JPH04160875A - Contour compensation device - Google Patents

Abstract

PURPOSE:To obtain a pattern in response to natural and self-possessed contrast by limiting the contour compensation effect of a video image in response to a voltage for contrast adjustment. CONSTITUTION:The contour compensation effect is controlled by velocity modulation(VM) in response to the contrast adjusted by the user. That is, a contrast adjustment voltage (DC voltage) 30 to adjust the contrast is in use to limit a control voltage of an amplitude limit circuit of a VM circuit 5. Moreover, the VM effect is reduced by decreasing the DC voltage 30 in the absence of a synchronizing signal line a noise pattern by a discrimination circuit 31 discriminating the presence of the synchronizing signal. Thus, the emphasis of the contour on the pattern is made proper and a sense of disorder is avoided and an easy-to-see pattern is always displayed.

Description

DETAILED DESCRIPTION OF THE INVENTION Field of the Invention The present invention relates to a contour compensation device using a velocity modulation circuit in a television receiver.

Conventional technology Large television receivers use cathode ray tubes (CR).
A speed change circuit (VM circuit) is added which emphasizes the image outline on the screen and improves the clarity by modulating the scanning speed of the electron beam (T) according to the image outline.

Generally, the signal input to this VM circuit is a luminance signal that has just been separated into a luminance signal and a chrominance signal using a comb filter, etc., and is the final signal that drives the CRT (contrast and chrominance signals). This is different from the signal to which image quality adjustments and II controls have been added.

Problems to be Solved by the Invention However, in a VM circuit using such an input signal, even when the user adjusts the contrast to reduce it, the input signal to the VM circuit does not change at all. The same VM effect works even when the user similarly adjusts the Noyabness to be small.

That is, when viewed on the screen, the VM effect does not change even though the contrast is low and the screen settings are firm and calm, so there is a problem that only the outlines are emphasized and the screen is difficult to see. Even when the sharpness is reduced, the V
Since the M effect does not change, there is a problem that only the outline is emphasized on the screen.

Furthermore, when the received signal is a noise screen, the noise signal is continuously amplified by the speed modulation circuit, so that the power at the output circuit 7 shown in Fig. 1 is lower than in the normal case where only the contour signal is amplified. Since power consumption increases dramatically and the temperature of the output transistor in particular increases, a circuit is required to suppress this noise signal.

In order to solve these problems, the signal after contrast and image quality has been adjusted can be used as the input signal to the VM circuit. , the delay time to the CRT cathode is small, and in order to match the phase of the CRT cathode waveform and the VM coil current waveform, it becomes necessary to provide delay elements for the luminance signal and color signal, which increases costs.

Furthermore, power consumption during noise signals is generally reduced by detecting the average current consumption flowing through the output transistor with a resistor, converting it into voltage, and controlling the gain of the amplifier circuit 3.

The present invention enables VM to adjust the contrast and sharpness adjusted by the user without increasing the contrast.
By changing the contour compensation effect, you can always obtain an easy-to-see image, and when there is a noise signal, by lowering the contrast and sharpness control voltages, you can lower the contour compensation effect and reduce power consumption. The object is to provide a compensation device.

Means for Solving the Problems In the present invention, the contour compensation effect by VM is controlled according to the contrast and sharpness adjusted by the user, and the contrast adjustment voltage ( Using a DC voltage (DC voltage), a sharpness adjustment voltage (DC voltage), or a DC voltage that is a combination of the contrast adjustment voltage and the sharpness adjustment voltage, limit the pressure of the amplitude limiting circuit 'a1 of the VM circuit, and also control the presence or absence of the synchronization signal. The discrimination circuit lowers the DC voltage to reduce the VM effect when there is no synchronizing signal such as in a noise screen.

Function: The VM circuit of the present invention uses only a contrast adjustment voltage, only a sharpness adjustment voltage, or a voltage that is a combination of two voltages to perform contour compensation by VM according to contrast and sharpness adjustment voltages by the user. When each adjustment voltage is large, the compensation effect is also large, and when the adjustment voltage is small, the compensation effect is also small, so that the contours on the screen are emphasized to the right level, eliminating any unnatural feeling, and always displaying a screen that is easy to see. At the same time, when there is a noise screen in which there is no synchronization signal, the adjustment voltage can be lowered to reduce the power consumption of the VM output circuit more easily.

