JP2004186765A - Television receiver, image display apparatus, method for controlling beam current of image display apparatus, and method for measuring maximum x-ray radiant quantity of image display apparatus - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To solve a problem of a time-consuming work attended with trial and error wherein an X-ray radiant quantity is measured by changing the luminance adjustment until the beam current becomes maximum. <P>SOLUTION: An image display apparatus is provided with: a high voltage generating means for generating a high voltage; and an image display means for receiving an image adjustment value to make the brightness of an image adjustable, applying prescribed color signal processing to the image for adjusting the brightness of an output image, and supplying a beam current to a picture tube on the basis of the generated high voltage to display the image whose brightness is adjusted by the color signal processing, the current amount of the beam current supplied to the picture tube 22 is detected, the image adjustment value is decided to maximize the current amount of the beam current supplied to the picture tube 22 on the basis of the detected current amount of the beam current, and the decided image adjustment value is outputted to the display means. Thus, the work for measuring the maximum X-ray radiant quantity can be facilitated. <P>COPYRIGHT: (C)2004,JPO&NCIPI

Description

[0001]
TECHNICAL FIELD OF THE INVENTION
The present invention is directed to a television, a video display device, a beam current control method for a video display device, and a video display device that display a video by generating a high voltage and passing a beam current to a picture tube based on the generated high voltage. The present invention relates to a method for measuring a maximum X-ray radiation amount.
[0002]
[Prior art]
Conventionally, a television shown in FIG. 10 has been known as this type of video display device. In the figure, a television 1 includes a microcomputer 11, a tuner IC 12, a chroma IC 13, a rectifier circuit 17, a color signal processing circuit 21, a picture tube 22, a flyback transformer (FBT) 27, an X-ray protection circuit 30, a power supply circuit 40, and the like. It has. The chroma IC 13 receives the intermediate frequency signal converted from the television broadcast signal and generates a video signal. The microcomputer 11 outputs a brightness adjustment value (Bright adjustment value), a contrast adjustment value (Contrast adjustment value), and a cutoff adjustment value (Cutoff adjustment value) that enable adjustment of brightness, contrast, and cutoff to the chroma IC 13. The chroma IC 13 receives these adjustment values and generates a luminance signal, a contrast signal, and a cutoff signal. The chroma IC 13 adjusts a luminance signal based on the beam current signal input from the FBT 27 via the rectifier circuit 17. These signals generated by the chroma IC 13 are input to the color signal processing circuit 21, where predetermined color signal processing is performed on the video signal. The picture tube 22 displays an image corresponding to the image signal on which the color signal processing has been performed by flowing a beam current based on the high voltage input from the FBT 27 on a predetermined tube surface. The X-ray protection circuit 30 stops supplying the high voltage to the picture tube 22 when the high voltage becomes equal to or higher than the predetermined voltage. The power supply circuit 40 generates a DC reference voltage, and the FBT 27 generates a high voltage substantially proportional to the reference voltage.
Further, as shown in FIG. 11, the power supply circuit 40 is connected to the semi-fixed resistor 2 that can change the magnitude of the reference voltage generated by the power supply circuit 40.
[0003]
In order to prevent the X-ray dose radiated from the picture tube 22 from exceeding an allowable amount, the maximum X-ray radiation amount is measured by sampling inspection when the television is shipped. The amount of X-ray radiation from the picture tube 22 increases as the high voltage increases, and increases as the beam current flowing through the picture tube 22 increases. Note that, as the amount of the beam current increases, the potential of the high voltage decreases. Therefore, as shown in FIG. 4, when the brightness adjustment value to be written to the chroma IC 13 is increased, the amount of the beam current peaks (maximum). ) Is present.
Therefore, when measuring the maximum X-ray radiation amount, a personal computer (PC) for shipment inspection is connected to the television 1, and first, the reference voltage is increased by turning the semi-fixed resistor 2 by an operator. Then, the high voltage is increased to a voltage immediately before the X-ray protection circuit operates. Next, write the luminance adjustment value directly from the PC for shipping inspection to the chroma IC 13 while gradually increasing the luminance adjustment value, and measure the X-ray radiation amount by holding the measuring unit of the X-ray radiation measurement device on the surface of the picture tube. The maximum X-ray radiation amount was defined as the maximum X-ray radiation amount.
[0004]
By storing the limit value of the operation parameter of the cathode ray tube corresponding to the limit of the amount of allowable X-ray generation by the cathode ray tube and keeping the operation parameter of the cathode ray tube lower than the same limit value, the X-ray generation from the cathode ray tube can be performed. A device for limiting the amount is also known (for example, see Patent Document 1).
A high-potential threshold and a low-potential threshold are set in accordance with the outputs of the beam current detection circuit and the X-ray detection circuit, and when the output potential of these circuits reaches both thresholds. There is also known a control circuit that outputs a control output signal indicating a change in output (see, for example, Patent Document 2).
[0005]
[Patent Document 1]
JP-A-5-244544
[Patent Document 2]
JP-A-8-340501
[0006]
[Problems to be solved by the invention]
In the above-mentioned conventional technology, since the point at which the beam amount of the above-mentioned beam current peaks differs from one another, the amount of X-ray radiation is measured while changing the brightness adjustment value until the amount of beam current becomes the maximum. This required work involving trial and error, and the work was time-consuming.
Note that the techniques disclosed in Patent Literature 1 and Patent Literature 2 do not create conditions that enable measurement of the maximum X-ray radiation amount, and thus cannot solve the above problem.
[0007]
The present invention has been made in view of the above problems, and has a television, a video display device, a beam current control method for a video display device, and a video display device capable of facilitating a task of measuring a maximum X-ray radiation amount. The purpose of the present invention is to provide a method for measuring the maximum amount of X-ray radiation.
[0008]
[Means for Solving the Problems]
In order to achieve the above object, in the invention according to claim 1, a current change amount of the beam current with respect to a change amount of the brightness adjustment value is larger than a current change amount of the beam current with respect to a change amount of the contrast adjustment value. The microcomputer has an A / D converter that inputs a voltage corresponding to the beam current signal and converts the voltage into a digital current value, and acquires a digital beam current value from the converted current value. The brightness adjustment value is output to the chroma IC while increasing the brightness adjustment value that has been set in a stepwise manner, and a brightness adjustment value that maximizes the obtained beam current value is determined. While changing the contrast adjustment value, which is a stepwise value, while outputting to the IC, the beam is output to the chroma IC and the acquired beam current value is minimized. Is determined, and the determined contrast adjustment value is output to the chroma IC, whereby the beam current is adjusted to a current amount at which the maximum amount of X-ray radiation from the picture tube can be measured. Perform control.
[0009]
The high voltage, which decreases as the beam current flowing through the picture tube increases, is generated by a flyback transformer. The beam current flows through the picture tube based on the high voltage, and an image corresponding to the video signal on which the color signal processing has been performed is displayed on the tube surface of the picture tube. Since the current change amount of the beam current with respect to the change amount of the brightness adjustment value is set to be larger than the current change amount of the beam current with respect to the change amount of the contrast adjustment value, the microcomputer first sets the brightness to a stepwise value. By increasing the adjustment value and roughly increasing the digital beam current value, the brightness adjustment value at which the beam current value becomes the largest is determined. Next, the contrast adjustment value that maximizes the beam current value is determined while finely changing the digital beam current value by changing the stepwise contrast adjustment value. Since the digital beam current value is approximately proportional to the amount of beam current flowing through the picture tube (hereinafter, also simply referred to as beam current amount), the beam current is automatically set to the maximum value in the picture tube. Flows, and the maximum amount of X-ray radiation from the picture tube can be measured. As described above, when there is a peak in the beam current amount, it is not necessary to perform trial and error to maximize the beam current amount, and the operation of measuring the maximum X-ray radiation amount can be facilitated.
