JP4505900B2 - Projection display - Google Patents

Description

[0001]
BACKGROUND OF THE INVENTION
The present invention relates to a projection display device, and more particularly to a projection display device capable of suppressing wasteful power consumption by automatically controlling lighting and extinction of a light source of the projection display device.
[0002]
[Prior art]
The projection display device is a device that projects an image based on a video signal output from a computer or a video signal output from video equipment such as a video camera onto a screen or the like. As described above, a light source for projecting an image onto a screen or the like is built in the projection display device. Conventionally, control of turning on and off the light source of a projection display device has been performed by an operator turning on / off a switch provided in the main body of the projection display device or a switch provided in a remote control device. .
[0003]
[Problems to be solved by the invention]
However, if the projection display device described above forgets to turn on the light source, the image is not displayed on the screen even though the video signal is input. At this time, the operator could not immediately determine what caused the image not to be displayed on the screen, and sometimes hesitated. In addition, when no video signal is input, the amount of light projected on the screen is small even when the light source is turned on. For this reason, the operator does not notice that the light source is turned on, and sometimes forgets to turn off the light source and consumes unnecessary power.
[0004]
An object of the present invention is to provide a projection display device that does not require an operator to turn on / off a light source and can suppress wasteful power consumption.
[0005]
[Means for Solving the Problems]
(1) The invention described in claim 1Image data recorded on the mounted recording medium, having mounting means capable of mounting a recording medium on which image data is recordedProjection type display device for projecting and displaying an image generated by an image generation device based onLeaveA light source for illuminating the image;Recording medium detecting means for detecting presence / absence of attachment of the recording medium, and recording medium detecting means for attaching the recording mediumLighting control means for turning on the light source when detectedDetermining means for determining whether or not audio data is recorded on the recording medium; and audio reproducing means for reproducing the audio data when the determining means determines that the audio data is recorded; Audio input means for inputting an external audio signal, and the audio reproduction means reproduces the audio signal input from the audio input means when the determination means determines that no audio data is recorded. DoIt is characterized by that.
(2) The invention described in claim 2Image data recorded on the mounted recording medium, having mounting means capable of mounting a recording medium on which image data is recordedProjection type display device for projecting and displaying an image generated by an image generation device based onLeaveA light source for illuminating the image;Recording medium detecting means for detecting presence / absence of attachment of the recording medium, and recording medium detecting means for attaching the recording mediumLighting control means for turning on the light source when detectedDetermining means for determining whether or not audio data is recorded on the recording medium; and audio reproducing means for reproducing the audio data when the determining means determines that the audio data is recorded. It is characterized by having.
[0007]
DETAILED DESCRIPTION OF THE INVENTION
A projection type display apparatus according to an embodiment of the present invention will be described with reference to FIG. The projection display device 1 generates an image based on a video signal output from an external device such as the computer 30 or the video camera 40 inside and projects the image on the screen 56 via the projection lens 22. The projection display device 1 can also be mounted with a memory card 52 in the IC card slot 18 and a transparent original 58 such as a slide film in the slot 20. The projection display device 1 generates an image based on the image data recorded on the memory card 52 and projects it on the screen 56 in addition to the above-described image projection based on the video signal. It can also be projected onto the screen 56.
[0008]
A plurality of input terminals described below are provided on the rear surface of the projection display device 1 in order to input video signals and audio signals output from the external device described above. A plug 32 attached to one end of an audio cable 34 is connected to the audio signal input terminal 2. The other end of the audio cable 34 is connected to the computer 30. A connector 38 attached to one end of the video cable 36 is connected to the video signal input terminal 4. The other end of the video cable 36 is connected to the computer 30.
[0009]
The signal input to the video signal input terminal 4 varies depending on the type of the computer 30. That is, as the above-mentioned signals, those in which a synchronizing signal is added to the video signal, those in which the video signal and the synchronizing signal are separated, and those in which the horizontal and vertical synchronizing signals are separated with respect to this synchronizing signal, or Some are superposed.
[0010]
A video signal plug 44, a left channel audio signal plug 46, and a right channel audio signal plug 48 are attached to one end of the connection cable 42. The other end of this cable is connected to the video camera 40. A video signal plug 44 is connected to the video signal input terminal 8 of the projection display device 1. A left channel audio signal plug 46 is connected to the left channel audio signal input terminal 10 (hereinafter, the left channel audio signal input terminal is referred to as “L audio signal input terminal”) 10. Further, a right channel audio signal plug 48 is connected to the right channel audio signal input terminal (hereinafter, the right channel audio signal input terminal is referred to as “R audio signal input terminal”) 12.
[0011]
The audio output terminal 16 is connected to the output of an audio amplifier circuit installed in the projection display device 1. A plug of a connection cable for connecting to an external speaker (not shown) is connected to the audio output terminal 16 as necessary.
[0012]
A window 26 is provided on the side surface of the projection display device 1. An infrared light receiving device 80 (not shown in FIG. 1, see FIG. 2) is disposed inside the window 26. In response to the operator operating the remote controller 50, infrared light is projected from the remote controller 50. The infrared light projected at this time is frequency-modulated with a pattern corresponding to the operation content of the remote controller 50 (the frequency of repetition of turning on / off the infrared light is modulated). ing. The light receiving device 80 receives infrared light output from the remote controller 50. As the remote controller 50, an ultrasonic wave, an electromagnetic wave, or the like may be used instead of the above-described one.
[0013]
The mouse 28 is for changing the position of the pointer projected on the image projected on the screen 56. That is, the display position of the pointer displayed on the screen 56 changes as the mouse 28 is slid back and forth and left and right on a plane such as a desk. By using the mouse 28, it is possible to instruct the attention point of the image projected on the screen 56 without using a pointer or the like. The pointer function may be performed by the remote controller 50. The mouse 28 can also be used for setting the operation mode and the like of the projection display device 1. The setting of this operation mode will be described later.
[0014]
FIG. 2 is a diagram schematically showing the internal configuration of the projection display apparatus 1. Hereinafter, the internal configuration and operation of the projection display apparatus 1 will be described with reference to FIGS. 1 and 2. In FIG. 2, a sync separation circuit 62 connected to the video signal input terminal 8 is a circuit for separating a sync signal superimposed in the video signal. The video signal from which the synchronization signal has been separated by the synchronization separation circuit 62 is output to the digital decoder 64. The digital decoder 64 outputs color digital data of each color of red, green, and blue (hereinafter referred to as “RGB”) to the terminal 66 a of the switch element 66 based on the video signal input from the synchronization separation circuit 62. While the video signal is being input to the sync separator 62, a pulse having a predetermined time width is repeatedly output from the sync separator 62 to the OR circuit 74.
