JP2022127027A - Video display device - Google Patents

Abstract

To output stable signals without generating influences of a noise generated when a cable is inserted and removed.SOLUTION: A video display device comprises: a display unit 15 for displaying a video; a display control unit 16 that controls the display unit 15; a receiver that receives a video signal transmitted from external equipment 2 connected via a communication interface and a connection detection signal for detecting connection with the external equipment 2; a main control unit 7 connected with the receiver and that transmits to the display control unit 16 a display control signal for controlling a display state of the display unit 15; and a display signal output unit that outputs a display control signal to the display control unit 16 depending on a state of the connection detection signal transmitted from the communication interface not via the receiver.SELECTED DRAWING: Figure 1

Description

The present invention relates to a video display device.

2. Description of the Related Art As a video display device having a video display function, there is a projection device that is connected to a video supply device, which is an external device, and projects video based on a signal input from the external device upon detection of connection.

In Patent Document 1, an external device is connected by HDMI (registered trademark) (High-Definition Multimedia Interface) as an external interface, the connection is detected by the input of a 5V signal that is a power supply signal, and the input from the external device is detected by the detection of the connection. Disclosed is a projection device that projects an image based on the received signal.

JP 2016-100664 A

Here, when connected to an external device, the projection device controls the light source and projects an image after a signal input from the external device is stabilized. For example, when the HDMI receiver detects a 5V signal and the video signal is input to the main controller of the projector, the main controller outputs a synchronization signal for turning on the light source, and outputs a lighting control signal through the sub-controller. do. The projection apparatus controls the light source control unit to light the light source and project an image based on the synchronization signal for lighting the light source and the lighting control signal.

At this time, when the projector is connected to an external device via an HDMI cable, noise may occur through the connection terminal when the HDMI cable is inserted into or removed from the connection terminal of the projection apparatus.

However, if the HDMI cable is unplugged during image projection, there is a gap between the time it takes to detect that the projector has been unplugged and stop projection, and the time it takes for the synchronization signal for turning on the light source to be input to the light source control unit. A gap occurs in the image, and as a result, an image based on the noise signal is projected. This happens because the main control unit checks whether the HDMI 5V signal needs to be input, transmits the result to the sub-control unit, and the sub-control unit sends the lighting control signal. be.

SUMMARY OF THE INVENTION It is an object of the present invention to output a stable signal without being affected by noise generated when a cable is inserted or removed.

A video display device according to the present invention includes:
a display unit for displaying images;
a display control unit that controls the display unit;
a receiver that receives a video signal transmitted from an external device connected via a communication interface and a connection detection signal that detects connection with the external device;
a main control unit connected to the receiver and transmitting a display control signal for controlling a display state of the display unit to the display control unit;
a display control signal output unit that outputs the display control signal to the display control unit according to the state of the connection detection signal transmitted from the communication interface without passing through the receiver.

According to the present invention, a stable signal can be output without being affected by noise that occurs when a cable is inserted or removed.

It is a figure showing composition of a projection device concerning a 1st embodiment of the present invention. It is a figure showing composition of a main control part of a projection device concerning a 1st embodiment of the present invention. 8A is a flowchart showing a 5V monitoring processing procedure of the main control unit of the projection apparatus according to the first embodiment of the present invention, and FIG. 7B is a flowchart showing a 5V detection processing procedure; 5 is a time chart showing timings of a light source lighting synchronization signal, a lighting permission signal, and a light source projection stop timing when an HDMI cable of the projection apparatus according to the first embodiment of the present invention is unplugged. It is a figure which shows the structure of the projection apparatus based on the 2nd Embodiment of this invention. 8 is a time chart showing display element control signals output from a logic circuit when an external device is connected to the projection apparatus according to the second embodiment of the present invention; It is a figure which shows the structure of the projection apparatus based on the 3rd Embodiment of this invention. FIG. 11 is a flow chart showing an input switching processing procedure of the projection device according to the third embodiment of the present invention; FIG. FIG. 11 is a time chart for explaining an input switching processing procedure of the projection device according to the third embodiment of the present invention; FIG.

A projection device as a video display device according to an embodiment of the present invention will be described below with reference to the drawings.

(First embodiment)
A projection device 1 according to the present embodiment is connected to an external device 2 that supplies a video signal via an HDMI cable 3, as shown in FIG. The communication interface is an HDMI interface, which is a video input/output digital interface. The external device 2 is an HDMI source device such as a video disc player, a personal computer, or the like that supplies a video signal. The projection device 1 is an HDMI sink device. An external device 2 that is an HDMI source device has an HDMI transmitter 4 .