In addition, the beam current amount changes roughly according to the brightness adjustment value to be in a state close to the maximum, and the beam current amount changes finely according to the contrast adjustment value to be surely at the maximum state. Therefore, it is possible to accurately measure the maximum amount of X-ray radiation. In addition, since such optimal conditions can be automatically created, it is possible to quickly measure the maximum X-ray radiation amount.
[0010]
By the way, the present invention can be applied to various video display devices used other than the television. Therefore, a second aspect of the present invention provides a high voltage generating means for generating a high voltage, and a predetermined color signal processing for adjusting the brightness of an output image by inputting an image adjustment value capable of adjusting the brightness of the image. Image display means for displaying an image whose brightness has been adjusted by the same color signal processing by flowing a beam current through a picture tube based on the generated high voltage, and a current of the beam current flowing through the picture tube Beam current detecting means for detecting the amount of the beam current, and the image adjustment value is determined based on the detected amount of the beam current so as to maximize the amount of the beam current flowing through the picture tube. Beam current control means for outputting an adjustment value to the image display means.
[0011]
That is, the high voltage is generated by the high voltage generation means. When an image adjustment value enabling the brightness of an image to be adjusted is input to the image display means, predetermined color signal processing for adjusting the brightness of the output image is performed. When the image display means applies a beam current to the picture tube based on the high voltage, an image whose brightness has been adjusted by color signal processing is displayed in the picture tube. The beam current amount is detected by the beam current detecting means. Then, based on the detected beam current amount, the image adjustment value is determined by the beam current control unit so that the amount of the beam current flowing through the picture tube is maximized, and the determined image adjustment value is determined by the image display unit. Is output to As a result, the amount of beam current flowing through the picture tube is maximized. Then, the beam current automatically flows through the picture tube so as to maximize the current amount, so that the maximum amount of X-ray radiation from the picture tube can be measured.
As described above, when there is a peak in the beam current amount, it is not necessary to perform trial and error to maximize the beam current amount, and the operation of measuring the maximum X-ray radiation amount can be facilitated.
[0012]
Here, as in the invention according to claim 3, the video display means receives the video adjustment value and generates a corresponding video control signal, and a video signal generation means based on the generated video control signal. Color signal processing means for performing the color signal processing for adjusting the brightness of the output image in accordance with the image adjustment value may be provided.
That is, the video signal generation unit generates a video control signal corresponding to a video adjustment value that enables the brightness of the video to be adjusted. When predetermined color signal processing for adjusting the brightness of the output video according to the video adjustment value is performed by the color signal processing means, the output video is adjusted based on the video control signal. When the picture tube sends a beam current based on the high voltage, an image whose brightness has been adjusted by color signal processing is displayed. Based on the beam current detected by the beam current detector, the image adjustment value is determined by the beam current controller so that the beam current is maximized. The determined video adjustment value is output to the video signal generation means.
Therefore, the beam current can be adjusted by using the general-purpose means used for television so that the amount of current is maximized by the video adjustment value.
[0013]
Incidentally, the image adjustment value is composed of first and second image adjustment values that are stepwise values, and the current change amount of the beam current with respect to the change amount of the first image adjustment value is the same as the second image adjustment value. The current change amount of the beam current with respect to the change amount of the image adjustment value is larger than the current amount of change of the beam current, and the image signal generating unit generates the first image control signal by inputting the first image adjustment value, The second adjustment value is input to generate a second video control signal, and the color signal processing unit performs the color signal processing based on the generated first and second video control signals, The beam current control means outputs to the video signal generation means while increasing the stepwise first video adjustment value, and outputs the beam current detected by the beam current detection means. The first movie with the largest amount After determining the adjustment value, the video signal generation is performed while changing the second video adjustment value, which is the stepwise value, while the determined first video adjustment value is output to the video signal generation means. A second image adjustment value that outputs a maximum amount of the beam current detected by the beam current detection unit and outputs the determined second image adjustment value to the image signal generation unit. May be output.
[0014]
The image adjustment value is composed of first and second image adjustment values that are stepwise values, and the current change amount of the beam current with respect to the change amount of the first image adjustment value is the second image adjustment value. The beam current control means first increases the beam current amount by increasing the stepwise first image adjustment value because the beam current control amount is larger than the current change amount of the beam current with respect to the change amount of the beam current. And the first image adjustment value at which the beam current amount becomes the largest. Next, the second image adjustment value that maximizes the beam current amount is determined while finely changing the beam current amount by changing the stepwise second image adjustment value.
That is, it is possible to create an optimum condition for measuring the maximum X-ray radiation amount by accurately maximizing the beam current amount, and thus to more accurately measure the maximum X-ray radiation amount. In addition, since such optimal conditions can be automatically created, it is possible to quickly measure the maximum X-ray radiation amount.
[0015]
It should be noted that a case where the image adjustment value is composed of three or more image adjustment values that are stepwise values is also included in the invention described in claim 4. For example, when the current change amount of the beam current with respect to the change amount of the second image adjustment value is larger than the current change amount of the beam current with respect to the change amount of the third image adjustment value, Generates the third video control signal by inputting the third video adjustment value, and the color signal processing means performs the color image processing on the basis of the generated first, second, and third video control signals. Performs color signal processing, the beam current control means determines a second image adjustment value at which the current amount of the beam current detected by the beam current detection means is the largest, and determines the determined second image adjustment value Is output to the video signal generation means while changing the third video adjustment value, which is the stepwise value, while being output to the video signal generation means, and is detected by the beam current detection means. Of the beam current Flow rate determines the third image adjustment value becomes maximum, a third image adjustment value may be output to the video signal generating means determined.
[0016]
Here, it may be configured as in the invention according to claim 5. Suitable specific examples of the first and second (first and second) image adjustment values and the first and second image control signals can be provided.
Of course, the video adjustment value and the video control signal may have various configurations. For example, the second video adjustment value may be a cutoff adjustment value, and the second video control signal may be a cutoff signal.
[0017]
In the invention according to claim 6, the beam current control means first increases the digital beam current value by roughly increasing the first image adjustment value which is a stepwise value, while maintaining the beam current value. The largest video adjustment value is determined. Next, while changing the digital beam current value finely by changing the stepwise second image adjustment value, the second image adjustment value that maximizes the beam current value is determined. Since the digital beam current value is substantially proportional to the beam current amount, it is possible to automatically create an optimum condition for accurately maximizing the beam current amount and measuring the maximum X-ray radiation amount.
[0018]
The video signal generating means receives the intermediate frequency signal converted from the television signal to generate a video signal, and outputs the first video control signal corresponding to the first video adjustment value to the beam current. A chroma IC that is generated while adjusting based on the signal, wherein the color signal processing means adjusts the color signal with respect to the video signal so as to adjust an output video based on the first and second video control signals. The configuration may be a color signal processing circuit that performs processing.
[0019]
Further, as in the invention according to claim 7, the video signal generating means generates the first video control signal corresponding to the first video adjustment value while adjusting the first video control signal based on the beam current signal. An IC, wherein the high-voltage generating means generates a substantially pulsed pulsed beam current signal whose integral value is substantially proportional to the current amount of the beam current, and rectifies the pulsed beam current signal. And a rectifier circuit for generating the beam current signal. Here, the substantially pulse shape includes not only a square wave but also a half wave or the like consisting only of a positive potential component of a sine wave. Even with these configurations, it is possible to more accurately and quickly measure the maximum X-ray radiation amount using a general-purpose configuration of a television.
Note that, other than the flyback transformer, a high voltage may be generated from the reference voltage using a predetermined high voltage generation circuit.
[0020]
Here, as in the invention according to claim 8, the rectifier circuit includes a capacitor interposed between the flyback transformer and the ground, and one end of the capacitor on the flyback transformer side and the chroma IC. The A / D converter includes an intervening resistor circuit, and the A / D converter converts the voltage between both ends of the resistor circuit into a digital current value, and the beam current control means converts the voltage between both ends of the resistor circuit. The difference between the digital current values may be used as the beam current value. A digital beam current value can be obtained using a rectifier circuit having a simple configuration.
