JP2007141413A - Television and dvd incorporated type television - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To reduce standby power in a slot-in type disk device and in a television provided with a slot-in type disk device. <P>SOLUTION: In the television 10 provided with a slot-in type DVD drive 60, "normal setting" and "power saving setting" are selectable from a menu picture. In the power saving setting, an infrared LED 70 emitting light to monitor disk insertion when the power is on is made to always emit light by a control program executed by a television microcomputer 48, and the light emitting interval of the infrared LED 70 is also made gradually longer at the time of standby to stop light emission after the elapse of a prescribed time. Meanwhile, in the normal setting, the infrared LED 70 is made to always emit light as usual when the power is on, and the infrared LED 70 is made to intermittently emit light with a prescribed time interval at the time of the standby. <P>COPYRIGHT: (C)2007,JPO&INPIT

Description

  The present invention relates to a television and a DVD-integrated television that include a slot-in DVD drive and can perform power saving settings.

  In recent years, in a combo model of a DVD and a television, a liquid crystal television has been frequently used for the television. Therefore, a thin slot-in type DVD device is often used. Slot-in type DVD devices, unlike disc tray-type DVD devices, generally start devices by detecting the insertion of a disc with an infrared LED and an infrared sensor during standby. The infrared LED for detecting the insertion of the disk always emits light when the power is on, and emits light intermittently at regular intervals during standby.

  Patent Document 1 discloses that a portable disc player that reproduces audio information recorded on a disc such as a CD or an MD can select a normal mode and a power saving mode in which the main body function is limited. Has been. Functions that can be restricted by the user in the power saving mode include liquid crystal display, key operation, resume function, random playback function, volume function, and the like.

Patent Document 2 discloses that in a drive device corresponding to a plurality of types of information recording media, it is possible to save power by setting an operation state of a processing system that does not perform processing during standby to a sleep state. Yes.
Utility model registration No. 3060892 JP 2004-310403 A

In a slot-in type disk device, in order to detect the insertion of a disk, the insertion of the disk must be monitored even during standby. For this reason, the infrared LED and the infrared sensor continue to emit light even during standby in order to monitor the insertion of the disk, which hinders power saving.
The device described in the above patent document is a technology related to portable audio players and disk drive devices in general, and is not a technology for power saving in a slot-in type disk device, but an infrared LED for monitoring the insertion of a disk. There is no description about the sensor including.
In recent energy-saving intentions, many people turn off the main power or unplug the power outlet when the television is not used, and further reduction of standby power has been desired. An object of the present invention is to further save power in a slot-in type disk device or a television including a slot-in type disk device.

  In order to achieve the above object, according to the present invention, a liquid crystal display panel with a flat display surface for displaying video on the screen, a speaker for outputting sound, a television broadcast, and displaying the video on the liquid crystal display. A main board that displays on the panel and outputs sound through the speaker, a resin cabinet that houses the liquid crystal display panel, the speaker, and the main board, an infrared sensor, and an infrared LED are installed facing each other. A slot-in DVD drive that detects the insertion of a disk when the disk is inserted between the infrared sensor and the infrared LED, and pulls the disk into the interior; a timer that measures a predetermined elapsed time; and the infrared In a DVD-integrated television including a microcomputer that controls the light emission timing of the LED, the microcomputer includes a plurality of light emission tags. It is possible to select and execute a power saving setting combined with a normal setting and a normal setting. In the power saving setting, when the television is turned on, the infrared LED is always lit, and when the television is on standby, After causing the infrared LED to emit light intermittently at regular intervals, gradually increase the emission interval of the infrared LED to intermittently emit light, and then stop emitting the infrared LED after a predetermined time has elapsed. The infrared LED stops emitting light while the disc is inserted in the DVD drive. In the normal setting, when the television is turned on, the infrared LED is always emitted, and the television is During standby, the infrared LED is caused to emit light intermittently at a predetermined time interval, and the disc is While being inserted into blanking is a configuration for stopping the light emission of the infrared LED.

  The fixed time interval may be 1 second or 2 seconds, and may be any other interval. Various time intervals can be adopted, and the interval is gradually changed to be longer. It doesn't matter. The predetermined time may be 5 minutes, 10 minutes, 1 hour, or any time.

  In order to achieve the above object, in the television set according to claim 2, a power supply circuit which can be supplied to each circuit by receiving a supply voltage from an external commercial power supply or the like, and a slot-in type disk-like recording A medium reading device; a disk-shaped recording medium insertion detection sensor comprising an infrared LED and an infrared sensor for detecting insertion of a disk-shaped recording medium into the disk-shaped recording medium reading device; a timer for measuring a predetermined elapsed time; A configuration is provided that includes a light emission interval setting means that increases the time of the light emission interval as the time measurement becomes longer based on the time measurement result of the timer, and a light emission control means that causes the infrared LED to emit light intermittently based on the light emission interval. .

  The light emission interval setting means lengthens the time of the light emission interval based on a predetermined elapsed time measured by the timer, and the light emission control means intermittently emits the infrared LED based on the light emission interval. Thus, the disk-shaped recording medium insertion detection sensor detects the insertion of the disk-shaped recording medium into the disk-shaped recording medium reader.

  The disk-shaped recording medium may be a DVD or a CD, and may be in any form as long as it is a disk-shaped recording medium. The intermittent light emitting means may be anything as long as the infrared LED can emit light intermittently, and may be a microcomputer, an IC, or an electronic circuit.

