JPH0827610B2 - Data display system - Google Patents

Description

The present invention relates to a data display system, and is particularly suitable for application to a data display system for reproducing character / graphic data (hereinafter referred to as data) using a color television set. It is something.

[Background technology and its problems]

In recent years, along with the widespread use of color television receivers, a data transmission system has been developed in which a color television set can be used as a display device to reproduce a variety of information. As the first example,
A captain system (Character And Pattern Telephone Acce) that reproduces color image information by transmitting the data accumulated in the data center via the telephone line to the color television set installed in the terminal on the subscriber telephone side.
ss Information Network System). As a second example, there is still image broadcasting that utilizes television broadcasting, puts data in the blanking period of the television signal and broadcasts, and receives this data by a color television set and reproduces it as color image information. .

By the way, when reproducing color image information based on data using a color television set, the area is small when color is applied to a small area such as a part of a line or a character (hereinafter referred to as a linear part). The more the color becomes lighter, the more practically the linear portion having a width of one dot which is the minimum unit of the display screen is not substantially colored.

[Object of the Invention]

The present invention has been made in consideration of the above points, and is intended to solve the problem that a thin linear portion is not colored.

[Outline of Invention]

In order to achieve such an object, the present invention provides that when a color signal corresponding to a linear portion having a width of 1 dot which is the minimum display amount on the display screen arrives, the time width is set to be 1 dot or more and less than a predetermined dot number. The time width corresponding to the linear portion is expanded, and when a color signal having a width equal to or larger than a predetermined dot number arrives, the time width corresponding to the predetermined dot number width is generated.

〔Example〕

An embodiment in which the present invention is applied to a captain system will be described in detail below with reference to the drawings. As shown in FIG. 1, this data transmission system includes a line switch (4) at a terminal of a telephone line (3) installed between a telephone subscriber's telephone (1) and a telephone exchange (2). By providing the line switching device (4), data transmitted from the data center (5) through the telephone exchange (2) and the telephone line (3) can be received and displayed by the information receiving device (6). It is done like this.

The information receiving device (6) is operated by a signal processing circuit (9) based on an information selection input from a keyboard (8) via a modulator / demodulator (this is called a modem) (7) connected to a line switch (4). The obtained command signal is sent to the telephone line (3) as an upstream data signal. At this time, the data returned from the data center (5) is again supplied to the modem (7) as a downlink data signal through the telephone line (3), demodulated and given to the signal processing circuit (9).

Here, the data is decoded in the image signal reproducing circuit (10) and converted into an image signal including the color signals R, G, B, the foreground signal Y _{D and the} like. When the foreground signal Y _D is at the logic "1" level, the brightness and color of the area where characters are to be displayed (this is called foreground) is the area where characters other than this area are not displayed (this is called back ground). ) Brightness and color to make them brighter (eg, twice as bright) and different, and the character signal is generated during the duration of the foreground signal Y _D. ing.

Accordingly, the decoded color signals R, G, B are subjected to correction for the time width together with the foreground signal Y _D in the color signal correction circuit (11) having the configuration shown in FIG. A video signal supplied to the circuit (12) and RF-modulated at its output end is input and displayed on the television set (13).

The color signal correction signal (11) is used in the television set (13).
When the color signals R, G, B having a time width corresponding to a 1-bit linear portion on the display screen of No. 3 arrive, the time width is expanded to a time width corresponding to a linear portion having a width of 3 dots. It has the configuration of. That is, the color signal correction circuit (11) controls the color signals R, G, B
And a time width correction circuit (15R), (15G), (15B) and (15Y) corresponding to the foreground signal Y _D and a color signal output circuit (16), each time width correction circuit (15R), (15
G), (15B) and (15Y) each include a sequential pulse generating circuit (17) and a logic output circuit (18).

As shown in FIG. 3, each sequential pulse generation circuit (17) has a shift register circuit (22) having a four-stage circuit configuration for receiving an input signal I (consisting of R, G, B and Y _D ), When the input signal I of the logic "1" having the time width corresponding to one dot width arrives at the end, the logic "1" signal is changed to the first by the first clock pulse CL. Read into the 1-stage circuit (23A). The logic "1" signal read into the first-stage circuit (23A) is the second-stage circuit (23B) every time the second, third, ... Clock pulse CL arrives at the shift-register circuit (22). It is sequentially shifted to the third stage circuit (23C) and the fourth stage circuit (23D), and thus FIG. 4 (B),
As shown in (D) and (E), the first, second, third and fourth stage circuits (23A), (23B), (23C) of the shift register circuit (22),
Output pulses S2, S3, S4, S5 having the same rising width as the cycle of the clock pulse CL are generated at the output end of (23D).

Here, the cycle of the clock pulse CL is selected to be equal to the time width corresponding to the width of the one-dot linear part, that is, 175 ns (that is, 5.727 MHz).
The rising periods of S2, S3, S4, and S5, when rewritten on the display screen, correspond to four dots that are sequentially adjacent to the dot corresponding to the input signal I.

