JP2011112924A - Display system and method for controlling the same - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide a display system which can display a video by after image, and pass outside light. <P>SOLUTION: The display system (12, 14) includes: a control part (100, 322); a display part (304, 350) including a plurality of display elements (P1 to P16) which are arranged at a window side, and which turns on light in a display period, according to a first control signal (PS_EN); a scan driving part (340) for mechanically scanning the plurality of display elements; an optical shielding device (330) which is arranged at a mirror side, and which intercepts light originating from the display element in the display part, in the display period of the display part, according to a second control signal (PS_S), and which transmits light from a window in the non-display period of the display part. <P>COPYRIGHT: (C)2011,JPO&INPIT

Description

  The present invention relates to a display device, and more particularly, to a display system that displays an image by an afterimage of a display element that blinks during periodic mechanical scanning.

  Using a display device near the rear window (rear window) separately from the normal display of the car, a message that expresses gratitude to the other car that interrupted your car while driving the car It is contemplated to display and display a message that emphasizes that the following car is being braked.

  By moving a one-dimensional array of a plurality of light-emitting elements such as blinking LEDs arranged in a straight line in a direction perpendicular to the straight line, the image is perceived as a two-dimensional image by an afterimage effect of light. A video like this is displayed. In this display, temporal flashing of the light emitting element is expressed as spatial resolution. Temporal resolution forms spatial resolution.

  A known display device includes a light emitter composed of a plurality of light emitting elements arranged in a unit row, drive means for moving the light emitter in a direction orthogonal to the unit row, and a predetermined position on a plane generated by the movement of the light emitter. Storage means for holding the light emission data of the light emitting element, processing means for reading out and outputting the light emission data of the issuing element for each unit from the storage means, and lighting for driving the light emitting element by a signal output from the processing means Means.

  The known video display device displays shutter glasses that open and close the left and right eye fields in synchronization with the video signal displayed on the screen, and N video signals are periodically and time-divisionally displayed on the same screen. Display means for selecting, and video selection means for selecting any one of the N video signals displayed on the screen and opening and closing the shutter glasses according to the cycle of the selected video signal. . Thereby, a plurality of videos can be displayed on one screen without losing the size, and a plurality of persons can view different videos at the same time.

Japanese Patent Laid-Open No. 3-133486 Japanese Patent Laid-Open No. 10-240212

  When a normal display device is arranged near the rear window of an automobile, the visual field behind the driver is narrowed by the display device. In addition, if a transparent hologram element is placed on the rear window of an automobile, the rear field of view can be secured. However, a part of the display message can be seen by the driver due to a shift in the wavelength or incident angle of the reproduction light, and the rear visibility is reduced. There are things to do. For example, such a decrease in visibility becomes remarkable when the outside is dark at night.

  Inventors display a message while ensuring visibility behind the driver of an automobile by displaying an image representing the message by an afterimage of a flashing display element row periodically mechanically scanned. I realized that I could do it.

  An object of the present invention is to realize a display system capable of displaying an image with an afterimage and allowing light from outside to pass therethrough.

  According to one aspect (feature) of the embodiment of the present invention, the display system is disposed on the window side and a plurality of lights that are lit for display in the display period according to the first control signal from the control unit. A display unit including a plurality of display elements, a scanning drive unit to which the plurality of display elements are attached and mechanically scan the plurality of display elements, and a second control from the control unit disposed on the mirror side An optical blocking device that blocks light originating from the display element of the display unit during the display period of the display unit and transmits light from the window during a non-display period of the display unit according to the signal. It is out.

  According to one aspect of the embodiment of the present invention, it is possible to realize a display system capable of displaying an image with an afterimage and allowing light from outside to pass therethrough.

FIG. 1 shows an example of a schematic configuration of a message display system according to an embodiment of the present invention. FIG. 2A shows an example of a schematic block diagram of the message display system of FIG. FIG. 2B shows another schematic block diagram example of the message display system of FIG. 3A to 3C show examples of the rotational movement, pendulum movement, or horizontal reciprocating movement of the display body mechanically scanned by the scanning drive unit. FIG. 4 shows an example of a timing chart of an address enable signal, an address signal, a display enable signal, a lighting signal, and a shutter pulse signal generated by the display element driver of FIG. 2A. FIG. 5 shows an example of another timing chart of an address enable signal, an address signal, a display enable signal, a lighting signal, and a shutter pulse signal generated by the display element driver of FIG. 2A. FIG. 6 shows another example of a timing chart of an address enable signal, an address signal, a display enable signal, a lighting signal, and a shutter pulse signal generated by the display element driving unit of FIG. 2B. 7A and 7B show an example of lighting and extinction or color emission for displaying an afterimage of a message by the display element of the display body according to the time chart of FIG. 4 in the display system of FIG. 2A. 8A and 8B show examples of lighting signals according to the time chart of FIG. 4 in the display system of FIG. 2A. 9A and 9B show another example of lighting and extinction or color emission for displaying an afterimage of a message by the display element of the display body according to the time chart of FIG. 5 in the display system of FIG. 2A. FIG. 9C shows an example of the non-display state of the display body. 10A and 10B show another example of the lighting signal according to the time chart of FIG. 5 in the display system of FIG. 2A. FIG. 10C corresponds to FIG. 9C and shows an example of a temporal sequence in the time when the display element of the display body is in the lighting stop state corresponding to the lighting signal. 11A and 11B show still another example of lighting and extinction or color emission for displaying a residual image of a message by the display element of the display body according to the time chart of FIG. 6 in the display system of FIG. 2B. FIG. 11C shows an example of the non-display state of the display body. 12A and 12B show still another example of the lighting signal according to the time chart of FIG. 6 in the display system of FIG. 2B. FIG. 12C corresponds to FIG. 9C and shows an example of a temporal sequence in the time when the display element of the display body is in the lighting stop state corresponding to the lighting signal. 13A and 13B show an example of a flowchart of control for message display executed by the information processing device. (Explained in Fig. 13A)

The objects and advantages of the invention will be realized and attained by means of the elements and combinations particularly pointed out in the appended claims.
The foregoing general description and the following detailed description are exemplary and explanatory only and are not intended to limit the invention.

