JP2004032620A - Television receiver, image adjustment apparatus, and image adjustment method - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To solve a task of disabled variable adjustment because no reference horizontal synchronizing signal exists in a non-signal state. <P>SOLUTION: A microcomputer 10 controls a deflection distortion correction IC 70 to execute distortion correction processing so as to thereby correct the deflection distortion caused in horizontal and vertical directions of a black screen video image on a CRT 62 resulting from variations in a high voltage supplied from a FBT 67 to the CRT 62 when no broadcast signal exists thereby enhancing video image quality of the black screen video image in the non-signal state. <P>COPYRIGHT: (C)2004,JPO

Description

[0001]
TECHNICAL FIELD OF THE INVENTION
The present invention relates to a television, an image adjustment device, and an image adjustment method, and more particularly, to a television, an image adjustment device, and an image adjustment method for adjusting a size of an image.
[0002]
[Prior art]
Conventionally, an image adjusting apparatus of this type is disclosed in Japanese Patent Application Laid-Open Nos. 7-92928, 2001-94817, and 8-265595. In the technology disclosed in each of the above publications, the horizontal synchronization signal is corrected according to the frequency of the horizontal synchronization signal included in the received broadcast signal, and is variably adjusted so that the horizontal size of the image displayed on the CRT becomes appropriate. Was.
[0003]
[Problems to be solved by the invention]
In the above-described conventional image adjustment apparatus, a circuit configuration that determines a correction amount based on a horizontal synchronization signal in which a received broadcast signal includes a horizontal synchronization signal, and variably adjusts the horizontal synchronization signal based on the correction amount Therefore, when the broadcast signal does not include a horizontal synchronization signal, that is, when there is no signal, there is no reference horizontal synchronization signal, so that there is a problem that the variable adjustment cannot be performed.
[0004]
The present invention has been made in view of the above problems, and has as its object to provide a television, an image adjustment device, and an image adjustment method capable of variably adjusting an image even in a no-signal state.
[0005]
[Means for Solving the Problems]
In order to achieve the above object, the invention according to claim 1 includes a tuner IC capable of receiving a broadcast signal carried by a broadcast wave, selecting a predetermined channel from a plurality of channels, and outputting an intermediate frequency signal. A chroma IC that receives the intermediate frequency signal and generates a horizontal / vertical drive signal based on a synchronization signal, and a deflection circuit that receives the horizontal / vertical drive signal and generates a beam current corresponding to the horizontal / vertical drive signal. A deflection coil for driving an electron beam based on the beam current in the horizontal and vertical directions of the CRT, and a fly for inputting a high-frequency signal generated by the deflection circuit and generating a high voltage to be supplied to the CRT based on the high-frequency signal A back transformer, and a microcomputer connected to the tuner IC and the chroma IC and executing predetermined control as appropriate. A horizontal drive capable of correcting the deflection distortion in a television in which a deflection distortion occurs in a horizontal direction of an image displayed on a CRT due to a change in a high voltage generated in the flyback transformer when a broadcast signal is in a non-signal state. The microcomputer is provided with a distortion correction circuit capable of inputting a signal to the deflection circuit. The microcomputer inputs a synchronization signal generated by the chroma IC, and checks whether the broadcast signal is in a non-signal state based on the input synchronization signal. It is determined whether or not there is no signal, and when it is determined that there is no signal, the horizontal drive signal is input to the deflection circuit by controlling the distortion correction circuit, whereby the deflection distortion generated in the horizontal direction is reduced. It is configured to correct.
[0006]
In television, a tuner IC can receive a broadcast signal carried by a broadcast wave, selects a predetermined channel from a plurality of channels, outputs an intermediate frequency signal, and outputs an intermediate frequency signal with a chroma IC. Input and generate a horizontal / vertical drive signal based on the synchronization signal. The horizontal / vertical drive signal is input to a deflection circuit, which generates a beam current corresponding to the horizontal / vertical drive signal, and drives an electron beam based on the beam current in a horizontal / vertical direction of a CRT by a deflection coil. The flyback transformer receives a high-frequency signal generated by the deflection circuit, and generates a high voltage to be supplied to the CRT based on the high-frequency signal. Here, the microcomputer is connected to the tuner IC and the chroma IC and appropriately executes predetermined control. In such a configuration, when the received broadcast signal is in a no-signal state, a change in high voltage generated in the flyback transformer occurs. This causes deflection distortion in the horizontal direction of the image displayed on the CRT.