An input signal I at the input end of the shift register circuit (22),
The output pulses S2, S3, S4, S5 of each stage circuit (23A), (23B), (23C), (23D) are given to the logic output circuit (18).
The logic output circuit (18) receives the input signal I as the first input signal S1 via the inverter (24A) and directly receives the output pulse of the first stage circuit (23A), as shown by the positive logic in FIG. The second stage circuit (23
A three-input AND circuit (25) that receives the output pulse of B) as a third input signal S3 via an inverter (24B);
The output pulse of the stage circuit (23B) is received as the first input signal S3 via the inverter (26A), the output pulse of the third stage circuit (23C) is directly received as the second input signal S4, and the fourth stage circuit is received. A 3-input AND circuit (27) that receives the output pulse of (23D) as a third input signal S5 via an inverter (26B).
Have and.

The outputs of the AND circuits (25) and (27) are the second stage circuit (23
B) Output pulse S3 and time width correction circuit (15R), (15G), (15B), (15Y) via 3-input OR circuit (28)
Is given to the color signal output circuit (16) (FIG. 2).

In the case of this embodiment, the logic output circuit (18) is actually composed of an inverter and a NAND circuit as shown in FIG. 2 with the same reference numerals as those in FIG. Incidentally, the 3-input OR circuit (28) of FIG. 3 has an AND output function of the NAND circuit (31) in FIG. 2 which has the inverting output function of the NAND circuits (29A) and (29B) and the inverting output function of the inverter (30). The OR output function is realized as a whole by connecting to.

Time width correction circuit (15R), (15G), (15B), (15Y)
Are output from the color signal output circuit (16) corresponding to the decoded color signals R, G, B and the foreground signal Y _D , respectively, corresponding to the switching transistors (31R), (31G),
Buffers (32R), (32G), (32 on (31B), (31Y)
B), (32Y). However, foreground signal Y _D NPN type emitter floor transistor (31
Y) becomes a high impedance state when the output of the time width correction circuit (15Y) is logic "0", and a relatively low voltage is applied to the color signal R, through the resistors (33R), (33G) and (33B). G, B PNP
-Shaped open collector transistor (31R), (31G),
Apply to (31B) Base to Pull It to a Lower Voltage Level. This transistor (31R), (31G), (31
B) is a color signal of low voltage level (that is, dark level) from the emitter, which reduces the internal impedance to a low level.
It delivers R _L , G _L , and B _L , which produces the brightness and color of the background.

On the other hand, the NPN transistor (31Y) of the foreground signal Y _{D is in} a low impedance state when the output of the time width correction circuit (15Y) is logic "1" and a relatively high voltage is applied to the resistor (33R), It is given to the bases of the transistors (31R), (31G), and (31B) via (33G) and (33B). At this time, transistors (31R), (31G), (31B)
Is a high impedance state, and the voltage of the positive voltage level is applied from the emitter side to the color signals R _L , G _L , B _{L of a} relatively bright level.
, Which causes the foreground brightness and color to be generated.

Thus, the time width correction circuit (15R), (15G), (15B)
Color signal of the level corresponding to the logical "1" or "0" output of
R _L , G _L , and B _L are supplied to the video signal forming circuit (12) from the post-color signal output circuit (16) after the brightness is adjusted by the foreground signal Y _D (FIG. 1). Video signal forming circuit (12) is a color signal R _L of the logic "1" or "0", G _L, B _L
Is received by a matrix to produce color difference signals RY and BY, and the carrier is modulated by the double balanced modulators. A luminance signal, a burst signal, and a synchronization signal are mixed with this modulation output to form a composite video signal, which is then modulated with a carrier of, for example, 2 channels by an RF modulator to generate a high frequency signal similar to a television broadcast wave. It is given to the television set (13) as the output of the processing circuit (9), thus displaying an image based on the data.

In the above configuration, the time width correction circuit (15R) to (15R
Y) logic output circuit (18) is a sequential pulse generation circuit (17)
A logical output W represented by the following logical expression is sent to the outputs S1 to S5 of FIG.

W = ▲ ▼ ・ S2 ・ ▲ ▼ ＋ S3 ＋ ▲ ▼ ・ S4 ・ ▲
▼ (1) However, for example, the decoded color signal R (and accordingly the pulse S1) of the output of the image signal reproducing circuit (10) based on the downlink data signal from the modem (7) is linear for one dot. When the logical value becomes "1" for the time corresponding to the part (FIG. 4 (A)), the shift register circuit (22) shifts every one dot equivalent time, and the first stage circuit (23A) From the four-stage circuit (23D), outputs S2 to S5 which become logic "1" are sequentially obtained for one dot equivalent time (Figs. 4 (B) to (E)), whereby the output of the logic output circuit (18). At the end, as shown in FIG. 4 (F), the output W which becomes the logic "1" is sent out as the output of the time width correction circuit (15R) for the period of 3 dots based on the equation (1). Accordingly, the color signal output circuit (16) outputs the color signal R _L whose rise time width is expanded to a time corresponding to 3 dots.

