JPH0683096B2 - Electronics - Google Patents

Description

The present invention relates to an electronic device suitable for application to, for example, a television receiver that digitally processes most of signal processing.

[Conventional technology]

A derevision receiver that digitally processes most of the signal processing is configured, for example, as shown in FIG.

In the figure, (1) is a tuner circuit including a tuner to a video detection circuit, and a composite video signal S _V is obtained from this tuner circuit (1). This video signal
After S _V is converted to a digital signal by the A / D converter (2),
The digital luminance signal Y _D is obtained by being supplied to the peaking filter (4) via the comb filter (3). The brightness signal Y _D is supplied to the signal processing circuit (5Y), processed for contrast and the like, and then supplied to the matrix circuit (7) which is converted into the analog brightness signal Y by the D / A converter (6Y). To be done.

Further, the output of the comb filter (3) is supplied to the bandpass filter (8) to obtain a digital carrier color signal C _D. This carrier color signal C _D is supplied to the signal processing circuit (5C), and after being adjusted for ACC, hue, color saturation, etc., is supplied to the color demodulation circuit (9), and the digital red color difference signal R _D − Y _D and a blue color difference signal B _D −Y _D are obtained. Then, these color difference signals R _D
-Y _D and B _D -Y _D are converted into analog color difference signals RY and BY by D / A converters (6R) and (6B), respectively, and supplied to the matrix circuit (7).

From the matrix circuit (7), the three primary color signals R of red, green and blue,
G and B are obtained, and an amplifier (11) for white balance and brightness adjustment is provided via adders (10R), (10G), and (10B), respectively.
R), (11G), and (11B), and the outputs of these amplifiers (11R), (11G), and (11B) are colored via drive amplifiers (12R), (12G), and (12B), respectively. It is supplied to the picture tube (13).

Further, the composite video signal S _V from the tuner circuit (1) is supplied to a sync separation circuit (14) to obtain a sync pulse, and this sync pulse is supplied to a pulse processing circuit (15H) to have a predetermined pulse width and A phase horizontal synchronizing pulse P _H is supplied to the horizontal output circuit (16H). Then, a horizontal deflection signal is supplied from the horizontal output circuit (16H) to the horizontal deflection coil (17H). Further, the sync pulse obtained from the sync separation circuit (14) is supplied to the integration circuit (18) to obtain a vertical sync pulse, and this pulse is supplied to the pulse processing circuit (15V) to obtain a vertical pulse having a predetermined pulse width and phase. The sync pulse P _V is supplied to the vertical output circuit (16 V). Then, a vertical deflection signal is supplied from the vertical output circuit (16V) to the vertical deflection coil (17V).

Further, (19) is a tuning microcomputer (microcomputer), and (20) is a controlling microcomputer. Microcomputer (1
A rewritable nonvolatile memory (21) is connected to 9), and a rewritable nonvolatile memory (23) is connected to the microcomputer (20) via a bus (22).
A key panel (24) is connected to. The key panel (24) is provided with a plurality of keys for the user to select a channel or adjust the contrast, brightness, hue, color saturation and the like. The memory (21) also stores channel tuning data preset corresponding to the numeric keypad on the panel (24) and data adjusted by the user such as contrast, brightness, hue and color saturation even when the power is turned off. It is for keeping. However, the data such as contrast, brightness, hue, and color saturation are offset values with respect to the standard value (center value), and the standard value is stored in the memory (23). The memory (23) stores data that does not require adjustment by the user but needs adjustment by the manufacturer, such as data of white balance, horizontal deflection, and vertical deflection. The data stored in the memory (23) is adjusted, for example, at the time of shipment by the adjustment commander (26) connected to the microcomputer (20).