The HDMI transmitter 4 is an interface for transmitting video signals via the HDMI cable 3 . In addition, the HDMI transmitter 4 receives EDID (Extended Display Identification Data) information for inter-device authentication transmitted via the HDMI cable 3, and transmits CEC (Consumer Electronics Control), which is a control signal for inter-device control. An interface for sending and receiving data. Also, the HDMI transmitter 4 is connected to the 5V signal line that is the power supply line of the HDMI cable 3 so that it can detect that the external device 2 as the source device and the projection device 1 as the sink device are connected. Control the voltage on the signal pin to 5V.

The projector 1 includes an HDMI terminal 5 to which an HDMI cable 3 is connected, an HDMI receiver 6 for receiving video signals transmitted from the external device 2, a main controller 7, a sub-controller 8, and a light source 9 for projecting light onto the screen. , a light source controller 10 that controls the operation of the light source 9 , a DMD (Digital Micromirror Device) 11 that is a display element, a display element controller 12 that controls the DMD 11 , and a logic circuit 13 . The light source 9, DMD 11, and lens 14 constitute a display section 15 that displays an image. The light source control unit 10 and the display element control unit 12 constitute a display control unit 16 that controls the display state/non-display state of the display unit 15 .

The HDMI terminal 5 is a terminal for receiving video signals from the external device 2 via the HDMI cable 3 .

When a digitized video signal is input from the HDMI terminal 5 , the HDMI receiver 6 receives the video signal and outputs it to the main control section 7 . Also, the HDMI receiver 6 is an interface for transmitting EDID information via the HDMI cable 3 and transmitting/receiving CEC. Also, the HDMI receiver 6 is connected to the 5V signal line that is the power supply line of the HDMI cable 3 so that it can detect that the external device 2 that is the source device and the projection device 1 that is the sink device are connected. It receives the voltage of the signal pin from the HDMI terminal 5 .

The main control unit 7 is composed of a main microcomputer including a processor with higher processing capacity in the projector 1. As shown in FIG. ) 22 , a RAM (Random Access Memory) 23 , and a storage unit 24 . Each of these is connected to each other via a system bus 25 .

The CPU 21 is, for example, a microprocessor or the like, and is a central processing unit that executes various processes and calculations. The ROM 22 stores an initial program for performing various initial settings, hardware inspection, program loading, and the like. The RAM 23 temporarily stores various software programs executed by the CPU 21, data necessary for executing these software programs, and the like, and is used as a work memory. The storage unit 24 is a non-volatile memory such as EPROM (Erasable Programmable Read Only Memory), EEPROM (Electrically Erasable Programmable Read Only Memory), flash memory, etc., and stores software programs and data used for various processes. .

The main control unit 7 performs overall control of the projection device 1 , such as display drive control of the DMD 11 composed of micromirror elements, according to the video data sent from the HDMI receiver 6 . In addition, as will be described later, the main control unit accesses the HDMI receiver 6, reconfirms the 5V signal, and executes 5V detection processing for controlling the on/off of the light source 9. FIG.

The sub control unit 8 is composed of a microcomputer that is a sub to the main control unit 7. As shown in FIG. 22 , a RAM (Random Access Memory) 23 , and a storage unit 24 .
The sub-controller 8 has a circuit scale smaller than that of the main controller 7 and has low specifications such as power saving and low-speed communication. The sub-controller 8 executes necessary processing when the projection device 1 is in the standby state, and can communicate with the main controller 7 even when the projection device 1 is in the standby state. Here, a 5V signal line is connected to the sub-controller 8 from the HDMI terminal 5 , and when the external device 2 is connected to the projector 1 via the HDMI cable 3 , the 5V signal is sent to the sub-controller 8 . is entered. The sub-controller 8 performs 5V monitoring processing to monitor whether or not the 5V signal has changed. When the 5V signal is input to the sub-controller 8 when the main controller 7 is in the standby state, the sub-controller 8 detects that the 5V signal has changed and turns on the main controller 7. Output commands. In response to this command, the main control unit 7 is turned on, executes 5V detection processing to reconfirm whether the 5V detection by the sub control unit was correct, and controls the on/off of the light source 9 .

The light source 9 emits blue wavelength band light, green wavelength band light, and red wavelength band light toward the display element in a time-division manner within one image frame. The light of each color emitted from the light source 9 can be appropriately adjusted by removing unnecessary wavelength components by a color wheel before being irradiated to the display element. The projection device 1 of this embodiment is of a DLP (Digital Light Processing) system, and a DMD 11 is used as a display element.

The light source control unit 10 controls the lighting of the primary color lights by driving the light sources 9 to emit the primary color lights in a time division manner.

DMD 11 comprises a micromirror element. The micromirror element performs a display operation by on/off control of the posture inclination angle of each of a large number of micromirrors arranged in a two-dimensional array. The display element control unit 12 controls the micromirror elements of the DMD 11 to reflect primary color light from the color wheel to form image light. The image light reflected by the DMD 11 is projected onto a screen or the like provided outside the projection device 1 via a lens 14 within the projection device 1 .

