JP2012155146A - Display system and display control method - Google Patents

Abstract

PROBLEM TO BE SOLVED: To display a message to drivers around an own vehicle with good visibility without disturbing driver's visibility around the own vehicle.SOLUTION: An EL display panel 11 has a light transmission surface and repeatedly emits pixels at a corresponding position on the light transmission surface according to display information to display the display information. An optical shutter 12 is arranged with a light transmission area at a position overlapping the light transmission surface of the EL display panel 11, and at least a part of the light transmission area can be switched to a light shielding area. A control device 20 controls a display device 10, thereby switching at least an area facing the corresponding position of the EL display panel 11 in the light transmission area of the optical shutter 12 to the light shielding area in synchronization with a period emitting the corresponding position.

Description

  The technical field discussed in this specification relates to a technique for displaying various types of information.

  In a display device using optical shutter glasses, a technique is known in which an arbitrary partial region of a display image is shielded only for a wearer of optical shutter glasses.

JP-A-6-153123

  A display device is installed near the rear window (rear window) of the car, and a message indicating the appreciation of the driver's own car being interrupted to the train or braking is applied to the driver of another car. It is considered to display a message or the like that emphasizes.

FIG. 1 is a first example of message display by such a display device. In this example, a message indicating gratitude is displayed on the display device installed in the automobile A.
For the purpose of expressing gratitude, a method of blinking the hazard lamp several times was also used, but the original meaning of turning on the hazard lamp is “emergency stop”, so this method does not convey the intention correctly. On the other hand, it could lead to dangerous situations. On the other hand, if the letter “thank you” is displayed on the rear window as in the case of the car A in FIG.

  FIG. 2 is a second example of message display by such a display device, and an example in which a message indicating that the driver of the vehicle A has suddenly applied a brake is displayed on the display device installed in the vehicle A. It is.

  If the driver applies the brake, the brake lamp of the car A is lit. However, since the degree of brake application cannot be determined from the brake lamp, if a sudden brake is applied, there is a possibility that the following vehicle will collide with the own vehicle. On the other hand, if a character such as “sudden brake!” Is displayed on the rear window according to the degree of braking, as shown in FIG. The possibility of rear-end collision is reduced.

However, in order to perform such a display, it is not preferable to disturb the rear view of the driver of the car.
In view of the above-described problems, the display system described later in this specification enables a message to be displayed with high visibility to the driver around the host vehicle without disturbing the driver's visibility around the host vehicle.

  One display system described later in this specification includes a display device including a display unit and an optical shutter, and a control device. Here, the display unit has a light transmission surface, and the display information is displayed by repeatedly emitting light at corresponding positions on the light transmission surface corresponding to the display information. In addition, the optical shutter has a light transmission region disposed at a position overlapping the light transmission surface of the display unit, and at least a part of the light transmission region can be switched to the light blocking region. Then, the control device controls the display device to synchronize at least a region of the light transmission region of the optical shutter that faces the corresponding position of the display unit with a period during which the corresponding position emits light. Switch to the light blocking area.

  A display control method described later in this specification is a method for controlling a display device. The display device includes a display unit and an optical shutter. Here, the display unit has a light transmission surface, and displays the display information by repeatedly emitting light at corresponding positions on the light transmission surface according to display information. In addition, the optical shutter has a light transmission region disposed at a position overlapping the light transmission surface of the display unit, and at least a part of the light transmission region can be switched to the light blocking region. One of the display control methods described later in this specification first causes the display unit to display the display information. Then, the corresponding position in the repeated light emission for displaying the display information on the display unit is synchronized with the light emission period, and is opposed to at least the corresponding position of the light transmission region of the optical shutter. The area is switched to the light blocking area.

  The display system described later in this specification has an effect that a message can be displayed with high visibility to the driver of the vehicle around the host vehicle without hindering the visibility of the driver around the host vehicle.

It is a 1st example of the message display by the display apparatus provided in the rear window vicinity of the motor vehicle. It is a 2nd example of the message display by the display apparatus provided in the rear window vicinity of the motor vehicle. It is a functional block diagram of one Example of a display system. It is a figure showing the example of installation of a display system. It is the figure which illustrated the structure of EL display panel. It is the figure which illustrated the structure of the optical shutter. It is FIG. (1) explaining the synchronizing operation with the EL display panel of an optical shutter. It is FIG. (2) explaining the synchronizing operation with the EL display panel of an optical shutter. It is a hardware structural example of a computer. It is the flowchart which illustrated the processing content of the control processing.

