JP2012155298A - Shutter spectacles and driving method thereof - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide easy-to-see shutter spectacles and a driving method thereof.SOLUTION: In the shutter spectacles having shutter parts 101 and 102 and a driving part 103, the shutter part 101 includes a first substrate part 110a having a first transparent electrode 112a, a second substrate part 120a having a second transparent electrode 122a opposed to the first transparent electrode, and a first liquid crystal layer 130a provided between the first transparent electrode and the second transparent electrode. The driving part 103 supplies a voltage to the shutter parts. The driving part supplies the shutter parts with a first voltage for placing the shutter parts in one of a translucent state and a light shielding state whose transmissivity is lower than that of the translucent state and a second voltage for placing the shutter parts in the other of the translucent state and the light shielding state, alternately. The driving part has a first control period in which the first voltage is set to a first polarity in a plurality of first voltage periods, in which the first voltage is supplied, succeeding across a second voltage period, in which the second voltage is supplied, among a plurality of first voltage periods.

Description

  Embodiments described herein relate generally to shutter glasses and a driving method thereof.

In the fields of entertainment, education, broadcasting, medical care, etc., stereoscopic vision systems have been put into practical use. In the stereoscopic system, for example, a left-eye image and a right-eye image corresponding to the left-right eye parallax are presented to the left and right eyes, respectively, in a time-sharing manner. For this purpose, liquid crystal is used for high-speed response shutter glasses.
It is desired that the shutter glasses are easier to see and less fatigued.

JP 08-327961 A

  Embodiments of the present invention provide easy-to-see shutter glasses and a driving method thereof.

  According to the embodiment of the present invention, shutter glasses including a first shutter unit and a driving unit are provided. The first shutter portion includes a first substrate portion having a first transparent electrode, a second substrate portion having a second transparent electrode facing the first transparent electrode, the first transparent electrode, and the second transparent electrode. And a first liquid crystal layer provided therebetween. The driving unit supplies a voltage to the first shutter unit. The driving unit includes a first voltage that causes the first shutter unit to be in one of a light-transmitting state and a light-blocking state in which the transmittance is lower than the transmittance in the light-transmitting state, and the first shutter unit. Is alternately supplied to the first shutter portion, with the second voltage for causing the other one of the light-transmitting state and the light-shielding state. The driving unit includes a plurality of first voltage periods that are continuous with respect to a second voltage period that supplies the second voltage among a plurality of first voltage periods that supply the first voltage. A first control period for setting the voltage to the first polarity;

FIG. 1A to FIG. 1D are schematic views illustrating the operation of shutter glasses according to the first embodiment. 1 is a schematic view illustrating the configuration of a display system in which shutter glasses according to a first embodiment are used. FIG. 3 is a schematic view illustrating the configuration of shutter glasses according to the first embodiment. FIG. 2 is a schematic cross-sectional view illustrating the configuration of shutter glasses according to the first embodiment. FIG. 5A to FIG. 5D are schematic cross-sectional views illustrating the operation of the shutter glasses according to the first embodiment. FIG. 6A to FIG. 6D are schematic views illustrating the operation of the shutter glasses of the reference example. FIG. 7A to FIG. 7D are schematic views illustrating the operation of another shutter glasses according to the first embodiment. FIG. 8A and FIG. 8B are schematic views illustrating the operation of another shutter glasses according to the first embodiment. It is a typical perspective view which illustrates the composition of another shutter glasses concerning a 1st embodiment. It is a typical perspective view which illustrates the composition of another shutter glasses concerning a 1st embodiment.

Each embodiment will be described below with reference to the drawings.
The drawings are schematic or conceptual, and the relationship between the thickness and width of each part, the size ratio between the parts, and the like are not necessarily the same as actual ones. Further, even when the same part is represented, the dimensions and ratios may be represented differently depending on the drawings.
Note that, in the present specification and each drawing, the same elements as those described above with reference to the previous drawings are denoted by the same reference numerals, and detailed description thereof is omitted as appropriate.

(First embodiment)
FIG. 1A to FIG. 1D are schematic views illustrating the operation of shutter glasses according to the first embodiment.
FIG. 2 is a schematic view illustrating the configuration of a display system in which the shutter glasses according to the first embodiment are used.
First, an example of a display system capable of stereoscopic viewing using the shutter glasses according to the embodiment will be described with reference to FIG.

  As shown in FIG. 2, the display system 11 includes a display 13 (display unit) and shutter glasses 12. The display system 11 has a three-dimensional display mode. In the three-dimensional display mode, a left-eye image and a right-eye image corresponding to parallax are displayed. The viewer views the left-eye image and the right-eye image as a three-dimensional image. Note that the display system 11 may have a two-dimensional display mode. In the two-dimensional display mode, the viewer views the image displayed on the display 13 as a two-dimensional image. Hereinafter, the three-dimensional display mode will be described.

  The display 13 has a display surface 13d. On the display surface 13d, images corresponding to the left-eye image and the right-eye image are alternately switched and displayed. For example, for the display 13, for example, an active matrix type liquid crystal display is used. Any operation mode can be applied to this display. For example, an OCB (Optically Compensated Bend) mode can be applied to the display. The display 13 has a plurality of pixels arranged in a matrix. For example, display is performed by converting the field frequency to 120 Hz, for example, by digital signal processing.

  The shutter glasses 12 include a first shutter unit 101, a second shutter unit 102, and a drive unit 103. Each of the first shutter unit 101 and the second shutter unit 102 is disposed to face the left eye and the right eye of the viewer. The viewer views the display image on the display 13 via the first shutter unit 101 and the second shutter unit 102. In the shutter glasses 12, a time-division shutter operation is performed. In synchronization with the display on the display 13, the first shutter unit 101 and the second shutter unit 102 are alternately in a light transmitting state and a light blocking state. The transmittance in the light shielding state is lower than the transmittance in the light transmitting state.

  The first shutter unit 101 and the second shutter unit 102 may be provided separately from each other. Further, the first shutter unit 101 and the second shutter unit 102 may be integrally continuous. For example, two electrodes may be provided on one substrate, and each of the two electrodes may be included in each of the first shutter unit 101 and the second shutter unit 102.

