which the left and right LCD panel transmittance correction control method is applied is configured to include the sunglass frame 110 and the optical characteristic adjusting system 120. [

The sunglasses frame 110 is rotatably hinged to both ends of the body part 111 and a body part 111 positioned in front of the wearer's eyes when worn, And 112a and 112b.

The sunglass frame 110 is provided with an optical characteristic adjusting system 120 for selecting colors of the left and right LCD panels 121a and 121b constituting left and right lenses and automatically controlling the optical transmittance.

The optical characteristic adjusting system 120 includes LCD panels 121a and 121b fixed to the main body 111, an LCD panel driver 126, a microcomputer 122, a sensor 127, and a function setting input unit 124 And a function setting display unit 125. [0050]

The optical characteristic adjusting system 120 further includes a light source unit (not shown), a power source unit (not shown), and a charging unit (not shown).

The LCD panels 121a and 121b are applied to the respective lenses installed in the main body 111, and the optical transmittance is controlled and adjusted by the supplied voltage. That is, each of the lenses installed in the main body 111 is provided to the LCD panels 121a and 121b so that the optical transmittance can be adjusted by the voltage supplied from the LCD panel driver 126.

For this, the LCD panels 121a and 121b are made of a shutter LCD whose optical transmittance is changed by an applied driving voltage, and each of the LCD panels 121a and 121b is made of a plastic LCD of a flexible material.

When the LCD panels 121a and 121b are applied to the sunglasses 100, polarizing films (not shown) are provided on both sides of the LCD panels 121a and 121b, and a diffusion type color filter (not shown) But it is not limited to this structure.

Here, the LCD panel driver 126 controls and controls the magnitude of the voltage applied to adjust the optical transmittance of the LCD panels 121a and 121b. To this end, the LCD panel driver 126 includes a driving voltage power supply 126b and a starting voltage power supply 126a.

Here, the driving voltage power supply 126b is constantly applied to the LCD panels 121a and 121b to maintain the optical transmittance of the LCD panels 121a and 121b when the optical transmittances of the LCD panels 121a and 121b are adjusted.

The starting voltage power source 126a may further include a driving voltage power source unit 121a and 121b for rapidly changing the optical transmittance of the LCD panels 121a and 121b to a new target optical transmittance in adjusting the optical transmittance of the LCD panels 121a and 121b. 126b at a time when the LCD panels 121a, 121b are driven.

As described above, the LCD panel driver 126 adjusts the voltage supplied to the LCD panels 121a and 121b according to the voltages applied from the driving voltage power supply 126b and the starting voltage power supply 126a, .

The microcomputer 122 includes a memory device (not shown) storing a control program for controlling the LCD panels 121a and 121b and a central processing unit (CPU) (not shown) for executing a control program .

The microcomputer 122 is powered by a power source (not shown).

The microcomputer 122 outputs a control signal to the LCD panel driver 126 in accordance with various data and information input through the sensor unit 127.

Here, the sensor unit 127 includes a temperature sensor 123a, a wear sensor 123b, and an illuminance sensor 123c.

The temperature sensor 123a senses the temperature around the sunglasses 100 and transmits data about the sensed ambient temperature to the microcomputer 122. [

The wear detection sensor 123b detects whether or not the sunglasses 100 are worn, and transmits data on the sensed wearing state to the microcomputer 122.

The illumination sensor 123c senses the illuminance around the sunglasses 100 and transmits data about the sensed ambient illuminance to the microcomputer 122. [

As described above, the data and information sensed and sensed by the temperature sensor 123a, the wear sensor 123b, and the illuminance sensor 123c are input to the microcomputer 122.

The function setting unit is connected to the microcomputer 122 and includes a function setting input unit 124 and a function setting display unit 125.

The function setting input unit 124 inputs function settings such as automatic adjustment and manual adjustment of the optical transmittance of the LCD panels 121a and 121b to the microcomputer 122. [

The function setting display unit 125 displays information on the current state of the sunglasses 100 such as various data and information input through the sensor unit 127 and the function setting input unit 124. [

The operation process of the sunglass having the above-described configuration will be described.

First, regardless of whether or not the wearer wears it, the setting and the status are displayed. At this time, the remaining capacity of the battery or the like is displayed through the function setting display unit 125.

When the wearer wears the sunglasses 100, the wearing sensation sensor 123b senses whether or not the wearer wears the sunglasses, the data sensed by the wear sensing sensor 123b is transmitted to the microcomputer 122, The wear state of the sunglasses 100 is sensed by determining whether the wearer 122 wears the sunglasses.