First, FIG. 3 will be described. FIG. 3 is a functional block diagram of an embodiment of the display system.
The display system 1 of FIG. 3 includes a display device 10 and a control device 20. Further, the display system 1 of FIG. 3 further includes an illuminance sensor 30.

The display device 10 includes an EL display panel 11, an optical shutter 12, and a shutter drive unit 13.
The EL display panel 11 is an example of a display unit. The EL display panel 11 has a light transmission surface, and displays the display information by repeatedly emitting light at corresponding positions according to display information on the light transmission surface.

The optical shutter 12 can switch at least a part of a light-transmitting shutter surface (light transmission region) to a light blocking region, and this shutter surface is a panel surface (light transmission surface) in the EL display panel 11. It is arranged at the position that overlaps.
Details of the structures of the EL display panel 11 and the optical shutter 12 will be described later.

  In response to the instruction indicated by the control instruction signal sent from the control device 20, the shutter drive unit 13 determines the area related to the instruction on the shutter surface of the optical shutter 12 as the light transmission area and the light blocking area. Switch between.

The control device 20 includes a display instruction unit 21, a message memory 22, an image generation unit 23, and a shutter controller 24.
The display instruction unit 21 instructs the display device 10 to select display information (message) and switches on / off the power supply to the EL display panel 11 and the optical shutter 12. Further, the display instruction unit 21 controls the EL display panel 11 to perform a display operation described later. Further, the display instruction unit 21 controls the optical shutter 12 so that at least a region facing the light emission position of the EL display panel 11 in the light transmission region of the optical shutter 12 emits the light emission position. Synchronize with the light blocking area. In order to enable this synchronous operation, the display instruction unit 21 sends a predetermined operation timing signal to the image generation unit 23 and the shutter controller 24.

  The message memory 22 is a memory in which a plurality of message data to be displayed on the display device 10 are stored in advance. When the display instruction unit 21 selects one of a plurality of messages stored in the message memory 22, the data of the selected message is read from the message memory 22 and sent to the image generation unit 23.

  The image generation unit 23 generates a video signal representing the message based on the message data received from the message memory 22, and outputs the generated video signal at a timing according to the operation timing signal received from the display instruction unit 21. It is passed to the EL display panel 11.

  The shutter controller 24 switches at least a region of the light transmission region facing the light emission position of the EL display panel 11 to the light blocking region at a timing according to the operation timing signal received from the display instruction unit 21.

  As described above, the control device 20 controls the display device 10 so that at least a region of the light transmission region of the optical shutter 12 that faces the above-described corresponding position of the EL display panel 11 is set to the corresponding position. Is switched to the light blocking area in synchronization with the period of light emission.

  In addition, the control device 20 further switches the light shutter region to the light blocking region in synchronization with the above-described period among the light transmitting regions other than the region facing the above-described corresponding position of the EL display panel 11 in the optical shutter 12. The display device 10 is controlled to change the area of the region where the display is performed.

  The illuminance sensor 30 detects the brightness (illuminance) of the environment around the EL display panel 11 and sends the detection result of the illuminance to the shutter controller 24. The shutter controller 24 changes the area area of the optical shutter 12 based on the detection result of the illuminance.

Here, FIG. 4 will be described. FIG. 4 illustrates an installation example of the display system 1 of FIG.
As illustrated in FIG. 4, the display device 10 in the display system 1 is installed in the interior of the automobile 40 so as to be inscribed in the rear window 41. More specifically, in the display device 10, the EL display panel 11 side of the EL display panel 11 and the optical shutter 12 arranged in an overlapping manner is arranged so as to face the outside of the automobile 40.

  The room mirror 42 reflects the light transmitted through the rear window 41, the EL display panel 11, and the optical shutter 12, and directs the traveling direction of the light toward the driver of the automobile 40. The field of view behind the automobile 40 is provided to the driver of the automobile 40 by this reflected light.