  For example, the display 13 displays the images corresponding to the left eye and the right eye by switching alternately for each field. At this time, during the period in which the left-eye image is displayed on the display 13, the left-eye shutter unit is in a light-transmitting state and the right-eye shutter unit is in a light-shielding state. Then, during the period in which the right-eye image is displayed on the display 13, the right-eye shutter unit is in a light-transmitting state and the left-eye shutter unit is in a light-shielding state.

  For example, the display system 11 can further include a control unit 14. The operation of the shutter unit is performed by the control unit 14, for example. However, the function of the control unit 14 may be included in either the display 13 or the shutter glasses 12. Signal transmission / reception between the control unit 14 and the display 13, signal transmission / reception between the control unit 14 and the shutter glasses 12, and signal transmission / reception between the display 13 and the shutter glasses 12 are wired or wireless. It is done by the method.

  In the display system 11, a stereoscopic image can be perceived by viewing the left-eye image with the left eye and viewing the right-eye image with the right eye.

FIG. 3 is a schematic view illustrating the configuration of the shutter glasses according to the first embodiment.
As illustrated in FIG. 3, the shutter glasses 12 according to the embodiment include a first shutter unit 101, a second shutter unit 102, and a drive unit 103.

  The first shutter unit 101 includes a first substrate unit 110a, a second substrate unit 120a, and a first liquid crystal layer 130a. The first substrate unit 110a includes a first transparent electrode 112a. The second substrate unit 120a has a second transparent electrode 122a. The second transparent electrode 122a faces the first transparent electrode 112a. The first liquid crystal layer 130a is provided between the first transparent electrode 112a and the second transparent electrode 122a.

  The second shutter unit 102 is juxtaposed with the first shutter unit 101. The second shutter unit 102 includes a third substrate unit 110b, a fourth substrate unit 120b, and a second liquid crystal layer 130b. The third substrate unit 110b has a second transparent electrode 112b. The fourth substrate unit 120b includes a fourth transparent electrode 122b. The fourth transparent electrode 122b faces the third transparent electrode 112b. The second liquid crystal layer 130b is provided between the third transparent electrode 112b and the fourth transparent electrode 122b.

  The driving unit 103 supplies a voltage to the first shutter unit 101 and the second shutter unit 102. The drive unit 103 is electrically connected to the first transparent electrode 112a, the second transparent electrode 122a, the third transparent electrode 112b, and the fourth transparent electrode 122b.

  The configuration of the second shutter unit 102 can be the same as the configuration of the first shutter unit 101. Below, the example of a structure of the 1st shutter part 101 is demonstrated.

  FIG. 4 is a schematic cross-sectional view illustrating the configuration of the shutter glasses according to the first embodiment. As illustrated in FIG. 4, the first substrate unit 110a further includes a first support substrate 111a and a first alignment film 113a in addition to the first transparent electrode 112a. A first transparent electrode 112a is provided on the first support substrate 111a. A first alignment film 113a is provided on the first transparent electrode 112a.

  The second substrate unit 120a further includes a second support substrate 121a and a second alignment film 123a in addition to the second transparent electrode 122a. A second transparent electrode 122a is provided on the second support substrate 121a. A second alignment film 123a is provided on the second transparent electrode 122a.

  In addition, you may provide the spacer (not shown) which controls the space | interval (space | interval between the 1st alignment film 113a and the 2nd alignment film 123a) between the 1st transparent electrode 112a and the 2nd transparent electrode 122a. As the spacer, for example, a columnar spacer provided on the first substrate portion 110a (for example, on the first transparent electrode 112a) can be used. The columnar spacer may be provided on the second substrate portion 120a. Moreover, the columnar spacer may be provided on both the first substrate unit 110a and the first substrate unit 120a.

  The first shutter unit 101 may further include a first polarizing plate 160a, a first optical compensation plate 140a, a second polarizing plate 170a, and a second optical compensation plate 150a. The first substrate unit 110a and the second substrate unit 120a are disposed between the first polarizing plate 160a and the second polarizing plate 170a. The first substrate unit 110a is disposed between the first polarizing plate 160a and the second substrate unit 120a. The second substrate unit 120a is disposed between the second polarizing plate 170a and the first substrate unit 110a. A first optical compensation plate 140a is disposed between the first polarizing plate 160a and the first substrate unit 110a. A second optical compensation plate 150a is disposed between the second polarizing plate 170a and the second substrate unit 120a.

  The first shutter part 101 further includes a first seal part 180a. The first seal part 180a surrounds the first liquid crystal layer 130a between the first substrate part 110a and the second substrate part 120a.

  A direction from the first substrate unit 110a toward the first substrate unit 120a is taken as a Z-axis direction. One axis perpendicular to the Z axis is taken as the X axis. An axis perpendicular to the Z axis and the X axis is taken as a Y axis.

  The first support substrate 111a and the second support substrate 121a are translucent. For the first support substrate 111a and the second support substrate 121a, for example, glass or resin is used.

  For the first transparent electrode 112a and the second transparent electrode 122a, a light-transmitting conductive material is used for light that is a target of light transmission and light shielding operations in the shutter glasses 12. That is, the first transparent electrode 112a and the second transparent electrode 122a are translucent to visible light. For example, ITO (Indium Tin Oxide) or ZnO can be used for the first transparent electrode 112a and the second transparent electrode 122a.

  For example, polyimide can be used for the first alignment film 113a and the second alignment film 123a. The polyimide film is subjected to a rubbing process, for example. The rubbing process direction of the first alignment film 113a is substantially parallel to the rubbing process direction of the second alignment film 123a. The rubbing process direction of the first alignment film 113a is substantially the same as the rubbing process direction of the second alignment film 123a.

  A nematic liquid crystal is used for the first liquid crystal layer 130a. Due to the functions of the first alignment film 113a and the second alignment film 123a, the liquid crystal molecules of the first liquid crystal layer 130a in the vicinity of the first substrate unit 110a and the second substrate unit 120a have a high pretilt angle. Thereby, the first liquid crystal layer 130a is in the splay alignment state in the initial state (state in which no voltage is applied). When the voltage is applied, the state transitions to the bend arrangement state. The first shutter unit 101 operates in the OCB mode.

  As the first optical compensation plate 140a and the second optical compensation plate 150a, for example, a biaxial film including an optically anisotropic layer in which a discotic liquid crystal compound is hybrid-aligned can be used.

  However, the configuration of the first shutter unit 101 (and the second shutter unit 102) is arbitrary. For example, the first liquid crystal layer 130a may operate in a mode other than the OCB mode. Hereinafter, an example in which the first liquid crystal layer 130a operates in the OCB mode will be described.