The logic circuit 13 is composed of an AND circuit that outputs a logical product of input signals, and outputs a control signal for controlling on/off of the light source 9 to the light source control section 10 . The main control section 7 and the sub-control section 8 are connected to inputs of the logic circuit 13 . As an input signal to the logic circuit 13, the main control unit 7 outputs a light source lighting synchronizing signal, which is a display control signal for controlling the light source 9 to emit primary color light in a time division manner. The sub-controller 8 outputs a lighting permission signal that permits lighting of the light source 9 as an input signal to the logic circuit 13 . Furthermore, the input of the logic circuit 13 is connected to the HDMI terminal 5 . The HDMI terminal 5 outputs the signal of the 5V signal pin as the input signal to the logic circuit 13 . The logic circuit 13 outputs the logical product of these input signals and outputs a high level signal only when the signal levels of all the input signals are high level. When the lighting permission signal is at a high level, which is a signal level that permits lighting, and the 5V signal pin is at a high level, which is a signal level indicating 5V, a light source lighting synchronization signal is output to the light source controller 10 . . Even if the lighting permission signal is at a high level that permits lighting, when the 5V signal pin is at a low level that does not indicate 5V, the light source lighting synchronization signal is not output to the light source controller 10. Here, since the 5V signal is used to detect the connection of the external device 2, it corresponds to the connection detection signal of the present invention. The synchronization signal for turning on the light source corresponds to the display control signal for controlling the display state of the invention, and the logic circuit 13 corresponds to the display control signal output section of the invention. The logic circuit 13 outputs a light source lighting control signal for controlling the on/off of the light source 9 based on the on/off control of the light source 9 by the 5V detection processing of the main control unit 7 . and serves as a gate circuit for limiting the output of the control signal for turning on the light source.

Next, in the projection device 1 described above, when the projection device 1 is in the standby state, the external device 2 is connected to the projection device 1 via the HDMI cable 3, and the operation until the projection device 1 is turned on will be described. do.
A 5V signal pin for power supply of the HDMI terminal 5 is connected to the sub-controller 8 and the logic circuit 13 , and rises to a high level when connected to the external device 2 via the HDMI cable 3 . In the standby state in which the projector 1 is not powered on, only the sub-controller 8 is active, and the sub-controller 8 is executing 5V monitoring processing for monitoring the state of the 5V signal. Receiver 6 is in the off state. At this time, the light source control section 10, the light source 9 and the display element control section 12 are also not operating.

In this standby state, when the HDMI cable 3 is inserted into the HDMI terminal 5 and the external device 2 is connected to the projector 1 via the HDMI cable 3, the sub-controller 8 detects the 5V signal and the main controller 7 to turn on the projector 1 . When the projector 1 is turned on, the main control unit 7 starts up the HDMI receiver 6, sets the HDMI receiver 6, equalizes, acquires received video information, HDCP (High-Bandwidth Digital Content Protection) authentication process, and the like. I do. Further, the main control unit 7 accesses the HDMI receiver 6, determines whether or not the external device 2 is connected via the HDMI cable 3 and the 5V signal is detected, and executes 5V detection processing for reconfirming.

Next, the operation of the 5V monitoring process and the 5V detection process will be described with reference to the flow charts of FIGS. 3(a) and 3(b).

3A is a flowchart showing 5V monitoring processing for monitoring whether or not the external device 2 is connected via the HDMI cable 3 in the projection device 1. FIG.

The sub-controller 8 determines whether a change has occurred in the input of the 5V signal pin. That is, it is determined whether or not the HDMI cable 3 has been newly connected to the HDMI terminal 5, or whether or not the HDMI cable 3 connected to the HDMI terminal 5 has been disconnected from the HDMI terminal 5 (step S101). Here, when the projector 1 is in the standby state, the external device 2 is connected to the projector 1 via the HDMI cable 3, and it is determined that the input of the 5V signal pin has changed (step S101: YES ), the sub control unit 8 issues a 5V detection processing event to the main control unit 7 for executing the 5V detection processing to the main control unit 7 (step S102). When the 5V detection processing event processing is issued, the main control unit 7 is activated as described above, and after setting the HDMI receiver 6 and the like, the main control unit 7 starts the 5V detection processing. If no change in the signal level of the 5V signal pin is detected (step S101: NO), the process returns to step S101 and the process of step S101 is repeated until a change in the signal level of the 5V signal pin is detected. This 5V monitoring process is always executed even when the projection device 1 is in the ON state other than when it is in the standby state. For example, when the projector 1 is on and the external device 2 is connected to the projector 1 via the HDMI cable 3, if the HDMI cable 3 is unplugged from the HDMI terminal 5, the input to the 5V signal pin detects 5V. from a high level of 5V to a low level of 5V undetected. In this case as well, the sub-controller 8 issues a 5V detection processing event to the main controller 7 .

