JPH1198538A - Drive unit of liquid crystal shutter eyeglass - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide the drive unit of liquid crystal shutter eyeglasses by which the shutter operation is maintained even when a signal denoting a shutter timing in the liquid crystal shutter eyeglasses is shut off. SOLUTION: An infrared ray receiving module 1 receives an infrared ray signal generated based on a signal denoting switchover of left/right eye videos (sent from an image display device not shown in the figure). An input signal type automatic discrimination section 3 and a field frequency detection and LR discrimination section 6 acquire data relating to a shutter timing of a left eye liquid crystal display device 13 and a right eye liquid crystal display device 14 in the liquid crystal shutter eyeglasses from the received infrared ray signal. An operating field frequency decision section 7 generates and holds decision data relating to a shutter timing to be given to the liquid crystal shutter eyeglasses based on a prescribed condition from data relating to the shutter timing obtained newly and sequentially. A liquid crystal drive pulse generating section 8 uses the held decision data to apply shutter operation to the liquid crystal shutter eyeglasses in the case that the decision data are not generated because the prescribed condition is not satisfied.

Description

DETAILED DESCRIPTION OF THE INVENTION

[0001]

BACKGROUND OF THE INVENTION In a liquid crystal shutter glasses worn by an observer, a right-eye image and a left-eye image are alternately displayed on a screen at a constant period. There is known a three-dimensional image display system in which transmission and non-transmission are alternately performed between a liquid crystal for use and a left-eye liquid crystal, and an observer performs stereoscopic viewing. The present invention relates to a driving device for driving the liquid crystal shutter glasses.

[0002]

2. Description of the Related Art Right-eye image (R) on a stereoscopic image display device side
There is a technique using an infrared signal to notify the liquid crystal shutter glasses of the switching between the left and right eye images (L).

[0003]

However, when a person passes between the three-dimensional image display device and the observer, the infrared signal may be blocked for several seconds. In such a case, the liquid crystal shutter glasses stop in the transmissive state of the right-eye image (R) or the transmissive state of the left-eye image (L), fall into a state in which stereoscopic viewing is impossible, and there is a problem that the screen flickers. .

[0004] Conventional liquid crystal shutter glasses support only the right-eye image (R) and the left-eye image (L) when the switching timing (field frequency) is 120 Hz, or at 60 Hz. If there is, it is not possible to cope with a plurality of frequencies, such as coping with only that frequency. That is, it cannot be applied to various stereoscopic image display devices having different field frequencies.

[0005] Conventionally, liquid crystal shutter glasses use liquid crystal which becomes opaque when a predetermined negative voltage and a predetermined positive voltage are applied, and becomes transparent when a 0 volt voltage is applied. However, since the response speed when a voltage of 0 volt is applied from the non-transmissive state to the transmissive state is slow, as shown in FIG. 16, a sufficient transmissive state is not obtained even after the vertical blanking period. ,
This causes a problem that the upper portion of the screen appears dark.

In view of the above circumstances, an object of the present invention is to provide a driving device for liquid crystal shutter glasses that can maintain a shutter operation even when a signal indicating shutter timing in the liquid crystal shutter glasses is interrupted. Another object is to support various stereoscopic image display devices having different field frequencies. It is also an object of the present invention to solve the problem that the upper part of the screen becomes dark and the crosstalk increases.

[0007]

A driving device for liquid crystal shutter glasses according to the present invention includes: a receiving section for receiving a spatial transmission signal generated based on a signal indicating switching between left and right eye images; Means for acquiring data relating to shutter timing in the liquid crystal shutter glasses, means for causing the liquid crystal shutter glasses to perform a shutter operation using the acquired data relating to the shutter timing,
It is characterized by having.

According to the above arrangement, the spatial transmission signal is generated based on a signal indicating switching between left and right eye images, and the liquid crystal shutter glasses acquires data on shutter timing in the liquid crystal shutter glasses from the spatial transmission signal. Then, the shutter shutter operation of the liquid crystal shutter glasses is performed. That is, if the switching frequency of the left and right eye images changes, the spatial transmission signal changes accordingly, and the change can be acquired by the liquid crystal shutter glasses. Therefore, it is possible to cope with various stereoscopic image display devices having different field frequencies.

Further, a driving device for liquid crystal shutter glasses according to the present invention includes a receiving unit for receiving a spatial transmission signal generated based on a signal indicating switching between left and right eye images, and a liquid crystal shutter glasses based on the received spatial transmission signal. Means for acquiring data relating to the shutter timing, means for retaining the acquired data relating to the shutter timing, and shutter operation of the liquid crystal shutter glasses using the retained data relating to the shutter timing under predetermined conditions. Means.