  Non-limiting embodiments of the present invention will be described with reference to the drawings. In the drawings, similar components and elements are provided with the same reference numerals.

  FIG. 1 shows an example of a schematic configuration of a message display system 12 or 14 according to an embodiment of the present invention.

FIG. 2A shows an example of a schematic block diagram of the message display system 12 of FIG.
FIG. 2B shows another schematic block diagram example of the message display system 14 of FIG.

  Referring to FIGS. 1, 2A and 2B, the message display system 12 or 14 is particularly suitable for the automobile 2 and includes a shutter device 330 such as a liquid crystal shutter device, a scan driving unit 340, and a scan driving unit 340. And a display member or display body 350 attached to the. The message display system 12 or 14 may further optionally include an illuminance sensor 120 for detecting external illuminance.

  The display member 350 includes, for example, a plurality of display elements or rows of light emitting elements P1 to P16 arranged in a line on an opaque printed circuit board (PCB). The display elements P1 to P16 may be LED elements, organic EL elements, or miniature bulbs, for example. The number of display elements of the display member 350 is not limited to 16 and may be any number. Each of the display elements P1 to P16 may be a single color display element or may be a display element of a plurality of colors such as three primary colors (R, G, B). The display member 350 is attached to the scanning drive unit 340 and is disposed outwardly inside the rear window 30 of the automobile 2. The display member 350 is periodically mechanically scanned by the scanning drive unit 340 in a direction substantially perpendicular to the display element array (longitudinal direction) of the display member 350. The display member 350 may be disposed in the normal direction of the trajectory of the rotational movement, pendulum movement, or reciprocation of the display member 350 by the scanning drive unit 340.

  The shutter device 330 is disposed on the front side (reflection surface side) of the room mirror 40. The liquid crystal shutter device takes two states, an optical scattering state and a transmission state, according to the applied voltage. The liquid crystal shutter device may use, for example, a Japanese plate glass-made um film (light control glass) that takes a transmissive state and a non-transmissive state according to whether a voltage is applied or not. The shutter device 330 may be, for example, a high-speed liquid crystal shutter device.

  The message display system 12 further includes an information processing device 200 for selecting a display message, and a display element driving unit or display driving unit 300 for driving the display elements P1 to P16 of the display member 350. Elements 200, 300, 330, 340 and 350 receive supply power from a power source (not shown). The display element driving unit 300 may be incorporated in the information processing device 200. The information processing device 200 may be a personal computer or a car navigation system.

  The information processing device 200 includes an input device 110 including operation keys and a display device 112. The information processing device 200 supplies information including a desired message to the display element driving unit 300 according to the input information input by the operation OP of the input device 110 by the user or the driver. The information processing device 200 supplies a control signal CTL (for example, on / off) to the display element driving unit 300, the scanning driving unit 340, and the shutter device 330 according to the input information. The information processing device 200 may supply the control signal CTL to the display element driving unit 300 and the shutter device 330 according to the input information and further according to the illuminance level of the illuminance sensor 120.

  The scanning drive unit 340 includes a motor, and causes the display member 350 to rotate, swing, or reciprocate in a scanning direction substantially perpendicular to the row of the display elements P1 to P16. The scanning drive unit 340 may include a cam mechanism that converts the rotational motion of the motor into a linear horizontal reciprocating motion.

  The scan driver 340 supplies the display element driver 300 with a reference position signal SP indicating the display range or the start position of the display scan range. The display element driving unit 300 performs on / off control and / or color control of the display elements P1 to P16 of the display member 350 synchronously with the reference position signal SP or asynchronously or independently of the reference position signal SP. A lighting signal PS_VS is generated. The display elements P1 to P16 are turned on or off according to the lighting signal PS_VS to emit light (light on) or turn off. The lighting signal PS_VS may include a plurality of m (for example, 16) pulse sequences in parallel for a plurality of (for example, 16) display elements P1 to P16. Each pulse sequence includes a series of a plurality of n (for example, 128) pulses on the time axis. When each of the display elements P1 to P16 is a set of display elements of a plurality of colors, the lighting signal PS_VS is a set (a plurality) or a single pulse representing a plurality of colors for each of the display elements P1 to P16. -It may be a sequence. The lighting signal PS_VS may be supplied to the display member 350 via a cable including a plurality of signal lines, for example, 16 lines for monochromatic display or 48 lines for 3-color display.

  The display elements P1 to P16 of the display member 350 blink in accordance with the lighting signal PS_VS from the display element drive unit 300 together with the rotation movement, pendulum movement or horizontal reciprocation movement of the display member 350 by the scanning drive section 340 and display in the display range. A spatial afterimage representing the message is formed. The horizontal scanning rate (frequency) of the display member 350 may be, for example, a certain scanning rate within a range of 4 to 20 scans per second (scanning cycle of 0.05 seconds to 0.25 seconds).

  The display element driver 300 further generates a shutter pulse signal PS_S in the generation period of the lighting signal PS_VS in synchronization with the reference position signal SP, or asynchronously or independently of the reference position signal SP, and supplies the shutter device 330 with the shutter pulse signal PS_S. Then, the shutter device 330 is closed.