[0007]
Therefore, in the invention according to claim 1 configured as described above, the television is provided with a distortion correction circuit capable of inputting a horizontal drive signal capable of correcting the deflection distortion generated in the horizontal direction to the deflection circuit. Then, the microcomputer inputs the synchronization signal generated by the chroma IC, and determines whether the broadcast signal is in a no-signal state based on the input synchronization signal. If it is determined that there is no signal, the microcomputer controls the distortion correction circuit to input the horizontal drive signal to the deflection circuit. Thereby, the horizontal deflection distortion generated in the CRT is corrected.
[0008]
With the configuration described above, it is possible to provide a television capable of correcting deflection distortion generated in a CRT due to a change in high voltage generated in a flyback transformer when there is no signal. On the other hand, it is needless to say that the technical idea is not limited to a specific device to which the technology is applied, that is, a television, but can also be realized as an image adjustment device for correcting deflection distortion when there is no signal.
[0009]
Therefore, an invention according to claim 2 is an image adjustment apparatus for correcting image deflection distortion caused by a change in high voltage generated in a flyback transformer when there is no signal, wherein the apparatus adjusts a broadcast signal carried by broadcast radio waves. Broadcast signal receiving means for receiving, and no-signal determining means for determining whether the broadcast signal is in a no-signal state based on the presence or absence of a synchronization signal included in the broadcast signal received by the broadcast signal receiving means; A deflection current output means for generating a deflection current capable of correcting the deflection distortion and outputting the deflection current to a CRT; and a deflection current output when the broadcast signal is determined to be in a no-signal state by the no-signal determination means. Means for generating the deflection current by means for correcting the deflection distortion.
[0010]
According to the second aspect of the present invention, there is provided an image adjusting apparatus for correcting a deflection distortion of an image caused by a change in a high voltage generated in a flyback transformer when there is no signal. To realize such a function, the broadcast signal receiving unit receives a broadcast signal carried by broadcast waves, and the absence of a synchronization signal included in the broadcast signal received by the broadcast signal receiving unit by the no-signal determination unit. It is determined whether or not the broadcast signal is in a no-signal state based on. Here, the deflection current output means generates a deflection current capable of correcting deflection distortion and outputs the deflection current to the CRT, and the distortion correction means determines whether the broadcast signal is in a no-signal state by the no-signal determination means. Then, the deflection current of the image is corrected by causing the deflection current output means to generate the above-described deflection current.
[0011]
As a preferred example of the deflection current generated by the deflection current output means, the invention according to claim 3 is the image adjustment apparatus according to claim 2, wherein the deflection current output means can correct horizontal deflection distortion. It is configured to generate and output a suitable horizontal deflection current.
In the invention according to claim 3 configured as described above, the deflection current output means can generate and output a horizontal deflection current capable of correcting horizontal deflection distortion. Then, when it is determined that there is no signal, the distortion correction means causes the deflection current output means to generate this horizontal deflection current. This makes it possible to correct the deflection distortion generated in the horizontal direction.
[0012]
As another preferable example of the deflection current generated by the deflection current output means, the invention according to claim 4 is the image adjustment apparatus according to any one of claims 2 or 3, wherein the deflection current output means is In this configuration, a vertical deflection current capable of correcting vertical deflection distortion can be generated and output.
In the invention according to claim 4 configured as described above, the deflection current output means can generate and output a vertical deflection current capable of correcting vertical deflection distortion. Then, when it is determined that there is no signal, the distortion correction means causes the deflection current output means to generate this vertical deflection current. This makes it possible to correct the deflection distortion generated in the vertical direction.