Here, when the wearer senses that the wearer wears the sunglasses 100, the microcomputer 122 displays the settings and states of the sunglasses 100 again.

Meanwhile, when the microcomputer 122 senses that the sunglasses 100 are worn, the optical transmissivity of the LCD panels 121a and 121b of the sunglasses 100 is controlled and color selection is performed simultaneously.

First, the concentration adjustment process includes a function selection confirmation step, a roughness / temperature change confirmation step, an illumination / temperature compensation step, a concentration variable value output step, an LCD panel drive step, and a basic concentration value output step.

The function selecting and confirming step is a step of confirming whether or not the wearer has selected the automatic density adjusting function, and is performed through the function setting input unit 124.

Here, when the automatic density control function is not selected in the function selection checking step, the microcomputer 122 outputs a control signal to each LCD panel so as to output a predetermined basic density value so that the microcomputer 122 outputs a predetermined basic density value Output.

At this time, the basic concentration value is composed of at least three levels of lightness, middle brightness, and darkness, and can be manually selected. After the basic concentration value output step, the LCD panel driving step is performed.

When the automatic density control function is selected, the microcomputer 122 receives the current temperature and illumination-related data from the temperature sensor 123a and the illumination sensor 123c, And a roughness / temperature change confirmation step for confirming whether or not there is a difference between the roughness and the roughness, and judging that the present temperature and roughness are different from the previous temperature and roughness.

At this time, automatic density adjustment of three or more stages is possible at the time of automatic density adjustment. At this time, the optical transmittance of each of the LCD panels 121a and 121b is set in a stepwise manner from 3.2% to 65%.

If there is a difference between at least one of the illuminance and the temperature, if the microcomputer 122 generates a difference between the current illuminance and the temperature and the previous temperature and illuminance, a new control Perform an illumination / temperature compensation step to calculate the value.

That is, before the illuminance sensor 123c judges the illuminance around the sunglasses 100, the microcomputer 122 determines a signal input to the illuminance sensor 123c and determines the concentration of each of the LCD panels 121a and 121b Correct to correspond to the changed illumination.

As the temperature of the LCD panels 121a and 121b decreases, the blocking concentration and the reaction rate of the LDC panel are lowered. In order to obtain a desired level of concentration and reaction speed in the LCD panels 121a and 121b, Is required, thereby correcting the temperature.

As described above, the microcomputer 122 outputs a control signal to the LCD panel driving unit 126 based on the illuminance and temperature data corrected in the illuminance / temperature compensation step to output the density variable value of the LCD panels 121a and 121b .

On the other hand, if there is no change in both the illuminance and the temperature in the illuminance / temperature change confirmation step, the concentration variable value output step is performed immediately.

Here, the LCD panel driving unit 126 applies a driving voltage to the LCD panels 121a and 121b to perform an LCD panel driving step.

At this time, the color selection process of the LCD panels 121a and 121b includes checking whether a color is selected, a selected color output step, a basic color output step, and a color filter driving step.

The step of confirming whether or not to select the color is a step of confirming whether the wearer has selected a desired color, and is performed through the function setting input unit 124.

Here, if the wearer does not select a desired color, a basic color output step of outputting control signals to the LCD panels 121a and 121b is performed to output the basic color set in advance to the microcomputer 122.

If the color is selected by the wearer, the microcomputer 122 outputs a control signal to the LCD panels 121a and 121b to output the color selected by the wearer to the LCD panels 121a and 121b. Conduct.

Meanwhile, as described above, the sunglasses 100 or the goggles (not shown) to which the LCD panel is applied with two left and right lenses are used for the left LCD panel 121a and the right LCD panel The LCD panels 121a and 121b have a variation in the optical transmittance of the LCD panels 121a and 121b when a defect occurs in the LCD panels 121a and 121b, 121b can be corrected to maintain the optical uniformity.

That is, the left LCD panel 121a and the right LCD panel 121a, which are applied as the left and right eye lenses of the sunglasses 100 after the production and manufacturing processes of the sunglasses 100 to which the LCD panels 121a and 121b are respectively applied as the left and right lenses, In the inspection process for checking the uniformity of the optical transmittance of the LCD panel 121a, it is preferable that any one of the two LCD panels 121a and 121b or the two LCD panels 121a and 121b, in which an optical transmittance deviation occurs among the two LCD panels 121a and 121b, 121b can be corrected to maintain the uniformity of the optical transmittance of the LCD panels 121a, 121b where defects and abnormalities are generated.