  In response to the shutter pulse signal PS_S, the shutter device 330 transmits light or scenery outside the room mirror 40 that has passed through the rear window 30 when the display member 350 is not emitting light. Thereby, the driver can see the scenery outside the rear window 30.

  On the other hand, when the display member 350 emits light, part of the light from the light emitting elements P <b> 1 to P <b> 8 leaks from the light emitter 350 or is reflected by the rear window 30. The leaked light or reflected light may be dazzling for the driver, and may make it difficult to see the scenery outside the rear window 30 during the light emitting period of the light emitting elements P1 to P8 and the non-light emitting period immediately after that. In response to the shutter pulse signal PS_S, the shutter device 330 blocks reflected light or light leakage derived from the light of the display member 350 from entering the room mirror 40 when the display member 350 emits light. Thereby, the visibility of the driver to the rear scenery through the rear window 30 can be prevented from being disturbed.

  The information processing device 200 may receive the state signal ST and generate the control signal CTL for the display element driving unit 300 and the shutter device 330 in response thereto. The state signal ST indicates an operation state of the automobile 2, for example, an engine key insertion / removal, an engine start / stop, an acceleration / deceleration of the automobile 2, a brake operation, a steering operation, a direction indicator operation, and the like. It is a signal to represent.

  2A and 2B, the information processing device 200 includes a control unit 100, an input device 110, a display device 112, a memory 202, and a message generation unit 204. The memory 202 includes a program storage area, a data storage area, and a display information storage area. The control unit 100 may be a processor or a microcomputer. The control function of the control unit 100 may be implemented in the form of an integrated circuit as hardware, or may be implemented in the form of a program stored in the memory 202. In this case, the control unit 100 operates according to a program stored in the memory 202.

  The control unit 100 stores the input information related to the display message input or selected by the user via the input device 110 in the message storage area of the memory 202 and supplies it to the message generation unit 204. The control unit 100 may supply message selection information to the message generation unit 204 as the control signal CTL according to the input information. Alternatively and / or additionally, the control unit 100 may supply message selection information to the message generation unit 204 as the control signal CTL according to the state signal ST.

  Under the control of the control unit 100, the message generation unit 204 stores information including the message M in the message storage area of the memory 202 and / or extracts the display message M from the message storage area of the memory 202, and stores the message M. The included information is supplied to the display element driving unit 300. The message generator 204 generates a video signal or display data representing the designated or selected message M. For example, the message generation unit 204 generates display data representing a message such as “Thank you”, “Rapid braking”, “In traffic jam”, “Turn right”, or “Please leave a distance”. . The display element driving unit 300 sequentially supplies, for example, a lighting signal or blinking signal PS_VS of a matrix of m rows × n columns or 3m rows × n columns represented by the display data to the display member 350.

  The display element driving unit 300 includes a memory 302 that stores information related to display data or pixel data of a display afterimage, a lighting signal generation unit 304, and a timing adjustment unit or display control unit 322. The timing adjustment unit 322 includes an oscillator and a pulse generation circuit (not shown). The memory 302 may be a part of the memory 202. The lighting signal generation unit 304 may be a part of the message generation unit 322. The lighting signal generation unit 304 may be integrated with the display member 350 as a display unit. The lighting signal generation unit 304 and the message generation unit 222 may be part of the control unit 100. The timing adjustment unit or display control unit 322 may be a part of the message generation unit 204 and / or the control unit 100.

  2A, the timing adjustment unit 322 of the display element driving unit 300 receives the reference position signal SP from the scanning driving unit 340. The reference position signal SP may be generated by a rotation angle position detector provided in the scanning drive unit 340 or a position detection sensor or proximity sensor 342 that detects the approach or passage of the display member 30.

  The timing adjustment unit 322 supplies an address enable signal ADR_EN for enabling an address operation to the memory 302 to the lighting signal generation unit 304 in synchronization with the reference position signal SP. Further, the timing adjustment unit 322 supplies a display enable signal PS_EN for enabling reading of display data addressed from the memory 302 to the lighting signal generation unit 304 in synchronization with the reference position signal SP. The address enable signal ADR_EN and the display enable signal PS_EN can also be viewed as timing signals or control signals.

  As an alternative form, the timing adjustment unit 322 synchronizes with the reference position signal SP and supplies the lighting signal generation unit 304 with a cycle shorter than the generation cycle of the reference position signal SP (for example, 1/2 cycle, 1/3 cycle). A display enable signal PS_EN may be supplied. In this case, in each one scanning cycle, only a different part of the display data for displaying the full message M including a plurality of characters is read from the memory 302 and displayed by the display elements P1 to P16. All the display data for displaying the full message M including a plurality of characters is read from the memory 302 and displayed by the display elements P1 to P16 in a plurality of consecutive h scanning cycles. Therefore, the display enable signal PS_EN has a sequence having high level H pulses in different time periods with respect to a plurality of continuous reference position signals SP.

  In response to the address enable signal ADR_EN, the lighting signal generation unit 304 sequentially generates the display data read address ADDR of the memory 302 and sequentially reads the display data of the designated read address ADDR from the memory 302 in units of columns. The lighting signal generation unit 304 supplies the display data to the display member 350 as the lighting signal PS_VS. The display data may represent on / off states (1, 0) of the display elements P1 to P16, for example. The display data is, for example, a combination of on / off states (1, 0) of three colors (R, G, B) of the display elements P1 to P16, for example, green (0, 1, 0). , Red (1, 0, 0), yellow (1, 1, 0).