[0015]
The terminals 4a and 4b that constitute the video signal input terminal 4 will be described. The type of video signal input to the video signal input terminal 4 varies depending on the type of computer 30 as described above. When a synchronization signal is superimposed on the video signal, the synchronization separation circuit 68 connected to the terminal 4a separates the synchronization signal from the video signal. The video signal output from the sync separation circuit 68 is converted into RGB color digital data by the A / D converter 70 and output to the terminal 66 b of the switch element 66. While the video signal on which the synchronization signal is superimposed is input to the synchronization separation circuit 68, a pulse having a predetermined time width is repeatedly output from the synchronization separation circuit 68 to the OR circuit 74. As described above, when the signal in which the synchronization signal is superimposed on the video signal is input to the terminal 4a, the terminal 4b to which the synchronization signal is input is in an unconnected (open) state. In order to cope with this, the terminal 4 b is pulled down by the resistor 72.
[0016]
On the other hand, when the video signal input to the video signal input terminal 4 is separated from the synchronization signal, a synchronization signal independent of the video signal input to the terminal 4a is input to the terminal 4b. Since the terminal 4b is connected to the OR circuit 74, a pulse having a predetermined time width is repeatedly output from the terminal 4b to the OR circuit 74 while the video signal is input to the video signal input terminal 4.
[0017]
The multivibrator 76 connected to the output of the OR circuit 74 is a retriggerable monostable multivibrator, and the pulse width of the signal output from the multivibrator 76 is set as follows. That is, among the video signal formats that can be input to the projection display device 1, the pulse width of the multivibrator 76 is equal to the time width corresponding to about 1.5 cycles of the horizontal synchronizing signal of the video signal having the lowest horizontal synchronizing signal frequency. Is set. That is, when a pulse signal having a certain width is input to the multivibrator 76, the multivibrator 76 outputs a signal that is at the 'H' level for the above-described time. Therefore, while the pulse signal is output from the OR circuit 74 to the multivibrator 76, the output signal of the multivibrator 76 is maintained at the 'H' level. Note that the setting of the 1.5 period is set with some allowance, and is not necessarily 1.5 period. In other words, the pulse width of the signal output from the multivibrator 76 may be set to an appropriate value that exceeds one cycle of the lowest horizontal synchronizing signal described above.
[0018]
The output terminal of the multivibrator 76 is connected to one input terminal of the 2-input OR circuit 78 and the CPU 84. The other input terminal of the OR circuit 78 is connected to the output of the CPU 84. The output terminal of the OR circuit 78 is connected to the lamp lighting circuit 88. That is, if any input of the OR circuit 78 is “H”, a signal “H” is output to the lamp lighting circuit 88. The lamp lighting circuit 88 supplies power to the lamp 90 while the input signal is “H”. That is, when a signal “H” is input to the lamp lighting circuit 88, the lamp 90 is lit. The lamp 90 is a light source for projection of the projection display device 1, and a high-pressure discharge lamp such as a metal halide is used. Regarding the lamp 90, depending on the specifications of the projection display device 1, not only the high-pressure discharge lamp but also a normal tungsten bulb or a halogen lamp can be used. The output of the multivibrator 76 is also input to the CPU 84. Therefore, the CPU 84 can detect the on / off state of the lamp 90. Further, in order to cope with the case where the lamp itself does not turn on due to a failure or the like, a light receiving device (not shown) is disposed in the vicinity of the lamp 90, and the output from the light receiving device is read by the CPU 84 to turn on / off the lamp 90. May be detected directly. Further, the lighting / extinguishing state of the lamp 90 can be detected by detecting the voltage at both ends of the lamp 90 and the current flowing through the lamp 90.
[0019]
When the transparent original 58 is inserted into the slot 20 (FIG. 1), the transparent original 58 is held by the holder 94 disposed in the projection display device 1. A photo interrupter 92 is installed in the vicinity of the holder 94, and a signal output from the photo interrupter 92 changes depending on whether or not the transparent original 58 is present. The CPU 84 receives a signal output from the photo interrupter 92 and determines whether or not the transparent original 58 is present. It should be noted that the presence or absence of the transparent original 58 can be determined without using the photointerrupter 92 for those having a magnetic recording layer on the surface of the transparent original 58 or the frame portion of the transparent original 58. In this case, the presence or absence of the transparent original 58 is determined by detecting the output of a signal from a magnetic reading head (not shown) installed in the vicinity of the holder 94. When the transparent original 58 is mounted, an optical system switching operation is performed in the projection display apparatus 1. Since this switching operation is disclosed in Japanese Patent Laid-Open No. 9-83915 by the applicant of the present application, the description thereof is omitted.
[0020]
When the memory card 52 is inserted into the IC card slot 18 (FIG. 1) and this memory card 52 is connected to the connector 98 disposed in the projection display device 1, the CPU 84 inserts the memory card 52 into the projection display device 1. Recognize that it is installed. Image data output from the memory card 52 is converted into RGB color digital data by the decode circuit 96 and input to the terminal 66 c of the switch element 66. The output of the switch element 66 is connected to the liquid crystal drive circuit 108. The liquid crystal drive circuit 108 drives the liquid crystal display device 110 based on RGB color image data input via the switch element 66. An image generated by the liquid crystal display device 110 is projected onto the screen 56 via the projection lens 22 (FIG. 1). At this time, the switch element 66 includes RGB color digital data output from any one of the image generation circuit 85 (details of the image generation circuit 85 will be described later), the digital decoder 64, the A / D converter 70, and the decode circuit 96. Is output to the liquid crystal driving circuit 108. The operation of switching the input of the switch element 66 is controlled by the CPU 84 via the control circuit 86. The input switching control operation of the switch element 66 by the CPU 84 will be described in detail later.
[0021]
The audio signal input terminal 2 is connected to the terminal 100 a of the switch circuit 100, and the L audio signal input terminal 10 and the R audio signal input terminal 12 are connected to the terminal 100 c of the switch circuit 100. Since the L audio signal and the R audio signal are inherently independent signals, the switch circuit 100 is wired independently from each of the terminals 10 and 12, but is simplified in FIG. Yes. The audio signal input to the audio input terminal 2 may be monaural or stereo as in the case of the terminals 10 and 12 described above.
[0022]
The memory card 52 may also record audio data along with image data. In this case, the decoding circuit 96 generates an audio signal based on the audio data recorded on the memory card 52 and outputs it to the terminal 100 b of the switch circuit 100. At this time, the CPU 84 can detect that audio data is recorded in the memory card 52.
