JP2003207843A - Image projector - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To improve the degree of freedom of the positions of a lamp and a control circuit to be arranged in an image projector and to suppress the rise of production cost of the image projector. <P>SOLUTION: A 1st control circuit outputs an initialization signal when a power supply for the image projector is turned on. A storage circuit stores state information indicating a power ON state in accordance with the initialization signal. A 2nd initializing circuit outputs an initialization signal to the control circuit when the power supply is turned on to initialize the control circuit. When the control circuit is in the power ON state after initialization, the control circuit requests the initialization signal to the 2nd initializing circuit. After the lapse of prescribed time from the request from the control circuit, the 2nd initializing circuit outputs the initialization signal. Further, the control circuit turns on a lamp after requesting the initialization signal. Although noise is generated immediately after turning on the lamp, the 2nd initializing circuit outputs the initialization signal to the control circuit after the disappearance of the noise. <P>COPYRIGHT: (C)2003,JPO

Description

Detailed Description of the Invention

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to an image projection device that projects an image on a screen using a liquid crystal panel or the like.

[0002]

2. Description of the Related Art There is known an image projection apparatus which projects an image on a screen to display a large screen image. The image projection device uses a lamp as a light source and projects an image displayed on a liquid crystal panel onto a screen. In addition to the liquid crystal panel and the lamp, the video projection device includes a control circuit that drives the liquid crystal panel, and a lighting circuit that switches lighting and extinction of the lamp.

FIG. 5 is a diagram showing an example of the appearance of a video projection device. A control circuit, a liquid crystal panel, a lighting circuit, a lamp and the like are arranged inside the image projection apparatus 101. The image projection device 101 also includes a projection lens 102. FIG. 6 is an explanatory diagram of a usage state of the video projection device 101. The light emitted from the lamp passes through the liquid crystal panel and the projection lens. An image is displayed on the screen 111 by orienting the projection lens 102 toward the screen 111. A video signal from the outside is input to the input interface 103. The control circuit drives the liquid crystal panel based on this video signal, and the video displayed on the liquid crystal panel is projected on the screen 111.

[0004]

The lighting circuit generates a voltage of several kV or more when the lamp is switched from the extinguished state to the lit state. As a result, noise occurs when switching to the lighting state. Then, the control circuit may be affected by noise and malfunction. For example, there are cases where a desired image is not displayed on the liquid crystal panel and a standby state occurs, or a state where normal operation is not performed at all. In particular, since a microcomputer is often used as a control circuit, it is easily affected by noise.

In order to prevent the control circuit from being affected by noise, a shield for cutting off noise is strengthened,
The lamp is placed away from the control circuit. But,
If the shield is strengthened, there is a problem that the production cost of the image projection device becomes high. Further, when the lamp is arranged away from the control circuit, the arrangement position of the lamp, the control circuit, and the like is limited, and it becomes difficult to downsize the image projection device.

It is an object of the present invention to provide a video projection device which can increase the degree of freedom in the arrangement positions of lamps and control circuits and can suppress an increase in production cost.

[0007]

An image projection apparatus according to the present invention comprises a light source for irradiating light, a light source lighting means for lighting or extinguishing the light source, and an image for passing light radiated by the light source for displaying an image. The display means, a control means for driving the video display means, outputting a lighting control signal for instructing the light source lighting means to turn on or off the light source, and an initialization means for initializing the control means to a predetermined initial state The control means requests the initialization means for initialization, and outputs a lighting control signal for instructing lighting of the light source after the request, and the initialization means outputs a lighting control signal when a predetermined time has elapsed after receiving the request from the control means. It is characterized in that the control means is initialized.

The initialization means initializes the control means when the power is turned on, and the control means requests the initialization means to perform the initialization after the initialization when the power is turned on, and after the request, turns on the light source. A control signal is output, and after initialization on demand, the image display means is driven.

For example, the control means is provided with a storage means for storing information specifying a process to be executed after the initialization, and the control means, based on the information stored in the storage means after the initialization,
It is determined whether the initialization means is requested to perform initialization, and after the request, a lighting control signal for instructing lighting of the light source should be output or the video display means should be driven. With such a configuration, the control unit can determine the processing to be executed after the initialization.