As described above, in order to correct the LCD panels 121a and 121b in which optical transmittances are varied, a spectroscope 130 (for measuring the optical transmittance deviation of the left and right LCD panels 121a and 121b of the sunglasses 100) A spectroscope data input unit 140 for receiving the transmittance data on the optical transmittances of the left and right LCD panels 121a and 121b measured by the spectroscope 130 and providing the transmittance data to the microcomputer 122, .

The transmittance data transmitted from the spectroscopic data input unit 140 to the microcomputer 122 is compared and analyzed through the microcomputer 122.

The spectroscope 130 and the spectroscope data input unit 140 are connected to each other through a wired line such as a cable. The spectroscope 130 and the spectroscope data input unit 140 are connected to each other via Wi-Fi, Bluetooth, Zigbee ZigBee), and the like, and they may be interconnected by various other methods.

The left and right LCD panels 121a and 121b of the left and right eye lenses of the sunglasses 100 are supplied with the same electrical signal and the left and right LCD panels 121a and 121b, And transmit the transmittance data of the LCD panels 121a and 121b measured by the spectroscope 130 to the spectroscope data input unit 140. The spectroscope data input unit 140 transmits the transmittance data of the LCD panels 121a and 121b to the spectroscope data input unit 140, The microcomputer 122 compares and analyzes whether the optical transmittance of each of the LCD panels 121a and 121b is deviated or not. Then, the left and right LCD panels 121a and 121b compare the optical transmittances of the left and right LCD panels 121a and 121b, The optical transmittance correction is performed.

Here, when the same optical transmittance appears on the left and right LCD panels 121a and 121b, it is recognized as a normal operation, but an optical transmittance deviation occurs in any one of the left and right LCD panels 121a and 121b When an optical transmittance deviation occurs in the left LCD panel 121a, for example, the supplied electrical signal is confirmed, and after the confirmation of the electrical signal, the optical transmittance deviation is supplied to the left LCD panel 121a where the optical transmittance deviation is generated When the electrical signal is lower than the electric signal supplied to the normal right LCD panel 121b, the electrical signal supplied to the LCD panel 121a in which the optical transmittance deviation is generated is increased and the optical transmittance of the LCD panels 121a and 121b Is corrected to be uniform.

When the electrical signal supplied to the left LCD panel 121a where the optical transmittance deviation is generated is higher than the electrical signal supplied to the normal right LCD panel 121b, the optical transmittance deviation is supplied to the left LCD panel 121a where the optical transmittance deviation occurs And corrects the optical transmittance of each of the LCD panels 121a and 121b to be uniform.

The left and right LCD panels 121a and 121b can be controlled by adjusting the electrical signals supplied only to the LCD panels 121a and 121b in which the light transmittance deviation of the left and right LCD panels 121a and 121b of the sunglasses 100 is generated, 121b are corrected so as not to cause a deviation in optical transmittance.

At this time, the microcomputer 122 outputs the output signal of the control circuit to the LCD panels 121a and 121b using the spectroscope 130 measuring the optical transmittance deviation of the left and right LCD panels 121a and 121b, And a program for correcting the correction amount so that it can be maintained.

After the optical transmittances of the LCD panels 121a and 121b thus corrected are re-measured and re-measured by the spectroscope 130, the transmittance data is input to the microcomputer 122 through the spectroscope data input unit 140, ) Of the left and right LCD panels 121a and 121b is compared with the left and right LCD panels 121a and 121b to determine whether or not an optical transmittance deviation occurs, , The corrected correction value is stored as a final value, and the stored final value is output as a reference value.

In an embodiment of the present invention, when an optical transmittance deviation occurs in the left and right LCD panels 121a and 121b, the electric signals supplied to the left and right LCD panels 121a and 121b are adjusted to be transmitted to the LCD panels 121a and 121b, 121b are corrected so as to correct the optical transmittance deviation of the left and right LCD panels 121a, 121b. However, when an optical transmittance deviation occurs in the left and right LCD panels 121a, 121b, The optical transmittance of the LCD panels 121a and 121b in which the optical transmittance deviation is generated may be corrected by adjusting the supply voltage of the LCD panels 121a and 121b in which the optical transmittance deviation occurs in the right LCD panels 121a and 121b, The optical transmittance of the LCD panels 121a and 121b in which the optical transmittance deviation is generated through the pulse width modulation (PWM) per unit time of the LCD panels 121a and 121b in which the optical transmittance deviation is generated among the right LCD panels 121a and 121b is It is preferable to correct it.