[0023]
The output of the switch circuit 100 is connected to the audio amplifier circuit 102. The audio amplifier circuit 102 amplifies the audio signal input via the switch circuit 100. The amplifier circuit 102 is provided with a mute terminal 102a. When a mute signal is issued from the CPU 84 via the control circuit 86, the amplification factor of the audio amplifier circuit 102 is lowered or made zero. Hereinafter, in the present specification, when the amplification factor of the audio amplification circuit 102 is lowered or made zero, it is referred to as “muted”, and when the amplification factor is returned to the normal amplification factor, it is referred to as “unmuted”. . The output of the audio amplifier circuit 102 is connected to the switch circuit 104. The signal amplified by the audio amplifier circuit 102 is output to the built-in speaker 106 or the audio output terminal 16 according to the switching state of the switch 104. At this time, the switch circuit 100 outputs an audio signal output from any one of the audio signal input terminal 2, the L audio signal input terminal 10, the R audio signal input terminal 12, and the decoding circuit 96 to the audio amplifier circuit 102. . The operation of switching the input of the switch circuit 100 is controlled by the CPU 84 via the control circuit 86. The input switching control operation of the switch circuit 100 by the CPU 84 will be described in detail later. Note that the switch 104 may be switched by providing a switch (not shown) in the projection display device 1 so that the operator can switch. Alternatively, the switch 104 may normally be connected to the built-in speaker 106 and connected to the audio output terminal 16 only when a plug of a connection cable to the external speaker is attached to the audio output terminal 16. Moreover, it is good also as a structure which outputs an audio | voice signal to both the built-in speaker 106 and the audio | voice output terminal 16. FIG. However, in this case, two audio amplifying circuits 102 having mute terminals 102a are required.
[0024]
When the operator operates the remote controller 50, the remote controller 50 emits, for example, infrared light subjected to frequency modulation in a pattern corresponding to the above operation. The light receiving element 80 receives this infrared light and converts it into an electrical signal. This electrical signal is decoded by the decoder 82 and input to the CPU 84. The CPU 84 executes a control operation described later based on a signal output from the decoder 82.
[0025]
The operation of the projection display device 1 configured as described above will be described. In the following description, it is assumed that no video signal is input to the projection display device 1 in the initial state, and neither the memory card 52 nor the transparent original 58 is mounted. Further, the audio amplification circuit 102 is muted by the CPU 84 in a state where no video signal is input and neither the memory card 52 nor the transparent original 58 is attached.
[0026]
The operator turns on a power switch (not shown) of the projection display device 1. At this time, since the projection display device 1 is in the above-described state, the signal input from the OR circuit 78 to the lamp lighting circuit 88 is in the state of “L”. Accordingly, since the lamp 90 is not lit, useless power is not consumed. Alternatively, only after the power is turned on, the lamp 90 may be turned on for a certain period of time regardless of whether a video signal is input or whether the memory card 52 or the transparent original 58 is mounted, and the lamp 90 may be warmed. The reason for this is that it takes time for the lamp 90 to warm to a temperature suitable for projection. By preheating the lamp 90 as described above, when a video signal is input to the projection display device 1 as described later, the projected image is suitable for viewing in a short time. Become. As described above, the CPU 84 controls the residual heat of the lamp. Specifically, the CPU 84 may output a signal “H” to the OR circuit 78 for a certain time immediately after the power is turned on. At this time, if no video signal is input and the memory card 52 or the transparent original 58 is not attached, a display such as “No Signal” may be displayed on the on-screen display. By performing such a display for a predetermined time immediately after the power is turned on, the operator can instantly grasp the situation such as the connection of the projection display device.
[0027]
− Projection display based on video signal output from computer −
When the operator turns on the power of the computer 30 in the above state, a video signal is output from the computer 30 to the video signal input terminal 4. Then, a pulse signal having a predetermined pulse width is repeatedly input from the synchronization separation circuit 68 or the terminal 4b to the OR circuit 74, and accordingly, the same signal as described above is input from the OR circuit 74 to the multivibrator 76. The When the pulse signal is repeatedly input to the multivibrator 76 in this way, the 'H' signal is output from the multivibrator 76 to the OR circuit 78, and the lamp 90 is lit. Subsequently, the CPU 84 waits for a predetermined time after the output of the multivibrator 76 changes from “L” to “H”, and issues a control signal to the audio amplifier circuit 102 via the control circuit 86. Cancel mute.
[0028]
The reason why the mute is released after waiting for a predetermined time after the lamp 90 is turned on will be described. When the lamp 90 is a high-pressure discharge lamp, a high-pressure pulse voltage is applied for several seconds at the start of lighting of the lamp 90. At this time, noise may be superimposed on the output signal of the audio amplifier circuit 102. When this noise is amplified by the audio amplifier circuit 102, a loud noise may be emitted from the speaker 106, or in the worst case, the speaker 106 may be damaged. In this regard, in the projection display device 1 according to the present invention, since the audio amplifier circuit 102 is muted until a predetermined time elapses after the lamp 90 is turned on, the above-described problem is suppressed. That is, when the lamp 90 is such that a high voltage pulse voltage is applied at the start of lighting, such as a high pressure discharge lamp, the predetermined time exceeds the time required to complete the application of the high voltage pulse voltage to the lamp 90. If you do. Further, when the lamp 90 is a tungsten bulb or a halogen lamp, voltage fluctuation may occur at the start of lighting, and the predetermined time may be set to a value exceeding the time required for the voltage fluctuation to settle.
[0029]
When the lamp 90 is a high-pressure discharge lamp, the sound amplifying apparatus 102 is muted until the above-described application of the pulse voltage is completed, so that the above-described problem does not occur. That is, since the sound amplifying device 102 is muted from the start of lighting of the lamp 90 to the end of the application of the high voltage pulse voltage to the lamp 90, no noise sound is generated. Although the example in which the audio amplifier circuit 102 is muted has been described above, other methods may be used. For example, the switch circuit 100 is provided with an OFF position that is not connected to any of the terminals 100a to 100c described above, and the CPU 84 switches the switch 100 to the OFF position instead of muting the audio amplifier circuit 102. Also good. In this case, it is assumed that the noise at the time of lamp lighting described above is superimposed in a portion before the sound amplifying device 102. When the noise is superimposed on the audio amplifying device 102, the power supply to the audio amplifying circuit 102 can be turned on and off by the CPU 84. Instead of muting the audio amplifying circuit 102, the CPU 84 can control the audio amplifying circuit 102. The power of 102 may be turned off. Further, the switch circuit 104 may be provided with an OFF position that is not connected to any speaker, and the CPU 84 may switch the switch circuit 104 to the OFF position instead of muting the audio amplifier circuit 102.
[0030]
When performing projection display based on the video signal output from the computer, the CPU 84 sets the switch element 66 in a state in which the terminal 66b and the liquid crystal driving circuit 108 are connected. At this time, similarly, the CPU 84 sets the switch circuit 100 in a state in which the terminal 100c and the audio amplifier circuit 102 are connected. Accordingly, an image based on the video signal output from the computer 30 is projected and displayed on the screen 56, and the audio signal output from the computer 30 is amplified and reproduced by the speaker 106. The switching control of the switch element 66 and the switch circuit 100 by the CPU 84 will be described later.
