JPH0711071U - Monitor display - Google Patents

Abstract

(57) [Abstract] [Purpose] To prevent a high frequency component of a video signal from being input with an excessive amplitude to a preamplifier that amplifies the video signal. [Configuration] Signal input terminal 1 _R for inputting video signals,
It is grounded through a series circuit of a resistor 4 _R and a switch 5 _R. The signal input terminal 1 _R is connected to the preamplifier PA via the low pass filter LF. When the switch 5 _R is turned off, the transistor Q of the low pass filter LF is turned on, and the high pass frequency component of the video signal is attenuated by the low pass filter LF.

Description

[Detailed description of the device]

[0001]

[Industrial applications]

 The present invention relates to a monitor display for displaying an image by video signals of three primary colors R, G and B.

[0002]

[Prior art]

FIG. 3 is a block diagram showing a configuration of a monitor display for displaying an image by video signals of three primary colors R (red), G (green) and B (blue) on a cathode ray tube (hereinafter referred to as CRT). When the video signals of the three primary colors R, G, B are input to the signal input terminals 1 _R , 1 _G , 1 _B separately, the R (red) video signal input to the signal input terminal 1 _R is output by the signal output terminal 2 _R. And is amplified by the preamplifier PA that constitutes the video signal circuit 3 _R.

The amplified video signal is further amplified by an output amplifier OA, and a cathode K of a CRT 14 is passed through a bright circuit BC for adjusting brightness._RGiven to. Signal input terminal 1 _G The video signal of the signal G (green) input to is input to the signal output terminal 2_GOutput to the video circuit 3_RVideo circuit 3 configured similarly to_GIt is amplified by the preamplifier PA. The amplified video signal is further amplified by the output amplifier OA, and passes through the bright circuit BC to the cathode K of the CRT 14._GGiven to.

Signal input terminal 1_BThe video signal of signal B (blue) input to is input to the signal output terminal 4 _B Output to the video circuit 3_RVideo circuit 3 configured similarly to_BIt is amplified by the preamplifier PA. The amplified video signal is further amplified by the output amplifier OA and then passed through the bright circuit BC to the cathode K of the CRT 14._BGiven to. As a result, the image of the video signals R, G, B is displayed on the screen of the CRT 14.

The signal input terminal 1_R(1_G, 1_B) Is, for example, a resistor 4 of, for example, 75Ω, whose impedance is matched with that of a personal computer connected to it._R(4_G, 4 _B ) And switch 5_R(5_G, 5_B) And is grounded via a series circuit.

By the way, using such a monitor display, an image portion other than characters can be easily displayed on a CRT monitor display having a large screen, and an image of a character portion can be easily displayed on a CRT monitor display having a small screen. For this reason, two monitor displays with different CRT screen sizes may be used in parallel by connecting them to a single personal computer that outputs a video signal.

FIG. 4 is a connection state diagram of monitor displays showing a state in which a video signal from a single personal computer is input to the two monitor displays configured as described above. And 2 _R one of the monitor display DSP ₁ signal output terminal, and the other monitor display signal input terminal 1 of the DSP _{2 R} are connected via the cable CA _1.

[0008] are connected to the ground portion of one of the monitor display DSP _1, the ground portion of the other of the monitor display DSP ₂ via the cable CA ₂ as a shield wire of the cable CA _1. Although not shown, the G and B signal input terminals of _one monitor display DSP ₁ are also connected to the G and B signal input terminals of the other monitor display DSP ₂ via a cable.

By the way, the output impedance of the personal computer connected to such monitor displays DSP ₁ and DSP ₂ is usually low impedance of 75Ω. Therefore personal computer monitor display DSP _1, when connected with the DSP ₂ includes a monitor display DSP _1, turns off any of the switches 5 _R of the DSP _2, monitor display DSP _1, the resistance input impedance of the DSP ₂ 4 _R To 75 Ω to match the impedance.

When the video signal from the personal computer is input to the signal input terminal 1 _R of the monitor display DSP ₁ with the impedance thus matched, the video signal is input to the preamplifier PA and its signal output The signal is input from the terminal 2 _R via the cable CA ₁ to the signal input terminal 1 _{R of} the other monitor display DSP ₂ , and then input to the preamplifier PA. As a result, the video signal circuits 3 _R and 3 _R of the monitor displays DSP ₁ and DSP ₂ amplify the same video signal and display the same image on the screen of each CRT as described above.