[0021]
According to the ninth aspect of the present invention, when a beam current having a maximum measurable amount of X-ray radiation is flowing through the picture tube, the fact can be known. The convenience is improved during the work of measuring the measurement.
Here, various configurations for outputting the above-mentioned facts are conceivable. For example, the above-mentioned facts may be output by displaying on a picture tube, or the above-mentioned facts may be output by audio output from a speaker.
[0022]
By the way, the above-mentioned television and the video display device may be used independently, or may be used in a state of being incorporated in another device.
In the method of controlling the beam current amount so as to maximize the beam current amount, the process is performed according to a predetermined procedure, and an invention exists in the procedure at the root thereof. Therefore, a tenth aspect of the present invention provides a high voltage generating means for generating a high voltage, and a predetermined color signal processing for inputting an image adjustment value enabling the brightness of an image to be adjusted and adjusting the brightness of an output image. Image display means for displaying an image whose brightness has been adjusted by the same color signal processing by flowing a beam current to a picture tube based on the high voltage generated by the high voltage generation means. A beam current control method for an apparatus, comprising detecting a current amount of a beam current flowing through the picture tube, and maximizing a current amount of the beam current flowing through the picture tube based on the detected current amount of the beam current. The video adjustment value is determined, and the determined video adjustment value is output to the video display means.
[0023]
Further, there is an invention in a method of measuring the maximum X-ray radiation using the above-mentioned television and video display device. Therefore, according to the present invention, there is provided a high voltage generating means for generating a high voltage, and a predetermined color signal processing for adjusting a brightness of an output video by inputting a video adjustment value enabling the brightness of the video to be adjusted. Image display means for displaying an image whose brightness has been adjusted by the same color signal processing by flowing a beam current to a picture tube based on the high voltage generated by the high voltage generation means. A method of measuring a maximum X-ray radiation amount of an apparatus, wherein the image display device detects a current amount of a beam current flowing through the picture tube, and flows the current through the picture tube based on the detected current amount of the beam current. The image adjustment value is determined so as to maximize the amount of beam current, the determined image adjustment value is output to the image display means, and the amount of beam current flowing through the picture tube is maximized. Video decided on When the integer value is output to the image display means, the maximum radiation amount of X-rays from the picture tube is measured using an X-ray radiation amount measuring device capable of measuring X-ray radiation amount. is there.
That is, the present invention is also applicable to a beam current control method of an image display device and a maximum X-ray radiation amount measuring method of an image display device. The device configuration according to claims 1, 3 to 9 is applicable. It is also possible to correspond to the method.
[0024]
【The invention's effect】
According to the first aspect of the present invention, the operation of measuring the maximum X-ray radiation amount can be facilitated, and the maximum X-ray radiation amount can be accurately and quickly measured.
According to the second, tenth, and eleventh aspects of the present invention, it is possible to easily perform the operation of measuring the maximum X-ray radiation amount.
According to the third aspect of the present invention, it is possible to adjust the beam current flowing through the picture tube with a simple configuration by using the video adjustment value so that the current amount is maximized.
According to the invention according to claim 4, it is possible to more accurately and quickly measure the maximum X-ray radiation amount.
According to the fifth aspect of the present invention, it is possible to easily adjust the beam current flowing through the picture tube so as to maximize the current amount by using a general-purpose configuration of the television.
[0025]
According to the sixth and seventh aspects of the present invention, it is possible to more accurately and quickly measure the maximum X-ray radiation amount using a general-purpose configuration of a television.
According to the invention of claim 8, it is possible to acquire a digital beam current value with a simple configuration.
According to the ninth aspect of the present invention, convenience can be improved when measuring the maximum X-ray radiation amount.
[0026]
BEST MODE FOR CARRYING OUT THE INVENTION
Hereinafter, embodiments of the present invention will be described in the following order.
(1) Configuration of television:
(2) Equipment used for measuring the maximum X-ray radiation:
(3) Operation of television and method of measuring maximum X-ray radiation amount:
(4) Summary:
[0027]
(1) Configuration of television:
FIG. 1 is a schematic block diagram of a configuration of a television (video display device) 100 according to an embodiment of the present invention. The operation panel and the like are not shown.
In the figure, a television 100 is a broadcast receiving apparatus, which is an IIC bus interface (I / F) 10a connected to an IIC bus 10, a microcomputer 11, a tuner IC 12, a chroma IC 13, an EEPROM 16, a remote control receiver 14, a remote control transmitter Machine 15, a rectifier circuit 17, and the like. An antenna 12a is connected to the tuner IC12. The chroma IC (video signal generating means) 13 is directly connected to the on-screen display circuit (OSD) 11 d of the microcomputer 11 and the tuner IC 12 in addition to the IIC bus 10. The remote control receiver 14 is directly connected to the microcomputer 11. When the operator operates an operation key of the remote control transmitter 15, the remote control transmitter 15 transmits an infrared remote control signal corresponding to the operation content, and the remote control receiver 14 receives the remote control signal.
The microcomputer 11 includes a CPU 11a, a ROM 11b, a RAM 11c, an OSD 11d, A / D converters 11e and f, a timer circuit (not shown), and the like for performing various controls. Then, in accordance with a remote control signal input from the remote control receiving unit 14, the entire television 100 is controlled by serial data communication.
[0028]
Devices such as the microcomputer 11, the ICs 12, 13 and the flyback transformer (FBT) 27 are supplied with a plurality of potential DC reference voltages from the power supply circuit 40, and these devices operate using the same reference voltages. It has become. An X-ray protection circuit 30 is connected to the power supply circuit 40. The high-potential reference voltage (E1) is equal to or higher than a predetermined voltage so that the X-ray radiation from the picture tube (CRT) 22 does not exceed an allowable amount. In such a case, the power supply circuit 40 stops generating the reference voltage. Further, a reset circuit 31 is connected to the X-ray protection circuit 30. When the X-ray protection circuit 30 operates to stop the generation of the reference voltage in the power supply circuit 40, a reset signal is sent to the microcomputer 11. It operates to output and reset each part of the television 100.
[0029]
The tuner IC 12 is a tuner of a frequency synthesizer system. The tuner IC 12 receives a television broadcast signal (a kind of television signal) as a broadcast wave from the antenna 12 a under the control of the microcomputer 11, and converts it into an intermediate frequency signal (IF). Output. Although not shown, a television signal can be input from an external input terminal, converted to an intermediate frequency signal, and output. The tuner IC 12 includes a high frequency amplifier circuit connected to the microcomputer 11, an intermediate frequency signal output circuit connected to the high frequency amplifier circuit and the microcomputer 11, and the like. The intermediate frequency signal output circuit includes a local oscillation circuit connected to the microcomputer 11, and a mixing circuit connected to the local oscillation circuit and the high frequency amplifier circuit. Note that these circuits can be applied to various television circuits that have been conventionally used.
[0030]
The high-frequency amplifier circuit has a band-pass filter, and receives a broadcast wave corresponding to a desired frequency from the antenna 12a via the band-pass filter under the control of the microcomputer 11, and amplifies to generate a high-frequency signal. And outputs it to the mixing circuit. The local oscillation circuit is constituted by a PLL (Phase Locked Loop) circuit, and based on a reference oscillation signal from a crystal oscillation circuit, a local oscillation signal having a local oscillation frequency corresponding to a desired frequency of a broadcast radio wave by the PLL circuit. Create and output to the mixing circuit. The mixing circuit mixes the output from the high-frequency amplifier circuit and the local oscillation signal from the local oscillation circuit, converts the mixed signal into an intermediate frequency signal, and outputs the intermediate frequency signal to the chroma IC 13.
