JP2728576B2 - Display monitor control circuit - Google Patents

Description

DETAILED DESCRIPTION OF THE INVENTION

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a display monitor control circuit for providing adjustment data according to a horizontal frequency and a vertical frequency of an input signal to a display monitor.

[0002]

2. Description of the Related Art FIG. 3 shows, for example, Mitsubishi Electric Technical Report Vol. 63, No. 6 (June 1989), p. 68-P. FIG. 72 is a block diagram showing a control circuit of the conventional display monitor shown at 72. In the figure, 5 is an electrically erasable programmable ROM (E ² PROM) storing adjustment data, 6
Is a change data input unit having a switch for inputting change data, 7 is a DA converter (DAC), 10 is R
It is a microcomputer having a built-in OM, RAM, counter, timer, and input / output port (I / O port). The ROM stores a control program.

Next, the operation will be described with reference to the flowchart of FIG. The E ² PRPM5, as shown in FIG. 5, the horizontal synchronizing frequency (f _H) that is expected as an attribute of an input signal, a vertical synchronizing frequency (f _V), the polarity of the horizontal sync signal (H-pol) and the vertical sync Adjustment data corresponding to each of various combinations of signal polarities (V-pol) is stored. That is, in the E ² PROM 5, the adjustment is performed when the values of f _H , f _V , H-pol, and V-pol in the key portion (hereinafter, a combination of four values is referred to as a key) are attributes of the input signal. Data is set corresponding to the key.

The adjustment data includes, for example, a horizontal oscillation frequency (H-OSC) and a horizontal display start position (H-OSC).
-Phase), horizontal screen width (H-Size), and vertical screen position (V-Posi).

[0005] When power supply to the microcomputer 10 is started, the microcomputer 10 first initializes an internal RAM and I / O ports (step ST1). Next, the horizontal synchronization frequency and the vertical synchronization frequency are measured using an internal counter or the like based on the horizontal synchronization signal and the vertical synchronization signal. Hereinafter, the measured values will be referred to as f _HC and f _VC , respectively.

Further, the polarity (H-SYNC.POL) of the horizontal synchronizing signal and the polarity (V-SYNC.POL) of the vertical synchronizing signal input to the input port are taken in, and their polarities are detected (step). ST2). Hereinafter, the detected signals are referred to as H-polc and V-polc, respectively.

Then, f _HC , f _VC , H-polc, V-polc
Is searched in the E ² PROM 5 (step 3). Here, the conditions under which they match are as follows.

[0008] (1) H-polc = H -pol (2) V-polc = V-pol (3) f H -Δf H <f HC <f H + △ f H (4) f V -Δf V < f _VC <f _V + △ f _V

Here, Δf _H and Δf _V are tolerances of the horizontal synchronization frequency and the vertical synchronization frequency, respectively, and are set in the internal ROM in advance. When there is a key that matches all the conditions, the microcomputer 1
0 reads out the adjustment data corresponding to the key and sets it in the internal RAM (steps ST4 and ST5). If not, the initial data for adjustment set in the internal ROM is set in the internal RAM (steps ST4 and ST4).
6). Then, the adjustment data in the internal RAM is given to the DA converter 7 (step ST7). DA converter 7
Converts the adjustment data into an analog value and outputs it to the display monitor as a signal for controlling each circuit of the display monitor.

The adjustment data is set in this manner. The operator can correct the adjustment data in the following manner. Microcomputer 1
0 always performs measurement of f _HC and f _VC and detection of H-polc and V-polc. If any of those values is different from the value measured or detected last time, the process returns to step ST2 to change the adjustment data supplied to the display monitor (step ST8).

When the operator looks at the screen of the display monitor and determines that correction is necessary, the operator operates a switch in the change data input section 6 to input change data. When the change data is input to the change data input unit 6,
The microcomputer 10 corrects the adjustment data in the internal RAM according to the changed data (step ST1).
0). Then, the corrected adjustment data is stored in the DA converter 7.
(Step ST11). Since the DA converter 7 outputs the corrected signal, the display screen of the display monitor is corrected accordingly. When the operator determines that further correction is necessary, the operator inputs the change data again. Further, the adjustment data in the E ² PROM 5 corresponding to the key targeted in step ST5 is replaced with the data in the internal RAM after correction when the internal RAM is corrected. Alternatively, when the operator performs a predetermined switch input of the change data input unit 6, the data is replaced with the data in the internal RAM.