[0013]
The deflection distortion depends on the degree of fluctuation of the high voltage. Then, it is considered that the deflection distortion occurs according to the degree of fluctuation. Therefore, it is preferable that a deflection current corresponding to the degree of fluctuation of the generated high voltage can be generated. According to a fifth aspect of the present invention, in the image adjustment apparatus according to any one of the second to fourth aspects, the deflection current output means determines a degree of fluctuation of a high voltage generated in the flyback transformer. There is a fluctuation detecting means for detecting, and the distortion correcting means is configured to generate the deflection current based on the detected fluctuation degree.
In the invention according to claim 5 configured as described above, the deflection current output means is provided with a fluctuation detecting means for detecting the degree of fluctuation of the high voltage generated in the flyback transformer. In such a case, the distortion correction unit causes the deflection current output unit to generate a deflection current based on the degree of change detected by the change detection unit.
[0014]
As described above, it is preferable to generate the deflection current in accordance with the degree of the fluctuation, because the deflection distortion can be corrected in accordance with the high voltage fluctuation state. On the other hand, as an example of a technique capable of easily generating a predetermined deflection current, the invention according to claim 6 is a method according to any one of claims 2 to 4, wherein The current generating output means has fixed data for adjusting the deflection current in advance, and generates the deflection current based on the fixed data.
In the invention according to claim 6, the deflection current output means is provided with fixed data for adjusting the deflection current in advance, and the deflection current is adjusted based on the fixed data in response to a command from the distortion correction means. Generate
[0015]
Also, the method of correcting the image deflection distortion caused by the fluctuation of the high voltage generated in the flyback transformer when there is no signal need not necessarily be limited to a substantial device, and it is easily understood that the method functions as the method. it can.
For this reason, the invention according to claim 7 is an image adjustment method for correcting image deflection distortion caused by a high voltage fluctuation generated in a flyback transformer when there is no signal, wherein the broadcast signal carried by a broadcast wave is provided. Receiving a broadcast signal, and a no-signal determining step of determining whether the broadcast signal is in a no-signal state based on the presence or absence of a synchronization signal included in the broadcast signal received in the broadcast signal receiving step. A deflection current output step of generating a deflection current capable of correcting the deflection distortion and outputting the deflection current to a CRT; and, when the broadcast signal is determined to be in a no-signal state in the no-signal determination step, the deflection is performed. A distortion correcting step of correcting the deflection distortion by generating the deflection current in the current output step.
In other words, there is no difference that the present invention is not necessarily limited to a substantial device and is effective as a method.
[0016]
【The invention's effect】
As described above, the present invention can provide a television capable of correcting a deflection distortion of an image generated on a CRT due to a change in a high voltage generated in a flyback transformer when there is no signal.
Further, according to the second aspect of the present invention, it is possible to provide an image adjusting apparatus capable of correcting image deflection distortion caused by a change in high voltage generated in a flyback transformer when there is no signal.
Further, according to the third aspect of the invention, it is possible to correct the deflection distortion generated in the horizontal direction.
Further, according to the invention of claim 4, it becomes possible to correct the deflection distortion generated in the vertical direction.
Further, according to the fifth aspect of the invention, it is possible to appropriately correct the deflection distortion that can occur in accordance with the degree of fluctuation of the high voltage.
Further, according to the invention of claim 6, it is possible to correct the deflection distortion by a simple method.
Further, according to the invention according to claim 7, it is possible to provide an image adjustment method capable of correcting an image deflection distortion caused by a high voltage fluctuation generated in a flyback transformer when there is no signal.
[0017]
BEST MODE FOR CARRYING OUT THE INVENTION
Here, embodiments of the present invention will be described in the following order.
(1) Configuration of television:
(2) Regarding the processing content of the no-signal state determination processing:
(3) Regarding the processing content of the no-signal control processing:
(4) Regarding the processing contents of the distortion correction control processing:
(5) Summary:
[0018]
(1) Configuration of television:
FIG. 1 is a block diagram showing a configuration of a television according to the embodiment of the present invention. FIG. 2 is an internal configuration diagram showing an internal configuration of a chroma IC provided in the television. In the figure, a television 100 includes a microcomputer 10, to which a tuner IC 20, a chroma IC 30, an EEPROM 40, an operation panel 50, and a deflection distortion correction IC 70 are connected by an IIC bus (not shown). A remote controller (not shown) is directly connected. The antenna 21 and the chroma IC 30 are connected to the tuner IC 20.