  The illuminance sensor 30 is installed in the vicinity of the rear window 41 outside the vehicle 40 and detects the brightness of the vehicle 40 outside the vehicle. The shutter controller 24 of the control device 20 in the display system 1 changes the area of the region to be switched to the light blocking region described above according to the brightness outside the vehicle 40 detected by the illuminance sensor 30.

Next, details of the configurations of the EL display panel 11 and the optical shutter 12 will be described.
The EL display panel 11 is configured by using an electroluminescence (electroluminescence) display element and a transparent electrode, and a panel surface for performing various displays is a light transmission surface. Light transmissive between the back surface. The EL display panel 11 displays the information by causing the pixel at the corresponding position on the light transmission surface corresponding to the input display target information (display information) to emit light.

  FIG. 5 illustrates the structure of the EL display panel 11. The transparent electrode line 51 is disposed in parallel with a predetermined direction on one surface of the front and back surfaces of the EL display panel 11, and the other surface is transparent in a direction orthogonal to the predetermined direction. Electrode lines 51 are arranged in parallel. When one transparent electrode line 51 is selected from each of the two surfaces and given a predetermined voltage, the position (light emitting point) at which the selected transparent electrode line 51 intersects is viewed from the panel surface. The display element emits light. Thus, the EL display panel 11 is a passive matrix display element.

Information display on the EL display panel 11 is performed as follows.
In accordance with the display information sent from the image generation unit 23, the EL display panel 11 first emits the pixels on the uppermost row of the panel surface sequentially from the left end to the right end, and then the pixels on the next lower row Light is emitted sequentially from the left end to the right end, and the same light emission operation is executed up to the bottom row. Thereafter, this light emission operation is repeated from the top row. In the present embodiment, the light emission operation from the top row to the bottom row is repeated 60 times per second to obtain the afterimage effect of light emission, so that each light emission point seems to emit light continuously. The display operation of the information by the EL display panel 11 is performed in this way.

  In this embodiment, an organic EL element is used as a light emitting element used for the EL display panel 11, but an inorganic EL element may be used instead. Instead of this, an LED (Light Emitting Diode) element may be used. However, when the LED element is used, the area of the LED element portion becomes opaque and the entire area of the panel surface cannot be made transparent, but the ratio of the area of the LED element portion to the entire area of the panel surface is reduced. By suppressing, the panel surface can be used as a light transmission surface.

FIG. 6 illustrates the structure of the optical shutter 12.
In this embodiment, a liquid crystal shutter is used as the optical shutter 12. The liquid crystal shutter has a transparent shutter surface when no voltage is applied.

  In this liquid crystal shutter, a plurality of strip-shaped transparent electrodes 52 are arranged side by side on the front surface side and the back surface side of the shutter surface. Here, when a pair of opposed strip-shaped transparent electrodes 52 facing each other are selected by the shutter controller 24 from each of the two surfaces and given a predetermined voltage, they are sandwiched between the pair of strip-shaped transparent electrodes 52 on the shutter surface. The lighted area is the light blocking area. When the application of a predetermined voltage to the pair of strip-shaped transparent electrodes 52 is stopped, the region sandwiched between the pair of strip-shaped transparent electrodes 52 on the shutter surface transitions from the light blocking region to the light transmitting region. .

Next, the synchronization operation of the optical shutter 12 with the EL display panel 11 will be described with reference to FIGS. 7A and 7B.
The example of FIG. 7A represents a case where the shutter surface of the optical shutter 12 is divided into two regions (region A and region B). Two of the above-described strip-shaped transparent electrodes 52 are arranged on the front and back surfaces of the shutter surface, and the regions A and B are sandwiched between a pair of opposed strip-shaped transparent electrodes 52.

  As described above, the EL display panel 11 sequentially emits the pixels in the uppermost row of the panel surface from the left end to the right end, and then sequentially emits the pixels in the next lower row from the left end to the right end. Execute the action to the bottom line.

  Here, the period during which the light emission operation is performed in the region of the panel surface facing the region A of the optical shutter 12, that is, the region from the uppermost row of the panel surface to the intermediate row between the uppermost row and the lowermost row, The area A is selected by the shutter controller 24 and switched to the light blocking area. Note that the region B remains a light transmission region during this period. On the other hand, during the period in which the light emission operation is performed in the region of the panel surface facing the region B of the optical shutter 12, that is, the region from the middle row to the bottom row of the panel surface, the region B is moved by the shutter controller 24. It is selected and switched to the light blocking area. Note that the region A is returned to the light transmission region during this period.