[0031]
− Projection display based on video signal output from video camera −
The same operation as described above is also performed when the video camera 40 is turned on. The operation at this time will be described below. As the video camera 40 is turned on, a video signal is input from the video camera 40 to the video signal input terminal 8. Then, a pulse signal having a predetermined pulse width is repeatedly input from the synchronization separation circuit 62 to the OR circuit 74, and accordingly, the same signal as described above is input from the OR circuit 74 to the multivibrator 76. When the pulse signal is repeatedly input to the multivibrator 76 in this way, the 'H' signal is output from the multivibrator 76 to the OR circuit 78 and the lamp 90 is lit. Subsequently, the CPU 84 waits for a predetermined time after the output of the multivibrator 76 changes from “L” to “H”, and issues a control signal to the audio amplifier circuit 102 via the control circuit 86. Cancel mute.
[0032]
In the above case, the CPU 84 sets the switch element 66 in a state in which the terminal 66a and the liquid crystal drive circuit 108 are connected. In addition, the switch circuit 100 is set to a state in which the terminal 100 a and the audio amplifier circuit 102 are connected by the CPU 84. Accordingly, an image based on the video signal output from the video camera 40 is projected and displayed on the screen 56, and the audio signal output from the video camera 40 is amplified and reproduced by the speaker 106. Switching control of the switch element 66 and the switch circuit 100 by the CPU 84 will be described later.
[0033]
The flowchart shown in FIG. 3 shows a part of the control procedure of the projection display device 1 executed by the CPU 84. The above-described control procedure executed by the CPU 84 when the projection display device 1 performs projection display based on the video signal output from the computer 30 or the video camera 40 will be described again with reference to FIG. To do. In the flowchart shown in FIG. 3A, the CPU 84 detects that a video signal has been input to the projection display device 1, turns on the lamp 90, and controls only the part of the control operation that releases the mute of the audio amplifier circuit 102. Show.
[0034]
The CPU 84 determines whether or not the signal output from the multivibrator 76 is 'H' in step S101. If the determination is negative, the determination in step S101 is continued. If the determination in step S101 is affirmative, the CPU 84 starts a timer in step S103, and determines in step S104 whether or not the timer timing has been completed. If the determination in step S104 is negative, the CPU 84 continues to perform the determination in step S104. If the determination in step S104 is positive, the CPU 84 proceeds to step S105 and issues a mute release command signal to the control circuit 86. Based on this command signal, the control circuit 86 issues a signal to the terminal 102a of the audio amplifier circuit 102 to cancel mute of the audio amplifier circuit 102.
[0035]
The above is the description of the operation of the projection display apparatus 1 when a video signal is input to the video signal input terminal 4 or 8. Next, an operation when the video signal input to the video signal input 4 or 8 is not input will be described. In this case, since the inputs of the OR circuit 74 are all 'L', the output of the OR circuit 74 is 'L' and the output of the multivibrator 76 is also 'L'. At this time, since the signal output from the CPU 84 to the OR circuit 78 is 'L', the output from the OR circuit 78 is 'L', and the lamp lighting circuit 88 turns off the lamp 90. In this case, the lamp 90 is turned on when a video signal is input to the video signal input terminal 4 or 8, and the lamp 90 is turned off immediately when the video signal is interrupted. Accordingly, when the video signal input to the video video signal input terminal 4 or 8 is intermittently interrupted in a relatively short time, such as when the connector is attached to or detached from the video signal input terminal 4 or 8, the lamp 90 is turned on and The turn-off will be repeated frequently. If this phenomenon is not desirable, the CPU 84 can output a signal to the OR circuit 78 as described below.
[0036]
Since the output signal of the multivibrator 76 is also output to the CPU 84, the CPU 84 can detect whether a video signal is input to the video signal input terminal 4 or 8. When the CPU 84 detects that a video signal has been input, it outputs a signal “H” to the OR circuit 78. At this time, the 'H' signal is also output from the multivibrator 76 to the OR circuit 78, and the lamp 90 is lit. If the video signal is interrupted in this state, the output of the multivibrator 76 becomes 'L'. However, since the signal output from the CPU 84 to the OR circuit 78 is “H”, the output signal of the OR circuit 78 is maintained in the “H” state, and thus the lighting state of the lamp 90 is also maintained. When the CPU 84 detects that the output signal of the multivibrator 76 has become “L”, it starts timing. When a predetermined time is reached, the output to the OR circuit 78 is set to 'L'. Then, since the output signal of the OR circuit 78 becomes 'L', the lamp 90 is turned off. In this way, by controlling the lamp 90 to be turned off after a predetermined time has elapsed after detecting that no video signal has been input, the video signal is input to the video signal input terminal 4 or 8. However, the lamp 90 is not frequently turned on and off repeatedly even when the input is intermittently input in a relatively short cycle. Further, in FIG. 2, a configuration similar to the multivibrator 76 may be provided at each input (previous stage) of the OR circuit 74 so that the CPU 84 can detect an output from the multivibrator. In this way, the CPU 84 can determine which of the video signal input terminals 4 and 8 is receiving the video signal, and based on this determination result, the terminals of the switches 66 and 100 May be selected.
[0037]
With reference to FIG. 3B, the above-described control operation of the CPU 84 when no video signal is input to the projection display device 1 will be described again. In the flowchart shown in FIG. 3B, only the part of the control operation in which the CPU 84 detects that the video signal is no longer input to the projection display device 1 and mutes the audio amplifier circuit 102 and turns off the lamp 90. Show.
[0038]
In step S201, the CPU 84 determines whether or not the output signal from the multivibrator 76 is 'L'. If the determination is negative, the determination operation in step S201 is continued. If the determination in step S201 is affirmative, the CPU 84 starts a timer in step S202. The CPU 84 determines whether or not the timer has ended in step S203, and if the determination is negative, the determination operation in step S203 is repeated. If the determination in step S203 is affirmative, the CPU 84 issues a mute command signal to the control circuit 86. When this signal is received from the CPU 84, the control circuit 86 issues a signal to the terminal 102a of the audio amplifying circuit 102 to put the audio amplifying circuit 102 in a mute state. In step S205, the CPU 84 sets the signal output to the OR circuit 78 to 'L'. Then, the output of the OR circuit 78 becomes 'L', and the lamp 90 is turned off. Accordingly, it is possible to suppress the repeated operation of turning on / off the lamp 90 due to imperfect contact when the connectors 38, 44 are attached to the terminals 8, 4a, 4b.
[0039]
Operations in the case where the memory card 52 or the transparent original 58 is mounted on the projection display device 1 will be sequentially described. In the following description, it is assumed that no video signal is input to the projection display device 1 in the initial state, and neither the memory card 52 nor the transparent original 58 is mounted. In this state, the audio amplifying circuit 102 is muted and the lamp 90 is off. Thereby, when attaching the connectors 38 and 44 to the terminals 8, 4 a, and 4 b, it is possible to suppress repeated operation of lighting and extinguishing the lamp due to imperfect contact.