  In FIG. 2B, the lighting signal generator 304 of the display element driver 300 receives the reference position signal SP from the scan driver 340, and internally generates the address enable signal ADR_EN in synchronization with the reference position signal SP. In this case, the timing adjustment unit 322 displays on the lighting signal generation unit 304 in a cycle shorter than the cycle of the reference position signal SP (for example, 1/2 cycle or 1/3 cycle) asynchronously or independently of the reference position signal SP. The enable signal PS_EN may be supplied.

  The lighting signal generation unit 304 sequentially generates display data read addresses ADDR of the memory 302 in response to the internally generated address enable signal ADR_EN. In response to the display enable signal PS_EN from the timing adjustment unit 322, the lighting signal generation unit 304 sequentially reads display data of the designated read address ADDR from the memory 302 in units of columns. The lighting signal generation unit 304 supplies the display data to the display member 350 as the lighting signal PS_VS.

  The lighting signal generation unit 304 sequentially reads the display data of the currently designated address ADDR from the memory 302 in units of columns only while the display enable signal PS_EN is at the high level H. Accordingly, in each one scanning cycle, only different parts or partly overlapping parts of the display data for displaying the full message M including a plurality of characters are read from the memory 302 and displayed on the display elements P1 to P16. Is displayed. All the display data for displaying the full message M including a plurality of characters is read from the memory 302 and displayed by the display elements P1 to P16 in a plurality of consecutive h scanning cycles. Accordingly, the display enable signal PS_EN has a sequence having a high level H pulse in a time period different from each other or partially overlapping with each other with respect to a plurality of continuous reference position signals SP.

  3A, 3B, and 3C show examples of the rotational movement, pendulum movement, or horizontal reciprocation of the display member 350 that is mechanically scanned by the scanning drive unit 340. FIG.

  In FIG. 3A, the display member 350 rotates to draw a circle, and the display member 350 is biased in the display range at the upper position. For example, the display member 350 may emit light during the odd-numbered rotational scanning period, and the display member 350 may not emit light during the even-numbered rotational scanning period. As an alternative, for example, the display member 350 may emit light during the first rotation scanning period during three consecutive rotations, and the display member 350 may not emit light during the second and third rotation scanning periods during three rotations. . For example, the display member 350 emits light in a certain angular range in the display range during the odd-numbered rotational scanning period, and the display member 350 emits light in another angular range in the display range during the even-numbered rotational scanning period. Also good. For example, the display member 350 emits light in a certain angle range in the display range in the first rotation scanning period in three consecutive rotations, and the display member 350 is in the second rotation scanning period in three rotations. The display member 350 may emit light during the third rotation scanning period of three rotations. Thereby, the partial images in the respective angle ranges are visually synthesized by the afterimage effect to form a complete afterimage display of the message.

  In FIG. 3B, the display member 350 reciprocates or swings so as to draw a fan or an arc in the display range. In FIG. 3C, the display member 350 moves horizontally so as to draw a rectangle in the display range. In the case of FIGS. 3B and 3C, the display member 350 may emit light during the forward scan period, and the display member 350 may not emit light during the return pass period. As an alternative, the display member 350 may emit light during the odd-numbered forward scanning period, and the display member 350 may not emit light during all the backward and even-numbered forward periods.

  Referring to FIGS. 3A to 3C, the position detection sensor 342 or the scanning drive unit 340 may detect that the display member 350 has passed the reference position SP. The scan driver 340 supplies the reference position detection signal SP to the display element driver 300. The display elements P1 to P16 of the display member 350 start displaying at the reference position SP, and the lighting signal PS_VS is displayed at each position of a plurality of m time periods or slots (t1, t2,...) In the display range. Lighting and extinction or color emission corresponding to may be performed.

  FIG. 4 shows an example of a timing chart of the address enable signal ADR_EN, the address signal ADDR, the display enable signal PS_EN, the lighting signal PS_VS, and the shutter pulse signal PS_S generated by the display element driving unit 300 of FIG. 2A. ing.

  Referring to the left side of FIG. 4, in synchronization with the first (for example, odd-numbered) reference signal SP for each of a plurality of h pieces, the timing adjustment unit 322 performs a high-level H address / address in the time period corresponding to the display range. An enable signal ADR_EN and a display enable signal PS_EN are generated. Meanwhile, the timing adjustment unit 322 maintains the shutter pulse signal PS_S at the low level L. The value of h may be 2 or 3, for example. The lighting signal generation unit 304 generates a sequence of addresses ADDR for each column in accordance with the address enable signal ADR_EN. In accordance with the display enable signal PS_EN, the lighting signal generation unit 304 sequentially reads the display data sequence in the memory 302 specified by the address ADDR at times t1 to t22, and supplies it as the lighting signal PS_VS to the display elements P1 to P16. While the shutter pulse signal PS_S is at the low level L, the shutter device 330 maintains the closed state and blocks the incident light to the room mirror 40.

  In the remaining period until the next reference signal SP, the timing adjustment unit 322 maintains the address enable signal ADR_EN and the display enable signal PS_EN at the low level L, and maintains the shutter pulse signal PS_S at the high level H. Therefore, the lighting signal generation unit 304 does not supply display data. While the shutter pulse signal PS_S is at the high level H, the shutter device 330 is maintained in the open state and transmits the incident light to the room mirror 40 and the reflected light from the room mirror 40.

  Referring to the right side of FIG. 4, in synchronization with the next one (for example, even number) or two reference signals SP for each of a plurality of h pieces, the timing adjustment unit 322 includes the address enable signal ADR_EN and the display enable signal PS_EN. Is maintained at the low level L, and the shutter pulse signal PS_S is maintained at the high level H. Therefore, the lighting signal generation unit 304 does not supply display data. While the shutter pulse signal PS_S is at the high level H, the shutter device 330 maintains an open state and transmits incident light to the room mirror 40.