  Such an open / close control operation of the optical shutter 12 is repeatedly performed in synchronization with light emission for display operation on the EL display panel 11. Accordingly, part of the light from the rear of the automobile 40 in FIG. 4 passes through the EL display panel 11 and the optical shutter 12, but the light emission of the EL display panel 11 is blocked by the optical shutter 12. As a result, the driver of the automobile 40 cannot see the light emission of the EL display panel 11, but can obtain the visual field behind the automobile 40, while the occupant of the vehicle following the automobile 40 can see the EL display panel. The information displayed by 11 light emission can be visually recognized.

  Next, the example of FIG. 7B will be described. The example of FIG. 7B represents a case where the shutter surface of the optical shutter 12 is divided into a plurality of regions (region A, region B, region C,...) More than the example of FIG. The above-described band-shaped transparent electrodes 52 are arranged on the front and back surfaces of the shutter surface by the number of divisions, and each region A, B, C,... Is formed on a pair of opposed band-shaped transparent electrodes 52. Each is sandwiched.

  In FIG. 7B, during the period in which the light emission operation is performed in the area of the panel surface facing the area A of the optical shutter 12, the area A is selected by the shutter controller 24 and switched to the light blocking area. The entire area is a light transmission area. Next, during the period in which the light emission operation is performed in the region of the panel surface facing the region B of the optical shutter 12, the region B is selected by the shutter controller 24 and switched to the light blocking region, and all other regions ( The area A) includes a light transmission area. The same opening / closing control is performed by the shutter controller 24 in each area after the area C of the optical shutter 12.

  Such an open / close control operation of the optical shutter 12 is repeatedly performed in synchronization with light emission for display operation on the EL display panel 11. Accordingly, part of the light from the rear of the automobile 40 in FIG. 4 passes through the EL display panel 11 and the optical shutter 12, but the light emission of the EL display panel 11 is blocked by the optical shutter 12. As a result, the driver of the automobile 40 cannot see the light emission of the EL display panel 11, but can obtain the visual field behind the automobile 40, while the occupant of the vehicle following the automobile 40 can see the EL display panel. The information displayed by 11 light emission can be visually recognized.

  In the above-described opening / closing control operation of the optical shutter 12, only one area of the plurality of divided areas of the shutter surface of the optical shutter 12 is switched to the light blocking area, and all other areas are set as light transmitting areas. Is done. In addition to such control, in this embodiment, the shutter controller 24 further sets the number of areas to be switched to the light blocking area on the shutter surface of the optical shutter 12 to the brightness of the environment around the EL display panel 11. In accordance with the change, control is performed to change the area of the light blocking region. That is, the shutter controller 24 determines the number of divided areas to be switched to the light blocking area based on the detection result of the illuminance outside the vehicle 40 received from the illuminance sensor 30, and determines the divided area of the shutter surface of the optical shutter 12 as the divided area. The number is switched to the light blocking area.

  In general, when the outside of the automobile 40 is bright, it is easy to see the scenery outside the vehicle from inside the vehicle, but it is difficult to see the display on the EL display panel 11 from outside the vehicle. On the other hand, when the outside of the vehicle 40 is dark, it is difficult to see the scenery outside the vehicle from inside the vehicle, but the display on the EL display panel 11 is easy to see from outside the vehicle. Therefore, the shutter controller 24 increases the number of divided areas for switching from the light transmission area to the light blocking area as the illuminance increases, based on the detection result of the illuminance outside the vehicle 40 received from the illuminance sensor 30. The number is determined as follows.

  In this way, the brighter the outside of the automobile 40 is, the larger the area of the light blocking area on the shutter surface of the optical shutter 12 is, so that the display contrast on the EL display panel 11 is increased and the outside of the automobile 40 is easy to see. Further, the darker the outside of the automobile 40 is, the smaller the area of the light blocking area on the shutter surface of the optical shutter 12 is, so that it is easier to see the scenery outside the automobile 40 from within the vehicle interior.