[0012]

The control circuit of the conventional display monitor is constructed as described above.
^2. When there is a signal input that does not match any of the keys in the key section of the PROM 5, a signal for circuit control of each section based on the initial data for adjustment is always supplied to the display monitor. Therefore, in such a case, the initial data for adjustment rarely matches the originally desired adjustment data. Therefore, the operator gives the initial data for adjustment to the D / A converter 7 using the change data input unit 6. Therefore, there is a problem that it takes time and effort to create originally desirable adjustment data.

SUMMARY OF THE INVENTION The present invention has been made to solve the above-described problems. When there is a signal input having a combination that does not match any of the combinations stored in the data storage unit, the signal is applied to the signal. It is an object of the present invention to provide a control circuit for a display monitor that can create the originally desired adjustment data in a short time and that can reduce the burden on the operator during the creation.

[0014]

According to a first aspect of the present invention, there is provided a control circuit for a display monitor, comprising: a measured horizontal synchronization frequency and a vertical synchronization frequency; a polarity of an input horizontal synchronization signal and a polarity of a vertical synchronization signal; Is searched from each key in the data storage unit, and if there is a matching key, the adjustment data corresponding to that key is taken out. If there is no matching key, measurement is performed and horizontal synchronization is performed. A search means for selecting a key having a frequency or a vertical synchronizing frequency, and extracting adjustment data corresponding to the key from the data storage unit, and retrieving the extracted adjustment data with the change data input to the change data input unit. Correction means for correcting.

A display monitor control circuit according to a second aspect of the present invention has a configuration including a storage means for storing corrected adjustment data in a data storage unit in addition to the above configuration.

[0016]

According to the first and second aspects of the present invention, when there is no key that matches the combination of the measured horizontal synchronization frequency and the like, the search means searches for a key similar to the combination of the horizontal synchronization frequency and the like. The selected data is provided to the display monitor via the output unit, with the adjustment data corresponding to the selected key.

[0017]

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS One embodiment of the present invention will be described below with reference to the drawings. In FIG. 1, reference numeral 1 denotes measuring means for measuring a horizontal synchronizing frequency and a vertical synchronizing frequency based on a horizontal synchronizing signal and a vertical synchronizing signal, and 2 denotes adjustment data suitable for a combination of a measured horizontal synchronizing signal or the like and an input polarity. Is a RAM for storing the adjustment data read from the data storage unit 5, and 4 is a correction unit for correcting the adjustment data in the RAM 3 based on the change data input to the change data input unit 6. Means, and storage means for storing the corrected adjustment data in the data storage unit 5;
Is a D / A converter (output unit) that converts the adjustment data into an analog signal and outputs it to a display monitor.

The counting means 1, searching means 2 and changing means 4 can be realized by a microcomputer. Therefore, in that case, the RAM 5 is an internal RAM of the microcomputer. The data storage unit 5 stores E ²
This can be realized by the PROM 5 (hereinafter referred to as E ² PROM 5).

Next, the operation will be described with reference to the flowchart of FIG. Also in this case, adjustment data as shown in FIG. 5 is set in the E ² PROM 5 together with the corresponding keys. Then, the counting means 1 and the searching means 2 measure f _HC and f _VC as in the conventional case. Then, f _HC , f _VC , H-polc and V-pol
c (hereinafter, referred to as f _HC ) and each key in the key portion of the E ² PROM 5 are compared in ascending order of the address where each key exists, and keys satisfying the conditions (1) to (4) (Steps ST1 to ST1)
3).

If there is a key that satisfies all of the conditions (1) to (4), the search means 2 reads the adjustment data corresponding to the key from the E ² PROM 5 and reads it out of the RAM 3.
(Steps ST4 and ST5).

If there is no key that satisfies all the conditions, the search means 2 determines whether there is a key having f _H having the same value as f _HC (specifically, f _H satisfying the condition (3)). The key portion of the E ² PROM 5 is searched in ascending order of the address (step ST21). If there is one satisfying the condition (3), the adjustment data corresponding to the key is read out from the E ² PROM 5 and is read out from the RAM 3.
(Steps ST22 and ST25). Also, f
If the f _H having the same value as the _HC did not exist in the key unit, the search unit 2 (specifically f _V satisfying the condition (4)) f _V having the same value as f _VC having E ² PROM5 in order from the smallest address
Is retrieved (step ST23). Condition (4)
If there is one that satisfies the condition, the adjustment data corresponding to the key is read out from the E ² PROM 5 and read out from the RAM.
3 (steps ST24 and ST5).