According to the above arrangement, even if the data relating to the shutter timing in the liquid crystal shutter glasses cannot be generated because the spatial transmission signal is blocked, the liquid crystal shutter is held using the held data relating to the shutter timing. Since the shutter operation of the glasses can be continued (self-propelled), it is possible to eliminate a problem such as a screen flicker when a signal is cut off.

Further, a driving device for liquid crystal shutter glasses according to the present invention includes: a receiving section for receiving a spatial transmission signal generated based on a signal indicating switching between left and right eye images; Means for acquiring data relating to shutter timing, means for generating and holding decision data relating to shutter timing to be given to the liquid crystal shutter glasses based on predetermined conditions from data relating to shutter timing newly newly acquired, and Means for allowing the liquid crystal shutter glasses to perform a shutter operation using the held decision data when the decision data is not generated because the condition is not satisfied.

In the above configuration, predetermined processing is executed in each of the three states of the field frequency indeterminate state, the field frequency fixed state, and the field frequency maintaining state, and a transition is made to another state according to the execution result. The field frequency uncertain state is a state in which the shutter operation is stopped, determines whether a predetermined condition is satisfied, and generates the determination data when the predetermined condition is satisfied. The field frequency determination state is a state in which the shutter operation is performed based on the determination data sequentially determined, and the determination data is determined when a predetermined condition is satisfied. Is generated and held, and when a predetermined condition is not satisfied, the state transits to the field frequency maintaining state. The field frequency maintenance state is a state in which the shutter operation is continued based on the held decision data.If a predetermined condition is satisfied, the state transits to the field frequency fixed state, and the predetermined condition is not satisfied. When the continuation of the shutter operation has been performed for a predetermined time, the state may advance to the field frequency uncertain state.

With this configuration, when the shutter timing obtained from the spatial transmission signal satisfies a predetermined condition, the field frequency is determined and the shutter operation is performed based on the sequentially determined data. . If the signal is interrupted for some reason in such a state, the state transits to the field frequency maintaining state. In this state, if the shutter timing again satisfies the predetermined condition, the state transits to the field frequency fixed state. If the timing does not satisfy the predetermined condition (if the condition where the signal is interrupted continues, the condition will not be satisfied), the shutter operation is continued based on the held decision data, during which the shutter timing is If the predetermined condition is satisfied, the state transits to the field frequency defined state. If the continuous state continues for a predetermined time, the state transits to the field frequency undefined state, and the shutter operation of the liquid crystal shutter glasses is stopped.

Further, the driving device for liquid crystal shutter glasses according to the present invention uses a liquid crystal which becomes opaque when a predetermined negative voltage and a predetermined positive voltage are applied, and becomes transparent when a 0 volt voltage is applied. A driving device for liquid crystal shutter glasses, which receives a spatial transmission signal generated based on a signal indicating switching between left and right eye images, and obtains data regarding shutter timing in the liquid crystal shutter glasses from the received spatial transmission signal. And applying the 0 volt voltage application timing by a preset time in consideration of the time required for the liquid crystal to be sufficiently transmitted, using the data on the obtained shutter timing and the obtained shutter timing data. Means for causing the shutter glasses to perform a shutter operation.

With the above configuration, when a 0 volt voltage is applied (when the liquid crystal is made to be in a transmission state), the timing is accelerated. Therefore, even if the response speed when the liquid crystal becomes in a transmission state is low, By the time the vertical blanking period ends, a sufficient transmission state can be achieved, and the problem that the upper part of the screen appears dark can be eliminated.

[0016]

BEST MODE FOR CARRYING OUT THE INVENTION

(Embodiment 1) Embodiments of the present invention will be described below with reference to the drawings.

FIG. 1 is a circuit diagram showing an infrared LED drive pulse generator 101 in an infrared signal transmission device provided in a stereoscopic video display device. FIG. 2 is a timing chart showing various signals in the infrared LED drive pulse generator 101. FIG. 3 is a circuit diagram showing a configuration in which the system LSI 200 including the infrared LED drive pulse generation unit 101 is used, and the infrared light emitting LED 33 is driven by the infrared LED drive pulse from the system LSI 200. .