  The number of divided areas provided on the shutter surface of the optical shutter 12 is arbitrary, and the number may be increased to perform finer control, or the number of the divided areas may be reduced to reduce the structure of the optical shutter 12. May be simplified.

  Next, FIG. 8 will be described. FIG. 8 illustrates a hardware configuration example of a computer 60 that can be operated as the control device 20 in the display system 1 of FIG. 3.

  The computer 60 includes an MPU 61, a ROM 62, a RAM 63, an input device 64, a display device 65, an interface device 66, and a recording medium driving device 67. These components are connected via a bus line 68, and various data can be exchanged under the management of the MPU 61.

An MPU (Micro Processing Unit) 61 is an arithmetic processing unit that controls the operation of the entire computer 60.
A ROM (Read Only Memory) 62 is a read-only semiconductor memory in which a predetermined control program and various constant values are recorded in advance. The MPU 61 reads out and executes the control program when the computer 60 is started, thereby enabling operation control of each component of the computer 60 and further performing control processing described later. The ROM 62 also functions as the message memory 22 in FIG.

  A RAM (Random Access Memory) 63 is a semiconductor memory that can be written and read at any time and used as a working storage area as necessary when the MPU 61 executes various control programs.

  The input device 64 is, for example, a keyboard device. When operated by a user of the computer 60, the input device 64 acquires input of various information from the user associated with the operation content, and the acquired input information is stored in the MPU 61. Send it.

The display device 65 is a liquid crystal display, for example, and displays various texts and images according to display data sent from the MPU 61.
The interface device 66 manages the exchange of various data with various devices connected to the computer 60. More specifically, the interface device 66 captures the detection result of the illuminance by the illuminance sensor 30, outputs various drive signals to the EL display panel 11 and the optical shutter 12 of the display device 10, and the like.

Thus, the computer 60 has a very standard configuration.
The computer 60 having such a configuration can function as the control device 20. For this purpose, first, a control program for causing the MPU 61 to perform the processing contents of the control processing described later is created. The created control program is stored in the ROM 62 in advance. Then, a predetermined instruction is given to the MPU 61 to read and execute this control program. By doing so, the MPU 61 functions as each component of the control device 20 illustrated in FIG. 3, and the control device 20 can be configured using the computer 60.

  The recording medium driving device 67 is a device that reads various control programs and data recorded on the portable recording medium 69. For example, the flash memory is used as the ROM 62, and the MPU 61 configures the computer 60 so that the control program recorded in the portable recording medium 69 is read out via the recording medium driving device 67 and stored in the ROM 62. May be. In this case, the MPU 61 reads and executes the control program stored in the ROM 62 when receiving a predetermined execution start instruction.

  As the portable recording medium 69, for example, a non-transitory recording medium such as a CD-ROM (Compact Disc Read Only Memory) and a DVD-ROM (Digital Versatile Disc Read Only Memory) can be used. It is. Further, as the portable recording medium 69, for example, a semiconductor memory provided with a USB (Universal Serial Bus) standard connector can be used.

  Moreover, you may comprise the control apparatus 20 using the computer system which consists of a terminal device and the server apparatus which can transmit / receive various data between the said terminal devices. When the control device 20 is configured by this computer system, the display device 10 and the illuminance sensor 30 are connected to the terminal device and installed in the automobile 40. On the other hand, the server device includes the configuration of the computer 60 of FIG. 8, for example. However, the interface device 66 includes a communication device that manages data communication with the communication device of the terminal device. Then, the terminal device sends the detection result of the illuminance sensor 30 to the server device. On the other hand, the server device performs a control process to be described later based on the detection result received from the terminal device, and sends drive information obtained by the control process to the terminal device to be transferred to the display device 10. By doing in this way, the control apparatus 20 can be comprised by the above-mentioned computer system.

  Next, FIG. 9 will be described. FIG. 9 is a flowchart illustrating the processing contents of the control processing performed by the control device 20 in the display system 1 of FIG. Here, it is assumed that the shutter surface of the optical shutter 12 is divided into a plurality of regions as in the example of FIG. 7B.

  The control process of FIG. 9 is started when it is detected that the driver has operated various operation units of the automobile 40 to start driving, and the display instruction unit 21 includes the EL display panel 11 and The power supply to the optical shutter 12 is started.