[0019]
An audio amplifier 63 and a deflection circuit 65 are connected to the chroma IC 30, and a cathode amplifier 61 is connected to the chroma IC 30 via an on-screen display (OSD) circuit 15 in the microcomputer 10. The CRT 62 has a deflection coil 66 attached thereto and is connected to the cathode amplifier 61 and a flyback transformer (FBT) 67 so that a screen can be displayed. Further, the speaker 64 is connected to the audio amplifier 63 and can output sound. The microcomputer 10 controls the entire television 100 to realize a function as a television.
[0020]
Here, the tuner IC 20 is a so-called frequency synthesizer type tuner, and includes therein a high-frequency amplifier circuit, a local oscillator circuit, a mixing circuit, and the like (not shown). Obviously, the tuner may be a frequency synthesizer system, but may be a voltage synthesizer system. The high-frequency amplifier circuit has a band-pass filter, and receives a broadcast radio wave corresponding to a desired frequency from the antenna 21 through the band-pass filter under the control of the microcomputer 10 and amplifies to generate a high-frequency signal. I do. The frequency of this high-frequency signal is the same frequency as the broadcast radio wave of the selected broadcast. The high-frequency amplifier circuit outputs the generated high-frequency signal to the mixing circuit.
[0021]
The local oscillation circuit is constituted by a PLL (Phase Locked Loop) circuit, and the PLL circuit generates a local oscillation signal having a local oscillation frequency corresponding to a desired frequency of a broadcast wave and outputs the signal 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 (IF), and outputs it to the chroma IC 30. At this time, the intermediate frequency signal may be output to the chroma IC after passing through the SAW filter. Note that as the high-frequency amplifier circuit, the local oscillation circuit, and the mixing circuit, various television circuits conventionally used can be applied.
[0022]
The chroma IC 30 includes an intermediate frequency amplification (VIF) circuit 31 connected to the tuner IC 20, a VCO (Voltage Controlled Oscillator) circuit 32 connected to the microcomputer 10 and a crystal oscillation circuit (not shown), a VCO circuit 32, and a VIF circuit 31. The detection circuit 33 includes a connected detection circuit 33, a synchronization circuit 34 connected to the detection circuit 33, and a video signal amplification circuit 35 connected to the detection circuit 33. As the VIF circuit 31, the VCO circuit 32, the detection circuit 33, the synchronizing circuit 34, and the video signal amplifying circuit 35, various television circuits conventionally used can be applied.
[0023]
The VIF circuit 31 amplifies the intermediate frequency signal output from the tuner IC 20 by an intermediate frequency, and outputs the amplified signal to the detection circuit 33. The VCO circuit 32 oscillates an oscillation signal based on a reference oscillation signal input from the crystal oscillation circuit, and can change the oscillation frequency of the oscillation signal according to the input voltage. Here, the microcomputer 10 controls the voltage input to the VCO circuit 32 so as to have an oscillation frequency corresponding to the type of the received broadcast radio wave. The detection circuit 33 detects the intermediate frequency signal amplified by the VIF circuit 31 based on the oscillation frequency of the oscillation signal, and outputs a video signal and an audio signal. More specifically, the detection circuit 33 performs video detection while synchronizing with the oscillation frequency of the oscillation signal from the intermediate frequency signal amplified by the intermediate frequency, performs predetermined color demodulation processing, separates the video signal, and outputs the video signal to the outside. Output.
[0024]
The video signal amplifying circuit 35 amplifies the luminance signal of the video signal obtained by the detection circuit 33 to a size necessary for operating the CRT 62. The video signal amplifier circuit 35 amplifies the video signal, adds the video signal to the cathode amplifier 61, and distributes the video signal to synchronization separation, band amplification, and the like. As for the audio signal, a second audio intermediate frequency signal is generated by mixing the audio component and the oscillation signal in the intermediate frequency signal that has been subjected to the intermediate frequency amplification, is subjected to FM detection, is converted into an audio signal, and is output to the outside. Further, the detection circuit 33 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 34. The synchronization circuit 34 generates a sawtooth-shaped horizontal / vertical drive signal based on the input horizontal / vertical synchronization signal, and outputs the signal to a deflection circuit 65 including a horizontal deflection circuit and a vertical deflection circuit.