As described above, according to the present invention, in the slot-in type DVD drive, the emission of the infrared LED used as a part of the sensor for monitoring the insertion of the disk is gradually changed. A power-saving setting that lasts longer and eventually stops light emission and a normal setting that continues to emit light intermittently at regular intervals are provided, allowing the power-saving setting and normal setting to be selected. When the power saving setting is selected, it is possible to reduce the standby power, which was conventionally about 1 W, by 0.1 to 0.2 W. Further, since the normal setting, which is a conventional standby method, can be selected, the convenience for the user is not impaired.
In addition, according to the invention of claim 2, since the emission interval of the infrared LED is gradually extended, the convenience of the user is impaired during standby or when only the television is used without using the DVD drive. It is possible to gradually reduce the standby power without using it.
According to the invention of claim 3, since it is not necessary to monitor the insertion of the disk while the disk is inserted in the DVD drive, the infrared LED emission during this period can be stopped to reduce power consumption. It becomes possible.
Furthermore, according to the invention of claim 4, when the infrared LED is caused to emit light intermittently, it is possible to select a setting for gradually extending the light emission interval and a setting for continuing to emit light at a constant interval. It becomes possible to cope with a user who feels that the convenience is reduced when the length of the button becomes longer.
According to the invention of claim 5, when the infrared LED is intermittently emitted, the light emission interval is gradually extended and finally the emission of the infrared LED is completely stopped. It becomes possible to reduce.
According to the sixth aspect of the present invention, since the method of emitting the infrared LED can be specified according to the lifestyle of the user, it is possible to reduce standby power without impairing the convenience for the user.

Hereinafter, embodiments of the present invention will be described in the following order.
(1) Configuration of a DVD-integrated television:
(2) Infrared LED emission timing:
(3) Power saving setting selection process:
(4) Modification:
(5) Summary:

(1) Configuration of a DVD-integrated television:
Hereinafter, a DVD integrated television according to an embodiment of the present invention will be described. FIG. 1 is a perspective view of a DVD-integrated television viewed obliquely from the front. In the figure, a television 10 includes a cabinet 12, a liquid crystal display panel 14 with a flat display surface for displaying an image on a screen facing the front, and legs 16. The cabinet 12 holds the liquid crystal display panel 14 so that its display surface is exposed to the front side, and a speaker (not shown) that outputs sound is installed inside the cabinet. The legs 16 support the cabinet 12, whereby the display surface of the liquid crystal display panel 14 is oriented substantially vertically. A rectangular hole corresponding to the front panel of the slot-in type DVD drive 60 is formed in the upper right side of the cabinet so that a disk can be inserted into the DVD drive installed inside the television 10 from the outside.

FIG. 2 is a block diagram showing a schematic configuration of the television 10 according to the embodiment of the present invention. The television 10 generally includes a television unit 30, a DVD unit 60, and a remote controller 80.
The television section 30 generally includes a tuner circuit 32 to which an antenna 33 is connected, an image data generation circuit 34, a panel drive circuit 36, a liquid crystal display panel 14, a power supply circuit 42, a television microcomputer 48, and an EEPROM 44. And an infrared light receiving circuit 46, an inverter circuit 40, a backlight 38, and a timer circuit 50. In the above configuration, the television microcomputer 48 is electrically connected to each part of the television unit 30 and a DVD microcomputer 62, an infrared sensor 68, an infrared LED 70, and the like, which will be described later, and serves as a component inside the television microcomputer 48. The CPU controls the entire television 10 in accordance with each program written in ROM, RAM, and the like, which are also components in the television microcomputer 48.

  The television microcomputer 48 includes an OSD (on-screen display) circuit. The OSD circuit is connected to the image data generation circuit 34, generates an OSD signal representing an image to be OSD-displayed on the screen of the liquid crystal display panel 14, and generates an image. Superimpose on the signal. Under the control of the CPU, the television microcomputer 48 receives an operation input from the remote control 80 when a voltage signal is input from the infrared light receiving circuit 46 and detects a corresponding key operation, and generates an OSD signal corresponding to the received operation input. . The CPU, ROM, RAM, and OSD circuit in the television microcomputer 48 are not shown.

  The tuner circuit 32 receives a television broadcast from the antenna 33 under the control of the television microcomputer 48, extracts a video signal as an intermediate frequency signal from the television broadcast signal while performing predetermined signal amplification processing and the like, and generates image data. Output to the circuit 34. The image data generation circuit 34 converts the input video signal into a digital signal according to the signal level, and performs a matrix conversion process based on the luminance signal and the color difference signal extracted from the video signal, and performs RGB conversion as image data. (Red, Green, Blue) signal is generated.

  In the panel drive circuit 36, when the RGB signal is input from the image data generation circuit 34, the RGB signal is subjected to scaling processing in accordance with the number of pixels (aspect ratio, m: n) of the liquid crystal display panel 14, Image data for one screen to be displayed on the liquid crystal display panel 14 is generated. Then, by outputting the image data generated in this way to the liquid crystal display panel 14, the liquid crystal display panel 14 is caused to display an image based on the image data.

The power supply circuit 42 is supplied with a power supply voltage (alternating current) from an external commercial power supply or the like, and supplies the supplied power supply voltage to each circuit such as the television microcomputer 48 and the inverter circuit 40. The power supply circuit 42 converts the voltage supplied to each circuit from AC to DC as necessary.
The inverter circuit 40 converts the DC voltage supplied from the power supply circuit 42 into an AC voltage, supplies the AC voltage as a drive signal to the backlight 38, and turns on the backlight 38. The backlight 38 serves as a light source that irradiates the liquid crystal display panel 14 from the back side.
Here, it is assumed that a tuner circuit 32, an image data generation circuit 34, a panel drive circuit 36, a power supply circuit 42, a television microcomputer 48, and a timer circuit 50 are mounted on the main board. .

  The DVD section generally includes a DVD microcomputer 62, a disk rotation motor 64, a loading motor 66, an infrared sensor 68, an infrared LED 70, an optical pickup 72, and a disk ejection button 74. In the above configuration, the DVD microcomputer 62 is electrically connected to each part of the DVD unit 60, and the CPU as a component inside the DVD microcomputer 62 is controlled in the DVD microcomputer 62 according to the control signal of the television microcomputer 48. The entire DVD unit 60 is controlled in accordance with each program written in a ROM, RAM, or the like that is a component of the above. The CPU, ROM, and RAM are not shown.