[0011]

[Problems to be solved by the device]

However, as mentioned above, when two monitor displays are connected to a single personal computer, the switch 5 _R of either monitor display DSP ₁ or DSP ₂ is turned off, so that monitor display DSP ₁ , The termination resistance of DSP ₂ becomes 75Ω due to one resistor 4 _R , but between the ground of resistor 4 _R of monitor display DSP ₁ and the ground of preamplifier PA, the high frequency component of the video signal is not detected. However, the inductance component L of the cable CA ₂ , which is the shield wire of the cable CA ₁ , acts equivalently.

Therefore, if a wideband video signal is input to the signal input terminal 1 _R of the monitor display DSP ₂ and the impedance is matched by the resistor 4 _R , the preamplifier PA of the other monitor display DSP ₂ is grounded. Since the operation is based on the potential of the part, the impedance is equivalently matched including the inductance component L. Since the impedance of the inductance component L increases as the frequency component of the video signal is higher, the impedance becomes higher than 75Ω for the video signal of the frequency component of high frequency, and the impedance becomes unmatched. Therefore, there is a problem that the amplitude of the video signal of the high frequency component of the video signal increases, and the operation of the preamplifier may cause oscillation in the video signal of the high frequency component.

In view of such a problem, the present invention may cause a preamplifier to oscillate due to a video signal of a high frequency component when a plurality of monitor displays are connected to a single signal source that outputs a video signal. Not intended to provide a monitor display.

[0014]

[Means for Solving the Problems]

 In the monitor display according to the present invention, a signal input terminal to which a video signal is input is connected via an input impedance changing circuit including a series circuit of a resistor and a switch, and the video signal input to the signal input terminal is connected. In a monitor display that is intended to input to the amplifier, a low-pass filter is inserted in the circuit that connects the signal input terminal and the amplifier, and the low-pass filter is provided when the switch is turned off. It is characterized in that the high frequency component of the video signal input to the amplifier is attenuated.

[0015]

[Action]

 The signal input to the signal input terminal is input to the amplifier through the low pass filter. When multiple monitor displays are connected to a single signal source that outputs video signals, switch off the monitor displays that are not directly connected to the signal sources. When switched off, the impedance of the signal source and the monitor display will match. When the switch is turned off, the low pass filter functions and the high frequency components of the video signal input to the low pass filter are attenuated. Then, the high frequency components of the video signal input to the amplifier are suppressed. As a result, the amplitude of the high frequency component of the video signal input to the amplifier does not become excessive and there is no risk of the amplifier oscillating.

[0016]

【Example】

Hereinafter, the present invention will be described in detail with reference to the drawings showing an embodiment thereof. FIG. 1 is a block diagram showing the configuration of a monitor display according to the present invention, showing an R (red) video signal circuit. The signal input terminal 1 _R for inputting the R video signal is connected to the signal output terminal 2 _R for outputting the input R video signal, and the input side of the preamplifier PA is connected via the resistor R _1. Connected with. The connection between the signal input terminal 1 _R and the resistor R ₁ is grounded via a series circuit of a resistor 4 _R and a switch 5 _R having a resistance value for impedance matching of, for example, 75Ω.

The connecting portion between the resistor R ₁ and the input side of the preamplifier PA is grounded via a low-pass filter LF including a series circuit of a capacitor C and a transistor Q at an emitter ground and resistors R ₁ and R _2. There is. A signal S which becomes H level when the switch 5 _R is turned off is input to the base of the transistor Q via the resistor R ₂ . The grounding portion of the preamplifier PA is grounded, and the output side is connected to the input side of an output amplifier OA (see FIG. 2) not shown. The monitor display is configured in the same manner for the other G (green) and B (blue) video signal circuits.

FIG. 2 is a connection state diagram in the case of using two monitor displays configured as described above and inputting a video signal from a single personal computer to each monitor display. The signal output terminal 2 _R of _one monitor display DSP ₁ is connected to the signal input terminal 1 _{R of} the other monitor display DSP ₂ via the cable CA ₁ . The ground section of the monitor display DSP ₁ is connected to the ground section of the monitor display DSP ₂ via the cable CA ₂ as the shield wire of the cable CA ₁ .

The switch 5 _R of the monitor display DSP ₂ is turned off. Thus, the common input impedance monitor display DSP _1, DSP _2, and has a 75Ω by resistor 4 _R of Monitade Isupurei DSP _1. If a personal computer (not shown) with an output impedance of 75Ω is connected to the signal input terminal 1 _R of the monitor display DSP ₁ connected in this way, if a personal computer is connected to the monitor display DSP ₁ and DSP ₂ , The impedance of is matched.