[0040]
− Projection display based on image data recorded on memory card −
When the memory card 52 is attached to the connector 98, the CPU 84 detects this and outputs a signal of “H” to the OR circuit 78. Then, a signal “H” is output from the OR circuit 78 to the lamp lighting circuit 88 and the lamp 90 is lit. Subsequently, the CPU 84 waits for a predetermined time to elapse after the lamp 90 is turned on, and issues a control signal to the audio amplifier circuit 102 via the control circuit 86 to cancel mute.
[0041]
In the above case, the CPU 84 sets the switch element 66 in a state in which the terminal 66c and the liquid crystal drive circuit 108 are connected. The CPU 84 also determines whether audio data is recorded along with image data in the memory card 52 attached. If it is determined that audio data is recorded, the CPU 84 issues a control signal to the switch circuit 100 to set the terminal 100b and the audio amplifier circuit 102 in a connected state. Therefore, an image based on the image data recorded on the memory card 52 is projected and displayed on the screen 56, and an audio signal based on the audio data recorded together with the image data on the memory card 52 is amplified and reproduced by the speaker 106. .
[0042]
On the other hand, if it is determined that no audio data is recorded in the memory card 52, the CPU 84 issues a control signal to the switch 100, and the predetermined one of the terminals 100a and 100c, the audio amplifier circuit 102, and the like. Set the to be connected. When the CPU 84 controls the switch circuit 100 in this manner, the audio signal is input from the audio input terminal 2, or the L audio signal input terminal 10 and the R audio signal input terminal 12, and the speaker 106 or an external speaker (not shown). Can be played.
[0043]
That is, when no audio data is recorded in the memory card 52, the audio signal input from any one of the audio input terminal 2, the L audio signal input terminal 10, and the R audio signal input terminal 12. Can be reproduced by the speaker 106 or the like. For this reason, a presentation etc. can be performed effectively. Regarding the switching of the switch 100, the CPU 84 may issue a control signal to the switch 100 when the operator detects an operation of a sound source selection switch (not shown) arranged in the projection display device 1. Further, the CPU 84 may issue a control signal to the switch 100 in response to the operator operating the remote controller 50 to select a sound source.
[0044]
The above-described control procedure executed by the CPU 84 when the memory card 52 is mounted on the projection display device 1 and projection display based on the image data recorded on the memory card 52 is performed will be described again with reference to FIG. explain. FIG. 4 shows a part of the control procedure of the projection display device 1 executed by the CPU 84. The CPU 84 detects that the memory card 52 is mounted on the projection display device 1, turns on the lamp 90, and switches Only the control procedure from switching 100 to releasing the mute of the audio amplifier circuit 102 is shown.
[0045]
In step S301, the CPU 84 determines whether it is detected that the memory card 52 is inserted. If the determination in step S301 is negative, the CPU 84 repeats the determination in step S301. If the determination in step S301 is affirmative, the CPU 84 outputs a connection switching command signal for the switch element 66 to the control circuit 86 in step S302. The control circuit 86 receives the command signal from the CPU 84, issues a control signal to the switch element 66, and connects the terminal 66 c to the liquid crystal drive circuit 108. In step S303, the CPU 84 sets the signal output to the OR circuit 78 to 'H'. Then, since the output of the OR circuit 78 becomes “H”, the lamp 90 is turned on. In step S304, the CPU 84 determines whether or not audio data is recorded in the attached memory card 52. If the determination is affirmative, the CPU 84 proceeds to step S305 and issues a switching control signal for the switch 100 to the control circuit 86. The control circuit 86 connects the terminal 100 b to the input of the audio amplification circuit 102 based on a control signal from the CPU 84. If the determination in step S304 is negative, that is, if it is determined that no audio data is recorded in the attached memory card 52, the CPU 84 branches to step S309, and the control circuit 86 switches the switching control signal for the switch 100. To emit. In response to this signal, the control circuit 86 connects the terminal 100 a or 100 c to the input of the audio amplifier circuit 102. In step S306, the CPU 84 starts a timer. The CPU 84 determines whether or not the timer has ended in step S307. If the determination is negative, the CPU 84 continues to determine in step S307. If the determination in step S307 is positive, the CPU 84 issues a mute release command signal to the control circuit 86 in step S308. The control circuit 86 issues a control signal to the terminal 102 a of the audio amplifier circuit 102 to cancel the mute of the audio amplifier circuit 102.
[0046]
An operation when the memory card 52 is removed from the projection display device 1 will be described. When detecting that the memory card 52 is removed from the connector 98, the CPU 84 sets the signal output to the OR circuit 78 to 'L'. Since the other input of the OR circuit 78 is 'L', the output of the OR circuit 78 is also 'L', and the lamp lighting circuit 88 turns off the lamp 90. The CPU 84 also issues a control signal to the audio amplifier circuit 102 via the control circuit 86 and mutes the audio amplifier circuit 102.
[0047]
When the insertion / removal of the memory card 52 is repeated at a relatively short time interval, the lamp 90 is turned on / off frequently. Furthermore, when the memory card 52 is replaced and another memory card 52 is inserted to display an image, the light is turned off / on repeatedly. When this phenomenon is not desirable, the CPU 84 detects that the memory card 52 has been removed and waits until a predetermined time elapses, and then the signal output to the OR circuit 78 may be set to “L”. . In this way, even if chattering occurs when the memory card 52 is inserted or removed, it is possible to eliminate the problem that the lamp 90 blinks rapidly.
[0048]
In addition, when the high pressure discharge lamp starts to be lighted from a cold state, the light output may not easily increase unless the vapor pressure of the light emitting metal increases after a certain period of time has elapsed since the start of lighting. As a lamp lighting circuit for solving this, there is one disclosed in, for example, Japanese Patent Laid-Open No. 2-10697. This lamp lighting circuit inputs a large amount of power immediately after the start of lighting, and reduces the power supplied to the lamp over time. However, when such a circuit is used, if power is intermittently supplied to the lamp, excessive power may be supplied to the lamp, or the lamp temperature may increase, thereby shortening the lamp life. In this regard, the above-described problem can be solved by waiting until a predetermined time has elapsed after detecting that the memory card 52 has been removed, and then turning off the lamp 90.
[0049]
The above-described control procedure executed by the CPU 84 when the memory card 52 attached to the projection display device 1 is removed will be described again with reference to FIG. FIG. 5 shows a part of the control procedure of the projection display device 1 executed by the CPU 84, detects that the memory card 52 attached to the projection display device 1 is removed, and mutes the sound amplification circuit 102. Only the control procedure until the lamp 90 is turned off is shown.