[0031]
The chroma IC 13 is generally configured as shown in FIG. 2, and performs various signal processing. The chroma IC 13 is a one-chip IC, and demodulates an RGB signal and a Y signal according to an intermediate frequency amplification (VIF) circuit 13a, a detection circuit 13b, a synchronization circuit 13c, a burst signal detection unit 13d, a PAL system, a SECAM system, and the like. It comprises a demodulation unit 13e, a video control signal generation unit 13f, and the like.
The intermediate frequency signal from the tuner IC 12 is input to the VIF circuit 13a. The VIF circuit 13a amplifies the intermediate frequency signal by an intermediate frequency and outputs the amplified signal to the detection circuit 13b. A VCO (Voltage Controlled Oscillator) circuit (not shown) is connected to the detection circuit 13b. The VCO circuit oscillates an oscillation signal based on a reference oscillation signal input from the crystal oscillation circuit and outputs the oscillation signal to the detection circuit 13b.
[0032]
The detection circuit 13b performs video detection while synchronizing with the oscillation frequency of the oscillation signal from the intermediate frequency signal amplified by the intermediate frequency, separates the composite video signal, and outputs it to the burst signal detection unit 13d. As for the audio signal, a second audio intermediate frequency signal is created by mixing the audio component and the oscillation signal in the intermediate frequency signal amplified by the intermediate frequency, and is subjected to FM detection to be an AUDIO signal, which is output to the outside. I do. Further, the detection circuit 13b also generates a horizontal / vertical synchronization signal (SYNC) based on the oscillation frequency of the oscillation signal during the detection process and outputs the signal to the synchronization circuit 13c. The synchronization circuit 13c creates a sawtooth DRIVE signal based on the input horizontal and vertical synchronization signals, and outputs the signal to a deflection circuit 25 including a horizontal deflection circuit and a vertical deflection circuit. At this time, processing is performed based on a signal input from the video control signal generation unit 13f.
Note that various television circuits conventionally used can be applied to the respective units 13a to 13f.
[0033]
The burst signal detection unit 13d to which the composite video signal from the detection circuit 13b is input determines whether the burst signal in the composite video signal has a constant frequency and determines whether the burst signal has a constant frequency. Is output to the demodulation unit 13 e and the microcomputer 11. When the burst signal has a constant frequency, the television broadcast signal is in the PAL system, and when the burst signal is not a constant frequency, the television broadcast signal is in the SECAM system.
[0034]
The demodulation unit 13e performs a predetermined color demodulation process corresponding to a broadcasting method on the input composite video signal, and outputs an RGB signal (video signal) and a Y signal (luminance signal, first video control signal). Circuit. Specifically, after separating the Y signal and the carrier chrominance signal, a subcarrier is generated from the burst signal, and the carrier chrominance signal is appropriately demodulated by the subcarrier to obtain a color difference signal. At this time, processing is performed based on a signal representing a luminance adjustment value input from the video control signal generation unit 13f. An RGB signal is generated from the color difference signal and the Y signal, and output to the color signal processing circuit 21.
[0035]
The video control signal generation unit 13f holds the digital brightness adjustment value (first video adjustment value), contrast adjustment value (second video adjustment value), and cutoff adjustment value input from the microcomputer 11, and demodulates the demodulation unit. 13e and a synchronizing circuit 13c, and outputs a contrast signal (second video control signal) to the color signal processing circuit 21 and a cutoff signal to the picture tube 22. is there.
Here, the brightness adjustment value, the contrast adjustment value, and the cutoff adjustment value are digital values that are stepwise values within a predetermined range in which the brightness, contrast, and cutoff of the output video can be adjusted, respectively. This is a value that allows the brightness of the output video to be adjusted. Therefore, according to the instruction from the microcomputer 11, it is possible to adjust the brightness of the image displayed on the picture tube 22 while adjusting the RGB signal and various image control signals (Y signal, contrast signal, cutoff signal) for each broadcasting system. it can.
The chroma IC 13 is connected to the OSD 11d, and can superimpose the OSD signal input from the OSD 11d on the RGB signal.
[0036]
The color signal processing circuit (color signal processing means) 21 performs predetermined color signal processing on the RGB signals so as to adjust the brightness (luminance and contrast) of the output image, and the RGB signals amplified as a result of the processing. Is supplied to the picture tube 22. Then, the picture tube 22 performs screen display based on the RGB signals whose brightness (brightness and contrast) has been adjusted. On the other hand, the audio amplifier 23 amplifies the AUDIO signal and supplies it to the speaker 24. Then, the speaker 24 outputs a sound based on the amplified AUDIO signal.
The deflection circuit 25 generates a predetermined horizontal / vertical drive current corresponding to the horizontal / vertical drive signal and supplies it to the deflection coil 26 attached to the picture tube 22 to drive the electron beam in the horizontal / vertical direction. . The high-frequency signal generated in the horizontal deflection circuit is supplied to the FBT 27. The FBT 27 receives a high-potential reference voltage and generates a high voltage (cathode voltage) to be supplied to the picture tube 22.
Then, the picture tube 22 emits an electron beam corresponding to the RGB signal toward a predetermined tube surface based on the high voltage. As a result, an image appears on the tube surface of the picture tube 22.
The chroma IC 13, the color signal processing circuit 21, the picture tube 22, the deflecting circuit 25 and the deflecting coil 26 constitute an image display means.
[0037]
The color signal processing circuit 21 performs a predetermined color signal processing on the RGB signal so as to adjust the contrast of the output image based on the contrast signal that enables the contrast of the output image to be adjusted. A luminance adjustment unit 21b that performs predetermined color signal processing on the RGB signals so as to adjust the luminance of the output image based on the Y signal (luminance signal) that enables the luminance of the video to be adjusted. The contrast adjuster 21a performs a process of finely adjusting the RGB signals so as to adjust the contrast of the output video by, for example, slightly shifting the timing of each RGB signal. At that time, the brightness of the output video changes slightly. For example, when the Y signal changes so as to increase the luminance, the luminance adjusting unit 21b performs a process of increasing the intensity of each of the RGB signals.
[0038]
The picture tube 22 receives the high voltage generated by the FBT 27 and supplies a beam current based on the high voltage, so that an image corresponding to the RGB signal on which the color signal processing is performed by the color signal processing circuit 21 is displayed. Display on the surface.
The FBT 27 that generates the high voltage has a property of decreasing as the beam current amount increases. Further, a pulse-like beam current signal having a substantially pulse shape corresponding to the beam current amount is generated and supplied to the rectifier circuit 17.
The upper part of FIG. 3 shows a time change of the voltage of the pulsed beam current signal S1. Here, the horizontal axis is the time axis, and the vertical axis is the voltage axis. The vertical axis also represents the current amount of the signal S1. As shown in the figure, the pulsed beam current signal S1 has a half-wave shape composed of only a positive current component from which a negative current component has been cut. Note that the voltage (current amount) change is close to the upper half of the sine wave, but such a signal is also included in a substantially pulse shape according to the present invention. It goes without saying that a square wave is also included in a substantially pulse shape.
The integrated value of the voltage (and the current amount) of the pulsed beam current signal S1 with respect to time is substantially proportional to the current amount of the beam current flowing through the picture tube 22.
[0039]
The rectifier circuit 17 includes a capacitor C1 interposed between the FBT 27 and the ground, and a resistor circuit R1 interposed between one end of the capacitor C1 on the FBT 27 side and the chroma IC 13. The pulsed beam current signal output from the FBT 27 is smoothed by the capacitor C1, the amount of current is limited by the resistor circuit R1, is converted into a substantially DC-shaped beam current signal, and is input to the chroma IC 13. Thus, the rectifier circuit 17 rectifies the pulsed beam current signal generated by the FBT 27 to generate a beam current signal.