  FIG. 3 shows a sectional view of the slot-in type DVD drive. Near the disc insertion opening, an infrared LED 70 and an infrared sensor 68 are installed facing each other, and infrared light is emitted from the infrared LED 70 toward the infrared sensor 68. When the disc is inserted from the disc insertion slot, the infrared sensor 68 cannot receive the infrared rays from the infrared LED 70 and outputs a signal indicating that no infrared rays are received. The DVD microcomputer 62 or the television microcomputer 48 monitors a signal output from the infrared sensor 68 and detects the insertion of the disk by detecting a signal indicating that no light is received from the infrared sensor 68.

  The infrared LED 70 and the infrared sensor 68 are controlled by the DVD microcomputer 62 when the power is turned on, but the power supply to the DVD microcomputer 62 is stopped at the standby time, so the infrared LED 70 and the infrared sensor 68 are directly controlled by the television microcomputer 48. At the same time, the voltage signal output from the infrared sensor 68 is output to the television microcomputer 48.

  When the DVD microcomputer 62 or the television microcomputer 48 detects the insertion of the disk, the DVD motor 62 or the television microcomputer 48 rotates the loading motor 66 to pull the disk into the DVD drive 60. Then, the disk rotation motor 64 contacts the hole in the center of the disk to rotate the disk, and the optical pickup 72 irradiates the disk with light while moving in the radial direction or the rotation direction of the disk, and detects the reflected light. Get information written to disk. When the disk eject button 74 is pushed down, the loading motor 66 rotates in the opposite direction to that when the disk is inserted, and ejects the disk.

  The remote controller 80 has a plurality of keys for accepting operations and an infrared transmission circuit for transmitting the infrared signals to the infrared light receiving circuit, and transmits infrared signals according to the operations of the keys in a predetermined format. . For example, when an operation is performed to receive a desired channel using the remote controller 80 illustrated in FIG. 4, a corresponding infrared remote controller signal is transmitted from the infrared transmitter 85. Then, the television microcomputer 48 receives the infrared remote control signal via the infrared light receiving circuit 46 and sends the frequency data to the tuner circuit 32 so as to receive the corresponding channel. The remote controller 80 also includes a numeric keypad 83, volume control keys 82a and 82b, up / down / left / right cursor movement keys 81a, 81b, 81c and 81d, a cursor selection key 81e, and a menu key 87.

  FIG. 5 is a block diagram showing a schematic configuration of the remote controller 80. The remote controller 80 includes a control circuit 92, and operation keys 91 (three operation keys are illustrated in the figure) connected to the control circuit 92 are the numeric keypad 83, volume adjustment keys 82a and 82b, and up / down / left / right cursor movement keys. 81a, 81b, 81c, 81d, cursor selection key 81e, and menu key 87. An infrared transmission circuit 96 is connected to the control circuit 92.

  The infrared transmission circuit 96 includes an infrared light emitting element (not shown), and an infrared signal (wireless signal) corresponding to the signal output from the control circuit 92 is transmitted to the outside. The control circuit 92 includes a CPU 93, a ROM 94, a RAM 95, and the like. Then, the CPU 93 executes a predetermined program stored in the ROM 94 while using the RAM 95 as a work area, and controls the entire remote controller 80. The remote controller 80 receives an operation input from an operation key, generates control data corresponding to the input content, converts it into an infrared signal, and transmits it.

(2) Light emission timing of infrared LED In a slot-in type DVD drive, since it is necessary to detect the insertion of a disk and to pull the disk, the infrared LED 70 and the infrared sensor 68 are installed opposite to each other near the insertion slot. The LED 70 emits light intermittently. This light emission interval is controlled by a control program executed by the DVD microcomputer 62 when the power is turned on, and is controlled by a control program executed by the television microcomputer 48 during standby.

  As a control method, on / off of the current flowing in the infrared LED 70 may be controlled by providing a L / H output from the television microcomputer 48 or the DVD microcomputer 62 by providing a switching circuit using a transistor. Needless to say, on / off control of the current flowing through the infrared LED 70 may be controlled by combining a button switch with an IC or electronic circuit.

  FIG. 6 is a timing chart showing the light emission interval of the infrared LED 70. In the figure, the infrared LED 70 emits light when turned on and stops emitting light when turned off. The infrared LED 70 continues to emit light in the first pattern, emits light intermittently at a certain interval in the second pattern, and intermittent light emission in which the interval between the light emission and the next light emission is longer than the second pattern in the third pattern. In the fourth pattern, no light is emitted. The power consumption decreases in the order of the first pattern, the second pattern, the third pattern, and the fourth pattern. In the fourth pattern, the power consumption of the infrared LED 70 is zero.

  The interval of the second pattern emission may be 1 second or 2 seconds and any other interval, and various time intervals can be adopted. In addition, the light emission interval of the third pattern is longer than that of the second pattern, and the light emission interval gradually increases with the elapsed time. For example, if the light emission interval of the second pattern is 1 second, light is emitted at an interval of 2 seconds in the initial state in the third pattern, and the interval is gradually extended to 3 seconds and 4 seconds as time passes.

  Conventionally, in a DVD device including a DVD-integrated television, the infrared LED 70 always emits light as shown in the first pattern of FIG. 6 when the power is turned on, and infrared light as shown in the second pattern of FIG. 6 during standby. The LED 70 emits light intermittently, and monitors the insertion of the disk while suppressing power consumption. Further, the infrared LED 70 continued to emit light while the disc was inserted into the DVD drive and loaded. In addition to the conventional method, the configuration in which the emission of the infrared LED 70 during the insertion of the disc is stopped is added. The first pattern at power-on, the second pattern at standby, and the fourth pattern at power-on / standby when the disc is inserted. The setting for causing the infrared LED 70 to emit light at the timing is the normal setting.

  In the present invention, in addition to the normal setting, a power saving setting that suppresses light emission of the infrared LED 70 more than the normal setting is provided, and the normal setting and the power saving setting can be selected. The light emission timing of the infrared LED 70 in the power saving setting is assumed to be a first pattern when the power is turned on and when a disk is not inserted into the DVD drive, and a fourth pattern when a disk is inserted into the DVD drive.