The image projection apparatus according to the present invention further comprises a light source for irradiating light, a light source lighting means for turning on or off the light source, and an image display means for passing the light emitted by the light source for displaying an image. Control means for driving the image display means and outputting a lighting control signal for instructing the light source lighting means to turn on or off the light source, and an initialization means for initializing the control means to a predetermined initial state when the control means malfunctions. It is characterized by having and.

For example, the control means periodically outputs an instruction for starting the measurement of the elapsed time to the initialization means, and the initialization means restarts the measurement of the elapsed time every time the instruction is received, and the predetermined time is restarted. If the elapsed time is measured, the control means is determined to have malfunctioned and the control means is initialized.

The initialization means initializes the control means when the power is turned on, and after the initialization when the power is turned on, the control means outputs a lighting control signal for instructing lighting of the light source, and after initialization when a malfunction occurs. , Drive the image display means.

For example, the control means is provided with a storage means for storing information for specifying a process to be executed after initialization, and the control means, based on the information stored in the storage means after initialization,
Whether to output a lighting control signal that instructs lighting of the light source,
It is determined whether the image display means should be driven. With such a configuration, the control unit can determine the processing to be executed after the initialization.

When the lighting control signal output by the control means is relayed to the light source lighting means and the lighting control signal output by the control means is switched from the signal instructing to turn off the light to the signal for instructing lighting, the lighting control signal is output for a certain period of time. It is preferable to include a relay unit that outputs only a signal for instructing lighting to the light source lighting unit. According to such a configuration, the lighting state of the light source can be maintained even when the lighting control signal is not stable due to the noise generated when the light source is turned on.

[0015]

BEST MODE FOR CARRYING OUT THE INVENTION Embodiments of the present invention will be described below with reference to the drawings. FIG. 1 is a block diagram showing an embodiment of a video projection apparatus according to the present invention. Control circuit 1
Drives the liquid crystal panel 2 to display an image on the liquid crystal panel 2. In addition, a lighting control signal for instructing the lighting circuit 7 to turn on or off the lamp 8 is output to the holding circuit 6 described later. The control circuit 1 is initialized to a predetermined initial state by inputting an initialization signal. That is, it is set to a predetermined state. After initialization, the control circuit 1 performs processing according to the state of the video projection device.

The liquid crystal panel 2 displays an image according to the control circuit 1. Further, the light emitted by the lamp 8 is passed to display an image on a screen provided outside the image projection device. The image displayed on the liquid crystal panel 2 is projected by the light of the lamp 8 onto a screen provided outside the image projection device.

The first initialization circuit 3 outputs an initialization signal to a storage circuit 4 which will be described later when the power of the image projection apparatus is turned on.

When the initialization signal is requested from the control circuit 1, the second initialization circuit 5 initializes the control circuit 1 by outputting the initialization signal to the control circuit 1 after a lapse of a predetermined time from the request. Turn into. The second initialization circuit 5 also outputs an initialization signal to the control circuit 1 to initialize the control circuit 1 even when the power of the image projection apparatus is turned on.

The storage circuit 4 stores information (hereinafter referred to as state information) indicating whether the image projection apparatus is in a state immediately after the power is turned on or the lamp 8 is in a lit state. The state immediately after the power is turned on is hereinafter referred to as the state when the power is turned on. Further, the state in which the lamp 8 is lit is hereinafter referred to as the lamp lit state. When the initialization signal is input from the first initialization circuit 3, the memory circuit 4 holds the state information as the power-on state. After that, at the request of the control circuit 1, the content of the state information is changed from the power-on state to the lamp lighting state.

After initialization, the control circuit 1 performs a process according to the state of the image projection device based on the state information. That is, the state information is information that identifies the process that the control circuit 1 should execute after initialization. If the state after initialization is the power-on state, the control circuit 1 requests the storage circuit 4 to change the content of the state information to the lamp lighting state,
It also requests the second initialization circuit 5 for an initialization signal. Further, the control circuit 1 switches the output lighting control signal from a signal instructing extinction (low level in this example) to a signal instructing lighting (high level in this example). If the state after the initialization is the lamp lighting state, the control circuit 1 executes the driving process of the liquid crystal panel 2.