  FIG. 5 is an example of another timing chart of the address enable signal ADR_EN, the address signal ADDR, the display enable signal PS_EN, the lighting signal PS_VS, and the shutter pulse signal PS_S generated by the display element driver 300 of FIG. 2A. Is shown.

  Referring to the left side of FIG. 5, in synchronization with the first (for example, odd-numbered) reference signal SP for each of a plurality of h pieces, the timing adjustment unit 322 has a high level H address enable in a time period corresponding to the display range. A signal ADR_EN is generated, and a display enable signal PS_EN having a high level H is generated in a part of the periodic period in the display range. While the display enable signal PS_EN is at the high level H in the display range, the timing adjustment unit 322 maintains the shutter pulse signal PS_S at the low level L.

  The lighting signal generation unit 304 generates a sequence of addresses ADDR for each column in accordance with the address enable signal ADR_EN. In accordance with the display enable signal PS_EN, the lighting signal generation unit 304 sequentially reads the display data sequence in the memory 302 specified by the address signal ADDR at times t1 to t8 and t17 to t22, and outputs the lighting signal PS_VS to the display elements P1 to P16. Supply.

  While the shutter pulse signal PS_S is at the low level L, the shutter device 330 maintains the closed state and blocks the incident light to the room mirror 40.

  In the remaining period until the low level L display enable signal PS_EN and the next reference signal SP, the timing adjustment unit 322 maintains the address enable signal ADR_EN and the display enable signal PS_EN at the low level L, and the shutter pulse signal PS_S. Is maintained at a high level H. Therefore, the lighting signal generation unit 304 does not supply display data. While the shutter pulse signal PS_S is at the high level H, the shutter device 330 is maintained in the open state and transmits the incident light to the room mirror 40 and the reflected light from the room mirror 40.

  Referring to the right side of FIG. 5, in synchronization with the next one (for example, even-numbered) reference signal SP for each of a plurality of h pieces, the timing adjustment unit 322 has a high level H in the time period corresponding to the display range. The address enable signal ADR_EN is generated, and the display enable signal PS_EN having a high level H is generated in another part of the periodic period in the display range. While the display enable signal PS_EN is at the high level H in the display range, the timing adjustment unit 322 maintains the shutter pulse signal PS_S at the low level L.

  The lighting signal generation unit 304 generates a sequence of addresses ADDR for each column in accordance with the address enable signal ADR_EN. In accordance with the display enable signal PS_EN, the lighting signal generation unit 304 sequentially reads the display data sequence in the memory 302 designated by the address signal ADDR at time t9 to t16, and supplies it as the lighting signal PS_VS to the display elements P1 to P16.

  While the shutter pulse signal PS_S is at the low level L, the shutter device 330 maintains the closed state and blocks the incident light to the room mirror 40.

  In the remaining period until the low level L display enable signal PS_EN and the next reference signal SP, the timing adjustment unit 322 maintains the address enable signal ADR_EN and the display enable signal PS_EN at the low level L, and the shutter pulse signal PS_S. Is maintained at a high level H. Therefore, the lighting signal generation unit 304 does not supply display data. While the shutter pulse signal PS_S is at the high level H, the shutter device 330 is maintained in the open state and transmits the incident light to the room mirror 40 and the reflected light from the room mirror 40.

  FIG. 6 is another timing chart of the address enable signal ADR_EN, the address signal ADDR, the display enable signal PS_EN, the lighting signal PS_VS, and the shutter pulse signal PS_S generated by the display element driver 300 of FIG. 2B. An example is shown.

  Referring to the left side of FIG. 6, in synchronization with the first (for example, odd-numbered) reference signal SP for each of a plurality of h units, the timing adjustment unit 322 performs a high level H address enable in a time period corresponding to the display range. A signal ADR_EN is generated. On the other hand, the timing adjustment unit 322 generates a display enable signal PS_EN having a high level H in a part of a periodic time period in the display range, asynchronously or independently of the reference signal SP. While the display enable signal PS_EN is at the high level H in the display range, the timing adjustment unit 322 maintains the shutter pulse signal PS_S at the low level L.

  The lighting signal generation unit 304 generates a sequence of addresses ADDR for each column in accordance with the address enable signal ADR_EN. In accordance with the display enable signal PS_EN, the lighting signal generation unit 304 sequentially reads the display data sequence in the memory 302 specified by the address signal ADDR at times t2 to t9 and t18 to t22, and outputs the lighting signal PS_VS to the display elements P1 to P16. Supply.

  While the shutter pulse signal PS_S is at the low level L, the shutter device 330 maintains the closed state and blocks the incident light to the room mirror 40.

  In the remaining period until the low level L display enable signal PS_EN and the next reference signal SP, the timing adjustment unit 322 maintains the address enable signal ADR_EN and the display enable signal PS_EN at the low level L, and the shutter pulse signal PS_S. Is maintained at a high level H. Therefore, the lighting signal generation unit 304 does not supply display data. While the shutter pulse signal PS_S is at the high level H, the shutter device 330 is maintained in the open state and transmits the incident light to the room mirror 40 and the reflected light from the room mirror 40.

  Referring to the right side of FIG. 6, in synchronization with the next one (for example, even-numbered) reference signal SP for each of a plurality of h pieces, the timing adjustment unit 322 has a high level H in the time period corresponding to the display range. Address enable signal ADR_EN is generated. On the other hand, the timing adjustment unit 322 generates a display enable signal PS_EN having a high level H during another part of the period in the display range that is asynchronous or independent of the reference signal SP. While the display enable signal PS_EN is at the high level H in the display range, the timing adjustment unit 322 maintains the shutter pulse signal PS_S at the low level L.