[0050]
In step S401, the CPU 84 determines whether or not the memory card 52 attached to the connector 98 has been removed. If the determination in step S401 is negative, the CPU 84 continues to perform the determination in step S401. If the determination in step S401 is affirmative, the CPU 84 starts a timer in step S402. The CPU 84 determines whether or not the time measurement has been completed in step S403, and if the determination is negative, the determination in step S403 is continued. If the determination in step S403 is affirmative, the CPU 84 determines whether or not the memory card 52 is attached to the connector 98 in step S404. The determination in step S404 is affirmed when a new memory card 52 is inserted at a relatively short time interval. In this case, the CPU 84 branches to step S304 in FIG. 4 and continues image display based on the image data recorded on the memory card 52 without turning off the lamp 90 or the like. If the determination in step S404 is negative, the CPU 84 issues a mute command signal to the control circuit 86 in step S405. The control circuit 86 issues a control signal to the terminal 102a of the audio amplifier circuit 102 to put the audio amplifier circuit 102 in a mute state. In step S406, the CPU 84 sets the signal output to the OR circuit 78 to 'L'. Then, the output of the OR circuit 78 becomes 'L' and the lamp 90 is turned off.
[0051]
− Projection display of transparent original image −
When the transparent original 58 is mounted on the holder 94, the CPU 84 detects this and outputs a signal “H” to the OR circuit 78. Then, a signal “H” is output from the OR circuit 78 to the lamp lighting circuit 88 and the lamp 90 is lit. Subsequently, the CPU 84 waits for a predetermined time to elapse after the lamp 90 is turned on, issues a control signal to the audio amplifier circuit 102 via the control circuit 86, and cancels mute.
[0052]
In the above control operation, the CPU 84 issues a control signal to the control circuit 86, and the control signal terminals 100a and 100c are set in a state in which one of the predetermined terminals and the audio amplification circuit 102 are connected. To do. When the CPU 84 controls the switch circuit 100 in this manner, the audio signal is input from the audio input terminal 2, or the L audio signal input terminal 10 and the R audio signal input terminal 12, and the speaker 106 or an external speaker (not shown). Can be played.
[0053]
The flowchart shown in FIG. 6 shows a part of the control procedure of the projection display device 1 executed by the CPU 84. The above-described control procedure executed by the CPU 84 when the transparent original 58 is mounted on the projection display device 1 to perform projection display will be described again with reference to FIG. The flowchart shown in FIG. 6A shows only the control operation part in which the CPU 84 detects that the transparent original is mounted, turns on the lamp 90, and cancels the mute of the audio amplifier circuit 102.
[0054]
In step S501, the CPU 84 determines whether or not the signal output from the photo interrupter 92 has changed, that is, whether or not the transparent original 58 is mounted. If this determination is negative, the determination in step S501 is repeated. If the determination in step S501 is affirmative, the CPU 84 sets the signal output to the OR circuit 78 to 'H' in step S502. Then, the output signal of the OR circuit 78 becomes 'H', and the lamp 90 is turned on. In step S <b> 503, the CPU 84 outputs a connection switching command signal for the switch 100 to the control circuit 86. When the control circuit 86 receives the command signal from the CPU 84, the control circuit 86 issues a control signal to the switch circuit 100, and one of predetermined terminals of the control signal terminals 100a and 100c is connected to the audio amplifier circuit 102. Switch to. In step S504, the CPU 84 starts a timer, and in step S505, determines whether or not the timer has been counted. If the determination is negative, the CPU 84 repeats the determination in step S505, and if the determination is positive, the CPU 84 issues a mute release command signal to the control circuit 86 in step S506. The control circuit 86 issues a control signal to the terminal 102 a of the audio amplifier circuit 102 to cancel the mute of the audio amplifier circuit 102.
[0055]
When the CPU 84 switches the switch circuit 100 as described above to project a transparent original image, the audio input terminal 2, the L audio signal input terminal 10, and the R audio signal input terminal 12, An audio signal input from any terminal can be amplified and reproduced by the speaker 106 or the like. For this reason, a tape recorder, a CD player, or the like can be connected to any of these audio input terminals, and presentations can be effectively performed.
[0056]
Regarding the switching of the switch 100, the CPU 84 may issue a control signal to the switch 100 when the operator detects an operation of a sound source selection switch (not shown) arranged in the projection display device 1. Further, the CPU 84 may issue a control signal to the switch 100 in response to the operator operating the remote controller 50 to select a sound source.
[0057]
The operation when the transparent original 58 is removed from the projection display device 1 will be described. When the CPU 84 detects that the transparent original 58 is removed from the holder 94, the CPU 84 sets the signal output to the OR circuit 78 to 'L'. Since the other input of the OR circuit 78 is 'L', the output of the OR circuit 78 is also 'L', and the lamp lighting circuit 88 turns off the lamp 90. The CPU 84 also issues a control signal to the audio amplifier circuit 102 via the control circuit 86 and mutes the audio amplifier circuit 102.
[0058]
By the way, when projecting the transparent original 58, it is expected that a plurality of originals are frequently exchanged at relatively short time intervals. At this time, lighting and extinguishing of the lamp 90 are frequently repeated. If this phenomenon is not desirable, the CPU 84 detects that the transparent document 58 has been removed and waits until a predetermined time elapses, and then the signal output to the OR circuit 78 may be set to “L”. . By doing so, it is possible to solve the problem that the lamp 90 is frequently turned on and off repeatedly as the transparent document 58 is frequently replaced, and the life of the lamp 90 is shortened.
[0059]
With reference to FIG. 6B, the above-described control operation by the CPU 84 when the transparent document 58 mounted on the projection display device 1 is removed will be described again. The flowchart shown in FIG. 6B shows only the control operation portion in which the CPU 84 detects that the transparent original 58 has been removed, puts the audio amplifier circuit 102 into the mute state, and turns off the lamp 90.
[0060]
In step S601, the CPU 84 determines whether or not the signal output from the photo interrupter 92 has changed, that is, whether or not the transparent original 58 has been removed. If the determination is negative, the determination in step S601 is repeated. If the determination in step S601 is affirmed, the CPU 84 starts a timer in step S602. In step S603, the CPU 84 determines whether or not the timer has been measured. If the determination is negative, the determination in step S603 is repeated. If the determination in step S603 is affirmative, the CPU 84 determines whether or not the transparent original 58 is mounted again based on whether or not the signal output from the photo interrupter 92 is changed in step S604. If the determination in step S604 is affirmative, this corresponds to the case where the transparent original 58 is replaced at a relatively short time interval. In this case, the CPU 84 maintains the lamp 90 in the lit state, maintains the mute cancellation state of the audio amplifier circuit 102, branches to the step following step S506 in FIG. 6A, and continues to perform projection display of the transparent original 58. . If the determination in step S604 is negative, the CPU 84 issues a mute command signal to the control circuit 86 in step S605. When this signal is received from the CPU 84, the control circuit 86 issues a signal to the terminal 102a of the audio amplifying circuit 102 to put the audio amplifying circuit 102 in a mute state. In step S606, the CPU 84 sets the signal output to the OR circuit 78 to 'L'. Then, the output of the OR circuit 78 becomes 'L', and the lamp 90 is turned off. The invention described above can also be applied to a general slide projector that projects a developed reversal film or the like.