Next, the operation of the monitor display when two such monitor displays are used will be described. Now, when the R video signal from the personal computer is input to the signal input terminal of the monitor display DSP ₁ , the R video signal input to the signal input terminal 1 _R is input to the preamplifier PA and the signal output terminal. The signal is input to the signal input terminal 1 _R of the monitor display DSP ₂ via the child 2 _R and the cable CA ₁ and then input to the preamplifier PA.

As a result, the same video signal is amplified by the preamplifiers PA of the monitor displays DSP ₁ and DSP ₂ , respectively. The amplified video signal is input to the output amplifier, amplified again, and given to the cathode of the CRT through the bright circuit (see Fig. 3), and the image by the same video signal is displayed on the monitor display DSP ₁ and DSP _{2 respectively.} Display on screen.

By the way, due to the inductance 12 of the cable CA ₂ , the amplitude of the high frequency component of the video signal input to the preamplifier PA of the monitor display DSP ₂ increases as described above. However, since the switch 5 _R of the monitor display DSP ₂ is turned off, the H-level signal S is input to the base of the transistor Q of the monitor display DSP ₂ and the transistor Q is turned on to turn on the high frequency component of the video signal. Is bypassed to the ground through the transistor Q and attenuates the high frequency components of the video signal input to the preamplifier PA. Therefore, the amplitude of the video signal input to the preamplifier PA becomes flat in a wide frequency range, the amplitude of the video signal input to the preamplifier PA does not become excessive, and the preamplifier PA always operates stably and oscillates. There is no fear that it will be easy to do.

On the other hand, for example, when the monitor display DSP ₁ is used alone, the switch 5 R is turned on to set the input impedance to 75Ω and match the output impedance of the personal computer. Then, since the switch 5 _R is turned on, an L level signal is input to the base of the transistor Q, the transistor Q is turned off, and the high pass frequency component of the video signal is not attenuated by the low pass filter LF. The video signal input to the signal input terminal 1 _R is input to the preamplifier PA as it is.

That is, when used alone, since CA ₂ is not used together with cable CA ₁ , it is not affected by the inductance component L of cable CA ₂ , and the high frequency components of the video signal input to preamplifier PA are not affected. Since the amplitude of does not become excessive, even if the high frequency component is input to the preamplifier PA without being attenuated, there is no risk that the preamplifier PA will oscillate easily.

In this embodiment, the case where the video signal from the personal computer is input to the signal input terminal has been described, but it goes without saying that the same effect can be obtained by inputting the video signal from the workstation. . Further, although the high frequency component of the video signal is bypassed by the transistor, the same effect can be obtained by bypassing it by using a relay or an impedance switching element. Further, in the present embodiment has been allowed to turn off the switch 5 _R of Monitadi spray DSP _2, the may be off the switch 5 _R of the monitor display DSP ₁ is a matter of course.

[0026]

[Effect of device]

 As described in detail above, in the monitor display according to the present invention, when a video signal from a single signal source is input to two monitor displays and an image of the same video signal is displayed on each monitor display, Since the high frequency component of the video signal is attenuated by the low pass filter and input to the amplifier, the high frequency component of the video signal is not input to the amplifier with an excessive amplitude. There is no fear that the will oscillate easily. As a result, the video signal from the signal source can be stably amplified over a wide band, which is an excellent effect.

[Brief description of drawings]

FIG. 1 is a block diagram showing a main configuration of a monitor display according to the present invention.

FIG. 2 is a connection state diagram when two monitor displays according to the present invention are connected to a single signal source.

FIG. 3 is a block diagram showing a main configuration of a conventional monitor display.

FIG. 4 is a connection state diagram when two conventional monitor displays are connected to a single personal computer.

[Explanation of symbols]

1 _R signal input terminal 2 _R signal output terminal 4 _R resistance (75Ω) 5 _R switch Q transistor C capacitor LF low pass filter PA preamplifier

Claims (1)

[Scope of utility model registration request] 1. A signal input terminal to which a video signal is input is grounded via an input impedance changing circuit composed of a series circuit of a resistor and a switch, and the video signal input to the signal input terminal is input to an amplifier. In the monitor display that is being done, a low-pass filter is provided in the circuit that connects the signal input terminal and the amplifier, and the low-pass filter is input to the amplifier when the switch is turned off. A monitor display having a structure for attenuating a high frequency component of a video signal.