That is, when an optical transmittance deviation occurs in the left and right LCD panels 121a and 121b, the optical signals supplied to the left and right LCD panels 121a and 121b, The optical signals are adjusted by adding and subtracting a supply voltage supplied to the LCD panels 121a and 121b to generate optical transmittance deviations. The optical transmittance of the LCD panels 121a and 121b Or the optical transmittance of the LCD panels 121a and 121b in which the optical transmittance deviation is generated by changing the pulse width through pulse width modulation (PWM) per unit time, or by adjusting the optical transmittance of the LCD panels 121a and 121b Is corrected.

Hereinafter, a method of controlling the optical transmittance correction of the left and right LCD panels of sunglasses or goggles according to the present invention will be described.

First, the same electrical signal is supplied to the left and right LCD panels 121a and 121b, which are applied to left and right eye lenses of the manufactured sunglasses 100 or goggles (not shown) (S10).

The optical transmittances of the left and right LCD panels 121a and 121b according to the electrical signals supplied to the left and right LCD panels 121a and 121b are respectively measured (S20).

That is, the left and right LCD panels 121a and 121b are connected to the left and right LCD panels 121a and 121b through a spectroscope 130 installed on the front surface of the sunglasses 100 to which the left and right eye lenses are applied, , And 121b are measured (S21).

As described above, the transmittance data of each of the LCD panels 121a and 121b with respect to the optical transmittance measured through the spectroscope 130 is input and transmitted to the spectroscope data input unit 140 (S22), and the spectroscopic data input unit The transmittance data inputted to the microcomputer 122 is input to and transmitted to the microcomputer 122 at step S23 and whether the optical transmittance measured at the left and right LCD panels 121a and 121b is deviated from the microcomputer 122 is compared And analyzes it (S24).

At this time, the microcomputer 122 is provided with a program for measuring and correcting the optical transmittance deviation of the left and right LCD panels 121a and 121b.

Here, when the same optical transmittance is generated in the left and right LCD panels 121a and 121b, it is recognized as a normal operation, and an electrical signal generating the same optical transmittance is stored as a final value and applied as a reference value.

If there is a deviation in the uniformity of the optical transmittance between the left and right LCD panels 121a and 121b (S30), for example, the left and right LCD panels 121a and 121b The optical transmittance of the LCD panels 121a and 121b in which the deviations are generated is corrected by adjusting the electrical signals supplied to only the left LCD panel 121a in which the deviations are generated (S40).

At this time, an electric signal supplied to the left LCD panel 121a in which the deviation is generated among the left and right LCD panels 121a and 121b is made to be a supply voltage, The optical transmittance of the light guide plate 121a is corrected (S41).

The electric signal supplied to the left LCD panel 121a in which the deviation is generated among the left and right LCD panels 121a and 121b is made up of a pulse width per unit time PWM, And adjusts the optical transmittance of the left LCD panel 121a (S43).

In an embodiment of the present invention, the electric signal supplied to the LCD panels 121a and 121b in which the deviation is generated among the left and right LCD panels 121a and 121b is applied to both the supply voltage and the pulse width per unit time PWM The LCD panels 121a and 121b which are configured to correct the optical transmittances of the LCD panels 121a and 121b in which the deviations are generated but the optical transmittance is varied due to the supply voltage or the pulse width per unit time PWM, It is also possible to correct the optical transmittance of the liquid crystal display device.

As described above, by adjusting the supply voltage and the pulse width per unit time (PWM) supplied to one of the LCD panels 121a and 121b in which the deviation is generated among the left and right LCD panels 121a and 121b, The optical transmittances of the first and second optical fibers 121a and 121b are measured (S50).

Then, it compares and analyzes whether the optical transmittance of the left LCD panel 121a whose deviation is corrected and the right LCD panel 121b which operates normally deviates.

At this time, the uniformity of the optical transmittance of the left LCD panel 121a corrected according to the supplied electrical signal is measured (S51).