As described above, the adjustment data corresponding to the key (similar key) having a value similar to the input signal f _HC or the like is set in the RAM 3. That is, f
_This means that data (similar data) close to the originally desirable adjustment data suitable for _HC or the like has been set. Note that the one satisfying the condition (3) or the condition (4) is the E ² PROM5
If it does not exist in the key part of, as in the conventional case,
The initial data for adjustment is written to the RAM 3 (step ST6).

The search means 2 gives the adjustment data set in the RAM 3 to the DA converter 7 (step S).
T7). The DA converter 7 converts the adjustment data into an analog value and outputs it to the display monitor as a signal for controlling each circuit of the display monitor.

Thereafter, the changing means corrects the adjustment data in the RAM 3 in accordance with the input change data, and converts the corrected adjustment data into a DA converter 7 as in the conventional case.
(Steps ST8 to ST11). In this case, since the similarity data is first set in RAM3 without a match for f _HC or the like in the key portion of the E ² PROM5, time and labor required for modification to reduce as compared with the conventional I have.

When the RAM 3 is modified or when the operator performs a predetermined switch input, the changing means 4
The data in M3 is stored in the E ² PROM5. here,
If the adjustment data written in the RAM 3 in step ST5 corresponds to a key that matches f _HC or the like, the data in the RAM 3 is the E ² P corresponding to the key.
The adjustment data in the ROM 5 is overwritten. That is, E
² The adjustment data in the PROM 5 is updated.

If the adjustment data written in the RAM 3 in step ST5 is similar data of a combination such as f _HC or the like, or is initial data for adjustment, the changing means 4 changes the combination of f _{HC and the} like. E ² PROM as a key
5 is newly registered in the key section, and the data in the RAM 3 is stored in the E ² PR as adjustment data corresponding to the new key.
Write to the data section of OM5. At this time, E ² PROM5
When there is no free space in the key portion, the oldest key is deleted and a new key is registered.

[0027]

As it is evident from the foregoing description, according to the present invention, when the control circuit of the display monitor, a key that matches the measured f _HC etc. is not present in the data storage unit, f _HC
The display monitor is provided with data similar to the original desired adjustment data corresponding to the above, and the correction data can be corrected based on the similar data. This saves time and effort, and in particular, provides an effect that can quickly respond to the case where it is necessary to continuously supply original desired adjustment data for a series of input signals in which only some attributes change. is there.

[Brief description of the drawings]

FIG. 1 is a block diagram showing a control circuit of a display monitor according to an embodiment of the present invention.

FIG. 2 is a flowchart showing the operation of the one shown in FIG.

FIG. 3 is a block diagram showing a control circuit of a conventional display monitor.

FIG. 4 is a flowchart showing the operation of the one shown in FIG.

FIG. 5 is an explanatory diagram showing an example of the contents of a data storage unit.

[Explanation of symbols]

1 count means 2 search unit 3 RAM 4 changing means (correction means, storage means) 5 E ² PROM (data storage unit) 6 change data input unit 7 D-A converter (output unit)

──────────────────────────────────────────────────続 き Continued on the front page (51) Int.Cl. ⁶ Identification code Agency reference number FI Technical display location H04N 5/04 H04N 5/04 Z 5/46 5/46 5/66 5/66 B

Claims (2)

(57) [Claims] A data storage unit storing various combinations of a horizontal synchronization frequency, a vertical synchronization frequency, a polarity of a horizontal synchronization signal, and a polarity of a vertical synchronization frequency, and adjustment data of a display monitor corresponding to the combination; Measuring means for measuring the frequency of the input horizontal synchronizing signal and the vertical synchronizing signal; and measuring the horizontal synchronizing frequency and the vertical synchronizing frequency measured by the measuring means with the polarity of the input horizontal synchronizing signal and the polarity of the vertical synchronizing signal. A match of the combination is retrieved from each combination in the data storage unit, and if there is a match, the adjustment data corresponding to the combination is extracted, and no match exists in the data storage unit. The data record having the measured horizontal synchronization frequency or the measured vertical synchronization frequency. Search means for selecting a combination in the storage unit and extracting the adjustment data corresponding to the combination;
A change data input unit for inputting change data, a correction unit for correcting the adjustment data extracted from the data storage unit according to the change data, and an output unit for providing the corrected adjustment data to the display monitor. Display monitor control circuit. 2. The display monitor control circuit according to claim 1, further comprising storage means for storing the corrected adjustment data in a data storage unit.