In FIG. 1, a 4-bit counter 21
A 1.8 MHz clock from a clock generator (not shown) is input to the clock (CLK) terminal, and every time 16 pulses of this clock are input, one pulse is output from the carry-out (C0) terminal. Output. That is, the 1.8 MHz clock is divided by 16. Further, when a High signal is input to a reset (RST) input unit, the reset is performed.

The divide-by-2 circuit 21 has its enable (E
N) The carry-out (C0) signal from the 4-bit counter 21 is input to the terminal unit. Clock (CLK)
The 1.8 MHz clock is supplied to the terminal section. The data (D) terminal portion is supplied with a signal from the Q bar output terminal. Each time a pulse of the carry-out (C0) signal is input, the divide-by-2 circuit 21 outputs a Hi signal at the Q output terminal.
The gh signal and the Low signal are output alternately. This output signal becomes 56 KHz and is used as a carrier (sub-carrier). Further, when a High signal is input to a reset (RST) input unit, the reset is performed.

The edge detector 23 outputs the clock (CL
K) The 1.8 MHz clock is input to the terminal section. Then, an LR polarity switching signal (a signal indicating switching between left and right eye images) corresponding to the L and R video signals is input. As shown in FIG. 2A, the LR polarity switching signal is a signal that alternately forms High and Low at regular intervals, and for example, indicates that High is in the right-eye image display state. Low indicates that the left eye image is displayed. As shown in FIG. 2 (i), the edge detecting unit 23 is 1.8 when the LR polarity switching signal is High.
The reset signal (High) is output when the first pulse of the MHz clock is input. This reset signal is supplied to the 4-bit counter 21, the frequency-dividing circuit 21, and a 9-bit counter 26 described later.

The 9-bit counter 26 has, at its enable (EN) terminal section, a logical product of a value obtained by inverting the carry-out (C0) signal by the inverter 25 and the 16-divided value by the AND circuit 24. input. The clock (C
LK) The 1.8 MHz clock is input to the terminal section. Then, a count value (9-bit signal) corresponding to the divide-by-16 value is output from the Q terminal. More specifically, as shown in (e), (f), (g), and (i) of FIG. 2, after the reset by the edge detection, a period from when the first High in the divide-by-16 output is output is output. The period is counted as the count value “0”, the period until the next High is output is the count value “1”, and the period until the next High is output is the count value “2”. When the count value reaches 511, the counting is stopped. Further, when a High signal is input to a reset (RST) input unit, the reset is performed. In addition,
The reason why the 9-bit count is used is that the generation of a gate signal to be described later is completed before 512 counts, and the count more than that is because the circuit scale is increased, and there is no advantage. is there.

The gate signal generation circuit 27 generates a signal based on the count value output from the 9-bit counter 26.
A gate signal as shown in FIG. 2B is generated. The gate signal is a signal composed of, for example, a relatively long High period, a short High period, and a Low period therebetween, as shown in FIG. 2B, and the length of the Low period is L (left eye). Image display state) and R (right-eye image display state). The High period and the Low period are defined by the count value. Note that the clock signal input to the gate signal generation circuit 27 is the Hig in the gate signal.
It is not used for setting the h period or the like, but for timing control in an internal flip-flop or the like.

The drive pulse generation AND circuit 28 receives the carrier wave (56 KHz) and the gate signal from the gate signal generation circuit 27, takes a logical product of them, and calculates the infrared L
Generate an ED drive pulse. That is, the carrier is modulated by the gate signal.

Here, the timing deviation (jitter) of the generation of the gate signal generated based on the edge of the LR polarity switching signal depends on the deviation width of the edge detection in the edge detection circuit 23 with respect to the LR polarity switching signal.
As shown in (j) of FIG.
This corresponds to one clock of 8 MHz, and the jitter is extremely small. In addition, when observing a large screen image or an image of a plurality of image display devices by a plurality of people, a plurality of infrared signal transmitting devices may be installed, but in this case, the jitter range is large. In addition, mutual interference easily occurs in infrared signals from a plurality of infrared signal transmitting devices. Since the jitter in the above configuration is extremely small, such interference can be reduced.

As shown in the circuit diagram of FIG. 3, the infrared LED driving pulse generated by the driving pulse generating and
The light is supplied to a light emitting unit 30 composed of 3 or the like. The infrared LED
33 emits light in response to the infrared LED drive pulse and outputs an infrared signal.

Next, the driving device of the liquid crystal shutter glasses will be described. FIG. 4 is a block diagram showing a driving device of the liquid crystal shutter glasses according to the embodiment of the present invention. The portion surrounded by the dotted frame in this figure is integrated. Hereinafter, the dotted frame portion is referred to as an integrated circuit portion 102. FIG. 5 is a block diagram when a system LSI 200 including the integrated circuit unit 102 is used.