FIG. 5A to FIG. 5D are schematic cross-sectional views illustrating the operation of the shutter glasses according to the first embodiment.
In these drawings, the first alignment film 113a and the second alignment film 123a are omitted.

  FIG. 5A illustrates a state when the first initial voltage V11 is applied. The first initial voltage V11 is a voltage lower than a threshold value at which the liquid crystal alignment in the first liquid crystal layer 130a transitions from the splay alignment to the bend alignment. The first initial voltage V11 is, for example, 0 volts (V). That is, FIG. 5A illustrates a state when the power is off.

  FIG. 5B illustrates a state when the second initial voltage V12 is applied. The second initial voltage V12 is a voltage equal to or higher than a threshold value at which the liquid crystal alignment in the first liquid crystal layer 130a transitions from the splay alignment to the bend alignment. The effective value of the second initial voltage V12 is larger than the effective value of the first initial voltage V11. That is, FIG. 5B illustrates the state after the initialization process.

  FIG. 5C illustrates a state when the first bend voltage VB1 is applied in the bend arrangement state after the initialization process. FIG. 5D illustrates a state when the second bend voltage VB2 is applied in the bend arrangement state after the initialization process. The effective value of the second bend voltage VB2 is larger than the effective value of the first bend voltage VB1.

  As shown in FIG. 5A, the liquid crystal molecules 130l of the first liquid crystal layer 130a are in a splay alignment state when the power is off.

  In the shutter glasses 12, the power is turned on and an initialization process is performed. In the initialization process, a predetermined transition voltage (second initial voltage V12 to be transitioned to a bend arrangement) is applied to the first liquid crystal layer 130a.

  Thereby, as shown in FIG. 5B, the arrangement state of the first liquid crystal layer 130a is changed from the splay arrangement to the bend arrangement.

The first initial voltage V11 is, for example, 0V.
The second initial voltage V12 is a voltage having a relatively large effective value. As a result, the splay arrangement can be quickly transferred to the bend arrangement.

  The absolute value (for example, effective value) of the second initial voltage V12 is, for example, 10V to 30V. However, the value of the second initial voltage V12 is arbitrary as long as it is equal to or higher than the threshold voltage. When the effective value of the second initial voltage V12 is large, the splay arrangement quickly transitions to the bend arrangement. For example, for the second initial voltage V12, for example, a combination of a positive pulse of about several hundred milliseconds (ms) at + 15V and a negative pulse of about several hundred milliseconds at -15V can be used. . By applying the second initial voltage V12, the first liquid crystal layer 130a changes from the splay arrangement to the bend arrangement.

  The driving unit 103 may supply the second initial voltage V12 for the transition from the splay arrangement to the bend arrangement to the first transparent electrode 112a and the second transparent electrode 122a.

  Thus, after the initialization process is performed, the operations shown in FIGS. 5C and 5D are performed. That is, in the bend arrangement state, for example, a state in which the first bend voltage VB1 is applied (state in FIG. 5B) and a state in which the second bend voltage VB2 is applied, for example (state in FIG. 5C). Switching is performed.

  During the operation of the shutter glasses 12, the alignment state of the liquid crystal molecules 130l of the first liquid crystal layer 130a is maintained in a bend alignment. When the voltage applied to the bend alignment liquid crystal molecules 130l is changed, the alignment state is changed. Corresponding to the change in the alignment state, the retardation of the first liquid crystal layer 130a changes. By using the first polarizing plate 160a and the second polarizing plate 170a, a light-transmitting state and a light-blocking state corresponding to this change in retardation can be obtained.

  For example, when the first bend voltage VB1 is applied, the first shutter unit 101 is in a light transmitting state, and when the second bend voltage VB2 is applied, the first shutter unit 101 is in a light shielding state. Alternatively, the light shielding state may be set when the first bend voltage VB1 is applied, and the light transmitting state may be set when the second bend voltage VB2 is applied.

  As described above, the light transmission state of the first shutter unit 101 is the first bend arrangement state of one of the bend arrangements, and the light shielding state of the first shutter unit 101 is the first bend arrangement state of the bend arrangements. Are different second bend arrangement states.

  In the shutter glasses 12, the first shutter unit 101 and the second shutter unit 102 alternately repeat a light-transmitting state and a light-blocking state. For example, the first shutter unit 101 is in a light shielding state in an odd field and in a light transmitting state in an even field. On the other hand, the second shutter unit 102 is in a light-transmitting state in the odd field and is in a light-shielding state in the even field.

  Such an operation in the first shutter unit 101 and the second shutter unit 102 is performed by the driving unit 103.

  FIG. 1A illustrates the voltage Vc1 supplied from the driving unit 103 to the first shutter unit 101. FIG. 1B illustrates the voltage Vc2 supplied from the driving unit 103 to the second shutter unit 102. FIG. 1C illustrates the transmittance Tr01 of the first shutter unit 101. FIG. 1D illustrates the transmittance Tr02 of the second shutter unit 102. The horizontal axis of these figures is time t.

  As illustrated in FIG. 1A, the driving unit 103 alternately supplies the first voltage V <b> 1 and the second voltage V <b> 2 to the first shutter unit 101.

  The first voltage V1 is a voltage that causes the first shutter unit 101 to be in one of a light-transmitting state and a light-blocking state in which the transmittance is lower than the transmittance in the light-transmitting state. The second voltage V2 is a voltage that causes the first shutter unit 101 to be in the other of the light transmitting state and the light shielding state.

  In the following description, it is assumed that the first voltage V1 is a voltage that causes the first shutter unit 101 to transmit light and the second voltage V2 is a voltage that causes the first shutter unit 101 to block light.

  In the first voltage periods T1 that are continuous across the second voltage period T2 that supplies the second voltage V2 among the multiple first voltage periods T1 that supply the first voltage V1, the drive unit 103 1 voltage V1 is set to the first polarity.

  That is, the drive unit 103 has a first control period TT1. In the first control period TT1, the driving unit 103 includes a plurality of continuous first and second voltage periods T2 for supplying the second voltage V2 among the plurality of first voltage periods T1 for supplying the first voltage V1. In the first voltage period T1, the first voltage V1 is set to the first polarity.

  In the first control period TT1 including the plurality of first voltage periods T1 for supplying the first voltage V1 and the second voltage period T2 for supplying the second voltage V2, the driving unit 103 has the first polarity of the first polarity. The voltage V1 is supplied to the first shutter unit 102.