FIG. 3B is a flowchart showing 5V detection processing for determining whether or not a 5V signal has been detected in the projector 1 .

The main control unit 7 accesses the HDMI receiver 6 and determines whether or not a 5V signal is detected from the 5V signal pin (step S201). When a 5V signal is detected (step S201: YES), it is determined that the external device 2 is connected via the HDMI cable 3, and the main control unit 7 accesses the HDMI receiver 6 to check the signal state of the video signal. It is determined whether it is stable (step S202). The stability of the signal state of the video signal is determined according to the error detection result of the video data by, for example, parity check, checksum, etc., or the vertical synchronization signal or horizontal synchronization signal of the video signal sent from the HDMI receiver 6 is output. The determination is made by measuring the time interval between the signals, and confirming that the signal is output for a certain period of time at the predetermined time interval. If the output time interval of the vertical synchronizing signal or the horizontal synchronizing signal of the video signal is output for a predetermined time or longer within the range of the predetermined time interval, it is determined that the signal state of the video signal is stable. . Conversely, if the output time interval of the vertical synchronizing signal or the horizontal synchronizing signal of the video signal is not output for a certain period of time or longer within the range of the predetermined time interval, it means that the signal state of the video signal is not stable. be judged.

When it is determined that the signal state of the video signal is stable (step S202: YES), the main controller 7 decides to turn on the light source 9, and instructs the sub-controller 8 to turn on the light source 9. (Step S203). If it is determined that the signal state of the video signal is not stable (step S202: NO), the process returns to step S202, and the process of step S202 is repeated until the signal state of the video signal is stabilized. After notifying the sub-controller 8 of turning on the light source 9 in step S203, the main controller 7 emits the primary color lights of R (red), G (green), and B (blue) from the light source 9 by time division. By outputting a synchronization signal for light source lighting, which is a control signal to be emitted, the light source controller 10 is instructed to turn on the light source 9 (step S204). The sub-controller 8 notified by the main controller 7 to turn on the light source 9 outputs a lighting permission signal to turn on the light source 9 . The synchronization signal for lighting the light source and the lighting permission signal are input to the logic circuit 13 . A 5V signal line, which is a power supply signal, is further connected to the logic circuit 13 from the HDMI terminal 5 . The synchronization signal for lighting the light source and the lighting permission signal are input to the light source control section 10 via the logic circuit 13 .

Next, the synchronization signal for light source lighting, the lighting permission signal, and the projection timing of the light source 9 when the external device 2 is connected to the projection apparatus 1 via the HDMI cable 3 will be described with reference to the time chart of FIG. do.

When the external device 2 is connected to the projector 1 via the HDMI cable 3, the voltage of the HDMI 5V signal pin rises to high level at time t1. In response to the rising voltage of the 5V signal pin, the main control section 7 starts executing the 5V detection process. Then, as described above, when it is determined that the signal state of the video signal input from the external device 2 is stable, the sub-controller 8 is notified to turn on the light source 9 . The main control section 7 outputs a synchronizing signal for lighting the light source at time t2, and at approximately the same time, the sub-control section 8 raises the lighting permission signal to a high level and outputs a signal for permitting lighting. Since the voltage of the 5V signal pin has risen to a high level at the time t1, the logic circuit 13 controls the lighting of the light source 9 from the time when both the synchronization signal for lighting the light source and the lighting permission control signal are output. A synchronization signal is output to the light source controller 10 . The light source 9 is turned on based on this signal. The synchronization signal for lighting the light source is not output unless the lighting permission signal outputs a signal permitting lighting of the light source 9 . In the above description, the lighting permission signal is output at approximately the same time as t2, which is the output timing of the lighting synchronization signal for the light source. can be adjusted. Thereby, the timing at which the light source 9 is turned on can be adjusted.

Next, returning to the flowchart of FIG. 3B, in step S201 for determining whether or not the 5V signal is detected from the 5V signal pin, the processing operation when the 5V signal is not detected (step S201: NO). will be explained.