At the same time, also in the time width correction circuit (15Y), if the logic level of the foreground signal Y _D becomes a logic "1" by one dot, a logic "1" having a time width of 3 bits.
By sending the output, the color signals R _L , G _L ,
Foreground brightness can be added to B _L.

Incidentally, the time T1 when the color signal R arrives in FIG.
From the output of the shift register circuit (22) S2, S3, S4, S5
When the logical output W at times T2, T3, T4, T5 in which the value becomes a logic "1" is obtained, S1 = 1 at the time T1, so that W = 1.0.0 + 0 + 0.0.0.0 = 0 (2) Since S2 = 1 for time T2, W = 1.1.1.1.1 + 0 + 10.1 = 1 = 1 (3) Since S3 = 1 for time T3, W = 1.0・ 0 + 1 + 0.1 ・ 1 = 1 (4) Since S4 = 1 for time T4, W = 1 ・ 0.1 ・ 0 + 1 ・ 1.1 = 1 = 1 (5) Since S5 = 1 for time T5 , W = 1 · 0 · 1 + 0 + 1 · 0 · 0 = 0 (6) Therefore, the output W of logic "1" can be obtained during the time T2 to T3.

On the other hand, if the decoded color signal R becomes logic "1" for a time longer than 2 dots, the output W of the decoded color signal R is corresponding to the output S3 of the sequential pulse generation circuit (17). Logic "1" during the time corresponding to the length of the dot
It is possible to obtain an output W that is

The above operation is exactly the same for the decoded color signals G and B.

Although the embodiment in which the present invention is applied to the captain system has been described above, the present invention is not limited to this and can be widely applied to the case of displaying data using a color television set, such as still image broadcasting.

Further, in the above description, the composite video signal VID obtained based on the output of the color signal correction circuit (11) is RF-modulated and then applied to the antenna terminal of the television set, but instead of this, the composite video signal is RF-modulated. Even if it is directly connected to the video detection output terminal of the television set, the same operational effect as in the above case can be obtained, and the point is to give it to the pre-stage circuit of the band amplifier of the color demodulation circuit. .

〔The invention's effect〕

As described above, according to the present invention, when the color signal corresponding to the width of one dot arrives on the display screen, the width of the signal of the color signal is expanded below the predetermined dot width and displayed on the display screen. By doing so, it is possible to reliably color even the narrow linear part of the character figure, and at the same time, when a color signal exceeding the predetermined dot width arrives, it is displayed with the width as it is. It is possible to prevent the inconvenience of the lines coming into contact with each other with respect to the wide linear portions adjacent to each other.

In addition, in order to select the time width other than that corresponding to 3 dots, the logic condition of the logic output circuit (18) may be changed as necessary, and the color correction effect described above can be obtained.

[Brief description of drawings]

FIG. 1 is a block diagram showing a data transmission system to which a character / graphics color signal correction circuit according to the present invention is applied, FIG. 2 is a connection diagram showing the color signal correction circuit, and FIG. 3 is a time width correction circuit. The connection diagram and FIG. 4 are signal waveform diagrams for explaining the operation. (1) ... Telephone, (2) ... Telephone exchange, (4) ... Line switch, (5) ... Data center, (6) ... Information signal device, (7) ... Modulator / demodulator, (8) ... Keyboard, (9)
... Signal processing circuit, (10) ... Image signal reproduction circuit, (11) ...
Color signal correction circuit, (12) ... Video signal forming circuit, (13) ...
Color television set, (15R) to (15Y) ... time width correction circuit, (16) ... color signal output circuit, (17) ... sequential pulse generation circuit, (18) ... logic output circuit, (21) ... waveform shaping circuit.

 ─────────────────────────────────────────────────── ─── Continuation of the front page (72) Inventor Kei Tsuchiya 6-735 Kita-Shinagawa, Shinagawa-ku, Tokyo Within Sony Corporation (72) Inventor Fumichi Otsuka 6-35 Kita-Shinagawa, Shinagawa-ku, Tokyo No. Sony Corporation (56) References JP-A-48-21940 (JP, A) JP-B 57-3075 (JP, B2)

Claims (1)

[Claims] 1. A data display system adapted to display a color image according to the received data by generating a video signal from the received data and supplying the video signal to a television set, the decoded data being decoded from the received data. A shift register for sequentially delaying a color signal by a time corresponding to one dot on the display screen of the television set, and the color signal output from each delay stage of the shift register are input to obtain the decoded color signal. When the pulse width is equal to or more than the one dot and less than the predetermined dot number, the pulse width of the color signal is expanded to the predetermined dot number or more and output, and the pulse width of the decoded color signal is the predetermined dot number or more. And a logic circuit that outputs a color signal having the same pulse width as the pulse width of the decoded color signal, Serial data display system and generates the image signal based on the output signal of the logic circuit.