  When this control process is started, first, in S101, the display instruction unit 21 performs a process of determining whether or not an instruction to turn on message display on the display device 10 is received from the driver of the automobile 40. Here, when it is determined that the instruction has been received (when the determination result is Yes), the process proceeds to S102, and when it is determined that the instruction has not been received (when the determination result is No), S108. The process proceeds.

  Next, in S102, the display instruction unit performs processing for reading message data corresponding to an instruction from the driver of the automobile 40 from the message memory 22 in which message data is stored in advance and sending the message data to the image generation unit 23. 21 does.

Next, in S <b> 103, the shutter controller 24 performs a process of acquiring the detection result of the illuminance outside the vehicle 40 by the illuminance sensor 30.
Next, in S104, based on the illuminance acquired in the process of S103, a process of determining the number of areas to be switched to the light blocking area among the plurality of divided areas provided on the shutter surface of the optical shutter 12 is performed by the shutter controller 24. Do.

  In step S <b> 105, the image generation unit 23 starts processing for performing a message display operation on the EL display panel 11. In this process, the image generation unit 23 first performs a process of generating a video signal representing the message represented by the data received from the message memory 22 in the process of S102. Then, at a timing corresponding to the operation timing signal sent from the display instruction unit 21, the generated video signal is transferred to the EL display panel 11 to display the message. The EL display panel 11 performs the display operation of the message represented by the received video signal as described above. That is, the EL display panel 11 sequentially emits the pixels in the uppermost row on the panel surface from the left end to the right end, and then sequentially emits the pixels in the next lower row from the left end to the right end. Execute up to the bottom line and display the message.

  Next, in S106, the shutter controller 24 starts the above-described opening / closing control processing of the optical shutter 12 in synchronization with the light emission for the display operation on the EL display panel 11. That is, the shutter controller 24 transmits light through a predetermined divided region of the optical shutter 12 including at least a position opposed to the light emission point in synchronization with the light emission period of the light emission point in light emission for display operation on the EL display panel 11. Switch from area to light blocking area. In this switching to the light blocking area, the number of divided areas to be simultaneously switched is the number determined in the process of S104.

  The shutter controller 24 uses a display instruction unit used by the image generation unit 23 to set the timing of the display operation in order to synchronize the opening / closing control of the optical shutter 12 with the display operation on the EL display panel 11. The operation timing signal sent from 21 is used.

  Next, in S107, the display instruction unit 21 performs a process of determining whether or not an instruction to turn off the message display on the display device 10 is received from the driver of the automobile 40. If it is determined that the instruction has been received (when the determination result is Yes), the process proceeds to S108. On the other hand, when it is determined that the instruction has not been received (when the determination result is No), the processing returns to S103 and the above-described processing is repeated.

In S <b> 108, the image generation unit 23 performs a process for ending the message display operation on the EL display panel 11 started in the process of S <b> 105.
In S109, the opening / closing control of the optical shutter 12 started in the process of S106 is ended, and the shutter controller 24 performs a process of setting the entire shutter surface of the optical shutter 12 to the light transmission region.

  In S <b> 110, the display instruction unit 21 performs a process of determining whether or not it has been detected that the driver has operated various operation units of the automobile 40 to perform an operation for ending driving. Here, when it is determined that the operation has been detected (when the determination result is Yes), the control process of FIG. 9 ends, and the display instruction unit 21 supplies power to the EL display panel 11 and the optical shutter 12. Stop supplying. On the other hand, here, when it is determined that the operation is not detected (when the determination result is No), the processing returns to S101 and the above-described processing is repeated.

  When the control device 20 performs the above control process, the visibility of the driver around the vehicle by the display system 1 in FIG. 3 is not hindered, and the visibility of the driver around the vehicle around the vehicle is not visible. A good message is displayed.

Next, the experimental result of message display using the display system 1 of FIG. 2 will be briefly described.
In the experiment, an organic EL panel (light emission intensity: 100 cd / m ² ) of 16 dots long × 80 dots wide was used as the EL display panel 11 and inscribed in the rear window 41 in the vehicle interior of the automobile 40. Further, a liquid crystal shutter was used as the optical shutter 12, and the number of divided areas on the shutter surface was set to 16. The light emission repetition rate for the display operation on the EL display panel 11 was 60 times per second.