The lower part of FIG. 3 shows the time change of the voltage of the beam current signal S2, and the pulsed beam current signal S1 is indicated by a dotted line. Here, the horizontal axis is the time axis, and the vertical axis is the voltage axis. The vertical axis also represents the current amount of the signal S2. As shown in the figure, the beam current signal S2 has a substantially DC shape. Since the integral value of the voltage (and the current amount) of the pulsed beam current signal S1 with respect to time is substantially proportional to the voltage (and the current amount) of the beam current signal S1, the voltage (and the current amount) of the beam current signal S2 is obtained. ) Is approximately proportional to the beam current.
Note that the FBT 27 and the rectifier circuit 17 constitute a high voltage generation unit.
[0040]
The chroma IC 13 which receives the intermediate frequency signal converted from the television broadcast signal and generates an RGB signal, receives a luminance adjustment value from the microcomputer 11, generates a corresponding Y signal, and inputs a contrast adjustment value to respond. And outputs a cutoff adjustment value to generate a corresponding cutoff signal. These video adjustment values are stepwise digital values (for example, integer values from 0 to 255 to which 8 bits are assigned).
The Y signal is generated while adjusting the brightness of the output image based on the current amount of the beam current signal input from the rectifier circuit 17.
[0041]
The microcomputer 11 can output various video adjustment values to the chroma IC 13. These video adjustment values are stored in an EEPROM 16 which is a nonvolatile memory in which data to be stored can be rewritten. Each video adjustment value is slightly different for each television 100, and is set for each television 100. The microcomputer 11 can acquire each video adjustment value from the EEPROM 16 via the IIC bus 10 and write each video adjustment value to the chroma IC 13 via the IIC bus 10.
[0042]
By the way, when a television product is shipped, the maximum amount of X-ray radiation is measured by sampling inspection. However, the amount of X-ray radiation emitted from the tube surface of the picture tube 22 outputting an image increases as the high voltage increases. In addition, the larger the beam current flowing through the picture tube 22, the larger the beam current. Since the high voltage generated by the FBT 27 has the property of decreasing as the beam current amount increases, there is a point where the beam current amount peaks when the luminance adjustment value written to the chroma IC 13 is increased. I do.
[0043]
FIG. 4 is a graph showing the relationship between the luminance adjustment value written to the chroma IC and the beam current amount. Actually, since the brightness adjustment value is a stepwise value, the beam current amount also changes stepwise. In the figure, the curve is shown for easy explanation. In the present embodiment, when the brightness adjustment value is relatively small, the beam current amount increases as the brightness adjustment value increases, but as the brightness adjustment value decreases, the beam current amount decreases as the brightness adjustment value increases. It is also possible to design such that the beam current amount increases. In the case of a television having such a design, the axis of the luminance adjustment value is merely in a direction opposite to that in FIG. 4 (the luminance adjustment value becomes smaller as it goes to the right side), and the present invention is applicable. It is.
As shown in the figure, there is a point P1 at which the beam current amount becomes maximum with respect to the brightness adjustment value, and when the brightness adjustment value is smaller than the ideal brightness adjustment value A1 corresponding to the point P1, the brightness adjustment value becomes smaller. The beam current increases as the value increases, and when it is larger than the brightness adjustment value A1, the beam current decreases as the brightness adjustment value increases. Conventionally, when measuring the maximum amount of X-ray radiation, a PC for shipping inspection is connected to the television, and first, an operator turns a semi-fixed resistor connected to the power supply circuit 40, thereby obtaining an X-ray protection circuit. After increasing the high voltage to the voltage immediately before the operation, the PC is directly written to the chroma IC while increasing the brightness adjustment value little by little from the shipping inspection PC, and the X-ray radiation amount is measured each time. The resulting X-ray radiation amount was defined as the maximum X-ray radiation amount. However, since the peak points P1 differ one by one, a time-consuming and cumbersome operation of measuring the amount of X-ray radiation while changing the brightness adjustment value until the beam current amount is maximized was required.
The television 100 obtains a beam current value corresponding to the beam current amount, and automatically controls the beam current value to be exactly the maximum, thereby facilitating the work of measuring the maximum X-ray radiation amount. This enables accurate and quick measurement of the maximum X-ray radiation amount.
[0044]
The microcomputer 11 has an A / D converter 11e connected to a connection portion of the resistor circuit R1 to the capacitor C1 and a connection portion of the resistor circuit R1 to the chroma IC 13 for detecting a voltage at both ends of the resistor circuit R1. The connected A / D converter 11f is provided. The A / D converter 11e receives a voltage (referred to as V1) of a current smoothed by the capacitor C1 from the pulsed beam current signal and converts the signal into a digital current value. On the other hand, the A / D converter 11f inputs a voltage (V2) dropped by flowing the smoothed current through the resistance circuit R1 (the resistance value is represented by R1) and converts the voltage into a digital current value. The current amount i1 of the beam current signal flowing through the chroma IC 13 is represented by the following equation.
i1 = (V1-V2) / R1 (1)
Since the resistance value R1 does not change, the difference between the two digital current values converted by the A / D converters 11e and 11f can be used as the digital beam current value substantially proportional to the beam current amount.
As described above, the A / D converters 11e and 11f receive the voltage across the resistor circuit, that is, the voltage corresponding to the beam current signal generated by the rectifier circuit 17, and convert the voltage into a digital current value. Therefore, the microcomputer 11 converts the current value converted by the A / D converter into a digital beam current value with a simple configuration of detecting the voltage between both ends of the resistance circuit R1 interposed between the FBT 27 and the chroma IC 13. Can be obtained. Then, by controlling the brightness adjustment value and the contrast adjustment value to be written to the chroma IC 13, control is performed to adjust the beam current to a current amount at which the maximum radiation amount of X-rays from the picture tube can be measured.
[0045]
FIG. 5 is an enlarged view of the vicinity (P11) of the peak P1 in FIG. Each point in the figure indicates the beam current amount with respect to the value that the luminance adjustment value can take, and the dotted line curve connects the points. While the brightness adjustment value is a stepwise value (integer value) within a predetermined range, if the brightness adjustment value is changed one by one, the beam current amount greatly changes. Then, even if an attempt is made to maximize the beam current amount by changing the brightness adjustment value, in many cases, there is no ideal brightness adjustment value A1 for setting the point P1 at which the beam current amount becomes maximum. As a result, the brightness can be adjusted only to the brightness adjustment value A2 which is the point P2 at which the beam current amount becomes the largest among the possible values of the brightness adjustment value. The present invention is also effective by setting the beam current to a current amount corresponding to the point P2. However, in order to more accurately measure the maximum X-ray radiation amount, the beam current amount is set so as to be closer to the point P1. Preferably, it is adjusted.
[0046]
FIG. 6 plots the beam current amount with respect to the contrast adjustment value. Each point in the figure shows the beam current amount with respect to a value that the contrast adjustment value can take. In the present embodiment, when the contrast adjustment value is relatively small, the beam current amount increases as the contrast adjustment value increases, but as the contrast adjustment value decreases, the beam current amount increases as the contrast adjustment value increases. It is also possible to design such that the beam current amount increases. In the case of a television having such a design, the characteristic of the present invention is merely that the axis of the contrast adjustment value is set in the direction opposite to that of FIG. 6 (the contrast adjustment value decreases as the axis moves to the right). It is.
The contrast adjustment value is also a stepwise value (integer value) within a predetermined range, but the current change amount of the beam current with respect to the change amount of the contrast adjustment value is the current change amount of the beam current with respect to the change amount of the brightness adjustment value. Less than. Therefore, by changing the contrast adjustment value, the beam current amount can be changed from the point P2 to a point P1 'where the beam current amount becomes almost maximum, and the beam current amount becomes a point P1' closer to the ideal maximum. That is, there is a contrast adjustment value A3. As a result, when the contrast adjustment value is used, the beam current amount is adjusted so as to be closer to the point P1.