The holding circuit 6 relays the lighting control signal output from the control circuit 1 to the lighting circuit 7. However, when the lighting control signal is switched from a signal for instructing extinction (low level) to a signal for instructing lighting (high level), the lighting control signal output from the control circuit 1 for a certain period of time after the switching is performed. Regardless, it outputs only the signal (high level) that instructs lighting. That is, the control circuit 1
If the lighting control signal output by the switch from the low level to the high level, the holding circuit 6 continues to output the high level signal even if the lighting control signal returns to the low level immediately after that. If a certain time has passed,
The holding circuit 6 relays the lighting control signal output from the control circuit 1 to the lighting circuit 7 again.

The lighting circuit 7 turns on or off the lamp 8 according to a signal input from the holding circuit 6. If the signal input from the holding circuit 6 is high level, the lighting circuit 7 lights the lamp 8. If the input signal is low level, the lighting circuit 7 turns off the lamp 8.

The light emitted when the lamp 8 is turned on is the liquid crystal panel 2 and the projection lens (not shown in FIG. 1).
Pass through. As shown in FIG. 6, by directing the projection lens toward the screen, an image is displayed on the screen.

In this example, the light source is the lamp 8. The light source lighting means is the lighting circuit 7. The image display means is the liquid crystal panel 2. The control means is the control circuit 1. The initialization means is the second initialization circuit 5. The storage means
The memory circuit 4. The relay means is the holding circuit 6.

Next, the operation after the power is turned on will be described. FIG. 2 is an explanatory diagram showing an example of operation timing after the power is turned on. When the power is turned on, the first initialization circuit 3 outputs an initialization signal to the memory circuit 4. When the initialization signal is input from the first initialization circuit 3, the memory circuit 4 holds the state information as the power-on state.

The second initialization circuit 5 outputs an initialization signal to the control circuit 1 to initialize the control circuit 1 when the power is turned on. After that, the control circuit 1 starts outputting a low-level lighting control signal to the holding circuit 6.

After initialization, the control circuit 1 reads the status information from the storage circuit 4 to determine the status of the image projection device. At this time, the status information indicates that the power is on. Therefore, the control circuit 1 requests the storage circuit 4 to change the content of the state information to the lamp lighting state. The storage circuit 4 changes the content of the state information to the lamp lighting state in response to this request. However, at this point,
Lamp 8 is not on yet. Then, the control circuit 1
Request an initialization signal from the second initialization circuit 5. Further, the control circuit 1 switches the lighting control signal output to the holding circuit 6 from low level to high level.

The holding circuit 6 relays the lighting control signal output from the control circuit 1 to the lighting circuit 7. And the holding circuit 6
When the input lighting control signal is switched to the high level, outputs only the high level signal to the lighting circuit 7 for a certain period of time after the switching.

The lighting circuit 7 turns off the lamp 8 while the signal from the holding circuit 6 is at a low level. When the signal from the holding circuit 6 becomes high level, the lamp 8 is turned on. Noise may occur immediately after the lamp 8 is turned on, and the control circuit 1 may malfunction due to the noise. As one mode of malfunction due to noise, the control circuit 1 may not be able to maintain the lighting control signal at a high level. That is, even if the control circuit 1 switches the lighting control signal from the low level to the high level to light the lamp 8, the lighting control signal may be returned to the low level due to the influence of noise. However, even if the control circuit 1 cannot maintain the lighting control signal at the high level, the holding circuit 6 outputs only the high level signal for a certain period of time, so that the lighting circuit 7 can continue to light the lamp 8.

Further, the second initialization circuit 5 outputs the initialization signal to the control circuit 1 after a lapse of a predetermined time after receiving the request for the initialization signal to initialize the control circuit 1. However,
This predetermined time is set so that the second initialization circuit 5 outputs the initialization signal after the lamp 8 stops producing noise.