The infrared receiving module 1 includes the light emitting section 30
Receive the infrared signal output from. A jack 2 for directly receiving an LR discrimination signal (corresponding to an LR polarity switching signal) is provided to enable selection between wireless (when an infrared signal is used) and wired.

The input signal type automatic discriminating section 3 judges the type of the input signal. For example, whether the input signal based on the infrared signal is a simple signal of repeating H and L, a signal coded corresponding to L and R, or a signal obtained by further adding a carrier wave to the coded signal Judge another.

The field frequency detection / LR discriminating section 6
Based on the received infrared signal or LR determination signal, a process of detecting a field frequency and determining whether the signal is an L signal or an R signal is performed. In this discrimination, in the case of the infrared signal, a signal corresponding to the above-described gate signal is obtained by the demodulation process, so that the relatively long High signal is obtained.
The length of the Low period between the short period and the short High period is L
(Left-eye image display state) and R (right-eye image display state) can be distinguished. In a wired connection, LR discrimination can be performed immediately from the LR discrimination signal. The field frequency is represented by the number of clocks (count) counted during the LR signal period (High / Low switching period).

The operation field frequency determination unit 7 performs a process of checking a frequency (timing) in the alternate shutter operation of the liquid crystal 13 for the left eye and the liquid crystal 14 for the right eye, and a process of determining and holding. That is, the Hig of the previous LR signal
By comparing the number of clocks (the old field frequency) counted during the h period or the Low period with the number of clocks (the new field frequency) counted during the Low period or the High period of the current LR signal, frequency fluctuation and stabilization can be achieved. Check. The determination is made when the stable state continues, and when the unstable state is reached, the shutter operation is continued (self-propelled) at the held timing. The purpose is that, even when the reception of the infrared signal is interrupted for some reason, the left-eye liquid crystal 13 and the right-eye liquid crystal 1 are kept at the field frequency held for a while.
4 is to maintain the alternate shutter operation. An outline of such processing is shown by state 3, state 4, and state 5 in the state transition diagram of FIG. The specific processing in each state will be described later in detail with reference to the flowcharts in FIGS.

The liquid crystal drive pulse generator 8 determines the generation of three types of voltages (V _LCD : liquid crystal non-transmission, 0 volt: liquid crystal transmission, -V _LCD : liquid crystal non-transmission) by the analog switches 11 and 12. The analog switch 1 is controlled by the control performed at the field frequency and the timing adjustment signal.
Control for adjusting the timing of 0 volt application (liquid crystal transmission) by 1 and 12 and control of LR polarity switching are performed.

[Control] The analog switch 11,
Reference numeral 12 denotes a voltage (V ₁ ) from the power control unit 4 and a DC / D
Receiving the supply of the voltage (−V ₂ ) from the C converter 10,
V _LCD (= V ₁ + V ₂ ) (closed: non-transmissive state), 0 volt (open: transmissive state), −V _LCD (= − (V ₁ + V ₂ )) (closed: 0 volt (open: transparent state), V
_The potential difference is supplied in the order of _LCD (closed: non-transmissive state). Which one of the three types of potential differences is to be generated can be determined by a 2-bit control signal, and this control signal may be given to the analog switches 11 and 12. The liquid crystal drive pulse generator 8 has a 3-bit output terminal, one of which is common, and the other two are mutually inverted signals.
Are controlled to give a 2-bit control signal to each of them. Which liquid crystal is to be opened and the other liquid crystal is to be closed can be determined by the LR discrimination signal from the field frequency detection / LR discrimination unit 6. The timing at which the 2-bit control signal is applied is determined by the clock count, which is the field frequency determined by the operation field frequency determination unit 7. That is, clock counting is started from the time when the field frequency is determined (see the pulse counter 8b in FIG. 6), and when the clock count in this count matches the clock count, which is the field frequency in principle, The pulse generator 8b (see FIG. 6) generates the 2-bit control signal.

[Control] The period t ₁ in FIG.
This is a control for adjusting. That is, the analog switch 1
The control of timing of the 2-bit control signal to be given to 1 and 12 is performed not by the timing of the determined field frequency but by t ₁ based on the timing adjustment signal. Specifically, the period t ₂ in FIG.
, The open timing of each of the liquid crystals 13 and 14 is advanced by t ₁ while supporting the vertical synchronization by defining the above-described field frequency.
At the end of the vertical blanking, the contrast ratio is set to substantially zero. As a result, it is possible to solve the problem that the upper part of the screen of the image display device becomes dark and visible. Since the timing adjustment signal is 4 bits in this embodiment,
Such control can be performed by adjusting in 16 steps. Also, how much to speed up depends on the open response characteristics of the liquid crystal used.