  As illustrated in FIG. 1B, the driving unit 103 alternately supplies the third voltage V <b> 3 and the fourth voltage V <b> 4 to the second shutter unit 102.

  The third voltage V3 is a voltage that causes the second shutter unit 102 to be in one of a light-transmitting state and a light-blocking state in which the transmittance is lower than the transmittance in the light-transmitting state. The fourth voltage V4 is a voltage that causes the second shutter unit 102 to be in the other of the light transmitting state and the light shielding state.

  In the following description, it is assumed that the third voltage V3 is a voltage that causes the second shutter unit 102 to transmit light, and the fourth voltage V4 is a voltage that causes the second shutter unit 102 to block light.

  The drive unit 103 puts the second shutter unit 102 in a light-shielding state when the first shutter unit 101 is in a light-transmitting state. When the first shutter unit 101 is in the light shielding state, the driving unit 103 brings the second shutter unit 102 into the light transmitting state.

  For example, the drive unit 103 supplies the fourth voltage V4 to the second shutter unit 102 when the first voltage V1 is supplied to the first shutter unit 101. The drive unit 103 supplies the third voltage V3 to the second shutter unit 102 when the second voltage V2 is supplied to the first shutter unit 101.

  The value of the third voltage V3 may be the same as or different from the value of the first voltage V1. The value of the fourth voltage V4 may be the same as or different from the value of the second voltage V2.

  In the plurality of third voltage periods T3 that supply the third voltage V3, among the plurality of third voltage periods T3 that supply the fourth voltage V4, the driving unit 103 includes a plurality of continuous third voltage periods T3 that sandwich the fourth voltage period T4. The third voltage V3 is set to either the first polarity or the second polarity opposite to the first polarity.

  That is, the drive unit 103 has a third control period TT3. In the third control period TT3, the drive unit 103 includes a plurality of continuous voltage elements across the fourth voltage period T4 for supplying the fourth voltage V4 among the plurality of third voltage periods T3 for supplying the third voltage V3. In the third voltage period T3, the third voltage V3 is set to either the first polarity or the second polarity.

The drive unit 103 has a first polarity in a period (third control period TT3) including a plurality of third voltage periods T3 for supplying the third voltage V3 and a fourth voltage period T4 for supplying the fourth voltage V4. The third voltage V3 having any one of the second polarities is further supplied to the second shutter unit 102.
The third control period TT3 may be the same as or different from the first control period TT1.

  In the example shown in FIG. 1B, in the third control period TT3, the third voltage V3 has the first polarity (the same polarity as the first voltage V1). However, in the third control period TT3, the third voltage V3 may have a second polarity (opposite polarity with respect to the first voltage V1).

  The first polarity is, for example, positive polarity. In the embodiment, the first polarity may be negative. The first polarity is defined as, for example, the potential of the second transparent electrode 122a with respect to the first transparent electrode 112a. When the first polarity is positive, electrons move from the first transparent electrode 112a toward the second transparent electrode 122a. Hereinafter, the case where the first polarity is positive will be described.

The first control period TT1 and the third control period TT3 may be different periods.
The absolute values of the first voltage V1 and the third voltage V3 are greater than 0 volts (V), for example, about 1 V or more and 2 V or less in consideration of color correction of transmitted light, for example. The absolute values of the second voltage V2 and the fourth voltage V4 are, for example, about 3V to 6V.

  As shown in FIG. 1C, in this example, the transmittance Tr01 of the first shutter unit 101 becomes the first transmittance Tr1 during the first voltage period T1. The transmittance Tr01 of the first shutter unit 101 becomes the second transmittance Tr2 during the second voltage period T2. The first transmittance Tr1 is higher than the second transmittance Tr2. The first voltage period T1 corresponds to the translucent state TS. The second voltage period T2 corresponds to the light shielding state CS.

  As shown in FIG. 1D, in this example, the transmittance Tr02 of the second shutter unit 102 becomes the third transmittance Tr3 during the third voltage period T3. The transmittance Tr02 of the second shutter unit 102 becomes the fourth transmittance Tr4 during the fourth voltage period T4. The third transmittance Tr3 is higher than the fourth transmittance Tr4. The third voltage period T3 corresponds to the translucent state TS. The fourth voltage period T4 corresponds to the light shielding state CS.

  In this way, in the first shutter unit 101 and the second shutter unit 102, the light transmission state TS and the light shielding state CS are alternately repeated.

  Each length of the first to fourth voltage periods T1 to T4 is, for example, 16.6 ms. Accordingly, video corresponding to the left eye and the right eye can be provided to the left eye and the right eye in a time division manner. Thereby, a three-dimensional stereoscopic image is perceived. However, in the embodiment, each length of the first to fourth voltage periods T1 to T4 is not limited to this as long as the flickering of the video is not substantially perceived. The degree of flickering of the image also depends on the conditions for viewing the image (such as the brightness of the image and the brightness of the environment).

  For example, the lengths of the first and second voltage periods T1 and T2 (that is, the third and fourth voltage periods T3 and T4) are 30 ms or less. Further, for example, the lengths of the first and second voltage periods T1 and T2 (that is, the third and fourth voltage periods T3 and T4) are 20 ms or less, for example.

  In the shutter glasses 12 according to the embodiment, the first voltage V1 has the first polarity during the first control period TT1. In the first control period TT1 that is longer than the length of each period of the shutter operation (first and second voltage periods T1 and T2), the first shutter unit 101 is driven by the unipolar first voltage V1.

  As a result, the transmittance Tr01 (first transmittance Tr1) of the first shutter unit 101 in the plurality of first voltage periods T1 is substantially constant.

  Similarly, during the third control period TT3, the third voltage V3 has the first polarity. In the third control period TT3 that is longer than the length of each period of the shutter operation (third and fourth voltage periods T3 and T4), the second shutter unit 102 is driven by the unipolar third voltage V3.

  Accordingly, the transmittance Tr02 (third transmittance Tr3) of the second shutter unit 102 in the plurality of third voltage periods T3 is substantially constant.

  Thereby, for example, flicker is suppressed. By suppressing the flicker, it becomes easy to see. And there is little fatigue. Thus, according to the embodiment, easy-to-see shutter glasses are provided.