The transmittance data of the left LCD panel 121a with respect to the corrected optical transmittance measured through the spectroscope 130 is input to and transmitted to the spectroscope data input unit 140 at step S52 and transmitted to the spectroscope data input unit 140 The corrected transmittance data is input to and transmitted to the microcomputer 122 at step S53 and the optical transmittance measured at the right LCD panel 121b and the normally operated left LCD panel 121a corrected by the microcomputer 122 And compares and analyzes whether a deviation occurs (S54).

If the corrected left LCD panel 121a and the right LCD panel 121b operate normally (S60), the electrical signal supplied to the corrected left LCD panel 121a is adjusted again The optical transmittance of the corrected left LCD panel 121a is corrected again (S40).

Here, when the same optical transmittance is generated in the left and right LCD panels 121a and 121b, it is recognized as a normal operation, and corrected data corresponding to an electrical signal having the same optical transmittance is stored as a final value, (S70).

The LCD panels 121a and 121b in which optical deviation occurs among the left LCD panel 121a and the right LCD panel 121b applied to the left and right eye lenses are repeatedly performed while performing the above- The electrical signal according to the optical transmittance which becomes uniform afterwards is stored as the final value and used as the reference value.

While the present invention has been particularly shown and described with reference to specific embodiments thereof, it will be understood by those skilled in the art that various changes and modifications may be made without departing from the spirit and scope of the invention as defined in the appended claims. It will be easy for anyone to know.

100: sunglasses, 110: sunglasses,
111:
112a, 112b: first and second leg portions,
120: optical characteristic adjustment system,
121a and 121b: left and right LCD panels, 122: microcomputer,
123a: temperature sensor, 123b: wear sensor,
123c: Illumination detection sensor, 124: Function setting input section,
125: function setting display section, 126: LCD panel driving section,
126a: a starting voltage power supply unit, 126b: a driving voltage power supply unit,
127: sensor unit, 130: spectroscope,
140: spectrometer data input.

Claims (5)

A method of controlling optical transmittance correction of left and right LCD panels applied to left and right eye lenses of sunglasses or goggles,
(S10) supplying the same electrical signal to the left and right LCD panels;
Measuring the optical transmittance of the left and right LCD panels (S20);
Determining whether the optical transmittance deviation occurs (S30);
A step (S40) of correcting the optical transmittance of the LCD panel in which the deviation is caused by adjusting an electrical signal supplied to the LCD panel in which the optical transmittance deviation occurs, when an optical transmittance deviation occurs in the left and right LCD panels;
Measuring the optical transmittance of the calibrated LCD panel and the normally operating LCD panel (S50); Determining whether the optical transmittance deviation occurs (S60); And
(S70) storing an electrical signal of the calibrated LCD panel as a reference value when the optical transmittances of the calibrated LCD panel and the normally operating LCD panel are uniform;
Measuring the optical transmittance of the left and right LCD panels with a spectroscope (S21);
(S22) transmitting transmittance data according to the optical transmittance of the left and right LCD panels measured by the spectroscope to a spectroscopic data input unit; Transmitting the transmittance data transmitted to the spectroscopic data input unit to the microcomputer (S23); And comparing and analyzing the transmittance data measured by the microcomputer (S24). A method for controlling optical transmittance correction of a left or right LCD panel of a sunglass or a goggle. delete The method according to claim 1,
When an optical transmittance deviation occurs in the left and right LCD panels,
(S41) the microcomputer adjusts the optical transmittance of the LCD panel in which the deviation occurs by adjusting and adjusting the supply voltage supplied to the LCD panel in which the optical transmittance deviation occurs;
And correcting the optical transmittance correction of the left and right LCD panels of the sunglasses or the goggles.
The method according to claim 1,
When the optical transmittance deviation occurs in the left and right LCD panels, the microcomputer adjusts and adjusts the pulse width (PWM) per unit time supplied to the LCD panel in which the optical transmittance deviation is generated to correct the optical transmittance of the LCD panel (S43);
And correcting the optical transmittance correction of the left and right LCD panels of the sunglasses or the goggles.
The method according to claim 1,
Measuring the optical transmittance of the calibrated LCD panel and the normally operating LCD panel using a spectroscope (S51);
(S52) transmitting transmittance data according to the optical transmittance of the calibrated LCD panel and the normally operating LCD panel measured by the spectroscope to the spectroscopic data input unit;
Transmitting the transmittance data transmitted to the spectroscopic data input unit to the microcomputer (S53); And
Comparing and analyzing the measured transmittance data (S54);
And correcting the optical transmittance correction of the left and right LCD panels of the sunglasses or the goggles.

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