When the 5V signal is not detected in the 5V detection process (step S201: NO), it is determined that the HDMI cable 3 has been pulled out and the external device 2 is disconnected, and the main control unit 7 turns off the light source 9. Then, the sub-controller 8 is notified to turn off the light source 9 (step S205). The sub-controller 8 notified by the main controller 7 to turn off the light source 9 stops outputting the lighting permission signal. After notifying the sub-controller 8 to turn off the light source 9 in step S205, the main controller 7 instructs the light source controller 10 to turn off the light source 9 by stopping the output of the synchronization signal for turning on the light source. instruct (step S206). Outputs of the synchronization signal for lighting the light source and the lighting permission signal are input to the logic circuit 13 . By stopping the output of the synchronization signal for lighting the light source and the lighting permission signal, the synchronization signal for lighting the light source is no longer output from the logic circuit 13 to the light source controller 10 . However, the signal of the 5V signal pin of the HDMI terminal 5 is also input to the logic circuit 13 . The signal of the 5V signal pin falls from a high level indicating 5V to a low level indicating that 5V is not detected before the output of the synchronization signal for turning on the light source from the main control unit is stopped. . Therefore, the logic circuit 13 receives the trailing edge of the 5V signal and prevents the light source lighting synchronization signal from being output to the light source control section 10 before the output of the light source lighting synchronization signal from the main control section is stopped. there is

The synchronization signal for light source lighting, the lighting permission signal, and the timing of stopping the projection of the light source 9 when the HDMI cable 3 is pulled out and the external device 2 is disconnected will be described with reference to the time chart of FIG. .

When the HDMI cable 3 is pulled out and the external device 2 is disconnected from the projector 1, the voltage of the HDMI 5V signal pin falls from high level to low level at time t3. In response to the fall of the voltage of the 5V signal pin, the main control section 7 starts executing the 5V detection process. Then, as described above, when it is determined that the 5V signal is not detected, the sub-controller 8 is notified to turn off the light source 9 . The main control section 7 stops outputting the synchronization signal for lighting the light source at time t4. Stop output. Thus, when the present invention using the output of the logic circuit 13 to which the voltage of the 5V signal pin is directly input is not adopted, the sync signal for lighting the light source and the lighting enable signal are generated after the voltage of the 5V signal pin falls. , the output is stopped by software processing in the main control section 7 and the sub-control section 8, so the processing takes time, and the stop processing is delayed by the time difference between t4 and t3. However, since the voltage of the 5V signal pin is directly input to the logic circuit 13, the logic circuit 13 turns off the light source 9 almost at the time t3 when the signal level of the 5V signal pin falls to a low level at which the 5V signal is not detected. A signal instructing to turn off is output to the light source control unit 10 . That is, the output of the synchronization signal for lighting the light source and the lighting permission signal is forcibly stopped instantaneously by the hardware in response to the fall of the voltage of the 5V signal pin. The light source 9 is turned off based on this signal. If the turning off of the light source 9 is controlled only by the synchronizing signal for turning on the light source and the turning-on permission signal, it takes time for the software processing to stop the output of both signals. It may be superimposed on the previous projected light. On the other hand, by inputting a 5V signal line to the logic circuit 13, it is possible to turn off the light source instantaneously after detecting that the cable is pulled out. There is no overlap with light.

In addition, the voltage of the 5V signal pin may be unstable, and even if the logic circuit 13 outputs a signal for controlling the light source 9 to be off in response to the fall of the 5V signal, this may be an erroneous detection. It is possible. In this case, the 5V detection is rechecked by accessing the HDMI receiver 6 in step S201 of the 5V detection process in FIG. (step S204). After receiving the light source off control signal from the logic circuit 13 and turning off the light source 9, the light source control unit 10 confirms the instruction in step S204 and turns on the light source 9 to return to the normal state.

In the above description, the lighting permission signal is supposed to be output from the sub-controller 8, but it may be output from the main controller 7 as well.

(Second embodiment)
In the above-described first embodiment, the on/off of the light source 9 is controlled by the output of the logic circuit 13 to which the signal of the 5V signal pin is directly input. The display element is controlled by the output of the logic circuit 13 which is directly input so that noise does not appear in the projected light.

As shown in FIG. 5, the projector 1 according to the present embodiment is the same as that shown in FIG. 1 except that a logic circuit 51 is provided instead of the logic circuit 13 and a logic circuit 52 is provided. Therefore, the same numbers are assigned to the same configurations as in FIG. 1, and the description thereof is omitted.

The logic circuit 51 is an AND circuit that outputs a logical product, and is a control signal for emitting primary color light from the light source 9 in a time division manner, which is output from the main control unit 7 . A lighting enable signal for controlling lighting of the light source 9 to be turned on is inputted. The logic circuit 51 outputs the logical product of these inputs, and the output is input to the light source control section 10 . A different point from the first embodiment is that the signal of the 5V signal pin of the HDMI terminal 5 is not input to the logic circuit 51 .

When the HDMI cable 3 is pulled out and the external device 2 is disconnected, the synchronization signal for lighting the light source and the lighting permission signal are transmitted to the main control unit 7 and the sub control unit after receiving the voltage drop of the 5V signal pin. Since the output is stopped by the software processing in the unit 8, turning off the light source 9 is delayed by the amount of time required for the software processing.