  On the other hand, at the time of standby, first, the insertion of the disc is monitored with the second pattern. In this case, the process shifts to the fourth pattern where no light is emitted. Furthermore, while the disc is being inserted into the DVD drive, the fourth pattern in which the infrared LED 70 does not emit light regardless of whether the power is on or standby is taken. Of course, the light emission pattern of the infrared LED 70 in the power saving setting when the power is turned on may be the second pattern instead of the first pattern.

(3) Power saving setting selection process:
The normal setting and the power saving setting are selected from a menu screen for performing various television settings. When the menu key 87 of the remote controller 80 is depressed, a menu screen is displayed as shown in FIG. The menu screen is OSD-displayed with a cursor corresponding to any position such as “image quality”, “sound quality”, “channel setting”, “reservation”, “standby power priority”.

  At this time, the television microcomputer 48 obtains information representing all the operation items on the menu screen from the ROM, causes the OSD circuit to generate an OSD signal for OSD display with a cursor corresponding to any position, and generates image data. The generated OSD signal is superimposed on the video signal from the circuit 34, and the video signal on which the OSD signal is superimposed is supplied to the image data generation circuit 34. Then, an RGB signal corresponding to the video signal on which the OSD signal is superimposed is generated by the image data generation circuit 34, and the panel drive circuit 36 receives the RGB signal from the image data generation circuit 34 and then the liquid crystal display panel 14. The image data for one screen to be displayed is generated and output to the liquid crystal display panel 14 to cause the liquid crystal display panel 14 to display an image based on the image data.

  Here, since the OSD signal is superimposed on the video signal, a list of operation items is displayed on the screen of the television 10 together with the cursor. At this time, the user can select and input an operation item by depressing an operation key arranged on the remote controller 60 according to the menu screen. Therefore, the television microcomputer 48 receives an operation input from the remote controller by inputting a voltage signal from the infrared light receiving circuit and detecting a corresponding key operation. Here, when the operation of the up / down / left / right cursor movement keys 81a, 81b, 81c, 81d is detected, the cursor is moved up / down / left / right.

  When the cursor movement key 81a, 81b, 81c, 81d is used to move the cursor to “standby power priority” and the cursor selection key 81e is depressed, the television microcomputer 48 acquires information indicating the current setting state from the EEPROM 44. And “YES” or “NO” operation items for displaying whether the current setting state is “normal setting” or “power saving setting” and selecting whether or not to select “power saving setting”. Is displayed as shown in FIG.

  Hereinafter, the processing of the television microcomputer 48 when selecting the normal setting and the power saving setting will be described with reference to the flowchart of FIG. This flow is performed when the “standby power priority” operation item is selected and input on the menu screen.

  When the process is started, first, information indicating the current setting of “standby power priority” stored in the EEPROM 44 is acquired in step S100, stored in the RAM of the television microcomputer 48, and the process proceeds to step S110. The information stored in the EEPROM 44 is “0” for “normal setting” and “1” for “power saving setting”, and the same information is stored at a predetermined address.

  In step S110, as shown in FIG. 11, the current setting is displayed based on the information acquired in step S100, and the operation items “YES” and “NO” are displayed together with a cursor according to one of the operation items. Then, the process proceeds to step S130.

  In step S125, the operation input of the cursor movement key and the cursor selection key 85e is detected and accepted. When the operation of the cursor selection key 85e is accepted, the process proceeds to step S130 as the condition is satisfied. On the other hand, when the operation of the cursor movement key is detected, if the operation of the left / right cursor movement keys 81b, 81d is detected, the cursor is moved to the left / right, and nothing is performed when the operation of the up / down cursor movement keys 81a, 81c is detected. Then, step S125 is repeated as the condition is not satisfied.

  When the condition is satisfied in step S125 and the process proceeds to step S130, it is determined whether the operation item being selected by the cursor is “YES” or “NO” when the cursor selection key 85e is pressed down. If “YES” is selected, the condition is satisfied and the process proceeds to step S140. If “NO” is selected, the condition is not satisfied and the process proceeds to step S150.

  In step S140, “1” indicating “power saving setting” is stored in a predetermined address of the EEPROM 44, and the light emission timing of the infrared LED 70 of the control program being executed in the RAM of the television microcomputer 48 is performed at the timing of “power saving setting”. The flow is terminated after the change.

On the other hand, when the routine proceeds to step 150, “0” indicating “normal setting” is stored in a predetermined address of the EEPROM 44, and the light emission timing of the infrared LED 70 of the control program being executed in the RAM of the television microcomputer 48 is “normal setting”. The flow is terminated after changing to the timing.
When step S140 is executed and the flow is finished, a control signal is output to the infrared LED according to the flowchart of FIG. 9, while when step S150 is executed and the flow is finished, the television microcomputer 48 is turned on when the television 10 is powered on. The infrared LED 70 in FIG. 6 outputs a control signal for causing the infrared LED 70 to emit light as shown in the first pattern of FIG. 6, and the infrared LED 70 is always energized to emit light constantly. On the other hand, at the time of standby, a control signal for causing the infrared LED 70 to emit light is output at regular intervals as shown in the second pattern of FIG. 6, and the infrared LED 70 is intermittently energized to emit light intermittently. In this case, the infrared LED 70 continues to emit light according to the second pattern throughout the standby time regardless of the passage of time.

As described above, the control program executed by the television microcomputer 48 that controls the light emission timing of the infrared LED 70 in the second pattern causes the infrared LED to emit light at a constant light emission interval regardless of the timing result of the timer. The intermittent light emitting means is configured.
Further, the television microcomputer 48 that performs the processes of steps S100 to S130 constitutes a light emission method selection means for switching between the light emission control means and the second light emission control means.