[0025]
The video signal output from the video signal amplification circuit 35 is output to the cathode amplifier 61 via the OSD circuit 15, amplified by the cathode amplifier 61, and supplied to the CRT 62. Then, the CRT 62 performs a screen display based on the amplified video signal. On the other hand, the audio signal is output to the audio amplifier 63, amplified by the audio amplifier 63, and supplied to the speaker 64. Then, the speaker 64 outputs sound based on the amplified sound signal.
[0026]
The deflection circuit 65 generates a predetermined beam current corresponding to the horizontal / vertical drive signal and supplies the beam current to a deflection coil 66 attached to the CRT 62. The deflection coil 66 drives the electron beam based on the beam current in the horizontal and vertical directions of the CRT 62. The high-frequency signal generated by the deflection circuit 65 is supplied to the FBT 67, and a high voltage to be supplied to the CRT 62 is generated. As a result, the CRT 62 emits an electron beam according to the video signal while being driven, and an image appears on the screen of the CRT 62.
[0027]
The EEPROM 40 is a readable / writable 1-kbit, ie, 128-byte, nonvolatile memory. In the EEPROM 40, in addition to channel preset data for the tuner IC 20, setting data of image quality parameters such as contrast and brightness, destination data for the United States or Japan, and whether the audio output is stereo is determined. A plurality of various data necessary for the above control, such as data and data for determining a model, are stored.
[0028]
Here, the microcomputer 10 includes a CPU 11, a ROM 12, a RAM 13, an I / O port 14, an OSD circuit 15, an A / D port 16, a timer circuit (not shown), and the like. A tuner IC 20, a chroma IC 30, an operation panel 50, and a remote controller are connected to the I / O port 14. Further, the chroma IC 30 and the cathode amplifier 61 are connected to the OSD circuit 15 as described above. Then, the CPU 11 executes a predetermined program stored in the ROM 12 while using the RAM 13 as a work area, and controls the entire television 100.
[0029]
In such a configuration, when the broadcast radio wave received by the tuner IC 20 is in a no-signal state, the image changes to a black screen image. In such a case, the high voltage supplied from the FBT 67 to the CRT 62 fluctuates with this change. Then, due to the fluctuation of the high voltage supplied from the FBT 67 to the CRT 62, deflection distortion occurs in which the horizontal direction of the black screen image in the no-signal state contracts. For this reason, the quality of the video in the no-signal state is reduced. Therefore, in the present embodiment, the deflection distortion correction IC 70 capable of correcting the deflection distortion is connected to an IIC bus (not shown), and the deflection drive IC 65 supplies a horizontal drive signal capable of correcting the deflection distortion to the deflection circuit 65. Input. Then, the deflection circuit 65 generates a beam current according to the horizontal drive signal and supplies the beam current to the deflection coil 66 attached to the CRT 62.
[0030]
Then, the deflection coil 66 drives the electron beam based on the beam current capable of correcting the generated deflection distortion in the horizontal direction of the CRT 62. This makes it possible to correct the deflection distortion that occurs in the horizontal direction of a black screen image in a no-signal state. Here, to realize this function, first, the chroma IC 30 is caused to execute a no-signal state determination process for determining whether or not the broadcast signal is in a no-signal state. Next, the microcomputer 10 is caused to execute a no-signal control process for controlling the deflection distortion correction IC 70 according to the determination. Then, it causes the deflection distortion correction IC 70 to execute a distortion correction control process according to the control of the microcomputer 10. This series of processing makes it possible to realize the above-described deflection distortion correction. Next, the contents of each of these processes will be described.