On the other hand, the logic circuit 52 is an AND circuit that outputs a logical product, and is provided between the main control section 7 and the display element control section 12 . The logic circuit 52 receives a display element control signal for controlling video display/non-display from the main control section 7 to the display element control section 12 and also receives a signal from the 5V signal pin of the HDMI terminal 5 . The logic circuit 52 outputs the logical product of these inputs, and the output is input to the display element control section 12 . Here, the display element control signal corresponds to the display control signal for controlling the display state of the present invention, and the logic circuit 52 corresponds to the display control signal output section.

The display element control signal for controlling video display/non-display for the display element control unit 12 output from the logic circuit 52 when the external device 2 is connected to the projection apparatus 1 via the HDMI cable 3 is shown in FIG. Description will be made with reference to the time chart.

When the external device 2 is connected to the projector 1 via the HDMI cable 3, the voltage of the HDMI 5V signal pin rises from low level to high level at time t5. In response to the rising voltage of the 5V signal pin, the main control section 7 starts executing the 5V detection process. When it is determined that the signal state of the video signal input from the external device 2 is stable, the main controller 7 outputs a display element control signal for controlling the DMD 11 at time t6. Since the voltage of the 5V signal pin has risen to a high level at time t5, the logic circuit 52 outputs the display element control signal to the display element control section 12 from the time when the display element control signal for ON-controlling the DMD 11 is output. do. The light from the light source 9 is projected based on this signal.

When the HDMI cable 3 is pulled out and the external device 2 is disconnected from the projector 1, the voltage of the HDMI 5V signal pin falls from high level to low level at time t7. In response to the fall of the voltage of the 5V signal pin, the main control section 7 starts executing the 5V detection process, and when it is determined that the 5V signal is not detected, the main control section 7 detects the display element at time t8. Turn off the control signal. However, if the present invention using the output of the logic circuit 13 to which the voltage of the 5V signal pin is directly input is not adopted, the main control section 7 receives the fall of the voltage of the 5V signal pin, and then, by software processing, the display element Since the control signal is turned off, processing takes time, and turning off of the control signal is delayed by the time difference between t8 and t7. However, since the voltage of the 5V signal pin is directly input to the logic circuit 52, the logic circuit 52 outputs the display element control signal almost at the time t7 when the signal level of the 5V signal pin falls from high level to low level. The DMD 11 is turned off by turning it off. That is, the output of the control signal from the main control section 7 is forcibly stopped instantaneously by the hardware in response to the fall of the voltage of the 5V signal pin. By the off control, the illumination light from the light source 9 is not projected and a black projection state is set. If the DMD 11 is turned off only by the display element control signal from the main control unit 7, it takes time for the software processing to turn off the display element control signal. It may be superimposed. On the other hand, by inputting the 5V signal line to the logic circuit 52, the black projection state is instantaneously established after detecting that the cable is pulled out. projected light is not projected.

(Third Embodiment)
In the first and second embodiments described above, one external device 2 is connected to the projection device 1, but in this embodiment, a plurality of external devices 71 and 72 are connected to the projection device 1. An example of input switching will be described.

As shown in FIG. 7, the projector 1 according to the present embodiment is provided with two ports of HDMI terminals 73 and 74, and logic circuits 75 and 76 are provided for each port. It is the same as FIG. Therefore, the same numbers are assigned to the same configurations as in FIG. 1, and the description thereof is omitted. Here, the logic circuits 75 and 76 correspond to the display control signal output section of the invention.

Next, the operation of the input switching process according to this embodiment will be described with reference to the flowchart of FIG. 8 and the time chart of FIG.

In a state where the HDMI terminal 73 is connected by the HDMI cable 77 and the video signal from the external device 71 is being projected by the projection device 1, the HDMI cable 77 is pulled out from the HDMI terminal 73 at time t10 as shown in FIG. Then, the voltage of the 5V signal pin falls from high level to low level. The main controller 7 is executing the 5V detection process shown in FIG. 3B, and instructs the light source controller 10 to turn off the light source 9 (step S206). However, the logic circuit 75 forcibly stops outputting the synchronization signal for turning on the light source in response to the fall of the signal of the 5V signal pin of the HDMI terminal 73, and according to this, the light source 9 has already been turned off. has been After step S206 in FIG. 3, the main control unit 7 executes input switching processing for switching to input from another external device 72 connected to the projection apparatus 1, as shown in FIG. The main control unit 7 accesses the HDMI receiver 6 to confirm the state of the 5V signal pin of the other HDMI terminal 74, and determines whether a 5V signal voltage is detected from the 5V signal pin of the other HDMI terminal 74, that is, 5V It is determined whether there is another HDMI terminal 74 whose signal voltage is detected (step S301). When it is determined that there is another HDMI terminal 74 from which a 5V signal voltage is detected (step S301: YES), the main control unit 7 connects the video signal input to the projector 1 to the other HDMI terminal 74. input from the external device 72 (step S302). If it is determined that there is no other HDMI terminal 74 from which the 5V signal voltage is detected (step S301: NO), the process ends.