[Control] In some stereoscopic image display devices, the signal indicating L and the signal indicating R may be opposite. This is a control for reversing the recognition of R and the recognition of R.

The power supply control unit 4 receives power supply from a power supply unit outside the integrated circuit unit 102 and turns on a power switch.
Then, while supplying power to each circuit in the integrated circuit unit 102, the external DC / DC converter 10
And so on. The clock control circuit 5 receives 300 KH from a clock generator (not shown).
A predetermined clock is supplied to each circuit in the integrated circuit unit 102 by controlling the clock of z. The clock control circuit 5
May include an RC oscillator (RC-oscillator) and generate a clock by itself (see FIG. 6). The timer 9 starts counting the timer when the operation field frequency determination unit 7 enters the field frequency indefinite state. When this state continues for approximately two minutes, the timer 9 issues a power stop command to the power control unit 4. It is supposed to emit.

FIG. 6 is an explanatory diagram schematically showing the internal configuration of the system LSI 200, the arrangement of pins, and the like.
This system LSI 200 is formed by forming the infrared LED drive pulse generator 101 and the integrated circuit unit 102 on one semiconductor substrate. Therefore, the system LSI 200 can be used to configure an infrared signal transmitting device and also to configure a driving device for liquid crystal shutter glasses. Therefore, mass production is possible as an LSI that can be shared by the stereoscopic video display device and the liquid crystal shutter, and cost can be reduced.

FIG. 8 is a state transition diagram for explaining the transition of the operation state of the driving device for the liquid crystal shutter glasses. Specific processing contents of states 3, 4, and 5 in this state transition diagram,
That is, the processing contents in the operation field frequency determination unit 7 will be described with reference to FIGS. 9 shows processing in the field frequency undefined state (state 3), FIG. 10 shows processing in the field frequency determined state (state 4), and FIG. 11 shows processing in the field frequency maintaining state (state 5). , Respectively.

In FIG. 9, first, a field frequency is detected, and the detected field frequency (clock count number) is set to fnow (step 1). Next, a field frequency check process is performed (step 2).
That is, it is determined whether or not the field frequency fnow detected this time is within a predetermined range (−a to a) based on the field frequency fold detected last time. If not, the check counter (chkcnt) is set to 0
(Clear) and the field frequency fno detected this time
The process returns to step 1 with w as fold. On the other hand, if it is within the range, the check counter (chkcnt) is incremented (step 3). Then, the counter value of the check counter (chkcnt) is determined (step 4). If the counter value becomes 16, it is determined that the frequency has become stable and the field frequency fnow detected this time is determined.
As ffix and fold (step 5),
The processing shifts to the processing in the state where the field frequency is determined.
This field frequency uncertain state (step 3)
In, the pulse counter 8b (see FIG. 6) of the liquid crystal drive pulse generator 8 stops counting. That is, the shutter operation is stopped in the liquid crystal shutter glasses (the shutter operation has not yet started if it is a transition from the state 2).

In FIG. 10, first, a field frequency is detected, and the detected field frequency (clock count number) is set to fnow (step 11). Next, the field frequency fnow detected this time is set to a predetermined range (−a) based on the determined field frequency ffix.
(A) is determined (step 12).
If the result of this check is YES, a new ffix is generated by slightly reflecting the current field frequency fnow (step 14), and the process returns to step 11. on the other hand,
If the determination is NO, the field frequency fnow detected this time is set to fold (step 13), and the state shifts to the field frequency maintaining state.

When the process proceeds to step 14, a reset signal is output to the pulse counter 8b of the liquid crystal drive pulse generator 8, so that the determination in step 15 is YES and the counter value is cleared. Go (step 18) and proceed to step 15. Step 1
When NO is determined in step 5, the counter value is ffix + a
It is determined whether or not the value is larger (step 16). If it is larger, the counter value is cleared (step 1).
9), the process proceeds to the field frequency maintaining state. If it is determined in step 16 that the value is smaller, the counter value is incremented, and step 1 is performed.
Go to 5.