The experiment was performed from 0 lux to 10,000 lux. 10,000 lux corresponds to the daytime brightness on a cloudy day.
At this time, in an environment of less than 700 lux, only one of the 16 divided areas on the shutter surface of the liquid crystal shutter is used as a light blocking area, and the other 15 sheets are used as a light transmitting area. Balanced external visibility from the passenger compartment. Thereafter, the number of divided areas to be light blocking areas is increased every 700 lux, and at 10,000 lux, only one of the divided areas is set as a light transmitting area, and the other 15 sheets are set as light blocking areas. As a result, the visibility from the outside of the vehicle and the visibility from the passenger compartment were balanced.

In addition, the selection method of the division area used as a light shielding area was performed as follows.
First, a divided area facing the light emitting point of the EL display panel 11 is always selected. Next, among the divided regions adjacent to the divided region facing the light emitting point, the lower divided region (that is, the divided region that will next face the light emitting point) is selected first, and then The upper divided area is selected. Thereafter, selection is similarly performed alternately from the divided areas close to the divided area facing the light emitting point. In this way, when the number of selected divided areas as light blocking areas is increased, the amount of light of the organic EL panel leaking from the liquid crystal shutter is surely reduced.

  In the above experiment, the visibility of the display could not be secured in an environment brighter than 10,000 lux due to the limitation of the luminance of the organic EL panel. However, if an EL display panel 11 having a higher luminance (for example, a display panel using the LED element described above) is used, it is clear that high external visibility can be obtained even in a brighter outside environment. is there.

  Since the display system 1 of FIG. 3 operates as described above, it is possible to display a message with high visibility to the driver of the vehicle around the host vehicle without hindering the visibility of the driver around the host vehicle. .

DESCRIPTION OF SYMBOLS 1 Display system 10 Display apparatus 11 EL display panel 12 Optical shutter 13 Shutter drive part 20 Control apparatus 21 Display instruction | indication part 22 Message memory 23 Image generation part 24 Shutter controller 30 Illuminance sensor 40 Automobile 41 Rear window 42 Room mirror 51 Transparent electrode line 52 Strip-shaped transparent electrode 60 Computer 61 MPU
62 ROM
63 RAM
64 input device 65 display device 66 interface device 67 recording medium driving device 68 bus line 69 portable recording medium

Claims (7)

A display unit that has a light transmission surface and repeatedly emits light at corresponding pixels on the light transmission surface according to display information to display the display information; and overlaps the light transmission surface of the display unit A display device provided with an optical shutter in which a light transmission region is disposed at a position and at least a part of the light transmission region can be switched to a light blocking region;
By controlling the display device, among the light transmission regions of the optical shutter, at least a region facing the corresponding position of the display unit is synchronized with a period during which the corresponding position emits light. A control device for switching to
A display system comprising:   The control device is further configured to switch to the light blocking area in synchronization with the period among the light transmitting areas other than the area facing the corresponding position of the display unit in the optical shutter. The display system according to claim 1, wherein the display device is controlled to change an area of the display.   The display system according to claim 2, wherein the control device performs control to change the area according to brightness of an environment around the display unit. The display device is arranged in a vehicle interior of the automobile with the display unit side facing the outside of the automobile.
A sensor for detecting brightness outside the vehicle;
The control device performs control to change the area according to the brightness outside the vehicle detected by the sensor.
The display system according to claim 3.   The display system according to any one of claims 1 to 4, wherein the display unit is configured using an electroluminescence display element and a transparent electrode.   An automobile comprising the display system according to any one of claims 1 to 5. A display unit that has a light transmission surface and repeatedly displays the display information by emitting light at corresponding positions on the light transmission surface according to display information; and a position overlapping the light transmission surface of the display unit A method for controlling a display device comprising an optical shutter, wherein a light transmission region is disposed, and at least a part of the light transmission region can be switched to a light blocking region,
Causing the display unit to display the display information;
A region facing at least the corresponding position of the light transmission region of the optical shutter in synchronization with a period in which the corresponding position is emitted in repeated light emission for displaying the display information on the display unit. To switch to the light blocking area,
A display control method characterized by the above.