Embodiment Hereinafter, a contour compensation device using VM according to an embodiment of the present invention will be explained with reference to the drawings.

FIG. 1 shows the configuration of the contour compensation circuit, in which an input signal (luminance signal) 9 passes through an amplifier circuit 1, and a differentiation circuit 2.
The contour of the image is detected by differentiation. The detection output is outputted to the output circuit 7 via the amplifier circuit 3 and the drive circuit 4.
The M coil 8 is driven and the deflection scanning speed of the electron beam is modulated to compensate for emphasizing the outline of the image. During this time, a diode limiter circuit 5 is provided which limits the amplitude above a certain level.

FIG. 2 shows in detail the diode limiter circuit 50 shown in FIG. 1, and this circuit will be explained according to the diagram.

In order to limit the amplitude of the differentiated and amplified contour detection signal, conventionally, the voltage 18, which is fixed at a constant voltage, is divided by resistors 12, 13, 14, and 15, and the voltage at the intersection of resistors 12 and 13 is Upper and lower limiters were applied to each voltage at the intersection of resistors 14 and 15. That is, the differential pulse is limited by the diode 10 and capacitor 16 on the upper side of the waveform, and is limited by the diode 11 and capacitor 17 on the lower side, so that the size of the differential waveform is always limited to a constant value.

In contrast, in the configuration of the present invention, the fixed voltage 18
Instead, the user can adjust the contrast and sharpness by using the contrast adjustment voltage 30, or in other cases, the sharpness adjustment voltage, and a voltage that is the sum of the contrast adjustment voltage 30 and the sharpness adjustment voltage. Adjust the voltage accordingly.

First, a circuit for applying the contrast adjustment voltage 30 in the case of the contrast-linked type will be explained with reference to FIG.

The voltage pulse for contrast adjustment output by the microcomputer 31 is applied to the resistor 19.20°21,2.
2 and diode 23. The capacitor 24 converts the voltage into a DC voltage. The minimum value of this voltage 30 is determined by the resistor 19.degree. 20, and is applied as the limit voltage 18 of the diode limiter circuit 5 for VM, and thereby the range of change in the limit voltage can be freely controlled.

The ABL voltage 28 is added to the contrast voltage by resistors 25, 26, 27, and is input to the video chroma IC as a contrast control voltage 29 to change the contrast of the luminance signal.

That is, the limiting voltage of the VM circuit is changed using a control voltage that is not affected by the ABL voltage, and the 7M effect is made to correspond to the contrast setting value, thereby creating a natural and easy-to-see screen.

Next, the sharpness-linked type will be explained. The circuit for applying the sharpness adjustment voltage has the same configuration as that shown in FIG. 3, but recently, in many cases, the microcomputer 31 already outputs the DC voltage. The same applies to contrast. This circuit configuration will be explained with reference to FIG.

The DC voltage for sharpness adjustment output by the microcomputer determines the voltage operating range by resistors 32, 33, 34, 35, and is input to the video chroma IC 36 to control the image quality. In addition, the voltage operating range is determined by resistors 38, 39 and 40, and a buffer circuit is formed by a transistor 41 and a resistor 42, and from its emitter, V
It is applied as the limiting voltage 18 of the diode limiter circuit 5 for M to change the compensation effect of VM.

Furthermore, the video chroma IC 36 in FIG. 4 has a circuit that determines the presence or absence of a synchronization signal of the video signal, and inputs information about the presence or absence state to the microcomputer 31 as a synchronization presence/absence determination signal 37. If not,
That is, in a noise screen state, if the contrast-linked type is used, the contrast adjustment voltage 30 is lowered, and if the sharpness-linked type is used, the sharpness adjustment voltage 44 is lowered.1. Furthermore, if both contrast and sharpness are linked, lower only the contrast adjustment voltage 30, or only the sharpness adjustment voltage 44, or lower both voltages at the same time to further lower the 7M effect and power consumption. To reduce noise and prevent contour compensation from being applied to unnecessary noise.