[0047]
(2) Equipment used for measuring the maximum X-ray radiation:
For adjustment and inspection at a television manufacturing factory, an IIC bus I / F 10a is connected to the IIC bus 10 of the television, and the television 100 can be connected to a PC.
FIG. 7 shows equipment used for measuring the maximum X-ray radiation amount together with the television.
In the figure, the tube surface 22 a of the picture tube 22 is arranged so as to be in front of the television 100. In the figure, an IIC bus I / F 10a is provided at the lower right of the television 100, and is connected to the shipping inspection PC 200 by the IIC bus cable 201 via the IIC bus I / F 10a. The PC 200 is connected to a display 202 as an output device, a keyboard 203 and a mouse 204 as input devices. When the PC 200 is connected to the IIC bus I / F 10a, the cable 201 is connected to the IIC bus I / F 10a after removing the rear cabinet 100a of the television. When a predetermined key operation is performed on the remote control transmitter 15 to set a so-called factory mode, the PC 200 can transmit various adjustment data to the television 100.
[0048]
Here, when an instruction to switch to the maximum X-ray radiation amount measurement mode is transmitted from the PC 200, the television 100 controls the high voltage so that the amount of beam current flowing through the picture tube 22 becomes maximum, which will be described later in detail. . When such control is being performed, the measuring unit 80a of the X-ray radiation measuring device 80 capable of measuring the amount of X-ray radiation is brought to be pressed against the tube surface 22a of the picture tube to receive the image. The maximum amount of X-ray emission from the tube 22 is measured.
[0049]
(3) Operation of television and method of measuring maximum X-ray radiation amount:
Hereinafter, the operation of the television according to the present embodiment will be described together with the procedure for measuring the maximum X-ray radiation amount.
First, the worker at the television manufacturing factory connects the inspection inspection PC 200 to the television 100 as shown in FIG. 7 and turns the semi-fixed resistor (not shown) connected to the power supply circuit 40 to the reference. The voltage is increased, and the high voltage is increased to a voltage immediately before the X-ray protection circuit operates. Next, a predetermined key operation for putting the television 100 into the factory mode is performed using the remote control transmitter 15, and a predetermined adjustment inspection program for the factory mode is activated on the PC 200 in advance. With the function of the adjustment inspection program, the PC 200 can receive an operation input for an instruction to set the maximum X-ray radiation measurement mode from the keyboard 203 or the like and transmit the instruction to the television 100. By inputting an operation for an instruction to set the maximum X-ray radiation dose measurement mode from the above, the instruction can be transmitted to the television 100. Then, when the television 100 obtains an instruction to set the maximum X-ray radiation amount measurement mode during the factory mode, the television 100 performs a control process for maximizing the amount of the beam current flowing through the picture tube 22. .
[0050]
The microcomputer 11 repeatedly performs a process of receiving an input of a remote control signal from the remote control transmitter 15 via the remote control reception unit 14. When a remote control signal corresponding to a key operation for setting a factory mode is input, a predetermined factory mode is input. When a flag is set and a remote control signal corresponding to a key operation for canceling the factory mode is input, the factory mode flag is reset. When the factory mode flag is set, the factory mode processing shown in FIGS. 8 and 9 is repeated. This process is performed by the CPU 11a of the microcomputer 11.
First, it is determined whether or not an instruction to enter the maximum X-ray radiation measurement mode has been input via the IIC bus I / F 10a (step S105; hereinafter, the description of “step” is omitted). If the instruction has not been input, this flow is terminated. Then, when this flow is started again, it is determined in S105 whether or not an instruction to enter the maximum X-ray radiation measurement mode has been input.
[0051]
When an instruction to enter the maximum X-ray radiation measurement mode is input, first, an initial value of a digital beam current value that is much smaller than the maximum value of the digital beam current value is set (S110). Next, the initial values of various image adjustment values (brightness adjustment value, contrast adjustment value, cutoff adjustment value) that enable the brightness of the output image to be adjusted are output to the chroma IC 13 (S115).
Then, the chroma IC 13 inputs these video adjustment values, which are stepwise values, and holds them in the video control signal generation unit 13f, generates a contrast signal corresponding to the contrast adjustment value, and corresponds to the cutoff adjustment value. And a Y signal corresponding to the brightness adjustment value is generated while adjusting based on the beam current signal input from the rectifier circuit 17. The color signal processing circuit 21 receives a contrast signal and a Y signal, and performs predetermined color signal processing on the RGB signals so as to adjust the contrast and brightness of an output image based on these signals. The picture tube 22 displays an image corresponding to the RGB signal subjected to the color signal processing for adjusting the brightness by flowing a beam current based on the high voltage input from the FBT 27 on the tube surface. The FBT 27 generates a pulsed beam current signal whose integral value is substantially proportional to the amount of beam current flowing through the picture tube 22. The rectifier circuit 17 rectifies the pulsed beam current signal to generate a beam current signal, and supplies the beam current signal to the chroma IC 13. As described above, the current amount of the beam current signal is substantially proportional to the beam current amount.
[0052]
The voltage across the resistor circuit R1 of the rectifier circuit is input to the A / D converters 11e and 11f and converted into digital current values. Therefore, in S120, digital current values are read from the A / D converters 11e and 11f, respectively. Next, by using the above equation (1), a digital beam current value is obtained from the read current value (S125). The acquired beam current value becomes a value substantially proportional to the beam current amount.
As described above, the processing in S120 to S125 constitutes a beam current detection unit that detects a beam current amount, together with the rectifier circuit 17 and the A / D converters 11e and f. Then, the beam current amount can be easily detected by using a general-purpose configuration of the television.
[0053]
Then, it is determined whether the beam current value has increased compared to the previous time, that is, whether the beam current value acquired this time is larger than the beam current value acquired last time (S130).
When the beam current value has increased from the previous time, the beam current amount has increased with the increase in the brightness adjustment value. Therefore, the current brightness adjustment value is the value A2 that maximizes the beam current amount in FIG. Or smaller. When the process of S130 is performed for the first time, the condition is always satisfied. In this case, the process proceeds to S135, where the brightness adjustment value is increased stepwise (1 or more), the increased brightness adjustment value is output to the chroma IC 13, and the process returns to S120. Therefore, the processing of S120 to S135 is repeatedly performed, and the output to the chroma IC can be performed while increasing the luminance adjustment value which is a stepwise value.
[0054]
On the other hand, if it is determined in S130 that the beam current value has not increased from the previous time, the beam current amount has not increased with the increase in the brightness adjustment value. The value that maximizes the amount will be A2 or greater. In this case, the process proceeds to S140, in which a brightness adjustment value at which the beam current value acquired in S125 is the largest is determined, and the determined brightness adjustment value is output to the chroma IC 13. Specifically, the brightness adjustment value output last time is determined. In this manner, the output is output to the chroma IC while increasing the brightness adjustment value, which is a stepwise value, and a digital beam current value is obtained from the current value converted by the A / D converter. The brightness adjustment value at which the beam current value becomes maximum can be determined. Here, when the beam current value becomes the largest, the beam current amount substantially proportional to the beam current value also becomes the largest. Therefore, while increasing the beam current amount roughly by increasing the stepwise value of the luminance adjustment value, the luminance adjustment value that maximizes the beam current amount is determined, and the determined luminance adjustment value is stored in the chroma IC. Output.
[0055]
Thereafter, the initial value of the digital beam current value, which is much smaller than the maximum value of the digital beam current value, is set again (S145). Next, an initial value of the contrast adjustment value that allows the contrast of the output video to be adjusted is determined, and the determined initial value of the contrast adjustment value is output to the chroma IC 13 (S150). For example, when the current change amount of the beam current when the contrast adjustment value is increased by 10 is equal to the current change amount of the beam current when the brightness adjustment value is increased by 1, the contrast adjustment value output in S115 is used. A value smaller by 10 is also set as the initial value of S150. In general, the initial value of S150 may be obtained by subtracting the increase value of the contrast adjustment value corresponding to the current change amount of the beam current increasing the brightness adjustment value by 1 from the contrast adjustment value output in S115.