[0061]
− Projection display when a function setting change operation is performed −
Here, how the projection display device 1 can be remotely operated by using the remote controller 50 will be described. When the operator operates the remote controller 50, the video source is selected, the lamp 90 is turned on / off, the color of the projected image, the inversion of the projected image, the color of the pointer, and amplified by the audio amplification circuit 102. Various function settings such as the size (volume) of the audio signal can be changed. During these operations, a list of settings that can be changed is displayed on the screen 56 in a menu format as will be described later. In the following description, such display is referred to as “on-screen display”. The operator changes various settings by operating the remote controller 50 while confirming an image displayed on the screen. In the following description, it is assumed that the projection display device 1 is in the initial state described above.
[0062]
As the operator operates the remote controller 50, the remote controller 50 emits pulsed infrared light that is frequency-modulated according to the operation content of the remote controller 50. The light receiving element 80 receives this infrared light, converts it into an electrical signal, and outputs it to the decoder 82. The decoder 82 decodes the electric signal output from the light receiving element 80 and outputs a command signal corresponding to the operation content of the remote controller 50 to the CPU 84. When this command signal is input, the CPU 84 sets the signal output to the OR circuit 78 to 'H'. Then, the lamp 90 is turned on. At this time, the CPU 84 issues a control signal to the image generation circuit 85, and further issues a control signal via the control circuit 86 so that the terminal 66 d of the switch element 66 is connected to the liquid crystal driving circuit 108.
[0063]
The image generation circuit 85 receives an instruction from the CPU 84 and generates image data of a setting change menu screen. Then, the setting change menu screen image data generated by the image generation circuit 85 is output to the liquid crystal driving circuit 108 and displayed on the screen 56. The image displayed on the screen changes as the CPU 84 issues a control signal to the image generation circuit 85. The operator operates the remote controller 50 while watching the content displayed on the screen. The CPU 84 interprets the content of the command signal output from the decoder 82 at this time and changes the setting content of the projection display device 1. When the operator finishes changing the setting contents, the operator issues a command to operate the remote controller 50 to turn off the on-screen display. The CPU 84 receives an on-screen display end command via the decoder 82 and sets the signal output to the OR circuit 78 to 'L'. Then, since the signal output from the OR circuit 78 to the lamp lighting circuit 88 is also “L”, the lamp lighting circuit 88 turns off the lamp 90. Instead of the operator performing the on-screen display end operation as described above, the following may be performed. That is, the operator finishes the operation of the remote controller 50 when the change of the setting contents is completed. When a predetermined time elapses after the signal input from the decoder 82 is interrupted, the CPU 84 sets the signal output to the OR circuit 78 to 'L'. Then, since the signal output from the OR circuit 78 to the lamp lighting circuit 88 is also “L”, the lamp lighting circuit 88 turns off the lamp 90.
[0064]
The above-described control procedure executed by the CPU 84 when on-screen display is performed on the projection display device 1 in response to the operator operating the remote controller 50 will be described again with reference to FIG. FIG. 7 shows a part of the control procedure of the projection display device 1 executed by the CPU 84, detects that a command signal is issued from the decoder 82, turns on the lamp 90, and then changes the setting contents. Only the control procedure until the lamp 90 is turned off when it is finished is shown.
[0065]
In step S701, the CPU 84 determines whether or not a command signal is output from the decoder 82. If the determination in step S701 is negative, the CPU 84 continues to determine in step S701. If the determination in step S701 is affirmative, the CPU 84 sets the signal output to the OR circuit 78 to 'H' in step S702. Then, since the output of the OR circuit 78 becomes “H”, the lamp 90 is turned on. In step S <b> 703, the CPU 84 outputs an image generation command signal to the image generation circuit 85 based on the command signal output from the decoder 82. In step S <b> 704, the CPU 84 outputs a connection switching command signal for the switch element 66 to the control circuit 86. The control circuit 86 receives the command signal from the CPU 84, issues a control signal to the switch element 66, and connects the terminal 66 d to the liquid crystal drive circuit 108. Through the above control operation by the CPU 84, the image generated by the image generation circuit 85 is projected and displayed. That is, on-screen display is performed. In step S705, the CPU 84 interprets and executes the command signal output from the decoder 82. In step S706, the CPU 84 determines whether or not the command signal output from the decoder 82 relates to a command for ending the setting content changing operation. If the command signal is negative, the CPU 84 returns to step S705 and continues to interpret the command signal. Perform. If the determination in step S706 is affirmative, the CPU 84 sets the signal output to the OR circuit 78 to 'L' in step S707. Then, the output of the OR circuit 78 becomes “L”, and the lamp 90 is turned off.
[0066]
Here, switching of the video source by operating the remote controller 50 will be described. The operator can select which device to display the image on the screen 56 based on which video signal is output from among a plurality of external devices connected by operating the remote controller 50 as described above. The CPU 84 switches the switch element 66 and the switch circuit 100 via the control circuit 86 in response to the input of a command signal related to video source switching from the decoder 82. Therefore, the computer 30 and the video camera 40 are turned on, and the image displayed on the screen 56 is based on the video signal output from the computer 30 and the image based on the video signal output from the video camera 40. It can be switched appropriately. Further, the image displayed on the screen 56 can be switched to an image based on the image data recorded on the memory card 52 or can be switched to the image of the transparent original 58.
[0067]
In the above, an example has been described in which an operator operates the remote controller 50 to switch which video signal is to be displayed based on which video signal is output from the computer 30 and the video camera 40. Automatic switching may be used. In this case, the signals from the sync separation circuits 62 and 68 and the terminal 4b may be individually input to the CPU 84. At this time, a video signal may be simultaneously input from a plurality of external devices. In such a case, if a video source to be preferentially selected is set in advance, there will be no confusion. Alternatively, the CPU 84 may detect the most recently input video source and automatically select the video source. If the video signal (including transparent originals and memory cards) is simultaneously input from a plurality of external devices as described above, for example, if the currently displayed video signal is input for more than a certain period of time, it is automatically In addition, video signals (including transparent originals and memory cards) input from other external devices may be displayed. At this time, the priority order of the displayed video signals may be set in advance.
[0068]
When the operator changes various settings while viewing the on-screen display, the mouse 28 may be operated instead of operating the remote controller 50. In this case, for example, the right button of the mouse 28 is pressed once (hereinafter, the operation described on the left is referred to as “right click”. Also, pressing the left button of the mouse 28 is referred to as “left click”). Is displayed on-screen. The operator operates the mouse while looking at the pointer superimposed on the on-screen menu screen, and moves the pointer to the position where the menu item whose setting is to be changed is displayed. Accordingly, setting of a desired item can be changed by appropriately performing a left click or right click operation. When the lamp 90 is turned off, the CPU 84 detects an operation of sliding the mouse 28 on a plane such as a desk in addition to detecting the right click and left click operations of the mouse 28. Can also be lit. The pointer function by the mouse 28 can also be performed by the remote controller 50.