[0031]
(2) Regarding the processing content of the no-signal state determination processing:
FIG. 3 is a flowchart showing the content of the no-signal state determination process executed by the above-described chroma IC 30. This no-signal state determination processing is executed by the synchronization circuit 34 of the chroma IC 30. In the figure, a horizontal / vertical synchronization signal is sampled and acquired based on a predetermined time. Then, it is determined whether or not the broadcast signal is in a no-signal state according to the presence or absence of the horizontal synchronization signal acquired by sampling. In such a case, first, it is determined whether or not a horizontal / vertical synchronization signal is input from the detection circuit 33 (step S100). If there is no horizontal / vertical synchronization signal, it is determined whether a predetermined time of sampling has elapsed (step S105).
[0032]
If the predetermined time has not elapsed, it is determined again in step S100 whether there is a horizontal / vertical synchronization signal. On the other hand, if it is determined in step S105 that the horizontal / vertical synchronizing signal has not been input for a predetermined time, the SD (station detect) signal is turned off, and the broadcast signal is output via the IIC bus in a non-signal state. The microcomputer 10 is notified of the existence (step S110). If it is determined in step S100 that a horizontal / vertical synchronization signal has been input, the predetermined time for sampling is reset (step S115), and measurement of the predetermined time for the next sampling is started (step S115). Step S120). Then, the SD signal is turned on, and the microcomputer 10 is notified via the IIC bus that the broadcast signal is present (step S125).
[0033]
(3) Regarding the processing content of the no-signal control processing:
FIG. 4 is a flowchart showing the content of the no-signal control process executed by the microcomputer 10. In the figure, first, it is determined whether or not the SD signal notified from the chroma IC 30 via the IIC bus is off (step S200). If the SD signal is off, it is determined that the broadcast signal is in a no-signal state, and the distortion correction control signal for causing the deflection distortion correction IC 70 to execute the distortion correction control processing is turned on. (Step S205). On the other hand, when the SD signal is on, the distortion correction control signal is turned off, and the deflection correction control signal is notified to the deflection distortion correction IC 70 via the IIC bus (step S210).
[0034]
(4) Regarding the processing contents of the distortion correction control processing:
FIG. 5 is a flowchart showing the processing content of the distortion correction control processing executed by the deflection distortion correction IC 70. FIG. 6 is a diagram illustrating a configuration of an image displayed on the CRT 62. In the figure, first, it is determined whether or not the distortion correction control signal notified from the microcomputer 10 via the IIC bus is on (step S300). If it is determined that the distortion correction control signal is ON, the frequency of the high-frequency signal output from the deflection circuit 65 to the FBT 67 is input (step S305). Then, based on a predetermined reference frequency (the frequency of the high-frequency signal output from the deflection circuit 65 to the FET 67 when the broadcast signal is present), the FBT 67 detects the degree of fluctuation of the high voltage supplied to the CRT 62 and (Step S310) Based on the degree of fluctuation of the high voltage, the degree of deflection of the deflection distortion occurring in the horizontal direction of the black screen image in the non-signal state is detected (Step S315).
[0035]
Then, a correction amount is calculated based on the degree of deflection (step S320), a horizontal drive signal based on the correction amount is generated (step S325), and output to the deflection circuit 65 (step S330). The deflection circuit 65 receives the horizontal drive signal, generates a beam current based on the horizontal drive signal, and supplies the beam current to the deflection coil 66. Then, the deflection coil 66 drives the electron beam based on the beam current in the horizontal direction of the CRT 62, so that the image A1 contracted and distorted in the horizontal direction can be corrected like the image A2.
[0036]
In the above-described embodiment, the mode in which the deflection distortion generated in the horizontal direction when the broadcast signal is in a no-signal state is corrected has been described. Here, the image deflection distortion that occurs when the broadcast signal is in a no-signal state can occur significantly in the horizontal direction, but can also occur in the vertical direction. Therefore, the deflection distortion correction IC 70 may generate a vertical drive signal capable of correcting the vertical deflection distortion, and output the vertical drive signal to the deflection circuit 65 to correct the vertical deflection distortion.