The processing of the television microcomputer 48 at the time of executing power saving setting will be described with reference to the flowchart of FIG. This flow is repeatedly executed while the power saving setting is selected except when the power is off.
When the process is started, the television microcomputer 48 determines whether or not it is in a standby state in step S195. In the standby state, the condition is satisfied and the process proceeds to step S200. On the other hand, when it is not in the standby state, that is, when the power is on, the process proceeds to step S196, where a control signal is output to the DVD microcomputer 62, steady light emission of the infrared LED 70 is started, and the flow is finished.

  When the condition is satisfied in step S195 and the process proceeds to step S200, the light emission interval time is initialized and stored in the RAM in step S200, and the process proceeds to step S210. The initial value of the light emission interval time in the flow is 2 seconds. In step S210, control signal output to the infrared LED 70 is started according to the emission interval time stored in the RAM, the infrared LED 70 is caused to emit light intermittently, and the process proceeds to step S211.

  In step S211, it is determined whether or not the disc has been inserted into the DVD drive 60 by monitoring the signal from the infrared sensor 68. When a disk is inserted between the infrared LED 70 and the infrared sensor 68 and the infrared sensor 68 outputs a signal indicating that infrared rays cannot be received from the infrared LED 68, the television microcomputer 48 detects the signal. In this case, the condition is satisfied, and the process proceeds to step S212. If the disc is not inserted in the DVD drive 60, the television microcomputer 48 does not detect the signal from the infrared sensor 68, so the condition is not satisfied and the process proceeds to step S220.

  In step S212, the power of the television main body 20 is turned on, and the emission of the infrared LED 70 is stopped, and the process proceeds to step S213. In step S213, a signal output when the DVD microcomputer 62 detects the ejection of the disc from the DVD drive 60 is monitored to determine whether or not the disc is ejected from the DVD drive 60. When the disk eject button 74 is depressed, the loading motor 66 ejects the disk and outputs a signal indicating the disk ejection to the DVD microcomputer 62. The DVD microcomputer 62 that has detected the signal outputs a signal indicating that the disk has been ejected to the television microcomputer 48, and the television microcomputer 48 detects the ejection of the disk by detecting this signal. In this case, the condition is satisfied and the flow ends. On the other hand, if the same signal is not detected, the condition is not satisfied, and step S213 is repeated.

  If the condition is not satisfied in step S211 and the process proceeds to step S220, it is determined whether or not the elapsed time from the start of light emission in the current light emission interval has exceeded a predetermined time. If the predetermined time is exceeded, the condition is satisfied and the process proceeds to step S230. On the other hand, if the predetermined time has not been exceeded, the condition is not satisfied, and step S220 is repeated. Any time can be adopted as the predetermined time.

  In step S230, the light emission interval time stored in the RAM is acquired, incremented and stored again in the RAM, and the process proceeds to step S240. In step S240, it is determined whether a predetermined time has elapsed since step S200 was executed in the flow. If the predetermined time has elapsed, the condition is satisfied and the process proceeds to step S250. On the other hand, if it is determined that the predetermined time has not elapsed, the condition is not satisfied, the process returns to step S210, and the processes of steps S210 to S240 are repeated. The predetermined time only needs to be longer than the predetermined time in step S220, and an arbitrary time can be adopted.

  When the condition is satisfied in step S240 and the process proceeds to step S250, the emission of the infrared LED 70 is stopped and the process proceeds to step S260. In step S260, it is determined whether or not the power of the television body 20 is turned on. When the power is turned on, the television microcomputer 48 detects a control signal indicating that. In this case, the flow is terminated as the condition is satisfied. On the other hand, the condition is not satisfied while the power is not turned on and in the standby state, and step S260 is repeated.

As described above, the television microcomputer 48 that performs the processes of steps S200 and S220 to S240 in FIG. 7 constitutes a light emission interval setting unit that lengthens the time of the light emission interval as the time measurement becomes longer based on the time measurement result of the timer.
Further, the television microcomputer 48 that performs the process of step S200 of FIG. 7 constitutes a light emission control means for causing the infrared LED to emit light intermittently based on the set light emission interval time.

The processing of the television microcomputer 48 at the time of normal setting execution will be described with reference to the flowchart of FIG. This flow is repeatedly executed while the normal setting is selected.
When the process is started, the television microcomputer 48 first determines whether or not it is in a standby state in step S300. In the standby state, the condition is satisfied and the process proceeds to step S310. On the other hand, when it is not in the standby state, that is, when the power is on, the process proceeds to step S350, a control signal is output to the DVD microcomputer 62, steady light emission of the infrared LED 70 is started, and the flow is finished.

In step S310, as shown in the second pattern of FIG. 6, control signal output to the infrared LED is started at regular intervals, the infrared LED 70 is caused to emit light intermittently, and the process proceeds to step S320.
In step S320, the signal of the infrared sensor 68 is monitored to determine whether or not the disc has been inserted into the DVD drive 60. When a disk is inserted between the infrared LED 70 and the infrared sensor 68 and the infrared sensor 68 outputs a signal indicating that infrared rays cannot be received from the infrared LED 68, the television microcomputer 48 detects the signal. In this case, the condition is satisfied, and the process proceeds to step S330. If the disc is not inserted in the DVD drive 60, the television microcomputer 48 does not detect the signal from the infrared sensor 68, so the condition is not satisfied and step S320 is repeated.

In step S330, the power of the television main body 20 is turned on, and the emission of the infrared LED 70 is stopped, and the process proceeds to step S340.
In step S340, a signal output when the DVD microcomputer 62 detects the ejection of the disc from the DVD drive 60 is monitored to determine whether or not the disc is ejected from the DVD drive 60. When the disk eject button 74 is depressed, the loading motor 66 ejects the disk and outputs a signal indicating the disk ejection to the DVD microcomputer 62. The DVD microcomputer 62 that has detected the signal outputs a signal indicating that the disk has been ejected to the television microcomputer 48, and the television microcomputer 48 detects the ejection of the disk by detecting this signal. In this case, the condition is satisfied and the flow ends. On the other hand, if the same signal is not detected, the condition is not satisfied, and step S340 is repeated.