The meaning of the above processing in the pulse counter 8b of the liquid crystal drive pulse generator 8 will be briefly described. When the liquid crystal drive pulse generator 8 counts the clocks corresponding to ffix, the liquid crystal shutter switching operation is performed. However, since the next ffix is not determined in step 14 (infrared signal) Also occurs when the count value exceeds ffix + a without resetting the count operation of the pulse counter 8b, and the shutter operation of the liquid crystal using the ffix is continued (self-propelled). ), The processing shifts to the processing in the state of maintaining the field frequency.

In FIG. 11, first, a field frequency is detected, and the detected field frequency (count value) is set as fnow (step 21). If the state where the infrared signal is interrupted continues, the field frequency cannot be detected during that time, and when it is detected, the field frequency (clock count number) is significantly different from the previous value. Next, a first check of the field frequency is performed in the same manner as in step 12 of FIG. 10 (step 22). If the result of this check is YES, a new ffix is generated by slightly reflecting the current field frequency fnow (step 2).
7) The processing shifts to the processing in the state where the field frequency is determined. On the other hand, if the determination is NO, step 2 in FIG.
The second check processing of the field frequency is performed by the same method as that described above (step 23). If the result of this check is NO, the counter value of the check counter (chkcnt) is cleared (step 28), and the field frequency fnow detected this time is set to fold, and step 21 is executed.
Proceed to.

If YES in step 23,
The counter value of the check counter (chkcnt) is incremented (step 24). Then, the counter value of the check counter (chkcnt) is determined (step 25). If the counter value becomes 16, it is determined that the frequency has become stable and the field frequency fnow detected this time is determined.
Are set as ffix and fold, and the reset counter (rscnt) is cleared (step 26).
The processing shifts to the processing in the state where the field frequency is determined.
If it is determined in step 25 that the counter value is not 16, the process proceeds to step 29. The reset counter (rscnt) determines how long the liquid crystal shutter operation continues (self-runs).

In such a field frequency maintaining state, the pulse counter 8b of the liquid crystal drive pulse generator 8
The counting operation is proceeding (step 30), and the counter value is ffix (this ffix is determined in step 13,
14 (that is, the one set in step S14), that is, whether the liquid crystal shutter switching timing has come (step 31). In this step 31, YE
If S, the counter value of the pulse counter 8b is reset to determine the arrival of the next shutter timing (step 32). Then, the reset counter (r
scnt) is incremented (step 33). As described above, the reset counter (rscnt) determines the continuation time (self-running) of the liquid crystal shutter operation, and determines whether or not this time exceeds a maximum allowable value (MAX: corresponding to about 10 seconds). (Step 34), and when it exceeds, the state transits to a state where the field frequency is indeterminate,
The shutter operation of the liquid crystal shutter glasses is stopped. Unless it exceeds, the shutter operation of the liquid crystal is continued (self-propelled). If the field frequency is stabilized during self-running, the state transits to a state where the field frequency is determined.

(Embodiment 2) A stereoscopic image display in which a three-dimensional display mode in which a right-eye image and a left-eye image are alternately displayed on a screen at a constant cycle and a normal two-dimensional display mode can be switched. There is a device. In this type of switchable stereoscopic image display device, in the two-dimensional display mode, no infrared signal indicating the shutter timing of the liquid crystal shutter glasses is transmitted. Therefore, it is impossible to determine whether the inability to receive the infrared signal on the side of the liquid crystal shutter glasses is due to the blocking or the two-dimensional display mode. Therefore, when the mode is switched from the three-dimensional display mode to the two-dimensional display mode while the liquid crystal shutter glasses are worn, the flicker occurs due to the continuation of the shutter operation (self-running) of the liquid crystal shutter glasses.

The driving apparatus for the liquid crystal shutter glasses according to the second embodiment has the following configuration in order to prevent such a screen flicker.

FIG. 12 is a schematic diagram showing the configuration of a driving device 300 for liquid crystal shutter glasses according to the second embodiment.
The driving device 300 includes an infrared sensor 301 for receiving an infrared signal from the three-dimensional display 299, a decoding unit 302 for extracting an LR signal (L pulse, R pulse) from the received infrared light, and judging the two-dimensional display mode.
A liquid crystal panel includes liquid crystal shutter control circuits 304 and a liquid crystal panel 305, 30 in liquid crystal shutter glasses.
In order to control the shutter operation of No. 6, the decision signal L '
An R 'signal (L' pulse, R 'pulse) is output. The decoding unit 302 performs an operation corresponding to the input signal type automatic discrimination unit 3 of the first embodiment.
The liquid crystal shutter control circuit 304 performs an operation corresponding to the liquid crystal drive pulse generation unit 3 and the analog switches 11 and 12, and performs an operation corresponding to the field frequency detection / LR determination unit 6 and the operation field frequency determination unit 7. When a signal indicating the two-dimensional display mode is obtained from the decoding unit 302, control for stopping the shutter operation of the liquid crystal panels 305 and 306 is performed.