In FIG. 9, at time t10 when the HDMI cable 77 is pulled out from the HDMI terminal 73 and the signal level of the 5V signal pin falls from high level to low level, the signal level of the 5V signal pin of the other HDMI terminal 74 is high level. Therefore, in step S301, it is determined that a 5V signal voltage has been detected. The main control unit 7 switches to another HDMI terminal 74 determined to have detected a 5V signal voltage, inputs a video signal from the external device 72 connected to the HDMI terminal 74, and executes projection. At this time, the 5V detection process shown in FIG. At time t12, the control unit 8 raises the signal level of the lighting control signal from low level to high level to permit lighting of the light source 9. FIG. The synchronization signal for lighting the light source and the lighting permission signal are input to the logic circuit 76. Since the signal level of the 5V signal pin that is also input to the logic circuit 76 is at a high level, the logic circuit 76 is used for lighting the light source. Outputs a sync signal. As a result, the light source 9 is turned on and projection is performed.

After that, at time t13, when the HDMI cable 78 is pulled out from the HDMI terminal 74, the signal level of the 5V signal pin falls to low level. In response to the fall of the signal level of the 5V signal pin, in the 5V detection process shown in FIG. At time t14, the unit 8 changes the lighting permission signal to a low level to instruct turning off. However, since the voltage of the 5V signal pin is directly input to the logic circuit 76, the logic circuit 76 outputs a low-level signal instructing to turn off the light source 9 substantially at the time t13 when the logic circuit 76 falls to the low level. Output to 10. The light source 9 is turned off based on this signal. In this way, since the light source 9 can be turned off instantly after detecting that the cable is pulled out, the noise caused by the cable being pulled out is not superimposed on the projection light.

As described above, even when a plurality of external connection terminals are provided and a plurality of external devices 71 and 72 are connected to the projection device 1, not only can noise be avoided when switching inputs or disconnecting cables. Since projection can be performed only when necessary, it is also possible to reduce power consumption. There is a strong demand for low power consumption of the projection apparatus 1 for mobile applications, etc., and the power-consuming light source is a particular bottleneck. It is possible to make a large contribution to electrification.

In the above-described first to third embodiments, the projection apparatus 1 is a DLP type projection apparatus 1 having a micromirror element, which is the DMD 11, but is not limited to this. , an LCOS (Liquid Crystal On Silicon) system, or the like. Moreover, an arc lamp, a laser, an LED (Light Emitting Diode), or the like can be used as the light source. Further, the image display device is not limited to the projection device 1, and may be a display device such as a display.

In the above first to third embodiments, the projection device 1 uses HDMI as a communication interface, but is not limited to this. For example, the projection device 1 also supports a USB (Universal Serial Bus) display function. It can be a thing. In this case, when the external device 2 is connected to the USB terminal, the power supply voltage +5V to the first pin of the USB terminal is input to the logic circuit 13 . The logic circuit 13 outputs a signal instructing to turn off the light source to the light source control section 10 depending on the presence or absence of the power supply voltage +5V.

Also, DVI (Digital Visual Interface), DisplayPort, etc. may be used as other communication interfaces.

In the above-described first to third embodiments, the CPU functions as the main controller 7 and the sub-controller 8 by executing programs stored in the ROM. However, instead of the CPU executing the program stored in the ROM, dedicated hardware such as ASIC (Application Specific Integrated Circuit), FPGA (Field-Programmable Gate Array), various control circuits, etc. are provided. may function as a control unit. In this case, one part may be implemented by dedicated hardware, and the other part may be implemented by software or firmware.

Although embodiments of the present invention have been described, the scope of the present invention is not limited to the above-described embodiments, but includes the scope of the invention described in the claims and equivalents thereof. The invention described in the scope of claims originally attached to the application form of this application is additionally described below. The appendix numbers are as in the claims originally attached to this application.

(Appendix 1)
a display unit for displaying images;
a display control unit that controls the display unit;
a receiver that receives a video signal transmitted from an external device connected via a communication interface and a connection detection signal that detects connection with the external device;
a main control unit connected to the receiver and transmitting a display control signal for controlling a display state of the display unit to the display control unit;
a display control signal output unit that outputs the display control signal to the display control unit according to the state of the connection detection signal transmitted from the communication interface without passing through the receiver;
A video display device.