By the initialization, the control circuit 1 returns from the malfunctioning state due to the influence of noise to the normal operating state. The noise is contained between the time when the second initialization circuit 5 receives the request for the initialization signal and the time when the second initialization circuit 5 outputs the initialization signal. Therefore, after the second initialization of the control circuit 1, it is not affected by noise. The control circuit 1 is
After the initialization, the status information is read from the memory circuit 4 to determine the status of the video projection device. At this time, the status information indicates that the lamp is in a lighting state. Therefore, the control circuit 1 executes the driving process of the liquid crystal panel 2.

When a certain time has passed since the control circuit 1 switched the lighting control signal to the high level, the holding circuit 6 relays the high level lighting control signal output from the control circuit 1 to the lighting circuit 7. During the time when the holding circuit 6 outputs only the high level regardless of the input lighting control signal, the second initialization circuit 5 outputs the initialization signal after the control circuit 1 switches the lighting control signal to the high level. Set to be longer than the time until is output. As a result, the holding circuit 6 resumes relaying the lighting control signal after the control circuit 1 returns to the normal state. Therefore, the lighting circuit 7 keeps lighting the lamp 8, and in this state, the control circuit 1 starts driving the liquid crystal panel 2.

According to the present invention, even if noise occurs when the lamp 8 is turned on, the control circuit 4 is initialized again after the noise disappears. Therefore, even if the control circuit 4 is affected by noise, it can return to the initial state and perform a normal operation without continuing the state. Therefore, it is not necessary to strengthen the shield or keep the lamp 8 and the control circuit 1 away from each other, and it is possible to suppress an increase in the production cost, and it is possible to improve the degree of freedom in the arrangement of the lamp 8 and the control circuit 1. it can.

Further, the holding circuit 6 outputs only a signal for instructing lighting for a fixed time after the control circuit 1 switches the lighting control signal to the high level. Therefore, even if the control circuit 1 cannot stably output a high-level lighting control signal due to noise immediately after lighting, the lighting of the lamp 8 can be continued. Further, since the storage circuit 4 stores the state information, the control circuit 1 can determine the process to be executed after the initialization based on the state information.

Next, another embodiment of the present invention will be described. FIG. 3 is a block diagram showing another embodiment of the image projection apparatus according to the present invention. Circuits common to the circuit shown in FIG. 1 are described with the same reference numerals as those in FIG. In this example, the operations of the liquid crystal panel 2, the first initialization circuit 3, the storage circuit 4, the holding circuit 6, the lighting circuit 7, and the lamp 8 are the same as those shown in FIG.

The image projection apparatus of this example includes a monitoring circuit 31 instead of the second initialization circuit 5 shown in FIG. The monitoring circuit 31 is a watchdog timer that monitors whether the control circuit 30 is malfunctioning. That is, the monitoring circuit 31 counts the elapsed time after the instruction to start the counting (measurement) of the elapsed time is input. Then, when it is measured that a predetermined time has elapsed, an initialization signal is output to initialize the control circuit 30. Further, the monitoring circuit 31 outputs an initialization signal to the control circuit 30 when the power is turned on to initialize the control circuit 30.

The control circuit 30 of this example is the control circuit 1 described above.
Similarly, the driving of the liquid crystal panel 2 and the output of a lighting control signal are performed. In addition, when an initialization signal is input, a predetermined initial state is set. However, the initialization signal is not requested when the state after initialization is the power-on state. If the state after initialization is the power-on state, the control unit 30 requests the memory circuit 4 to change the content of the state information to the lamp lighting state, and sets the lighting control signal to a signal (low signal) for turning off the lamp. The level is changed to a signal for instructing lighting (high level). If the state after initialization is the lamp lighting state, the control circuit 30 executes the drive process of the liquid crystal panel 2.

Further, the control circuit 30 of the present example periodically outputs to the monitoring circuit 31 an instruction (hereinafter, referred to as CLRWDT instruction) for instructing to start counting elapsed time. The monitoring circuit 31 restarts counting the elapsed time from 0 each time the CLRWDT command is input. The control circuit 30
The CLRWDT instruction is output at an interval shorter than the time until the monitoring circuit 31 outputs the initialization signal. When the CLRWDT command is input to the monitoring circuit 31 at such intervals, the monitoring circuit 31 restarts counting from 0 in the middle of counting the elapsed time, and thus does not output the initialization signal.