Next, the operation of the present embodiment configured as described above will be described.
For those who rarely watch DVDs or who are interested in saving energy and want to reduce standby power as much as possible, select “Energy saving” from the “Energy saving” setting on the menu screen. Reductions can be made. When the menu screen is displayed, the user operates the cursor movement keys 81a, 81b, 81c, 81d to set the cursor to “standby power priority” and depresses the cursor selection key 81e. Then, the television microcomputer 48 acquires information indicating the current setting state from the EEPROM 44 (step S100), and displays whether the current setting state is “normal setting” or “power saving setting”. Operation items “YES” and “NO” for selecting whether or not “power saving setting” is selected are displayed as shown in FIG. 11 (step S110).

  When the user depresses the cursor movement keys 81 a, 81 b, 81 c, 81 d to move the cursor to “YES” and depresses the cursor selection key 81 e, the television microcomputer 48 receives the cursor movement key from the infrared light receiving circuit 46. Then, by detecting the input of the voltage signal for the key operation of the cursor selection key, it is determined whether either the cursor movement key or the cursor selection key has been pressed (step S125). When the user depresses either the cursor movement key or the cursor selection key on the remote controller 80, the infrared transmission unit 85 transmits an infrared signal corresponding to the key in a predetermined format. Then, the television microcomputer 48 receives the infrared signal from the remote controller via the infrared light receiving circuit 46 and detects that the infrared signal includes information corresponding to the operation of the key (hereinafter, cursor key information). Then, information corresponding to the operation item “YES” in which the cursor was selected at the time of the cursor selection key pressing operation is acquired.

  If the cursor key information received at this time is information on the cursor movement key, the cursor is moved in the corresponding direction, and step S125 is repeated because the condition is not satisfied. On the other hand, if the received cursor key information is for the cursor selection key, the condition is satisfied and the process proceeds to step S130. If neither the cursor movement key nor the cursor selection key of the remote controller 60 is depressed, the television microcomputer 48 does not detect the operation of the cursor key, so the condition is not satisfied and the determination process of step S125 is repeated. Wait for user input.

  In step S130, when the cursor selection key is pressed down in step S125, the television microcomputer 48 determines whether the operation item being selected by the cursor is “YES” or “NO”. Since the user has selected “YES”, the process proceeds to step S140 where the television microcomputer 48 stores “1” representing “power saving setting” at a predetermined address of the EEPROM 44 and is being executed in the RAM of the television microcomputer 48. Causes the control program to execute "Power Save Setting".

  Then, when the television 10 is powered on, the control program executed by the television microcomputer 48 starts outputting a control signal to the infrared LED 70 according to the light emission interval time stored in the RAM. Steady light emission is performed according to the pattern (step S196).

  On the other hand, during standby, intermittent light emission is started as in the second pattern of FIG. 6 (steps S200 to S210). Each time a predetermined time elapses, the control program executed by the television microcomputer 48 increments the light emission interval time stored in the RAM, so that the light emission interval gradually increases (steps S220 to S240). When the total time from the start of light emission has elapsed for a predetermined time, the output of the control signal from the television microcomputer 48 is stopped, and the light emission of the infrared LED 70 is stopped (steps S240 to S260).

  Further, when the insertion of the disk is detected while the infrared LED 70 is emitting light during standby (step S211), the television microcomputer 48 turns on the power of the television body and stops outputting the control signal to the infrared LED 70. The infrared LED 70 stops emitting light (step S212).

  On the other hand, when the user gives priority to convenience, the user can select “normal setting” for monitoring the insertion of the disc as usual. In this case, the same operation as that for selecting “power saving setting” may be performed up to step S120. Then, the user depresses the cursor movement keys 81a, 81b, 81c, 81d, sets the cursor to “NO”, and depresses the cursor selection key 81e (step S125). Then, the television microcomputer 48 acquires information corresponding to the operation item “NO” in which the cursor was being selected when the cursor selection key was pressed down. The processing of the television microcomputer 48 when the cursor movement key and other keys are operated is the same as “power saving setting”.

  In step S130, when the cursor selection key is pressed down in step S125, the television microcomputer 48 determines whether the operation item being selected by the cursor is “YES” or “NO”. Since the user has selected “NO”, the process proceeds to step S150 where the television microcomputer 48 stores “0” representing “normal setting” at a predetermined address in the EEPROM 44 and is being executed in the RAM of the television microcomputer 48. Cause the control program to execute “normal setting”.

  Then, when the television 10 is turned on, the infrared LED 70 emits light regularly according to the first pattern of FIG. 6 (step S350). Further, during standby, intermittent light emission is started as in the second pattern of FIG. 6 (step S310). When the insertion of a disc is detected during standby (step S320), the television is turned on, the control signal output to the infrared LED 70 is stopped, and the infrared LED 70 stops emitting light (step S340).

(4) Modification:
Alternatively, the start time and end time of the power saving setting may be specified, and the normal setting and the power saving setting may be changed and applied. At this time, the normal setting is executed before the start time, the power saving setting is executed when the start time is reached, and the power saving setting is ended and the normal setting is executed when the end time is reached.

  If the television is used at home and the user does not use it for work during the daytime on weekdays, the television is not used during that time. Therefore, power saving is set from 9:00 am to 5:00 pm on weekdays, and normal settings are set from 5:00 pm to 0:00 am and from 6:00 am to 9:00 am when the user is likely to go home and watch the DVD. Power saving is set from 0:00 am to 6:00 am. Of course, not only the time but also the start time and end time including the day of the week and the date may be used.

With reference to the flowchart of FIG. 12, the process of the microcomputer when the start time and the end time are designated and the power saving setting is executed will be described. This flow is executed when the television is activated.
When the process is started, the television microcomputer 48 acquires information indicating the start time and the end time stored in the EEPROM 44 in step S400, and proceeds to step S410. In step S410, the infrared LED 70 starts to emit light with the normal setting.