(Appendix 2)
The display control signal output unit does not output the display control signal to the display control unit when the connection detection signal does not detect connection,
The display control unit puts the display unit into a non-display state,
The image display device according to appendix 1.

(Appendix 3)
The display control signal output unit is a logic circuit that outputs a logical product of the connection detection signal and the display control signal.
The image display device according to appendix 1.

(Appendix 4)
The display unit includes a light source,
The display control unit includes a light source control unit that controls the light source,
The main control unit transmits, as the display control signal, a light source lighting synchronization signal for controlling lighting of the light source to the light source control unit,
The display control signal output unit outputs the light source lighting synchronization signal to the light source control unit according to the state of the connection detection signal.
3. The image display device according to any one of Appendices 1 to 3.

(Appendix 5)
The display unit includes a display element,
The display control unit includes a display element control unit that controls the display element,
The main control unit transmits a display element control signal for controlling the display element to the display element control unit as the display control signal,
The display control signal output unit outputs the display element control signal to the display element control unit according to the state of the connection detection signal.
3. The image display device according to any one of Appendices 1 to 3.

(Appendix 6)
A sub control unit that transmits a lighting permission signal that permits lighting of the light source to the light source control unit;
The display control signal output unit outputs the light source lighting synchronization signal to the light source control unit according to the states of the connection detection signal and the lighting permission signal.
The image display device according to appendix 4.

(Appendix 7)
The display control signal output unit does not output the light source lighting synchronization signal to the light source control unit when the connection detection signal is in a state where the connection is not detected,
The light source control unit sets the light source to a non-lighting state,
7. The video display device according to appendix 4 or 6.

(Appendix 8)
The display control signal output unit does not output the display element control signal to the display element control unit when the connection detection signal does not detect connection,
The display element control unit puts the display element in a non-display state,
The image display device according to appendix 5.

(Appendix 9)
the communication interface is an HDMI interface, and the connection detection signal is a 5V signal;
9. The image display device according to any one of Appendices 1 to 8.

DESCRIPTION OF SYMBOLS 1... Projection apparatus 2, 71, 72... External equipment 3, 77, 78... HDMI cable 4... HDMI transmitter 5, 73, 74... HDMI terminal, 6... HDMI receiver, 7... Main control part, 8... Sub-controller 9 Light source 10 Light source controller 11 DMD 12 Display element controller 13, 51, 52, 75, 76 Logic circuit 14 Lens 15 Display 16 Display Control unit 21 CPU 22 ROM 23 RAM 24 storage unit 25 system bus

Claims (9)

a display unit for displaying images;
a display control unit that controls the display unit;
a receiver that receives a video signal transmitted from an external device connected via a communication interface and a connection detection signal that detects connection with the external device;
a main control unit connected to the receiver and transmitting a display control signal for controlling a display state of the display unit to the display control unit;
a display control signal output unit that outputs the display control signal to the display control unit according to the state of the connection detection signal transmitted from the communication interface without passing through the receiver;
A video display device. The display control signal output unit does not output the display control signal to the display control unit when the connection detection signal does not detect connection,
The display control unit puts the display unit into a non-display state,
The image display device according to claim 1. The display control signal output unit is a logic circuit that outputs a logical product of the connection detection signal and the display control signal.
The image display device according to claim 1. The display unit includes a light source,
The display control unit includes a light source control unit that controls the light source,
The main control unit transmits, as the display control signal, a light source lighting synchronization signal for controlling lighting of the light source to the light source control unit,
The display control signal output unit outputs the light source lighting synchronization signal to the light source control unit according to the state of the connection detection signal.
The image display device according to any one of claims 1 to 3. The display unit includes a display element,
The display control unit includes a display element control unit that controls the display element,
The main control unit transmits a display element control signal for controlling the display element to the display element control unit as the display control signal,
The display control signal output unit outputs the display element control signal to the display element control unit according to the state of the connection detection signal.
The image display device according to any one of claims 1 to 3. A sub control unit that transmits a lighting permission signal that permits lighting of the light source to the light source control unit;
The display control signal output unit outputs the light source lighting synchronization signal to the light source control unit according to the states of the connection detection signal and the lighting permission signal.
5. The image display device according to claim 4. The display control signal output unit does not output the light source lighting synchronization signal to the light source control unit when the connection detection signal is in a state where the connection is not detected,
The light source control unit sets the light source to a non-lighting state,
7. The image display device according to claim 4 or 6. The display control signal output unit does not output the display element control signal to the display element control unit when the connection detection signal does not detect connection,
The display element control unit puts the display element in a non-display state,
The video display device according to claim 5. the communication interface is an HDMI interface, and the connection detection signal is a 5V signal;
The image display device according to any one of claims 1 to 8.

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