FIG. 13 is a diagram showing the relationship between the left-eye / right-eye image display switching state (LR) and the infrared signal. FIG. 13 shows the relationship between (a) and (b) in FIG. Equivalent to. In this embodiment, as shown in FIG. 14, the meaning of the signal is determined by the first Low period T1, the second Low period T2, and the third Low period T3, and T2 <
A signal that satisfies (T1 + T3) means L, and T2 = (T
1 + T3) indicates R, and T2> (T1 + T
A signal satisfying 3) indicates 2D. 3D display 2
99 indicates that when displaying in the two-dimensional mode, T2> (T
1 + T3).

FIG. 15 is an explanatory diagram simply showing the control contents of the second embodiment. In process 1, mode detection is performed. If an LR signal is detected in this mode detection, 3D
A mode determination signal is output. If a 2D signal is detected thereafter, a 2D mode determination signal is output. If an LR signal is detected in the 2D mode, a 3D mode determination signal is output. In process 2, the LR pulse interval P
W (n) is detected. This detection is performed based on the number of clocks (count number) counted (process 3) during the pulse interval. In processing 4, it is determined whether or not the difference between the current pulse interval PW (n) and the previous pulse interval PW (n-1) is within a predetermined allowable range. If the allowable state occurs continuously for m times or more (process 5), the process shifts to the normal shutter mode, and the average value (PWX) is calculated by dividing the sum of the pulse intervals up to a total of m times before and including this time by m. Is updated (process 7).

If the answer is NO in the process 4 or if the answer is NO in the process 5, the mode shifts to the self-propelled shutter mode using the average value (PWX). The pulse counter for driving the liquid crystal is reset by the L pulse and the R pulse in the normal shutter mode (corresponding to step 18 in FIG. 10 of the first embodiment) as shown in process 8, and in the self-running shutter mode. , Is reset by the average value (PWX) (corresponding to steps 31 and 32 in FIG. 11 of the first embodiment). Then, as shown in process 9, in the normal shutter mode, in the self-propelled shutter mode, and in the 2D
In the mode, predetermined pulse output processing for driving the liquid crystal or pulse output stop (power OFF) processing is performed.

Thus, according to the configuration of the second embodiment, when switching from the three-dimensional display mode to the two-dimensional display mode, the continuation (self-running) of the shutter operation of the liquid crystal shutter glasses is stopped, and the screen is displayed. Flicker will be prevented.

[0052]

As described above, according to the present invention, even if the infrared signal indicating the shutter timing in the liquid crystal shutter glasses is interrupted, the shutter operation can be continued at the held timing. It is possible to prevent the screen from flickering and eliminate the problem that the screen appears to flicker. When the mode is switched from the three-dimensional display mode to the two-dimensional display mode,
Continue shutter operation with LCD shutter glasses (self-propelled)
Is stopped, and screen flicker is prevented. In addition, even if the response speed when the liquid crystal enters the transmissive state is slow, it is possible to make the transmissive state enough before the vertical blanking period ends, eliminating the problem that the upper part of the screen appears dark. It has the effect of being able to.

[Brief description of the drawings]

FIG. 1 is a circuit diagram of an infrared LED drive pulse generator in an infrared signal transmission device.

FIG. 2 is a timing chart showing various signals in an infrared LED drive pulse generator.

FIG. 3 is a circuit diagram of an infrared signal transmission system using a system LSI including an infrared LED drive pulse generator.

FIG. 4 is a block diagram showing a driving device of the liquid crystal shutter glasses according to the embodiment of the present invention;

FIG. 5 is a block diagram in a case where a system LSI including a dotted frame portion in FIG. 4 is used;

6 is an explanatory diagram showing a system LSI including the circuit part of FIG. 1 and the dotted frame part of FIG. 4;

FIG. 7 is a timing chart showing the timing of applying 0 volt (open) to the liquid crystal shutter glasses.

FIG. 8 is a state transition diagram in the driving device for liquid crystal shutter glasses according to the embodiment of the present invention.

FIG. 9 is a flowchart showing control contents in a state where the field frequency is indeterminate according to the embodiment of the present invention.