  FIG. 6A to FIG. 6D are schematic views illustrating the operation of the shutter glasses of the reference example. The configuration of the first shutter unit 101 and the second shutter unit 102 in the shutter glasses 12x of the reference example is the same as the configuration of the first shutter unit 101 and the second shutter unit 102 in the shutter glasses 12 according to the embodiment. In the shutter glasses 12x, the operation of the drive unit 103 is different from the operation of the drive unit 103 of the shutter glasses 12.

  FIG. 6A illustrates the voltage Vc1 supplied from the driving unit 103 to the first shutter unit 101. FIG. 6B illustrates the voltage Vc2 supplied from the driving unit 103 to the second shutter unit 102. FIG. 6C illustrates the transmittance Tr01 of the first shutter unit 101. FIG. 6D illustrates the transmittance Tr02 of the second shutter unit 102. The horizontal axis of these figures is time t.

  As illustrated in FIG. 6A, in the reference example, the driving unit 103 changes the polarity of the first voltage V1 in a plurality of first voltage periods T1 that are continuous with the second voltage period T2 interposed therebetween. In addition, the drive unit 103 changes the polarity of the second voltage V2 in a plurality of second voltage periods T2 that are continuous across the first voltage period T1.

  Similarly, as illustrated in FIG. 6B, in the reference example, the driving unit 103 changes the polarity of the third voltage V3 in a plurality of third voltage periods T3 that are continuous across the fourth voltage period T4. change. In addition, the drive unit 103 changes the polarity of the fourth voltage V4 in a plurality of fourth voltage periods T4 that are continuous across the third voltage period T3.

  As described above, in the shutter glasses 12x of the reference example, voltages in which positive and negative are alternately repeated are used as the first voltage V1 to the fourth voltage V4.

  According to the inventors' experiment, it has been found that flicker is likely to occur when such a voltage that alternates between positive and negative is used.

  That is, as illustrated in FIG. 6C, for example, the transmittance Tr01 when the positive first voltage V1 is applied is lower than the transmittance Tr01 when the negative first voltage V1 is applied. . That is, the translucent state TS changes alternately in two states, a state where the transmittance is high and a state where the transmittance is low. The period of change of the transmittance Tr01 is, for example, twice the first voltage period T1.

  As illustrated in FIG. 6D, for example, the transmittance Tr02 when the positive third voltage V3 is applied is lower than the transmittance Tr02 when the negative third voltage V3 is applied. The period of change of the transmittance Tr02 is, for example, twice the third voltage period T3.

  Since the transmittance Tr01 and the transmittance Tr02 change in a long cycle (twice the first voltage period T1 and the third voltage period T3), flicker is perceived.

  Thus, it has not been pointed out in the past that flicker occurs in shutter glasses when a voltage that alternates between positive and negative is used. That is, this problem was found by the inventors' experiment.

  In general, when a liquid crystal is used for a display or the like, “burn-in” occurs when driven using a unipolar voltage. For example, when a second image having a content different from the first image is displayed on the display after the first image is displayed for a long time, for example, the content of the first image remains light. In order to suppress the occurrence of such “burn-in”, a bipolar voltage that alternately repeats positive and negative is used in the display. However, even when a bipolar voltage is used, “burn-in” may not be completely eliminated due to the bias of ions existing in the liquid crystal layer.

  When ions or the like are present in the liquid crystal layer, the optical response with respect to the first polarity may be different from the optical response with respect to the second polarity.

  Focusing on one pixel in the display, flicker is considered to occur if the optical response differs depending on the polarity. However, even if flicker occurs in one pixel, for example, by alternately changing the polarity of the voltage applied to a plurality of signal lines in the display, the flicker as a whole of the screen is suppressed. It doesn't matter.

  On the other hand, in the shutter glasses, the first shutter unit 101 and the second shutter unit 102 each have one switching unit (corresponding to one pixel in the display). For this reason, the fact that the optical response varies depending on the polarity is directly linked to flicker. This problem has been found for the first time by the inventors' investigation.

  According to the inventor's study, in shutter glasses, the optical response differs depending on the polarity and flicker occurs, for example, related to ions in the liquid crystal layer. For example, flicker tends to improve by reducing the amount of ions. However, in the case of using a bipolar voltage, it is difficult to make flicker virtually unnoticeable in consideration of productivity.

  In the embodiment, a unipolar voltage is used as the applied voltage. As a result, the optical response varies depending on the polarity, and flicker is not substantially generated.

  That is, in the reference example using the voltage that alternately repeats positive and negative, the light transmission state TS alternately changes in two states, a high transmittance state and a low state, and thus flicker occurs. On the other hand, in the embodiment using a unipolar voltage, the translucent state TS is only in one of a high transmittance state and a low state, and the translucent state TS is constant. Thereby, flicker is suppressed.

  As shown in FIGS. 1A and 1B, in this example, the second voltage V2 and the fourth voltage V4 corresponding to the light shielding state CS are in the first control period TT1 and the third control period TT3. Is unipolar.

  In this example, in the first control period TT1, the second voltage V2 has a first polarity. However, the embodiment is not limited to this. That is, in the first control period TT1, the second voltage V2 may have a second polarity opposite to the first polarity.

  However, the embodiment is not limited to this. As will be described later, the second voltage V2 and the fourth voltage V4 corresponding to the light shielding state CS may be bipolar.

  In the embodiment, it is effective that the voltage to be unipolar is a voltage corresponding to the translucent state TS. That is, when the drive unit 103 is supplying the first voltage V1 to the first shutter unit 101, the first shutter unit 101 is in the translucent state TS. This effectively suppresses flicker. Further, the voltage corresponding to the light shielding state CS may be unipolar.

  As shown in FIG. 1A, the polarity of the first voltage V1 can be reversed after the first control period TT1.

  That is, the driving unit 103 continues after the first control period TT1 across the second voltage period T2 for supplying the second voltage V2 among the plurality of first voltage periods T1 for supplying the first voltage V1. The plurality of first voltage periods T1 includes a second control period TT2 for setting the first voltage V1 to a second polarity opposite to the first polarity.

  That is, the drive unit 103 includes a plurality of first voltage periods T1 for supplying the first voltage V1 and a second voltage period T2 for supplying the second voltage V2 after the first control period TT1. In the control period TT2, the first voltage V1 having the second polarity opposite to the first polarity is supplied to the first shutter unit 101.

