JPH07203469A - Color cathode ray tube display device - Google Patents

Abstract

PURPOSE:To effectively eliminate various adverse effects of an external magnetic field in the tube axis direction in the color cathode ray tube display device. CONSTITUTION:A current supply circuit 3 supplies a current in proportion to the strength of an external magnetic field in the tube axis direction based on an output of a magnetism detection element 2 in a direction corresponding to the polarity. Then compensation coils 9, 10, 11 receiving the current from the current supply circuit 3 are arranged respectively in the vicinity of a panel for purity rotation prevention, in the vicinity of a deflection yoke for raster rotation prevention and in the vicinity of a neck for misconvergence change prevention for longitudinal crack of side beam.

Description

Detailed Description of the Invention

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a color cathode ray tube display device having a compensation function for effectively canceling various image distortions caused by an external magnetic field acting in the tube axis direction.

[0002]

2. Description of the Related Art FIG. 9 is a side sectional view showing a conventional color cathode ray tube display device disclosed in, for example, Japanese Utility Model Laid-Open No. 61-33574. In FIG. 9, 1 is a shadow mask type color cathode ray tube (hereinafter referred to as a shadow mask type color cathode ray tube). , CRT; CATHODE RAY TU
BE) 2 is a magnetic detection element, 3 is a current supply circuit, 4
Is a compensation coil, 5 is a deflection yoke, and 6 is a separator flange on the panel side of the deflection yoke 5.

The CRT 1 comprises a three-beam type electron gun 1a and a panel 1b, and a deflection yoke 5 is disposed around a funnel 1c between them, except for the panel 1b which needs to be exposed to the outside. It is magnetically shielded by being covered with an omitted magnetic material. The magnetic detection element 2 is CR
The polarity and strength of the external magnetic field in the tube axis direction of T1 are detected and an electric signal corresponding to the detected polarity is output. For example, a Hall element is used. The current supply circuit 3 includes the magnetic detection element 2
An electric signal is received from the compensating coil 4 in proportion to the strength of the external magnetic field and flows in the direction corresponding to the polarity to cancel the external magnetic field. The compensation coil 4 is wound in the vicinity of the panel 1b of the CRT 1,
By supplying the current from the current supply circuit 3, C
It is for generating a compensating magnetic field that cancels the external magnetic field in the tube axis direction of RT1.

Next, the operation will be described. The electron beam emitted from the electron gun 1a scans the panel 1b while being deflected by the magnetic field formed by the deflection yoke 5, and causes the phosphor coated on the panel 1b to emit light to form an electronic image on the panel 1b. Display it. At this time, the panel 1b of the CRT 1
The magnetic substance that covers the portions other than the above blocks the effect of magnetic fields other than the external magnetic field in the tube axis direction connecting the panel 1b and the electron gun 1a in the external magnetic field such as the earth magnetism, and the adverse effect caused by this magnetic field (electron beam hits) Position change on the panel 1b).

Then, when an external magnetic field in the tube axis direction connecting the panel 1b and the electron gun 1a acts, the polarity and strength of this external magnetic field are detected by the magnetic detection element 2 and input to the current supply circuit 3 as an electric signal. To be done. The current supply circuit 3 outputs a current flowing in a direction in which the external magnetic field is canceled in a magnitude proportional to the strength of the external magnetic field based on the electric signal input from the magnetic detection element 2 for compensation. Supply to the coil 4. Then, the compensation coil 4 produces a compensation magnetic field proportional to the external magnetic field and having a polarity opposite to that of the external magnetic field.

For this reason, even when the installation position of the CRT 1 changes and the polarity and strength of the external magnetic field such as the earth's magnetism change, the compensation magnetic field generated by the compensation coil 4 follows this automatically and automatically. By changing, the adverse effect of the external magnetic field in the tube axis direction in the vicinity of CRT1 is mitigated.

By the way, it can be generally said that the effect (adverse effect) on the screen when a magnetic field acts in the tube axis direction of the CRT 1 is to move the position of the electron beam. Further analysis of migration shows that
Rotation of the whole raster (screen to be scanned) as shown in 0,
Rotation of purity as shown in FIG. 11 and FIG.
It can be divided into three types of vertical beam misconvergence change of the side beam (red / blue) as shown in 2.

Here, the raster rotation means that the entire screen to be scanned rotates with respect to an appropriate position. Purity rotation means that the electron beam 8 that has passed through a shadow mask (not shown) rotationally moves (right rotation in this case) with respect to the phosphor 7 of the panel 1a to cause mislanding as shown by a dotted line in FIG. Is. When this purity rotation occurs, the electron beam 8 impinges only on the portion of the phosphor 7 indicated by the diagonal lines in FIG. 11, and only this portion emits light. Further, the misconvergence change means that the raster distortion is not uniform among the electron beams, resulting in color shift. In this case, for example, the red beam 8R and the blue beam 8B are vertically displaced as shown in FIG.