When the initial value of the contrast adjustment value is output, digital current values are read from the A / D converters 11e and 11f (S155). Next, by using the above equation (1), a digital beam current value is obtained from the read current value (S160). That is, the processing of S150 to S160 also constitutes the beam current detecting means together with the rectifier circuit 17 and the A / D converters 11e and f.
[0056]
Then, it is determined whether the beam current value has increased compared to the previous time (S165).
When the beam current value has increased compared to the previous time, the beam current amount has increased with the increase in the contrast adjustment value. Therefore, the current contrast adjustment value is the value A3 that maximizes the beam current amount in FIG. Or smaller. When the process of S165 is performed for the first time, the condition is always satisfied. In this case, the process proceeds to S170, where the contrast adjustment value is increased stepwise (1 or 2 or more), the increased contrast adjustment value is output to the chroma IC 13, and the process returns to S150. Therefore, the processing of S155 to S170 is repeatedly performed, and the luminance adjustment value determined in S140 is output to the chroma IC while the contrast adjustment value, which is a stepwise value, is changed while changing the contrast adjustment value. Can be output.
[0057]
On the other hand, if it is determined in step S165 that the beam current value has not increased from the previous time, the beam current amount has not increased with respect to the increase in the contrast adjustment value. The value that maximizes the amount will be A3 or greater. In this case, the process proceeds to S175, and a contrast adjustment value at which the beam current value acquired in S160 is maximized is determined. Specifically, the contrast adjustment value output last time is determined. In this way, the output is output to the chroma IC while changing the stepwise contrast adjustment value, and a digital beam current value is obtained from the current value converted by the A / D converter, and the obtained value is obtained. The contrast adjustment value at which the beam current value becomes maximum can be determined. As described above, since the beam current amount is substantially proportional to the digital beam current value, by changing the stepwise contrast adjustment value, the beam current amount can be changed while finely changing the beam current amount. The maximum contrast adjustment value is determined, and the determined contrast adjustment value is output to the chroma IC. As described above, it is possible to perform control for maximizing the amount of beam current using a general configuration of a conventional television.
[0058]
In the present embodiment, after that, in order to inform the worker that the maximum X-ray radiation amount has become measurable, the maximum X-ray radiation amount from the picture tube 22 such as “XSENSE TECHNOLOGY” is measured. Is displayed on the picture tube 22 via the OSD 11d (S205). Further, predetermined audio data corresponding to prompting measurement of the maximum X-ray radiation amount is output to the chroma IC 13 and predetermined audio is output from the speaker 24 (S210). Therefore, when a beam current capable of measuring the amount of X-ray radiation is flowing through the picture tube, the fact can be known from the display or the audio output, which is convenient when measuring the maximum amount of X-ray radiation. is there.
[0059]
Therefore, the operator uses the X-ray radiation amount measuring device 80 to bring the measuring unit 80a against the tube surface 22a of the picture tube 22 and move the X-ray radiation amount while moving on the tube surface 22a. By reading the maximum value, the maximum amount of X-ray radiation from the picture tube 22 is measured. At this stage, since the contrast adjustment value at which the beam current value becomes maximum is output to the chroma IC 13, the television 100 sets the beam current to the maximum current capable of measuring the maximum radiation amount of X-rays from the picture tube. Control to adjust to the amount is performed. That is, the beam current is automatically passed through the picture tube so that the current amount becomes maximum, and the maximum X-ray radiation amount from the picture tube can be measured. Therefore, unlike the related art, there is no need to perform a work involving trial and error of inputting a brightness adjustment value from the shipping inspection PC while changing the beam current amount until the beam current amount becomes maximum, and measuring the X-ray radiation amount each time. The task of measuring the maximum X-ray radiation is facilitated.
[0060]
Thereafter, for example, by detecting whether or not the end key of the remote control transmitter 15 has been operated, it is determined whether or not the measurement of the maximum X-ray radiation amount has been completed (S215). This determination processing is repeatedly performed until the measurement of the maximum X-ray radiation amount is completed. Of course, it may be determined whether or not the measurement has been completed by using the timer circuit of the microcomputer 11 to determine whether or not a predetermined time has elapsed. If it is determined that the measurement has been completed, a predetermined video adjustment value is output to the chroma IC 13 in order to bring the various video adjustment values held by the chroma IC 13 into the initial state (S220), and this flow ends.
In the processing in S105 to S115, S130 to S150, and S165 to S220 described above, the video adjustment value is determined based on the detected beam current amount so as to maximize the amount of the beam current flowing through the picture tube, and the determination is made. Beam current control means for outputting the adjusted image adjustment value to the image display means.
[0061]
(4) Summary:
As described above, when the television and the video display device of the present invention are used, the beam current can be automatically supplied to the picture tube so that the current amount is maximized. When there is a peak, the trouble of maximizing the current amount of the beam current can be omitted, and the maximum X-ray radiation amount can be quickly measured. Further, the amount of the beam current flowing through the picture tube changes roughly according to the brightness adjustment value to be close to the maximum, and changes finely according to the contrast adjustment value to ensure the maximum state. Therefore, it is possible to accurately measure the maximum amount of X-ray radiation. In addition, since such optimal conditions can be automatically created, it is possible to quickly measure the maximum X-ray radiation amount.
[0062]
Various modifications are conceivable for the television and the video display device of the present invention.
In the above-described embodiment, the beam current value is detected from the voltage between both ends of the resistance circuit R1. However, since the current amount of the beam current signal and the voltage have a correlation, only the voltage at either end of the resistance circuit R1 is used. The beam current value may be detected. Then, the beam current value can be detected with a simple configuration.
Further, in the above-described embodiment, the current amount of the beam current is maximized by a rough control using the brightness adjustment value, and then the current amount of the beam current is finely controlled by using the contrast adjustment value. If there is a third video adjustment value capable of controlling the current amount of the beam current more finely than the adjustment value, the third video adjustment value may be used. For example, if the current change amount of the beam current with respect to the change amount of the cutoff adjustment value is smaller than the current change amount of the beam current with respect to the change amount of the contrast adjustment value, the beam current can be finely controlled using the cutoff adjustment value. Can be maximized.
[Brief description of the drawings]
FIG. 1 is a schematic block diagram of a configuration of a television according to an embodiment of the present invention.
FIG. 2 is a block diagram illustrating a schematic configuration of a chroma IC.
FIG. 3 is a diagram illustrating a temporal change of a pulsed beam current signal and a beam current signal.
FIG. 4 is a diagram illustrating a relationship between a brightness adjustment value written to a chroma IC and a current amount of a beam current.
FIG. 5 is an enlarged view showing the vicinity of a peak in FIG. 4;
FIG. 6 is a diagram showing a relationship between a contrast adjustment value written to a chroma IC and a current amount of a beam current in an enlarged manner near a peak.
FIG. 7 is a diagram showing equipment used for measuring the maximum X-ray radiation amount together with a television.
FIG. 8 is a flowchart showing a factory mode process.
FIG. 9 is a flowchart showing a factory mode process.
FIG. 10 is a schematic block diagram of a configuration of a television according to a conventional example.
FIG. 11 is a diagram illustrating a configuration of a main part of a television according to a conventional example.