FIG. 10 is a flowchart showing control contents in a state where the field frequency is determined according to the embodiment of the present invention.

FIG. 11 is a flowchart showing control contents in a state of maintaining a field frequency according to the embodiment of the present invention.

FIG. 12 is a block diagram showing a driving device for liquid crystal shutter glasses according to a second embodiment of the present invention.

FIG. 13 is an explanatory diagram showing a relationship between switching between a right-eye image display state and a left-eye image display state and an input (right-eye / left-eye discrimination signal) corresponding thereto.

FIG. 14 shows a right eye / eye image according to the second embodiment of the present invention.
FIG. 4 is an explanatory diagram showing a left eye determination signal and a 2D mode determination signal.

FIG. 15 is an explanatory diagram showing control contents according to the second embodiment of the present invention.

FIG. 16 is an explanatory diagram illustrating that the upper portion of the screen looks dark when conventional liquid crystal shutter glasses are used.

[Explanation of symbols]

 DESCRIPTION OF SYMBOLS 1 Infrared light receiving module 3 Input signal type automatic discrimination part 4 Power supply control part 5 Clock control part 6 Field frequency detection / LR discrimination part 7 Operating field frequency decision part 8 Liquid crystal drive pulse generation part 9 Timer 10 DC / DC converter 11,12 Analog switch 13 14 Liquid crystal 101 Signal control unit of infrared signal transmitting device 102 Integrated circuit unit 200 System LSI 300 Liquid crystal shutter glasses driving device

Claims (5)

[Claims] A receiving unit configured to receive a spatial transmission signal generated based on a signal indicating switching between left and right eye images, a unit configured to acquire data related to shutter timing in liquid crystal shutter glasses from the received spatial transmission signal, Means for causing the liquid crystal shutter glasses to perform a shutter operation using the acquired data relating to the shutter timing. 2. A receiving unit that receives a spatial transmission signal generated based on a signal indicating switching between left and right eye images, a unit that acquires data related to shutter timing in liquid crystal shutter glasses from the received spatial transmission signal, Means for holding data relating to the acquired shutter timing, and means for allowing the liquid crystal shutter glasses to perform a shutter operation using the data relating to the held shutter timing under predetermined conditions. For driving liquid crystal shutter glasses. 3. A receiving section for receiving a spatial transmission signal generated based on a signal indicating switching between left and right eye images, means for acquiring data relating to shutter timing in liquid crystal shutter glasses from the received spatial transmission signal, and Means for generating and holding shutter timing decision data to be given to the liquid crystal shutter glasses based on a predetermined condition from newly obtained shutter timing data; and means for determining when the decision data is not generated because the predetermined condition is not satisfied. Means for causing the liquid crystal shutter glasses to perform a shutter operation using the held determination data. 4. The driving device for liquid crystal shutter glasses according to claim 3, wherein predetermined processing is executed in each of three states of a field frequency uncertain state, a field frequency fixed state, and a field frequency maintaining state. It is configured to transit to another state according to the result, and the field frequency uncertain state is a state in which the shutter operation is stopped, and it is determined whether a predetermined condition is satisfied. The processing for generating the determination data is performed when the determination is made. The field frequency determination state is a state in which the shutter operation is performed based on the determination data sequentially determined, and a predetermined condition is satisfied. If the condition is satisfied, the decision data is generated and held, and if the predetermined condition is not satisfied, a transition to the field frequency maintaining state is performed. The field frequency maintenance state is a state in which the shutter operation is continued based on the held decision data, and when a predetermined condition is satisfied, the state transits to the field frequency determination state, The liquid crystal shutter glasses drive device characterized in that when the continuation of the shutter operation is carried out for a predetermined time without satisfying the condition (1), the state proceeds to the field frequency uncertain state. 5. A driving device for liquid crystal shutter glasses using liquid crystal, which is opaque when a predetermined negative voltage and a predetermined positive voltage are applied, and becomes transparent when a 0 volt voltage is applied, comprising: A receiving unit that receives a spatial transmission signal generated based on a signal indicating switching of an eye image, a unit that acquires data related to shutter timing in liquid crystal shutter glasses from the received spatial transmission signal, and data that relates to the acquired shutter timing. Means for causing the liquid crystal shutter glasses to perform a shutter operation by speeding up the application timing of the 0 volt voltage for a preset time in consideration of a time required for the liquid crystal to be sufficiently transmitted while using the liquid crystal. A driving device for liquid crystal shutter glasses.