  Accordingly, a unipolar voltage is not applied to the first liquid crystal layer 130a for an excessively long time. Thereby, for example, reliability is improved.

  At this time, as illustrated in FIG. 1C, the transmittance Tr01 in the second control period TT2 changes from the transmittance Tr01 in the first control period TT1, but the first control period TT1 and the second control period TT2 However, it is practically not a problem.

  Similarly, as shown in FIG. 1B, the polarity of the third voltage V3 can be reversed after the third control period TT3.

  That is, the drive unit 103 continues after the third control period TT3 with a fourth voltage period T4 supplying the fourth voltage V4 among the plurality of third voltage periods T3 supplying the third voltage V3. The plurality of third voltage periods T3 includes a fourth control period TT4 in which the third voltage V3 is set to a second polarity opposite to the first polarity.

That is, the driving unit 103 includes a plurality of third voltage periods T3 for supplying the third voltage V3 and a fourth voltage period T4 for supplying the fourth voltage V4 after the third control period TT3. In the control period TT4, the third voltage V3 having the second polarity opposite to the first polarity is supplied to the second shutter unit 102.
The fourth control period TT4 may be the same as or different from the second control period TT2.

  The length of the period during which the first voltage V1 is unipolar (first control period TT1) is equal to or longer than the time during which no flicker is felt. The length of the first control period TT1 is, for example, 10 seconds or longer.

  When the polarity of the first voltage V1 is changed, the transmittance Tr1 in the first voltage period T1 changes. If the change interval of the transmittance Tr1 is less than 10 seconds, flickering is perceived, which may cause a problem in practice. When the length of the first control period TT1 is 10 seconds or longer, a change in the transmittance Tr1 becomes difficult to perceive.

  The first control period TT1 can be a time from when the power is turned on to when it is turned off. The time for which the shutter glasses 12 are continuously used is, for example, a time for viewing a three-dimensional image, and is several hours or less. By setting the time from when the power is turned on to when it is turned off, the drive control is simplified, and the circuit included in the drive unit 103 is simplified.

  Thus, the first control period TT1 can be a period from when the drive unit 103 is turned on to when the drive unit is turned off.

  Then, the polarity of the first voltage V1 (and the third voltage V3) can be reversed when the next on state is entered.

  That is, the first control period TT1 is a period from when the drive unit 103 is turned on to when the drive unit 103 is turned off. Then, after the first control period TT1, the driving unit 103 includes the first voltage period T1 that supplies the first voltage V1 when the driving unit 103 is in another ON state. A plurality of first voltage periods T1 that are continuous across a second voltage period T2 for supplying two voltages V2 have a second control period TT2 for setting the first voltage V1 to a second polarity opposite to the first polarity. .

FIG. 7A to FIG. 7D are schematic views illustrating the operation of another shutter glasses according to the first embodiment.
In the shutter glasses 12a according to the embodiment, the operation of the drive unit 103 is different from the operation of the drive unit 103 of the shutter glasses 12.

  FIG. 7A illustrates the voltage Vc1 supplied from the driving unit 103 to the first shutter unit 101 in the shutter glasses 12a. FIG. 7B illustrates the voltage Vc2 supplied from the driving unit 103 to the second shutter unit 102. FIG. 7C illustrates the transmittance Tr01 of the first shutter unit 101. FIG. 7D illustrates the transmittance Tr02 of the second shutter unit 102. The horizontal axis of these figures is time t. In these figures, the first control period TT1 is illustrated.

  As shown in FIG. 7A, in the shutter glasses 12a, the first voltage V1 is unipolar, but the second voltage V2 is bipolar. As shown in FIG. 7B, the third voltage V3 is unipolar, but the fourth voltage V4 is bipolar.

  That is, in the first control period TT1, the driving unit 103 includes a plurality of continuous voltage elements across the first voltage period T1 for supplying the first voltage V1 among the plurality of second voltage periods T2 for supplying the second voltage V2. In the second voltage period T2, the polarity of the second voltage V2 is changed.

  In the third control period TT3, the driving unit 103 includes a plurality of fourth voltage periods T4 that supply the fourth voltage V4 and a plurality of continuous second voltage periods T3 that supply the third voltage V3. In the four voltage period T2, the polarity of the fourth voltage V4 is changed.

That is, the polarities of the second voltage V2 and the fourth voltage V4 corresponding to the light shielding state CS alternately repeat positive and negative. In this case, strictly speaking, the optical response may change in a period twice as long as the second voltage period T2 (a period twice as long as the fourth voltage period T4). Flicker is not perceived.
Even in such a configuration, easy-to-see shutter glasses can be provided.

  Thus, in the embodiment, in the first control period TT1, the first voltage V1 corresponding to the translucent state TS is unipolar. In the third control period TT3, the third voltage V3 corresponding to the translucent state TS is unipolar.

  It is desirable that the effective value of the first voltage V1 driven with a single polarity is smaller than the effective value of the second voltage V2. For example, the influence on the reliability can be reduced by setting the first voltage V1 having a small effective value to be unipolar and the second voltage V2 having a large effective value to be bipolar. For example, the first voltage V1 having a small effective value may be unipolar, and the second voltage V2 having a large effective value may be unipolar. Thereby, the circuit configuration of the drive unit 103 is simplified.

FIG. 8A and FIG. 8B are schematic views illustrating the operation of another shutter glasses according to the first embodiment.
In the shutter glasses 12b according to the embodiment, the operation of the drive unit 103 is different from the operation of the drive unit 103 of the shutter glasses 12.

  FIG. 8A illustrates the voltage Vc1 supplied from the drive unit 103 to the first shutter unit 101 in the shutter glasses 12b. FIG. 8B illustrates the voltage Vc2 supplied from the driving unit 103 to the second shutter unit 102.

  As shown in FIG. 8A, a voltage (reverse polarity voltage Vr1) opposite to the polarity of the first voltage V1 is applied after the first control period TT1. That is, the driving unit 103 supplies the first shutter unit 101 with the reverse polarity voltage Vr1 having the second polarity opposite to the first polarity after the first control period TT1.

  In the first control period TT1, since the first voltage V1 is unipolar, charges based on the first voltage V1 are accumulated in the first liquid crystal layer 130a. If the charge accumulation time is excessively long, reliability may be adversely affected. On the other hand, in the shutter glasses 12b, the reverse polarity voltage Vr1 having the second polarity opposite to the first voltage V1 is applied after the first control period TT1 having a predetermined length. Thereby, reliability is improved.