  In step S420, the start time acquired in step S400 is compared with the current time acquired from the timer circuit 50 to determine whether the start time has elapsed. If the current time has passed the start time, the condition is satisfied and the process proceeds to step S430. On the other hand, if the current time has not passed the start time, it is determined that the condition is not satisfied, and the determination in step S420 is repeated.

In step S430, the infrared LED 70 starts to emit light with the power saving setting.
In step S440, the end time acquired in step S400 is compared with the current time acquired from the timer circuit 50 to determine whether or not the end time has elapsed. If the current time has passed the end time, the condition is satisfied, the process proceeds to step S410, and the processes of steps S410 to S440 are repeated. On the other hand, if the current time has not passed the end time, the determination in step S440 is repeated because the condition is not satisfied.

As described above, the EEPROM 44 storing the information indicating the start time and the end time constitutes a storage means for storing the start date and time for starting the light emission control means and the end date and time for ending.
12 acquires the start date and time and the end date and time from the storage medium, and the light emission control when the date and time of the timer means becomes the start date and time. And a reservation execution means for stopping the light emission control means when the end date / time is reached.

(5) Summary:
That is, in the present invention, in the television 10 provided with the slot-in type DVD drive 60, “normal setting” and “power saving setting” can be selected from the menu screen. In the power saving setting, when the power is turned on, the infrared LED 70 that emits light is constantly emitted to monitor the insertion of the disc, and during standby, the emission interval of the infrared LED 70 is gradually increased, and the light emission is stopped after a predetermined time has elapsed. On the other hand, in the normal setting, the infrared LED 70 always emits light when the power is turned on as usual, and intermittently emits light at a constant time interval during standby.

  As described above, the invention according to claim 2 corresponding to the present embodiment includes a power supply circuit that can be supplied to each circuit by receiving a power supply voltage from an external commercial power supply or the like, and a slot-in type disk-like recording A medium reading device; a disk-shaped recording medium insertion detection sensor comprising an infrared LED and an infrared sensor for detecting insertion of a disk-shaped recording medium into the disk-shaped recording medium reading device; a timer for measuring a predetermined elapsed time; A configuration is provided that includes a light emission interval setting means that increases the time of the light emission interval as the time measurement becomes longer based on the time measurement result of the timer, and a light emission control means that causes the infrared LED to emit light intermittently based on the light emission interval. .

  That is, the light emission interval setting means lengthens the light emission interval as the time elapses based on a predetermined elapsed time measured by the timer, and the light emission control means intermittently turns the infrared LED on the basis of the light emission interval. The disc-shaped recording medium insertion detection sensor detects the insertion of the disc-shaped recording medium into the disc-shaped recording medium reader.

The disk-shaped recording medium may be a DVD or a CD, and may be in any form as long as it is a disk-shaped recording medium. The intermittent light emitting means may be anything as long as the infrared LED can emit light intermittently, and may be a microcomputer, an IC, or an electronic circuit.
In the invention according to claim 2 configured as described above, in order to gradually extend the light emission interval of the infrared LED, the user can be used during standby or when only the television is used without using the DVD drive. The standby power can be gradually reduced without impairing the convenience of the system.

According to a third aspect of the present invention, in the television set according to the second aspect, the light emission control means is configured to stop the light emission of the infrared LED while the disk-shaped recording medium reader is loading the disk-shaped recording medium. .
In the invention according to claim 3 configured as described above, since it is not necessary to monitor the insertion of the disc while the disc is inserted into the DVD drive, by stopping the emission of the infrared LED during this period, It becomes possible to reduce power consumption.

And in Claim 4, in the television according to Claim 2 or 3, the television is a second light emission control means for causing the infrared LED to emit light at a constant light emission interval regardless of the timing result of the timer. The light emission control means and the second light emission control means are switched to select a light emission method selection means.
As the second light emission control means, it is sufficient if the infrared LED can be made to emit light at a constant interval, and various configurations such as a device in which a transistor is controlled by a microcomputer and a combination of a switch and an IC or an electronic circuit can be adopted It is. The light emission method selection means may be any one as long as the light emission control means and the second light emission control means can be switched and selected. Various configurations such as provided electronic circuits and ICs can be employed.
In the invention according to claim 4 configured as described above, when the infrared LED emits light intermittently, it is possible to select a setting for gradually extending the light emission interval and a setting for continuing to emit light at a constant interval. Therefore, it is possible to cope with a user who feels that convenience is lowered when the light emission interval is increased.

Further, according to claim 5, in the television set according to any one of claims 2 to 4, the light emission control means is configured to stop light emission of the infrared LED when the light emission interval is equal to or greater than a predetermined interval. .
As the predetermined time in the fifth aspect, various times such as 5 minutes, 10 minutes, or 1 hour can be adopted.
In the invention according to claim 5 configured as described above, since the emission of the infrared LED is completely stopped, the standby power can be greatly reduced.

According to a sixth aspect of the present invention, the timer holds time, and the television stores storage means for storing a start date and time and an end date and time for starting the light emission control means, and the start date and time and the In addition to acquiring an end date and time, the apparatus includes a reservation execution unit that executes the light emission control unit when the date and time of the timer unit reaches the start date and time, and stops the light emission control unit when the end date and time is reached.
The start date and time and the end date and time may be any as long as they can be specified with regularity within a certain period of time. It may be specified by the day of the week, or may be specified by the month and day of the year, and various ways of specification are possible.
In the invention according to claim 6 configured as described above, since the method of emitting the infrared LED can be specified according to the lifestyle of the user, standby power can be reduced without impairing the convenience of the user. Is possible.