With the above configuration, when the power is turned on, the microcomputer (19)
The channel selection data of the channel that was selected before the power was turned off is read from the memory (21), this data is supplied to the tuner circuit (1), and the channel was selected before the power was turned off. The channel is selected. Also, microcomputer (19)
The brightness offset value data is read from the memory (21) by the and supplied to the microcomputer (20) via the interface (29), and the brightness (20) and brightness and white balance data are also read from the memory (23) by the microcomputer (20). Is read and these data are supplied to the amplifier control circuit (11) via the bus (22) and the interface (27),
The control circuit (11) controls the amplifiers (11R) to (11B) and adjusts the three primary color signals RB so that the brightness and the white balance are as set. In addition, the deflection data is read from the memory (23) by the microcomputer (20) and is supplied to the pulse processing circuits (15H) and (15V) via the bus (22) and the interface (28) for horizontal and vertical. The deflection waveform is adjusted to be as set. In addition, offset value data such as contrast, hue, and color saturation are read from the memory (21) by the microcomputer (19) and supplied to the microcomputer (20) through the interface (29). ) Reads standard value data such as contrast, hue, and color saturation from the memory (23), adds the offset value data and the standard value data, and adds the added data to the interface ( 27) and is supplied to the signal processing circuits (5Y) and (5C), so that the signals Y _D and
C _D is adjusted. Therefore, the channel selected when the power is turned off is displayed in the same state on the color picture tube (13).

The data set in the interfaces (27) and (28) is latched in the registers (not shown) provided in the interfaces (27) and (28) until new data is supplied next. ing.

Next, when the user operates, for example, a numeric keypad on the key panel (24), the microcomputer (19) reads out the tuning data of the channel preset corresponding to the operated key from the memory (21). This data is supplied to the tuner circuit (1) and the channel designated by the ten keys of the key panel (24) is brought into the selected state. The tuning data of the channel selected at this time is stored in the memory (2
It is written in 1) and is prepared when the power is turned off.

When, for example, a hue key on the key panel (24) is operated, the hue offset value data in the memory (21) is updated each time the key is operated, and the data is also transmitted via the interface (29). Microcomputer (20)
And added to the standard value data from the memory (23), and the added data is added to the interface (27).
Is supplied to the signal processing circuit (5C) via the to adjust the hue.

Further, in FIG. 3, (30) is a display circuit, which is a circuit for displaying a channel selected on the screen of the color picture tube (13) at the time of channel selection and a volume at the time of sound adjustment. Is. This display circuit (30) has a microcomputer (19)
Display data, that is, channel data, volume data, and the like are supplied from the microcomputer (20). Then, from the display circuit (30), red, green, and blue three primary color signals R _I , G _I , and B _I corresponding to the display contents are obtained, and the adders (10R) and (10
G), (10B), and the channel, volume, etc. are displayed over the image on the screen of the color picture tube (13).

Note that, in FIG. 3, the portion surrounded by the alternate long and short dash line is actually formed by one IC.

[Problems to be solved by the invention]

In the television receiver shown in FIG. 3, for example, an adjustment commander (26) is connected to the microcomputer (20) at the time of shipment to adjust the setting data of each circuit section. In this case, if the operation mode is changed from the actual use mode, that is, the user mode to the above-mentioned adjustment mode, by operating some switch, the switch state is erroneously operated or the software always determines the switch position (position). Since it has to be monitored, there is a problem that the restrictions on the program are large.

Therefore, the present invention is intended to prevent such a problem.

[Means for solving problems]

In order to solve the above-mentioned problems, the present invention is provided with control means, and the control means determines the adjustment mode when the power is turned on and automatically switches to the adjustment mode. For example, a microcomputer (20) is used as the control means, and the adjustment mode is determined by whether or not the adjustment commander (26) is connected to the microcomputer (20) when the power is turned on.

〔Example〕

An embodiment of the present invention will be described below with reference to FIG. In FIG. 1, parts corresponding to those in FIG. 3 are designated by the same reference numerals, and detailed description thereof will be omitted.