  The lighting signal generation unit 304 generates a sequence of addresses ADDR for each column in accordance with the address enable signal ADR_EN. In accordance with the display enable signal PS_EN, the lighting signal generation unit 304 sequentially reads the display data sequence in the memory 302 designated by the address signal ADDR at times t1 and t10 to t17, and supplies the read data to the display elements P1 to P16.

  While the shutter pulse signal PS_S is at the low level L, the shutter device 330 maintains the closed state and blocks the incident light to the room mirror 40.

  In the remaining period until the low level L display enable signal PS_EN and the next reference signal SP, the timing adjustment unit 322 maintains the address enable signal ADR_EN and the display enable signal PS_EN at the low level L, and the shutter pulse signal PS_S. Is maintained at a high level H. Therefore, the lighting signal generation unit 304 does not supply display data. While the shutter pulse signal PS_S is at the high level H, the shutter device 330 is maintained in the open state and transmits the incident light to the room mirror 40 and the reflected light from the room mirror 40.

  5 and 6, the operations of the odd-numbered and even-numbered timing adjusting units 322 and the lighting signal generating unit 304 described above may be alternately repeated. As an alternative, all the plurality of portions of the display range may be displayed (covered) by three or more consecutive scanning periods for each of a plurality of h (h ≧ 3).

  5 and 6, as an additional form, in synchronization with the next one (for example, every third) reference signal SP for each of a plurality of h (h ≧ 3), the timing adjustment unit 322 includes an address The enable signal ADR_EN and the display enable signal PS_EN may be maintained at a low level L, and the shutter pulse signal PS_S may be maintained at a high level H. In this case, the lighting signal generation unit 304 does not supply display data (PS_VS). While the shutter pulse signal PS_S is at the high level H, the shutter device 330 maintains an open state and transmits incident light to the room mirror 40.

  7A and 7B show an example of lighting and extinction or color emission for displaying a residual image of a message by the display elements P1 to P16 of the display member 350 according to the time chart of FIG. 4 in the display system 12 of FIG. 2A. . In this case, the message “HELLO” is displayed as an afterimage by the display elements P1 to P8. 7A and 7B, the horizontal direction represents a mechanical rotation or horizontal scanning direction, and the vertical direction represents the column direction of the display member 350. When the scanning is a pendulum motion or a rotational motion, the downward direction of the display member 350 is the direction of the center of rotation.

  8A and 8B show an example of the lighting signal PS_VS according to the time chart of FIG. 4 in the display system 12 of FIG. 2A.

  In FIGS. 7A and 8A, a circle and a rectangular pulse with halftone dots of the display elements P1 to P8 indicate, for example, no lighting or green light emission, and a circle and a rectangular pulse with a diagonal line indicate, for example, lighting or red It shows luminescence. In FIGS. 7B and 8B, blank circles and rectangular pulses indicate no lighting.

  7A and 8A, the light emitting elements P1 to P8 perform blinking or lighting during the first or odd number of scanning periods of every h by the scanning driving unit 340 for display. For example, at time t1, the light emitting elements P1 to P7 are lit or emit red light, and the light emitting element P8 is not lit or emit green light. For example, at time t2, the light emitting elements P1 to P3 and P5 to P8 are in a non-lighting state or a green light emitting state. Some of the light from the light emitting elements P <b> 1 to P <b> 8 may leak from the light emitter 350 or be reflected by the rear window 30. The leaked light or reflected light feels dazzling for the driver, and reduces the visibility of the scenery outside the rear window 30 during the light emitting period of the light emitting elements P1 to P8 and the immediately subsequent non-light emitting period.

  As shown in FIG. 8A, at time t1 to t22 in the scanning period, the shutter pulse signal PS_S is in the low level L state, the shutter device 330 is closed, and the display member 350 is displayed during display or light emission of the display member 350. The reflected light or light leakage derived from the light from the light is blocked from entering the room mirror 40.

  In FIG. 7B, the light emitting elements P1 to P8 are completely turned off during the scanning period, so that the scenery outside the rear window 30 can be easily seen by the driver even during the scanning. As shown in FIG. 8B, during the scanning period in which the lighting signal PS_VS is at the low level L, the shutter pulse signal PS_S is in the high level H state, and the shutter device 330 is opened and transmitted through the rear window 30. The incident light on the outside mirror or the room mirror 40 is transmitted.

  The display state of FIGS. 7A and 8A and the non-display state of FIGS. 7B and 8B may occur alternately. As an alternative, the display state of FIGS. 7A and 8A and the non-display state of FIGS. 7B and 8B may occur periodically at a rate of once and twice every three scan periods, respectively.

  9A and 9B show another example of lighting and extinction or color emission for displaying a residual image of a message by the display elements P1 to P16 of the display member 350 according to the time chart of FIG. 5 in the display system 12 of FIG. 2A. ing. FIG. 9C shows an example of the non-display state of the display member 350.

  10A and 10B show another example of the lighting signal PS_VS according to the time chart of FIG. 5 in the display system 12 of FIG. 2A. FIG. 10C corresponds to FIG. 9C and shows an example of a temporal sequence at times t1 to t22 in which the display elements P1 to P8 of the display member 350 are in the non-lighting state corresponding to the lighting signal PS_VS.

  In FIGS. 10A and 10B, a broken-line rectangular pulse indicates the absence of pulses for the display elements P1 to P8 in the lighting signal PS_VS. The broken pulse indicates that the display data addressed in the memory 302 is not read out, or is not supplied to the display member 350 as the lighting signal PS_VS even if the display data is read out.