Next, the contrast and sharpness linked circuit is added to the fifth circuit.
This will be explained using figures.

The contrast adjustment voltage 30 is applied through a resistor 45 and a buffer circuit composed of a transistor 46 and a resistor 47.
The sharpness adjustment voltage 43 is connected to the resistors 49, 48, and 50.
and is applied as the limit voltage 18 of the diode limiter circuit 5 for VM. In this case, by changing the ratio of the resistors 48 and 49, it is possible to select whether contrast or sharpness is the main focus, or whether the effect is the same.

In this way, it is possible to obtain an easy-to-see screen according to contrast and sharpness, and to reduce power consumption without adding unnecessary 7M effects to noise screens using software using a microcomputer, and the amount of reduction can be freely controlled. Can be configured.

Effects of the Invention As described above, the contour compensation device of the present invention limits the contour compensation effect of the image according to the voltage for contrast adjustment and the voltage for sharpness adjustment. The 7M effect was too large and the outlines were overemphasized, even when the sharpness was set to a soft level. This is extremely advantageous in practice since it is possible to easily reduce the power consumption without emphasizing the outline of the screen.

[Brief explanation of drawings]

FIG. 1 is a basic block diagram of a contour compensation device according to an embodiment of the present invention, FIG. 2 is a circuit diagram of a diode limiter circuit, and FIG. 3 is a circuit diagram of a contrast adjustment voltage generating circuit.
FIG. 4 is a circuit diagram of a sharpness adjustment voltage generating circuit, and FIG. 5 is a circuit diagram of a circuit that mixes a contrast ffl adjustment voltage and a sharpness adjustment voltage. 1.3... Amplifier circuit, 2... Differential circuit, 4... Drive circuit, 5... Diode limiter circuit, 7... Output circuit, 8...
...VM coil, 9.16.17°24...
Capacitor, 10.11.23... Diode, 12, 13.14.15.19.20.21.22.
25.26.27゜32.33.34.35.38.3
9.40.42.45.47.48°49,50...
...Resistance, 30...Contrast adjustment voltage,
41, 46...transistor, 43...
・Sharpness adjustment voltage. Name of agent: Patent attorney Akira Okaji and two others Figure 1 Figure 3 Kan 2r! 3-18 Introduction to Figure 4 Figure 5

Claims (5)

[Claims] (1) Equipped with a circuit that detects the contour of the image and a speed modulation circuit that compensates for the contour of the image by modulating the scanning speed of the electron beam of the cathode ray tube according to the contour detection signal, and also compensates for the contour of the image. a speed modulation circuit that adjusts the contrast of the image, and a control circuit that increases the amount of compensation for the contour as the contrast is adjusted to increase by controlling the contrast adjustment voltage that adjusts the contrast of the image; A contour compensation device comprising: a detection circuit for detecting the presence or absence of a synchronization signal of a video signal, the circuit lowering the contrast voltage and reducing the contour compensation amount only when the synchronization signal is “absent”. (2) Equipped with a speed modulation circuit, a control circuit that is controlled by a sharpness adjustment voltage that adjusts the sharpness (image quality) of the image and increases the amount of contour compensation in conjunction with the sharpness adjustment, and a synchronization signal detection circuit, and a synchronization signal A contour compensating device characterized in that the sharpness voltage is lowered to reduce the amount of compensation for the contour only when the sharpness voltage is "absent". (3) Controlled by a speed modulation circuit, a contrast adjustment voltage, and a sharpness adjustment voltage, as the contrast is adjusted to increase, the compensation amount for the contour is increased, and as the sharpness is adjusted to increase, the contour is Equipped with a control circuit that further increases the amount of compensation for the sync signal and a sync signal detection circuit,
1. A contour compensating device, characterized in that the contrast voltage is lowered only when the contour compensation amount is reduced. (4) The contour compensation device according to claim 3, further comprising a circuit that lowers the sharpness voltage to reduce the amount of contour compensation only when the synchronization signal is "absent." (5) The contour compensation device according to claim 3, comprising a circuit that lowers both the contrast voltage and the sharpness voltage at the same time to make the contour compensation amount smaller only when the synchronization signal is “absent”. .