In this example, the light source is the lamp 8. The light source lighting means is the lighting circuit 7. The image display means is the liquid crystal panel 2. The control means is the control circuit 30.
The initialization means is the monitoring circuit 31. The storage means is the storage circuit 4. The relay means is the holding circuit 6.

FIG. 4 is an explanatory diagram showing an example of the operation timing of the image projection apparatus of this example. When the power is turned on, the first initialization circuit 3 outputs an initialization signal to the memory circuit 4.
When the initialization signal is input from the first initialization circuit 3, the memory circuit 4 holds the state information as the power-on state.

The monitoring circuit 31 also outputs an initialization signal to the control circuit 30 to initialize the control circuit 30 when the power is turned on. After that, the control circuit 30 starts outputting a low-level lighting control signal to the holding circuit 6. Further, the operation of periodically outputting the CLRWDT command to the monitoring circuit 31 is started.

After initialization, the control circuit 30 reads the status information from the storage circuit 4 to determine the status of the image projection device. At this time, the status information indicates that the power is on. Therefore, the control circuit 30 requests the storage circuit 4 to change the content of the state information to the lamp lighting state. The storage circuit 4 changes the content of the state information to the lamp lighting state in response to this request. However, at this point, the lamp 8 has not been turned on yet. Further, the control circuit 30 switches the lighting control signal output to the holding circuit 6 from low level to high level.

The operations of the holding circuit 6, the lighting circuit 7, and the lamp 8 when the control circuit 30 switches the lighting control signal to the high level are the same as those shown in FIG.

The lighting circuit 7 lights the lamp 8 when the signal from the holding circuit 6 becomes high level. Noise may occur immediately after the lamp 8 is turned on, and the control circuit 30 may malfunction due to the noise. When the control circuit 30 malfunctions, the control circuit 30 stops outputting the CLRWDT instruction. Then, the monitoring circuit 31 measures that a predetermined time has elapsed, outputs an initialization signal to the control circuit 30, and initializes the control circuit 30.

By the initialization, the control circuit 30 returns from the malfunctioning state due to the influence of noise to the normal operating state. After initialization, the control circuit 30 reads the status information from the storage circuit 4 and determines the status of the video projection device. At this time, the status information indicates that the lamp is in a lighting state. Therefore, the control circuit 30 executes the driving process of the liquid crystal panel 2.

If a malfunction occurs due to the influence of noise again after the recovery, the control circuit 30 again detects the CLRWD.
Stop outputting T command. As a result, again the monitoring circuit 31
Outputs an initialization signal to initialize the control circuit 30.
The control circuit 30 and the monitoring circuit 31 repeat this operation until it is no longer affected by noise.

When a certain period of time has passed since the control circuit 30 switched the lighting control signal to the high level, the holding circuit 6 relays the high level lighting control signal output from the control circuit 30 to the lighting circuit 7. In this example, the control circuit 30
Regardless of the lighting control signal of, the holding circuit 6 outputs the high level for the duration of noise and the monitoring circuit 3.
1 is set to be longer than the sum of the predetermined time until 1 outputs the initialization signal. As a result, the holding circuit 6
After the control circuit 30 returns to the normal state, the relay of the lighting control signal is restarted. Therefore, the lighting circuit 7 keeps lighting the lamp 8, and in this state, the control circuit 30 starts driving the liquid crystal panel 2.

In the image projection apparatus of this example, the control circuit 30
Can be initialized even if it malfunctions due to the influence of noise, and can return to the initial state to perform normal operation. Therefore,
There is no need to strengthen the shield or keep the lamp 8 away from the control circuit 30. As a result, it is possible to suppress an increase in production cost and improve the degree of freedom of arrangement of the lamp 8 and the control circuit 30.

Further, similarly to the embodiment shown in FIG. 1,
Even if the control circuit 30 cannot stably output a high-level lighting control signal due to noise immediately after lighting, the lighting of the lamp 8 can be continued. Since the storage circuit 4 stores the state information, the control circuit 30 can determine the process to be executed after the initialization based on the state information.