  9A and 10A, the light-emitting elements P1 to P8 perform blinking or lighting at times t1 to t8 and t17 to t22 in the scanning period by the scan driving unit 340 according to the lighting signal PS_VS. During this period, while the shutter pulse signal PS_S is at the low level L, the shutter device 330 maintains the closed state and blocks the incident light to the room mirror 40.

  9A and 10A, the light emitting elements P1 to P8 are turned off at times t9 to t16 in the scanning period by the scanning drive unit 340 in accordance with the lighting signal PS_VS. During this period, while the shutter pulse signal PS_S is at the high level H, the shutter device 330 maintains an open state, and transmits the incident light to the room mirror 40 and the reflected light from the room mirror 40.

  9B and 10B, the light emitting elements P1 to P8 perform blinking or lighting during the time t9 to t16 in the scanning period by the scanning driving unit 340 according to the lighting signal PS_VS. During this period, while the shutter pulse signal PS_S is at the low level L, the shutter device 330 maintains the closed state and blocks the incident light to the room mirror 40. During this period, while the shutter pulse signal PS_S is at the high level H, the shutter device 330 maintains an open state, and transmits the incident light to the room mirror 40 and the reflected light from the room mirror 40. The message “HELLO” is displayed by a combined afterimage of light emission at different positions of the light emitting elements P1 to P8 in FIGS. 9A and 9B.

  9B and 10B, the light emitting elements P1 to P8 are turned off at times t1 to t8 and t17 to t22 in the scanning period by the scan driving unit 340 in accordance with the lighting signal PS_VS. During this period, while the shutter pulse signal PS_S is at the high level H, the shutter device 330 maintains an open state, and transmits the incident light to the room mirror 40 and the reflected light from the room mirror 40.

  9C and 10C correspond to FIGS. 7B and 8B. However, the scanning period of FIGS. 9C and 10C may not be provided.

  11A and 11B show still another example of lighting and extinction or color emission for displaying an afterimage of a message by the display elements P1 to P16 of the display member 350 according to the time chart of FIG. 6 in the display system 14 of FIG. 2B. Show. FIG. 11C shows an example of the non-display state of the display member 350.

  12A and 12B show still another example of the lighting signal PS_VS according to the time chart of FIG. 6 in the display system 14 of FIG. 2B. FIG. 12C corresponds to FIG. 9C and shows an example of a temporal sequence at times t1 to t22 in which the display elements P1 to P8 of the display member 350 are in the non-lighting state corresponding to the lighting signal PS_VS.

  In FIGS. 11A and 12A, the light emitting elements P1 to P8 perform blinking or lighting at times t2 to t9 and t18 to t22 in the scanning period by the scanning driving unit 340 in accordance with the lighting signal PS_VS. During this period, while the shutter pulse signal PS_S is at the low level L, the shutter device 330 maintains the closed state and blocks the incident light to the room mirror 40.

  In FIGS. 11A and 12A, the light emitting elements P1 to P8 are turned off at times t1 and t10 to t17 in the scanning period by the scanning driver 340 in accordance with the lighting signal PS_VS. During this period, while the shutter pulse signal PS_S is at the high level H, the shutter device 330 maintains an open state, and transmits the incident light to the room mirror 40 and the reflected light from the room mirror 40.

  11B and 12B, the light emitting elements P1 to P8 perform blinking or lighting at times t1 and t10 to t17 in the scanning period by the scanning driving unit 340 in accordance with the lighting signal PS_VS. During this period, while the shutter pulse signal PS_S is at the low level L, the shutter device 330 maintains the closed state and blocks the incident light to the room mirror 40. During this period, while the shutter pulse signal PS_S is at the high level H, the shutter device 330 maintains an open state, and transmits the incident light to the room mirror 40 and the reflected light from the room mirror 40. The message “HELLO” is displayed by a combined afterimage of light emission at different positions of the light emitting elements P1 to P8 in FIGS. 11A and 11B.

  11B and 12B, the light emitting elements P1 to P8 are turned off at times t2 to t9 and t18 to t22 in the scanning period by the scan driving unit 340 in accordance with the lighting signal PS_VS. During this period, while the shutter pulse signal PS_S is at the high level H, the shutter device 330 maintains an open state, and transmits the incident light to the room mirror 40 and the reflected light from the room mirror 40.

  11C and 12C correspond to FIGS. 7B and 8B. However, the scanning period of FIGS. 11C and 12C may not be provided.

  When the illuminance detected by the illuminance sensor 120 is small, that is, the illuminance of outside light is low, the control unit 100 or the timing adjustment unit 322 displays the entire message M within a display range over a plurality of h scanning periods. The ratio R (= Nd: Nn or Td: Tn) between the number Nd or the total period Td and the non-display number Nn or the total period Tn may be reduced. Thereby, the period of the open state of the shutter device 330 may be relatively long. Thereby, when the outside scenery is dark, the outside scenery which is incident through the rear window 30 and reflected on the room mirror 40 can be brightened. When the outside scenery is dark, it is not difficult to see even if the brightness (luminance) on the display member 350 is somewhat lowered.

  In this case, the control unit 100 of the information processing device 200 can change the illuminance DTC detected by the illuminance sensor 120 according to FIGS. 7A and 7B, FIGS. 9A and 9B, or FIGS. 11A and 11B, or FIGS. The ratio R of the display Nd or Td and the non-display Nn or Tn in 9C or FIGS. 11A to 11C is changed. Further, in addition to or as an alternative to the change in the ratio described above, the light emission intensity of the display elements such as LEDs or the light emitting elements P1 to P16 may be determined or changed according to the illuminance DTC of the external light. That is, when the illuminance DTC of outside light is high, the light emission intensity of the display element may be adjusted to increase.