[Explanation of symbols]
10… IIC bus
10a ... IIC bus interface
11 ... microcomputer
11a CPU
11b ROM
11c ... RAM
11d ... On-screen display circuit
11e, f ... A / D converter
12 ... Tuner IC
12a ... antenna
13 ... Chroma IC
13e demodulation unit
13f: video control signal generation unit
16… EEPROM
17… Rectifier circuit
21 ... Color signal processing circuit
21a ... Contrast adjuster
21b: brightness adjustment unit
22 ... picture tube (CRT)
22a ... tube surface
23 ... Audio amplifier
24 ... Speaker
25 ... deflection circuit
26 ... deflection coil
27 ... Flyback transformer (FBT)
30 X-ray protection circuit
31 ... Reset circuit
40 ... Power supply circuit
80 X-ray radiation dose measuring device
80a ... Measurement unit
100 ... Television
200 ... Personal computer
R1 ... Resistor circuit
C1… Capacitor

Claims (11)

A video signal is generated by inputting an intermediate frequency signal converted from a television broadcast signal, and a luminance adjustment value and a contrast adjustment value that are stepwise values are input, and a contrast signal corresponding to the same contrast adjustment value is input. A chroma IC that generates and adjusts a luminance signal corresponding to the luminance adjustment value based on the input beam current signal;
A microcomputer capable of outputting the contrast adjustment value and the brightness adjustment value to the chroma IC;
A color signal processing circuit that performs predetermined color signal processing on the video signal so as to adjust contrast and luminance of an output video based on the contrast signal and the luminance signal;
A picture tube that displays an image corresponding to the image signal on which the color signal processing has been performed by flowing a beam current based on the input high voltage on a predetermined tube surface,
A flyback transformer that generates the high voltage that decreases as the beam current increases and generates a substantially pulsed pulsed beam current signal whose integral value is substantially proportional to the current amount of the beam current;
A rectifier circuit that rectifies the generated pulsed beam current signal to generate the beam current signal;
An X-ray protection circuit for stopping supply of the high voltage to the picture tube when the high voltage is equal to or higher than a predetermined voltage,
The current change amount of the beam current with respect to the change amount of the brightness adjustment value is larger than the current change amount of the beam current with respect to the change amount of the contrast adjustment value,
The microcomputer has an A / D converter that inputs a voltage corresponding to the beam current signal and converts the voltage into a digital current value, acquires a digital beam current value from the converted current value, and The brightness adjustment value is output to the chroma IC while increasing the brightness adjustment value, and the brightness adjustment value that maximizes the obtained beam current value is determined, and the determined brightness adjustment value is applied to the chroma IC. In the output state, the contrast adjustment value is output to the chroma IC while changing the stepwise contrast adjustment value. The contrast adjustment value that maximizes the obtained beam current value is determined, and the determined contrast adjustment value is determined. Is output to the chroma IC so that the beam current is controlled to a current amount at which the maximum amount of X-ray radiation from the picture tube can be measured. Television and butterflies. High voltage generating means for generating a high voltage;
By inputting an image adjustment value that enables adjustment of the image brightness, performing predetermined color signal processing to adjust the brightness of the output image, and passing a beam current to the picture tube based on the generated high voltage. Image display means for displaying an image whose brightness has been adjusted by the same color signal processing,
Beam current detection means for detecting the amount of beam current flowing through the picture tube,
Based on the detected current amount of the beam current, the image adjustment value is determined so as to maximize the current amount of the beam current flowing through the picture tube, and the determined image adjustment value is transmitted to the image display unit. An image display device comprising: a beam current control means for outputting. The video display means receives the video adjustment value and generates a corresponding video control signal, and a brightness of an output video corresponding to the video adjustment value based on the generated video control signal. 3. The video display device according to claim 2, further comprising: a color signal processing unit that performs the color signal processing for adjusting the color signal processing. The image adjustment value is composed of first and second image adjustment values that are stepwise values, and the current change amount of the beam current with respect to the change amount of the first image adjustment value is the second image adjustment value. It is made larger than the current change amount of the beam current with respect to the change amount of the value,
The video signal generating means receives the first video adjustment value to generate a first video control signal, and receives the second adjustment value to generate a second video control signal,
The color signal processing means performs the color signal processing based on the generated first and second video control signals,
The beam current control means outputs to the video signal generation means while increasing the stepwise first video adjustment value, and outputs the beam current detected by the beam current detection means. After determining the first video adjustment value that maximizes the amount, the second video adjustment value is set to the stepwise value while the determined first video adjustment value is output to the video signal generation unit. The value is output to the image signal generating means while changing the value, the second image adjustment value at which the current amount of the beam current detected by the beam current detecting means is maximized is determined, and the determined second image adjustment value is determined. 4. The video display device according to claim 3, wherein a video adjustment value is output to said video signal generating means. The first image adjustment value is a brightness adjustment value that enables adjustment of the brightness of the output image, and the second image adjustment value is a contrast adjustment value that enables adjustment of the contrast of the output image. The video display device according to claim 4, wherein the video control signal is a luminance signal corresponding to the same brightness adjustment value, and the second video control signal is a contrast signal corresponding to the same contrast adjustment value. The high-voltage generating means generates a beam current signal having a current amount substantially proportional to a beam current flowing through the picture tube,
The beam current detecting means includes an A / D converter that inputs a voltage corresponding to the generated beam current signal and converts the voltage into a digital current value.
The beam current control means obtains a digital beam current value from the converted current value, and outputs the digital beam current value to the video signal generation means while increasing the first video adjustment value which is a stepwise value. Then, after determining the first image adjustment value at which the acquired beam current value is the largest, the stepwise value is output in a state where the determined first image adjustment value is output to the image signal generation unit. The second image adjustment value is output to the image signal generating means while changing the second image adjustment value, and the second image adjustment value at which the obtained beam current value is maximized is determined. The video display device according to claim 4, wherein a value is output to the video signal generation unit. The video signal generating means is a chroma IC that generates the first video control signal corresponding to the first video adjustment value while adjusting the first video control signal based on the beam current signal.
The high-voltage generating means includes a flyback transformer that generates a substantially pulsed pulsed beam current signal whose integral value is substantially proportional to the current amount of the beam current, and a rectified pulsed beam current signal to generate the beam current. The video display device according to claim 6, further comprising a rectifier circuit that generates a signal. The rectifier circuit includes a capacitor interposed between the flyback transformer and ground, and a resistor circuit interposed between one end of the capacitor on the flyback transformer side and the chroma IC,
The A / D converter converts the voltage across the resistor circuit into a digital current value,
8. The image display device according to claim 7, wherein the beam current control means sets a difference between both digital current values converted from voltages at both ends of the resistance circuit as the beam current value. The beam current control means determines the second image adjustment value at which the current amount of the beam current is maximized, and outputs the second image adjustment value to the image signal generation means. 9. The image display device according to claim 4, wherein a message prompting the user to perform measurement is output to the outside. A high voltage generating means for generating a high voltage, and a predetermined color signal processing for adjusting the brightness of the output video by inputting a video adjustment value enabling the brightness of the video to be adjusted; Beam current control method for a video display device, comprising: a video display means for displaying a video whose brightness has been adjusted by the same color signal processing by flowing a beam current to a picture tube based on the generated high voltage.
The amount of beam current flowing through the picture tube is detected, and based on the detected amount of beam current, the image adjustment value is determined so as to maximize the amount of beam current flowing through the same picture tube. Outputting the adjusted video adjustment value to the video display means. A high voltage generating means for generating a high voltage, and a predetermined color signal processing for adjusting the brightness of the output video by inputting a video adjustment value enabling the brightness of the video to be adjusted; Image display means for displaying an image whose brightness has been adjusted by the same color signal processing by passing a beam current through a picture tube based on the generated high voltage. So,
The image display device detects a current amount of a beam current flowing through the picture tube, and, based on the detected current amount of the beam current, controls the image so as to maximize the current amount of the beam current flowing through the picture tube. Determine the adjustment value, output the determined video adjustment value to the video display means,
X-ray radiation measurement capable of measuring the amount of X-ray radiation when an image adjustment value determined to maximize the amount of beam current flowing through the picture tube is output to the image display means. A method for measuring a maximum X-ray radiation amount of an image display device, wherein the maximum X-ray radiation amount from the picture tube is measured using an apparatus.

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