  Based on the above configuration, the invention of claim 1 is directed to a liquid crystal display panel with a flat display surface for displaying video on the screen, a speaker for outputting audio, a television broadcast, and video. Are displayed on the liquid crystal display panel and sound is output by the speaker, a resin cabinet that houses the liquid crystal display panel, the speaker, and the main substrate, an infrared sensor, and an infrared LED are opposed to each other. And a slot-in DVD drive that detects the insertion of the disk when the disk is inserted between the infrared sensor and the infrared LED and pulls the disk into the inside, and a timer that measures a predetermined elapsed time And a DVD-integrated television comprising a microcomputer for controlling the emission timing of the infrared LED, the microcomputer has a plurality of It is possible to select and execute a power saving setting combined with light timing and a normal setting. In the power saving setting, when the television is turned on, the infrared LED is always turned on, and when the television is in a standby state. First, the infrared LED emits light intermittently at a certain time interval, and then the infrared LED emits light intermittently by gradually increasing the emission interval of the infrared LED, and then the infrared LED stops emitting light after a predetermined time has elapsed. The infrared LED is turned off while the disc is inserted in the DVD drive. In the normal setting, the infrared LED is always turned on when the television is turned on. When in standby, the infrared LED is intermittently emitted at a predetermined time interval, and the disc is While being inserted into the drive it is constituted to stop the emission of the infrared LED.

Needless to say, the present invention is not limited to the above embodiments. It goes without saying for those skilled in the art,
・ Applying mutually interchangeable members and configurations disclosed in the above embodiments by appropriately changing the combination thereof.− Although not disclosed in the above embodiments, it is a publicly known technique and the above embodiments. The members and configurations that can be mutually replaced with the members and configurations disclosed in the above are appropriately replaced, and the combination is changed and applied. It is an embodiment of the present invention that a person skilled in the art can appropriately replace the members and configurations that can be assumed as substitutes for the members and configurations disclosed in the above-described embodiments, and change the combinations and apply them. It is disclosed as.

1 is an external view of a slot-in type DVD drive integrated liquid crystal television. FIG. It is a schematic block diagram of a slot-in type DVD drive integrated liquid crystal television. It is sectional drawing of a slot-in system DVD drive. It is a figure which shows an example of the remote control of this invention. It is a block diagram which shows schematic structure of the remote control of this invention. It is a timing chart which shows the light emission timing of infrared LED. It is a flowchart which shows the process of the television microcomputer at the time of power saving setting execution. It is a flowchart which shows the process of the television microcomputer at the time of normal setting execution. It is a flowchart which shows the process of the microcomputer at the time of selecting a power-saving setting and a normal setting. It is an example of a menu screen. It is an example of the screen which sets standby power priority. It is a flowchart which shows the process of the television microcomputer at the time of normal setting execution.

Explanation of symbols

DESCRIPTION OF SYMBOLS 10 ... Television 12 ... Cabinet 14 ... Liquid crystal display panel 16 ... Leg part 20 ... Television main body 30 ... Television part 32 ... Tuner circuit 33 ... Tuner 34 ... Image data generation circuit 36 ... Panel drive circuit 38 ... Backlight 40 ... Inverter circuit 42 ... Power supply circuit 44 ... EEPROM
46 ... Infrared light receiving circuit 48 ... Television microcomputer 60 ... DVD drive (DVD part)
62 ... DVD microcomputer 64 ... disk rotation motor 66 ... loading motor 68 ... infrared sensor 70 ... infrared LED
72 ... Optical pickup 80 ... Remote control

Claims (6)

A liquid crystal display panel with a flat display surface for displaying images on the screen facing the front,
A speaker that outputs sound;
A main board for receiving television broadcast and displaying video on the liquid crystal display panel and outputting sound through the speaker;
A resin cabinet that houses the liquid crystal display panel, the speaker, and the main substrate;
An infrared sensor and an infrared LED are installed facing each other, and when a disk is inserted between the infrared sensor and the infrared LED, a slot-in DVD drive that detects the insertion of the disk and pulls the disk into the interior;
A timer for measuring a predetermined elapsed time;
In a DVD-integrated television comprising a microcomputer that controls the emission timing of the infrared LED,
The above microcomputer
It is possible to select and execute the power saving setting and the normal setting that combine multiple flash timings.
In the power saving setting, the infrared LED always emits light when the television is turned on, and the infrared LED emits light intermittently at a certain time interval when the television is on standby. Gradually increase the light emission interval of the infrared LED to intermittently emit light, and after a predetermined time has elapsed, stop the emission of the infrared LED, and while the disc is inserted in the DVD drive, the infrared LED emits light. Stop,
In the normal setting, the infrared LED always emits light when the television is turned on, and the infrared LED emits light intermittently at a predetermined time interval when the television is on standby. A DVD-integrated television, wherein the infrared LED stops emitting light while being inserted into the DVD drive. A power supply circuit that can be supplied to each circuit by receiving a supply voltage from an external commercial power supply,
A slot-in type disk-shaped recording medium reader;
A disk-shaped recording medium insertion detection sensor comprising an infrared LED and an infrared sensor for detecting insertion of the disk-shaped recording medium into the disk-shaped recording medium reader;
A timer for measuring a predetermined elapsed time;
A light emission interval setting means for increasing the time of the light emission interval as the time measurement becomes longer based on the time measurement result of the timer;
A television comprising: light emission control means for causing the infrared LED to emit light intermittently based on the light emission interval.   3. The television according to claim 2, wherein the light emission control means stops the light emission of the infrared LED while the disk-shaped recording medium reader is loading the disk-shaped recording medium. The above television is
A second light emission control means for causing the infrared LED to emit light at a constant light emission interval irrespective of the timing result of the timer;
The television according to claim 2 or 3, further comprising: a light emission method selection means for switching between and selecting the light emission control means and the second light emission control means.   The television according to any one of claims 2 to 4, wherein the light emission control means stops light emission of the infrared LED when the light emission interval is equal to or greater than a predetermined interval. The timer keeps the time,
The above television is
Storage means for storing a start date and time and an end date and time for starting the light emission control means;
The start date and time and the end date and time are acquired from the storage medium, and the light emission control means is executed when the date and time of the timer means reaches the start date and time, and the reservation execution is performed to stop the light emission control means when the end date and time is reached. The television according to claim 2, further comprising: means.

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