  13A and 13B show an example of a flowchart of control for message display executed by the information processing device 200. FIG.

  Referring to FIG. 13A, in step 502, the control unit 100 of the information processing device 200 refers to the message storage area of the memory 202 and determines whether the message display state is on. If it is determined that the message display state is the on state, the procedure proceeds to step 504. If it is determined that the message display state is not the on state, that is, the off state, the procedure proceeds to step 526.

  In step 504, the control unit 100 selects a message to be displayed from the message storage area of the memory 202 according to information input by the user and / or according to the status signal ST of the automobile 2. One or more messages may be stored in the message storage area of the memory 202 by the user.

  In step 506, the control unit 100 acquires a signal DTC representing the intensity of illuminance from the illuminance sensor 120. In step 507, the control unit 100 determines or changes the light emission intensity of the display elements P1 to P16 according to the intensity of illuminance. In step 508, the control unit 100 determines a display / non-display ratio R (= Nd: Nn or Td: Tn) in the display range according to the magnitude of the illuminance. The ratio R is, for example, 1: 1, 1: 2, or 1: 3. When the light emission intensity and the ratio R of the display elements P1 to P16 are fixed, steps 506 to 508 may be skipped as indicated by a broken line.

  In step 510, the control unit 100 activates the display element driving unit 300, the shutter device 330, and the scanning driving unit 340. When the ratio R is variable, the control unit 100 supplies a control signal CTL representing the ratio R to the display element driving unit 300.

  Referring to FIG. 13B, in step 512, the display element driving unit 300 (timing adjustment unit 322) enables and disables display in a time-sharing manner. That is, the display element driver 300 supplies the lighting signal PS_VS and the shutter pulse signal PS_S. When the ratio R is variable, the display element driving unit 300 enables and disables display in a time-sharing manner according to the ratio R.

  In step 514, the control unit 100 refers to the message storage area of the memory 202 and determines whether the message display is in an off state. If it is determined that the message display is in the off state, the procedure proceeds to step 524. Steps 512 to 514 are repeated until it is determined that the message display is in the off state.

  In step 524, the control unit 100 stops the display element driving unit 300, the shutter device 330, and the scanning driving unit 340 to stop the generation of the lighting signal PS_VS and the pulse signal PS_S. At this time, the shutter device 330 is stopped in the open state.

  In step 526, control unit 100 determines whether driving of automobile 2 has been completed or the engine key has been turned off based on state signal ST. If it is determined that driving of the automobile 2 has been completed, the procedure exits the routine of FIGS. 13A and 13B. If it is determined that the driving of the automobile 2 has not ended, the procedure returns to step 502 in FIG. 13A.

  All examples and conditional expressions given here are intended to help the reader understand the inventions and concepts that have contributed to the promotion of technology, such examples and It should be interpreted without being limited to the conditions. Also, the organization of such examples in the specification is not related to showing the superiority or inferiority of the present invention. Although embodiments of the present invention have been described in detail, it should be understood that various changes, substitutions and variations can be made thereto without departing from the spirit and scope of the present invention.

12, 14 Message display system 30 Rear window 40 Room mirror 120 Illuminance sensor 200 Information processing device 100 Control unit 110 Input device 112 Display device 202 Memory 204 Message generation unit 300 Display element driving unit 302 Memory 304 Lighting signal generation unit 306 Timing Adjustment unit 330 Shutter device 340 Scanning drive unit

Claims (7)

A control unit;
A display unit including a plurality of display elements disposed on the window side and lit for display in a display period in accordance with a first control signal from the control unit;
A plurality of display elements attached, and a scanning drive unit that mechanically scans the plurality of display elements;
According to a second control signal from the control unit, arranged on the mirror side, blocks light originating from the display element of the display unit in the display period of the display unit, and in the non-display period of the display unit An optical blocking device that transmits light from the window;
Including display system. The display system further includes a memory,
The scan driver generates a reference position signal;
The display unit reads out display data in the memory based on an address signal synchronized with the reference signal and supplies the display data to the display element according to the first control signal. The display system according to 1. A control unit;
A display member disposed on the window side and including a plurality of display elements;
A scanning drive unit attached to the display member and mechanically scanning the display member;
A display element driving unit that drives the display member in a display period in scanning of the display member in accordance with a first control signal from the control unit;
Arranged on the mirror side, according to a second control signal from the control unit, blocking light originating from the display element of the display member in the display period of the display member, and in the non-display period of the display member An optical blocking device that transmits light from the window;
Including display system. The display system further includes a memory,
The scan driver generates a reference position signal;
The display element driver reads out display data in the memory and supplies the display member to the display member according to the first control signal based on an address signal synchronized with the reference signal. The display system according to claim 3.   5. The display period according to claim 1, wherein the display period is generated once or more in one scanning period by the scanning driving unit in synchronization with scanning by the scanning driving unit. Display system described.   6. The display period according to claim 1, wherein the display period occurs at least once in one scanning period by the scanning driving unit, asynchronously or independently of scanning by the scanning driving unit. Display system described. Control a display system including a control unit, a display member disposed on the window side and including a plurality of display elements, a scanning drive unit that mechanically scans the display member, and an optical blocking device disposed on the mirror side. A method,
Driving the display member in a display period while the scan driving unit mechanically scans the display member in accordance with a first control signal from the control unit;
According to a second control signal from the control unit, the optical blocking device blocks light originating from the display element of the display member in the display period of the display member, and in a non-display period of the display member Transmitting light from the window;
Including methods.

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