  Similarly, as illustrated in FIG. 8B, the driving unit 103 supplies the second shutter unit 102 with the reverse polarity voltage Vr2 opposite to the polarity of the third voltage V3 after the third control period TT3. . Thereby, reliability is improved.

FIG. 9 is a schematic perspective view illustrating the configuration of another shutter glasses according to the first embodiment.
In FIG. 9, the drive unit 103 is omitted. As illustrated in FIG. 9, another shutter glasses 12 c according to the embodiment includes the first shutter unit 101 and the second shutter unit 102 in addition to the first shutter unit 101, the second shutter unit 102, and the drive unit 103. A connection part 355 to be connected, a left support part 351 for the left ear, and a right support part 352 for the right ear can be further provided. The left support part 351 has a left ear hook part 353, and the right support part 352 has a right ear hook part 354.

  For example, the first shutter unit 101 is arranged corresponding to the left eye, and the second shutter unit 102 is arranged corresponding to the right eye. The arrangement of the first shutter unit 101 and the second shutter unit 102 may be reversed.

  Further, the third substrate unit 110b of the second shutter unit 102 is disposed on the first substrate unit 110a side of the first shutter unit 101, but the fourth substrate unit 120b is disposed on the first substrate unit 110a side. May be.

  In this specific example, the second substrate portion 120a is disposed closer to the left ear hook portion 353 than the first substrate portion 110a, and the fourth substrate portion 120b is disposed closer to the right ear hook portion 354 than the third substrate portion 110b. Arranged on the side. The first substrate portion 110a is disposed on the left ear hook portion 353 side with respect to the second substrate portion 120a, and the third substrate portion 110b is disposed on the right ear hook portion 354 side with respect to the fourth substrate portion 120b. Also good.

FIG. 10 is a schematic perspective view illustrating the configuration of another shutter glasses according to the first embodiment.
In FIG. 10, the drive unit 103 is omitted. As illustrated in FIG. 10, another shutter glasses 12 d according to the embodiment also includes a first shutter unit 101 and a second shutter unit 102. In this example, the first substrate portion 110a and the third substrate portion 110b are provided on the same support substrate 411, and the second substrate portion 120a and the fourth substrate portion 120b are provided on the same separate support substrate 421. Yes.

  That is, the first transparent electrode 112 a is provided on a part of the support substrate 411. The third transparent electrode 112b is provided on another part of the support substrate 411 in parallel with the first transparent electrode 112a. The portion where the first transparent electrode 112a is provided becomes the first substrate portion 110a. The portion where the third transparent electrode 112b is provided becomes the third substrate portion 110b.

  Similarly, the second transparent electrode 122a is provided on a part of another support substrate 421. A fourth transparent electrode 122b is provided on another part of the support substrate 421 in parallel with the second transparent electrode 122a. The portion where the second transparent electrode 122a is provided becomes the second substrate portion 120a, and the portion where the fourth transparent electrode 122b is provided becomes the fourth substrate portion 120b.

  Thus, the 1st shutter part 101 and the 2nd shutter part 102 may be provided integrally.

  The first substrate unit 110a and the second substrate unit 120a can be interchanged. The third substrate unit 110b and the fourth substrate unit 120b can be interchanged.

  As described above, the shutter glasses according to the embodiment include the first shutter unit 101, the second shutter unit 102, the driving unit 103, and the mounting unit 360 (for example, the left support unit 351 and the right support unit 352). be able to. The mounting unit 360 is connected to at least one of the first shutter unit 101 and the second shutter unit 102 and is mounted on the user's head, and the first shutter unit 101 and the second shutter unit 102 are connected to the user's head. To fix. Note that the mounting portion 360 may have a belt shape, and the liquid crystal shutter may have a goggle shape.

  In the embodiment, the first shutter unit 101 and the second shutter unit 102 desirably use an OCB mode to which a π cell is applied. Thereby, a high-speed response is obtained. In addition, since a nematic liquid crystal is used, the reliability is high.

  In the present embodiment, the display 13 is optional. As the display 13, for example, an active matrix type liquid crystal display that operates in the OCB mode is used. As the display 13, any display having high-speed response can be used. For example, an organic EL display or a plasma display may be used as the display 13.

(Second Embodiment)
In the present embodiment, the first substrate portion 110a having the first transparent electrode 112a, the second substrate portion 120a having the second transparent electrode 122a facing the first transparent electrode 112a, the first transparent electrode 112a, and the second transparent electrode. This is a driving method of shutter glasses including a first shutter unit 101 including a first liquid crystal layer 130a provided between the electrodes 122a.

  In the present driving method, the first voltage V1 that causes the first shutter unit 101 to be in one of the light-transmitting state TS and the light-shielding state CS whose transmittance is lower than the transmittance of the light-transmitting state TS, Including alternately supplying the first shutter unit 101 with a second voltage V2 that causes the shutter unit 101 to be in the other of the light-transmitting state TS and the light-shielding state CS.

In this driving method, the first polarity of the first polarity in the first control period TT1 including the plurality of first voltage periods T1 for supplying the first voltage V1 and the second voltage period T2 for supplying the second voltage V2. The voltage V1 is supplied to the first shutter unit 101.
Thereby, shutter glasses can be driven easily.

  According to the embodiment, easy-to-see shutter glasses and a driving method thereof are provided.

  The embodiments of the present invention have been described above with reference to specific examples. However, embodiments of the present invention are not limited to these specific examples. For example, a specific configuration of each element such as a substrate unit, a transparent electrode, a support substrate, an alignment film, a liquid crystal layer, and a driving unit included in the shutter glasses is appropriately selected from a known range by those skilled in the art. Are included in the scope of the present invention as long as they can be carried out in the same manner and the same effects can be obtained.

  Moreover, what combined any two or more elements of each specific example in the technically possible range is also included in the scope of the present invention as long as the gist of the present invention is included.

  In addition, all shutter glasses and driving methods that can be implemented by those skilled in the art based on the shutter glasses and driving methods described above as embodiments of the present invention are included in the gist of the present invention. As long as it belongs to the scope of the present invention.

  In addition, in the category of the idea of the present invention, those skilled in the art can conceive of various changes and modifications, and it is understood that these changes and modifications also belong to the scope of the present invention. .