[0037]
FIG. 7 is a flowchart showing the processing contents of the distortion correction control processing executed by the deflection distortion correction IC 70 in such a case. FIG. 8 is a diagram illustrating a configuration of an image displayed on the CRT 62. In the figure, first, it is determined whether or not the distortion correction control signal notified from the microcomputer 10 via the IIC bus is on (step S400). If it is determined that the distortion correction control signal is ON, the frequency of the high-frequency signal output from the deflection circuit 65 to the FBT 67 is input (step S405). Then, based on a predetermined reference frequency (the frequency of the high-frequency signal output from the deflection circuit 65 to the FBT 67 when the broadcast signal is in a signal state), the FBT 67 detects the degree of fluctuation of the high voltage supplied to the CRT 62, and (Step S410), the degree of deflection of the deflection distortion generated in the vertical direction is detected based on the degree of fluctuation of the high voltage (Step S415).
[0038]
Then, a correction amount is calculated based on the degree of deflection (step S320), a vertical drive signal is generated based on the correction amount (step S325), and output to the deflection circuit 65 (step S330). The deflection circuit 65 receives the vertical drive signal, generates a beam current based on the vertical drive signal, and supplies the beam current to the deflection coil 66. Then, the deflection coil 66 drives the electron beam based on the beam current in the vertical direction of the CRT 62, so that the image B1 contracted and distorted in the vertical direction can be corrected like the image B2.
[0039]
In the embodiment described above, when the deflection distortion correction IC 70 generates a horizontal / vertical drive signal capable of correcting the deflection distortion, the deflection circuit 65 changes the high frequency signal supplied to the FBT 67 based on the degree of fluctuation of the black screen image. A method of detecting the degree of deflection distortion occurring in the horizontal and vertical directions was adopted. Such a method is suitable because it can appropriately correct the deflection distortion generated according to the degree of fluctuation, but may increase the number of processing steps and complicate the processing time and the processing realization configuration. Therefore, the processing contents of the distortion correction processing capable of correcting the deflection distortion by a simple method are shown in the flowchart of FIG. In the figure, first, it is determined whether or not the distortion correction control signal notified from the microcomputer 10 via the IIC bus is on (step S500). If it is determined that the distortion correction control signal is ON, a horizontal (vertical) drive signal is generated based on the setting data set in a predetermined storage area of the deflection distortion correction IC 70 in advance (step S505). Then, the generated horizontal (vertical) drive signal is output to the deflection circuit 65 (step S510). By employing such a method, the processing in the deflection distortion correction IC 70 can be simplified.
[0040]
In the above-described embodiment, in order to cope with horizontal and vertical deflection distortions occurring in a black screen image in a non-signal state, a method of causing the deflection distortion correction IC 70 to generate a horizontal / vertical drive signal is used. The deflection distortion that can occur in an image is not limited to horizontal and vertical. That is, other deflection distortion may occur depending on the situation of the fluctuation of the high voltage. Therefore, a predetermined control signal is output from the deflection distortion correction IC 70 to the deflection circuit 65 so that the other deflection distortion can be corrected, a beam current is generated based on the control signal, and the other deflection distortion is corrected. You may do it.
[0041]
(5) Summary:
As described above, when the broadcast signal is in a non-signal state, the high voltage supplied from the FBT 67 to the CRT 62 fluctuates, and the fluctuation of the high voltage causes the black screen image of the CRT 62 to be generated in the horizontal and vertical directions. The deflection distortion can be corrected by causing the deflection distortion correction IC 70 to execute the distortion correction process under the control of the microcomputer 10, and the image quality of a black screen image in a no-signal state can be improved.
[Brief description of the drawings]
FIG. 1 is a block diagram showing a configuration of a television according to an embodiment of the present invention.
FIG. 2 is a configuration diagram showing an internal configuration of a chroma IC provided in a television.
FIG. 3 is a flowchart showing the processing content of a no-signal state determination process executed by a chroma IC.
FIG. 4 is a flowchart showing a process of a no-signal control process executed by the microcomputer.
FIG. 5 is a flowchart showing a processing content of a distortion correction control process executed by a deflection distortion correction IC.
FIG. 6 is a diagram showing a configuration of an image displayed on a CRT.
FIG. 7 is a flowchart showing the processing content of a distortion correction control process executed by the deflection distortion correction IC.
FIG. 8 is a diagram showing a configuration of an image displayed on a CRT.