In the figure, (26) is a commander for adjustment, which includes a key panel (26A) and a microcomputer (26A) for generating remote control signals.
B) and. In this case, by operating a predetermined key on the key panel (26A), a control signal corresponding to the operation key is output as serial data from the microcomputer (26B).

The power supply terminal and the ground terminal of the microcomputer (26B) are connected to the terminals B and E of the connector plug (32) through the conductors (31B) and (31E) that form the cord (31), respectively. The control signal output terminal of the microcomputer (26B) is connected to the terminal IR of the plug (32) through the conductor (31I). The terminal SR of the plug (32) is connected to the terminal E.

Further, (33) is a connector jack to which the plug (32) is connected, and the terminal B of this jack (33) has a power source + B.
Is supplied, and the terminal E is grounded. The signals obtained at the terminals IR and SR of the jack (33) are supplied to the microcomputer (20), respectively. Terminals B and I of the above-mentioned plug (32)
R, SR and E are connected to terminals B, IR, SR and E of this jack (33), respectively.

The microcomputer (20) operates according to the flowchart shown in FIG.

When the power is turned on, it is determined whether the adjustment mode is set.
In this case, when the signal supplied from the terminal SR of the jack (33) is at a low level (ground level), the adjustment mode is determined, and otherwise, the user mode used by the user is determined. That is, when the plug (32) of the commander (26) is connected to the jack (33), the terminal SR of the jack (33) is grounded, so that the adjustment mode is determined.

When it is determined that the adjustment mode is set, the adjustment mode flag is turned on, and the average initial setting data of each part of the circuit written in advance in a partial area of the ROM (not shown) of the microcomputer (20) is read. , Based on this, each part of the circuit is set. Then, when the control signal generated from the microcomputer (26B) of the commander (26) is input through the terminal IR of the jack (33), the setting data for each set is adjusted and adjusted based on this. It is written in the setting data memory (23) of each part of the circuit. And the commander (2
By pressing the adjustment end key of 6), for example, "EXIT", the adjustment mode flag is turned off and the adjustment mode is released.

On the other hand, in the user mode, the initial setting data written in the adjusting mode is read from the memory (23), each circuit portion is set based on the initial setting data, and the user mode processing is performed thereafter.

This example is configured as described above. By connecting the plug (32) of the commander (26) to the jack (33), the microcomputer (20) will determine the adjustment mode when the power is turned on, and the adjustment mode will automatically be set. Can be switched.

As described above, according to this example, the adjustment mode is determined when the power is turned on, and the adjustment mode is automatically switched.
The erroneous operation is reduced as compared with the case where the adjustment mode is switched by a separate switch. Also. Since the determination is made at the beginning of the processing program, that is, when the power is turned on, efficient software can be created without disturbing the flow of the main program (user mode program).

Although the above-described embodiment applies the present invention to a television receiver, it goes without saying that it can be applied to other electronic devices as well.

〔The invention's effect〕

According to the present invention described above, the adjustment mode is determined when the power is turned on, and the adjustment mode is automatically switched. Therefore, there is less erroneous operation compared to the case where the adjustment mode is switched by a separate switch, and the start of the processing program Since it is determined by, you can create efficient software.

[Brief description of drawings]

FIG. 1 is a block diagram showing an embodiment of the present invention, FIG. 2 is a flow chart for explaining the operation thereof, and FIG. 3 is a block diagram showing an example of a television receiver. (20) is a control microcomputer, (23) is a non-volatile memory,
(26) is a commander for adjustment, (32) is a connector plug,
(33) is a connector jack.

Claims (1)

[Claims] 1. An electronic device, comprising a control microcomputer inside, configured to give setting data to respective internal circuit parts under the control of the microcomputer to control the internal circuit parts. A terminal to which an adjustment commander for adjusting data is connected, a means for detecting whether or not the terminal is connected to the adjustment commander when the power is turned on, and automatically when the adjustment commander is connected. An electronic device comprising: a mode switching unit that switches to an adjustment mode and switches to a user mode when the adjustment commander is not connected.