  Although several embodiments of the present invention have been described, these embodiments are presented by way of example and are not intended to limit the scope of the invention. These novel embodiments can be implemented in various other forms, and various omissions, replacements, and changes can be made without departing from the scope of the invention. These embodiments and modifications thereof are included in the scope and gist of the invention, and are included in the invention described in the claims and the equivalents thereof.

  DESCRIPTION OF SYMBOLS 11 ... Display system 12, 12a, 12b, 12c, 12d, 12x ... Shutter glasses, 13 ... Display, 13d ... Display surface, 14 ... Control part, 101 ... 1st shutter part, 102 ... 2nd shutter part, 103 ... Drive unit 110a ... first substrate unit 110b ... third substrate unit 111a ... first support substrate 112a ... first transparent electrode 112b ... third transparent electrode 113a ... first alignment film 120a ... second substrate Part, 120b ... fourth substrate part, 121a ... second support substrate, 122a ... second transparent electrode, 122b ... fourth transparent electrode, 123a ... second alignment film, 130a ... first liquid crystal layer, 130b ... second liquid crystal layer , 130l ... liquid crystal molecule, 140a ... first optical compensation plate, 150a ... second optical compensation plate, 160a ... first polarizing plate, 170a ... second polarizing plate, 180a ... first seal portion, 351 ... left support portion, 352 ... right support portion, 353 ... left ear hook portion, 354 ... right ear hook portion, 355 ... connecting portion, 360 ... mounting portion, 411, 421 ... support substrate, CS: light shielding state, T1 to T4: first to fourth voltage periods, TS: light transmitting state, TT1 to TT4: first to fourth control periods, Tr01, Tr02: transmittance, Tr1 to Tr4: transmittance, V1 ˜V4, first to fourth voltages, V11, V12, first and second initial voltages, VB1, VB2, first, second bend voltages, Vc1, Vc2, voltages, Vr1, Vr2, reverse polarity voltages, t, time

Claims (10)

A first substrate portion having a first transparent electrode;
A second substrate portion having a second transparent electrode facing the first transparent electrode;
A first liquid crystal layer provided between the first transparent electrode and the second transparent electrode;
A first shutter unit including:
A driving unit for supplying a voltage to the first shutter unit;
With
The drive unit is
A first voltage that causes the first shutter unit to be in one of a light-transmitting state and a light-blocking state in which the transmittance is lower than the transmittance in the light-transmitting state;
A second voltage that causes the first shutter unit to be in the other of the light-transmitting state and the light-blocking state;
Alternately to the first shutter unit,
The driving unit includes a plurality of first voltage periods that are continuous with respect to a second voltage period that supplies the second voltage among a plurality of first voltage periods that supply the first voltage. A shutter glasses having a first control period for setting a voltage to a first polarity.   2. The shutter glasses according to claim 1, wherein the first shutter unit is in the translucent state when the driving unit supplies the first voltage to the first shutter unit.   The shutter glasses according to claim 1 or 2, wherein the length of the first control period is 10 seconds or more. After the first control period, the driving unit
Among the plurality of first voltage periods for supplying the first voltage, in the plurality of first voltage periods continuous across the second voltage period for supplying the second voltage, the first voltage is changed to the first voltage period. The shutter glasses according to any one of claims 1 to 3, further comprising a second control period set to a second polarity opposite to the polarity.   5. The shutter glasses according to claim 1, wherein the first control period is a period from when the driving unit is turned on to when the precursor driving unit is turned off. . The first control period is a period from when the driving unit is turned on until the precursor driving unit is turned off,
When the driving unit is in another ON state after the first control period, the driving unit outputs the second voltage among a plurality of first voltage periods for supplying the first voltage. A plurality of first voltage periods that are continuous across the second voltage period to be supplied have a second control period in which the first voltage is set to a second polarity opposite to the first polarity. The shutter glasses according to any one of claims 1 to 5.   The said drive part supplies the reverse polarity voltage of the 2nd polarity opposite to the said 1st polarity to the said 1st shutter part after the said 1st control period. The shutter glasses according to one. The liquid crystal alignment of the first liquid crystal layer is a splay alignment when a potential difference between the first transparent electrode and the second transparent electrode is set to a first initial voltage, and the first potential difference is the first potential difference. When the second initial voltage having a larger effective value than the initial voltage is set, the bend arrangement is transferred,
The translucent state of the first shutter unit is a first bend arrangement state of one of the bend arrangements, and the light shielding state of the first shutter unit is the first bend arrangement state of the bend arrangements. The shutter glasses according to any one of claims 1 to 7, wherein the second bend arrangement state is different from that of the shutter glasses. A second shutter unit juxtaposed with the first shutter unit;
The second shutter unit is
A third substrate portion having a third transparent electrode;
A fourth substrate portion having a fourth transparent electrode facing the third transparent electrode;
A second liquid crystal layer provided between the third transparent electrode and the fourth transparent electrode;
Including
The drive unit is
A third voltage that causes the second shutter portion to be in one of a light-transmitting state and a light-shielding state in which the transmittance is lower than the transmittance in the light-transmitting state;
A fourth voltage for causing the second shutter portion to be either the light-transmitting state or the light-shielding state;
Alternately to the second shutter unit,
The drive unit is
When the first shutter portion is in the translucent state, the second shutter portion is in the light shielding state,
When the first shutter portion is in the light shielding state, the second shutter portion is in the light transmitting state,
The drive unit includes the third voltage period in the plurality of third voltage periods that supply the third voltage, and the third voltage period that is continuous across the fourth voltage period that supplies the fourth voltage. The shutter glasses according to any one of claims 1 to 8, wherein the voltage is set to one of a first polarity and a second polarity opposite to the first polarity. A first substrate portion having a first transparent electrode;
A second substrate portion having a second transparent electrode facing the first transparent electrode;
A first liquid crystal layer provided between the first transparent electrode and the second transparent electrode;
A method for driving shutter glasses including a first shutter unit including:
A first voltage that causes the first shutter unit to be in one of a light-transmitting state and a light-blocking state in which the transmittance is lower than the transmittance in the light-transmitting state;
A second voltage that causes the first shutter unit to be in the other of the light-transmitting state and the light-blocking state;
Alternately to the first shutter unit,
In a first control period including a plurality of first voltage periods for supplying the first voltage and a second voltage period for supplying the second voltage, the first voltage of the first polarity is supplied to the first shutter unit. A method for driving shutter glasses, characterized by comprising:

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