FIG. 9 is a flowchart showing the processing content of a distortion correction control process executed by the deflection distortion correction IC.
[Explanation of symbols]
10 ... microcomputer
11 CPU
12 ... ROM
13 ... RAM
14 ... I / O port
15 ... OSD
16 ... A / D port
20 ... Tuner IC
21 ... Antenna
30 ... Chroma IC
40… EEPROM
50 ... Operation panel
61 ... Cathode amplifier
62 ... CRT
63 ... Audio amplifier
64 ... speaker
65 ... deflection circuit
66 ... deflection coil
67 ... FBT
70: deflection distortion correction IC

Claims (7)

A tuner IC capable of receiving a broadcast signal carried by broadcast waves, selecting a predetermined channel from a plurality of channels and outputting an intermediate frequency signal, and a horizontal IC based on the synchronization signal based on the input of the intermediate frequency signal A chroma IC for generating a vertical drive signal, a deflection circuit for receiving the horizontal / vertical drive signal and generating a beam current corresponding to the horizontal / vertical drive signal, and an electron beam based on the beam current in a horizontal / vertical direction of a CRT. A deflection coil to be driven, a flyback transformer that receives a high-frequency signal generated by the deflection circuit and generates a high voltage to be supplied to a CRT based on the high-frequency signal, and is connected to the tuner IC and the chroma IC and appropriately connected to the tuner IC and the chroma IC. And a microcomputer for executing the control of the flyback when the received broadcast signal is in a non-signal state. In television deflection distortion in the horizontal direction of the image displayed on the CRT are generated by variations in the high voltage generated by Nsu,
The microcomputer is provided with a distortion correction circuit capable of inputting a horizontal drive signal capable of correcting the deflection distortion to the deflection circuit. The microcomputer receives the synchronization signal generated by the chroma IC and performs the above-described synchronization based on the input synchronization signal. Determine whether the broadcast signal is in a no-signal state, if determined to be in the no-signal state, by inputting the horizontal drive signal to the deflection circuit by controlling the distortion correction circuit, A television, wherein the deflection distortion generated in the horizontal direction is corrected. An image adjustment device for correcting deflection distortion of an image caused by a change in high voltage generated in a flyback transformer when there is no signal,
Broadcast signal receiving means for receiving a broadcast signal carried by broadcast radio waves,
No-signal determining means for determining whether the broadcast signal is in a no-signal state based on the presence or absence of a synchronization signal included in the broadcast signal received by the broadcast signal receiving means,
Deflection current output means for generating a deflection current capable of correcting the deflection distortion and outputting the deflection current to a CRT;
Distortion correction means for correcting the deflection distortion by causing the deflection current output means to generate the deflection current when the broadcast signal is determined to be in the no signal state by the no signal determination means. An image adjustment device, comprising: 3. The image adjustment apparatus according to claim 2, wherein the deflection current output unit is capable of generating and outputting a horizontal deflection current capable of correcting horizontal deflection distortion. 4. The image adjustment apparatus according to claim 2, wherein said deflection current output means is capable of generating and outputting a vertical deflection current capable of correcting vertical deflection distortion. The deflection current output means has a variation detection means for detecting a variation degree of a high voltage generated in the flyback transformer, and the distortion correction means generates the deflection current based on the detected variation degree. The image adjustment device according to claim 2, wherein the image adjustment device performs the adjustment. 5. The deflection current output means has fixed data for adjusting the deflection current in advance, and generates the deflection current based on the fixed data. Image adjustment device. An image adjustment method for correcting deflection distortion of an image caused by a change in high voltage generated in a flyback transformer when there is no signal,
A broadcast signal receiving step of receiving a broadcast signal carried by broadcast waves,
A no-signal determination step of determining whether the broadcast signal is in a no-signal state based on the presence or absence of a synchronization signal included in the broadcast signal received in the broadcast signal receiving step;
A deflection current output step of generating a deflection current capable of correcting the deflection distortion and outputting the deflection current to a CRT;
A distortion correction step of correcting the deflection distortion by generating the deflection current in the deflection current output step when the broadcast signal is determined to be in the no signal state in the no signal determination step. An image adjustment method, comprising:

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