[0050]

According to the image projection apparatus of the present invention, the control means requests the initialization means to perform initialization, and outputs a lighting control signal for instructing lighting of the light source after the request, and the initialization means Since the control means is initialized when a predetermined time has elapsed after receiving a request from the control means, the control means can return to a normal operation state even if it is affected by noise generated when the light source is turned on. Therefore, it is not necessary to dispose the light source away from the control means, and the degree of freedom in disposing the light source and the control means can be improved. In addition, it is not necessary to strengthen the shield that blocks noise, and it is possible to suppress an increase in production cost.

Further, according to the image projection apparatus of the present invention, the control means is provided with the initialization means for initializing the control means to a predetermined initial state when the control means malfunctions.
Even if it is affected by noise generated when the light source is turned on, it is possible to return to the normal operation state. Therefore, it is not necessary to dispose the light source away from the control means, and the degree of freedom in disposing the light source and the control means can be improved. In addition, it is not necessary to strengthen the shield that blocks noise, and it is possible to suppress an increase in production cost.

[Brief description of drawings]

FIG. 1 is a block diagram showing an embodiment of a video projection device according to the present invention.

FIG. 2 is an explanatory diagram showing an example of operation timing.

FIG. 3 is a block diagram showing another embodiment of a video projection device according to the present invention.

FIG. 4 is an explanatory diagram showing an example of operation timing.

FIG. 5 is an external view of a video projection device.

FIG. 6 is an explanatory diagram of a usage state of the image projection device.

[Explanation of symbols]

1 control circuit 2 LCD panel 3 First initialization circuit 4 memory circuits 5 Second initialization circuit 6 holding circuit 7 lighting circuit 8 lamps

Claims (8)

[Claims] 1. A light source for irradiating light, a light source lighting means for turning on or off the light source, an image display means for passing the light emitted by the light source for displaying an image, and a light source for driving the image display means. The lighting means includes a control means for outputting a lighting control signal for instructing turning on or off of the light source, and an initialization means for initializing the control means to a predetermined initial state, and the control means initializes the initialization means. A request is made and a lighting control signal for instructing lighting of the light source is output after the request, and the initialization means initializes the control means when a predetermined time has elapsed after receiving the request from the control means. Video projection device. 2. The initialization means initializes the control means when the power is turned on, the control means requests the initialization means to perform initialization after the initialization when the power is turned on, and instructs the lighting of the light source after the request. The image projection device according to claim 1, wherein the image display unit is driven after outputting a lighting control signal to turn on and performing initialization based on the request. 3. The control means comprises storage means for storing information specifying a process to be executed after initialization, and the control means initializes the initialization means after initialization based on the information stored in the storage means. The image projection apparatus according to claim 2, wherein it is determined whether a lighting control signal for instructing lighting of the light source should be output after the request is made, or whether the image display means should be driven. 4. A light source for irradiating light, a light source lighting means for turning on or off the light source, an image display means for passing the light emitted by the light source for displaying an image, and a light source for driving the image display means. The control means outputs a lighting control signal for instructing the lighting means to turn on or off the light source, and an initialization means for initializing the control means to a predetermined initial state when the control means malfunctions. Video projection device. 5. The control means periodically outputs an instruction for starting measurement of elapsed time to the initialization means, and the initialization means repeats measurement of elapsed time each time the instruction is received, and the predetermined time The image projection apparatus according to claim 4, wherein when the elapsed time is measured, the control means is determined to be malfunctioning and the control means is initialized. 6. The initialization means initializes the control means when the power is turned on, and the control means outputs a lighting control signal for instructing lighting of the light source after the initialization when the power is turned on, and an initialization in case of malfunctioning. The image projection apparatus according to claim 4, wherein the image display means is driven after the conversion. 7. The control means comprises storage means for storing information specifying a process to be executed after initialization, and the control means instructs to turn on the light source based on the information stored in the storage means after initialization. 7. The image projection apparatus according to claim 6, wherein it is determined whether to output a lighting control signal for driving or to drive the image display means. 8. The lighting control signal output by the control means is relayed to the light source lighting means, and when the lighting control signal output by the control means is switched from a signal instructing to turn off to a signal instructing to turn on, a predetermined time period is reached. The image projection apparatus according to claim 1, further comprising a relay unit that outputs only a signal instructing lighting to the light source lighting unit during the period.