[0069]
Further, instead of the remote controller 50 and the mouse 82 described above, a switch for changing function settings may be provided in the main body of the projection display apparatus 1. Alternatively, a control panel separate from the projection display device 1 may be provided, and the control panel and the projection display device 1 may be connected by a cable. In this case, the function setting is changed by operating the control panel.
[0070]
Furthermore, the projection display device according to the present invention may incorporate a DVD player or the like. In this case, the CPU 84 can detect that the DVD medium has been set on the tray and can turn on the lamp 90. Further, instead of the memory card 52, a magnetic recording medium such as a floppy disk or an MO disk, or a magneto-optical recording medium can be mounted.
[0071]
In the correspondence between the embodiments of the present invention and the claims, the liquid crystal driving circuit 108 and the liquid crystal display device 110 are the image generating device, the lamp 90 is the light source, the synchronization separating circuits 62 and 68 are the video signal detecting means, the lamp The lighting circuit 88 or the CPU 84 is a lighting control means and a light-off control means, the sound amplification circuit 102 is a sound amplification device, the CPU 84 is a weak sound control means, the light receiving element 80, the decoder 82 and the CPU 84, or the mouse 28 and the CPU 84 is an operation detection means. The image generation circuit 85 is a video signal generation means, the CPU 84 is a delay light extinction control means, the memory card 52 is a recording medium, the CPU 84 is a recording medium detection means, the photo interrupter 92 and the CPU 84 are original detection means, and the computer 30. And the video camera 40 is connected to an external device, audio signal input terminal 2, L audio The signal input terminal 10 and the R audio signal input terminal 12 are audio signal input terminals, the switch circuit 100 is an audio signal switching device, the connector 98 is first mounting means, the holder 94 is second mounting means, and the CPU 84 is A detection means and a voice switching control means are configured.
[0072]
【The invention's effect】
As described above, according to the projection type display device of the present invention, whether or not a video signal is input, whether or not a recording medium is mounted, whether or not a transparent document is mounted, and whether or not a function setting is changed Since the lamp is turned on / off by detecting this, it is not necessary for the operator to turn on / off the lamp one by one, and the operability is improved.
If there is no image to be projected and displayed, that is, no video signal is input, no recording medium or transparent original is mounted, and there is no function setting change operation, the lamp is automatically turned off. Therefore, power consumption can be suppressed. At this time, after a predetermined time has elapsed since it was determined that there is no image to be projected, the lamp is turned off, so that chattering at the time of insertion / removal of the connector of the connection cable with the recording medium or the external device, etc. Even if this occurs, the lamp does not blink rapidly and the stability of operation increases. In addition, the problem that the lamp life is shortened by unnecessary blinking of the lamp is also suppressed.
Furthermore, the state in which the amplification factor of the audio amplifying device is suppressed or the signal of the audio amplifying device is cut off until a predetermined time elapses after the video signal is input, the recording medium or the transparent original is detected to be mounted. By maintaining this state, it is possible to suppress the occurrence of unnecessary audio noise.
[Brief description of the drawings]
FIG. 1 is a diagram illustrating a schematic configuration of a projection display device according to an embodiment of the present invention.
FIG. 2 is a diagram schematically illustrating an internal configuration of a projection display apparatus according to an embodiment of the present invention.
FIG. 3 is a flowchart for explaining a part of the control procedure of the projection display device executed by the CPU. FIG. 3A is a control operation when an image signal is input, and FIG. It is a flowchart explaining control operation when an image signal stops.
FIG. 4 is a flowchart for explaining a part of the control procedure of the projection display device executed by the CPU, and is a flowchart for explaining the control operation when a memory card is mounted.
FIG. 5 is a flowchart for explaining a part of the control procedure of the projection display device executed by the CPU, and is a flowchart for explaining the control operation when the memory card is removed.
FIG. 6 is a flowchart for explaining a part of the control procedure of the projection display device executed by the CPU. FIG. 6A is a control operation when a transparent original is mounted, and FIG. 6 is a flowchart illustrating a control operation when a transparent original is removed.
FIG. 7 is a flowchart for explaining a part of the control procedure of the projection display device executed by the CPU, and is a flowchart for explaining the control operation when the remote controller is operated.
[Explanation of symbols]
DESCRIPTION OF SYMBOLS 1 ... Projection type display apparatus 2 ... Audio | voice signal input terminal
4, 8 ... Video signal input terminal 10 ... L audio signal input terminal
12 ... R audio input signal input terminal 28 ... Mouse
30 ... Computer 40 ... Video camera
50 ... Remote controller 52 ... Memory card
58 ... Transparent original 62, 68 ... Sync separation circuit
64 ... Digital decoder 66 ... Switch element
76 ... Multivibrator 80 ... Light receiving element
82 ... Decoder 84 ... CPU
85 ... Image generation circuit 86 ... Control circuit
88… Lamp lighting circuit 90… Lamp
92 ... Photo interrupter 96 ... Decoding circuit
98 ... Connector 100, 104 ... Switch circuit
102 ... Audio amplification circuit 108 ... Liquid crystal drive times
110 ... Liquid crystal display device

Claims (5)

Having mounting means capable of mounting a recording medium on which image data is recorded;
In a projection display device that projects and displays an image generated by an image generation device based on image data recorded on the recording medium to be mounted ,
A light source for illuminating the image;
Recording medium detecting means for detecting whether or not the recording medium is mounted;
A lighting control means for turning on the light source when the recording medium detection means detects that the recording medium is mounted ;
Determining means for determining whether audio data is recorded on the recording medium;
Audio reproduction means for reproducing the audio data when the determination means determines that the audio data is recorded;
Voice input means for inputting a voice signal from the outside,
The projection display device , wherein the sound reproduction means reproduces the sound signal input from the sound input means when the determination means determines that no sound data is recorded . Having mounting means capable of mounting a recording medium on which image data is recorded;
In a projection display device that projects and displays an image generated by an image generation device based on image data recorded on the recording medium to be mounted ,
A light source for illuminating the image;
Recording medium detecting means for detecting whether or not the recording medium is mounted;
A lighting control means for turning on the light source when the recording medium detection means detects that the recording medium is mounted ;
Determining means for determining whether audio data is recorded on the recording medium;
A projection display device , comprising: an audio reproduction unit that reproduces the audio data when the determination unit determines that the audio data is recorded . The projection display device according to claim 2 ,
A projection display device , further comprising a light-off control unit that turns off the light source when the recording medium detection unit detects that the recording medium is not attached . In the projection type display device according to claim 2 or 3 ,
A projection display apparatus , further comprising: a delay light extinction control unit that turns off the light source when a predetermined time has elapsed after the recording medium detection unit detects that the recording medium is not attached . In the projection type display apparatus of any one of Claims 2-4 ,
An audio amplifying device for amplifying the input audio signal;
A state in which the amplification factor of the audio amplifying device is suppressed or the signal of the audio amplifying device is cut off until a predetermined time elapses after the recording medium detecting means detects that the recording medium is loaded. A projection type display apparatus , further comprising a weak sound control means for maintaining the state .

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