Experiments have confirmed that the effect on the screen generated by the magnetic field formed by the compensation coil 4 wound around the CRT 1 varies depending on the position where the compensation coil is wound. That is, when the compensating coil is wound around the panel 1b like the coil 4 in FIG. 9, the raster rotation and the purity rotation simultaneously appear. If the compensation coil is wound near the deflection yoke (for example, around the funnel 1c), raster rotation mainly appears. And the compensation coil is neck 1.
If it is wound around d, a vertical beam misconvergence change of the side beam appears.

[0010]

Since the conventional color cathode ray tube display device is constructed as described above,
With a single compensation coil wound around the panel,
As described above, since only the raster rotation and the purity rotation can be changed, there has been a problem that vertical beam misconvergence correction of the side beam cannot be performed. Also,
Even if the raster rotation and the purity rotation are corrected, the specifications (number of turns, etc.) of the compensation coil 4 can be set only once, so
Only the best adjustment, focusing on one, or the compensatory compromise between the two, was insufficiently corrected. Therefore, there is a problem in that color shift, position shift, etc. on the screen may occur depending on the state of the external magnetic field such as the earth magnetism.

The present invention has been made to solve the above problems, and an object thereof is to obtain a color cathode ray tube display device capable of effectively eliminating various adverse effects of an external magnetic field in the tube axis direction.

[0012]

A color cathode ray tube display device according to the invention of claim 1 is based on the output of a magnetic detection element and is proportional to the strength of an external magnetic field in the tube axis direction and corresponds to the polarity thereof. A compensating coil, which is supplied with a current by a current supply circuit that outputs a current, is arranged near the neck of the color cathode ray tube, and the neck side compensating coil strikes a vertical beam misconvergence change due to the external magnetic field. It generates a magnetic field for erasing.

In the color cathode ray tube display device according to the invention of claim 2, a current supply for outputting a current in a direction proportional to the strength of the external magnetic field in the tube axis direction and corresponding to the polarity thereof based on the output of the magnetic detection element. Compensation coils, to which current is supplied by the circuit, are arranged near the deflection yoke and near the neck of the color cathode ray tube, and the deflection yoke side compensation coil generates a magnetic field for canceling the raster rotation due to the external magnetic field. Then, the neck side compensating coil generates a magnetic field for canceling the vertical crack misconvergence change of the side beam due to the external magnetic field.

A color cathode ray tube display device according to a third aspect of the present invention is a current supply for outputting a current in a direction proportional to the strength of an external magnetic field in the tube axis direction and corresponding to the polarity thereof based on the output of a magnetic detection element. Compensation coils supplied with current by the circuit are respectively arranged near the panel of the color cathode ray tube and near the neck, and a magnetic field for canceling the purity rotation by the external magnetic field is generated by the panel side compensation coil, The neck side compensating coil generates a magnetic field for canceling the vertical beam misconvergence change of the side beam due to the external magnetic field.

A color cathode ray tube display device according to a fourth aspect of the present invention is a current supply for outputting a current in a direction proportional to the strength of an external magnetic field in the tube axis direction and corresponding to its polarity based on the output of the magnetic detection element. Compensation coils, to which current is supplied by the circuit, are arranged near the panel of the color cathode ray tube, near the deflection yoke, and near the neck, respectively, and the panel-side compensation coil is for canceling the purity rotation due to the external magnetic field. To generate a magnetic field, the deflection yoke side compensating coil generates a magnetic field for canceling the raster rotation due to the external magnetic field, and the neck side compensating coil cancels the vertical crack misconvergence change of the side beam due to the external magnetic field. To generate a magnetic field.

According to the fifth aspect of the present invention, there is provided a color cathode ray tube display device comprising a compensating coil supplied with a current by a current supply circuit for outputting a current having a magnitude and a direction according to the output of the user control means. Disposed near the panel of the tube and near the deflection yoke, the panel side compensation coil generates a magnetic field for canceling the purity rotation due to the external magnetic field in the tube axis direction, and the deflection yoke side compensation coil generates the external magnetic field. A magnetic field is generated to cancel the raster rotation due to

According to a sixth aspect of the present invention, there is provided a color cathode ray tube display device comprising a compensating coil supplied with a current by a current supply circuit for outputting a current having a magnitude and a direction according to the output of the user control means. The deflection yoke side compensating coil generates a magnetic field for canceling the raster rotation by the external magnetic field, and the neck side compensating coil generates a side beam by the external magnetic field. A vertical magnetic field is generated to cancel the vertical convergence misconvergence change.

According to a seventh aspect of the present invention, there is provided a color cathode ray tube display device comprising a compensating coil supplied with a current by a current supply circuit for outputting a current having a magnitude and a direction according to an output of the user control means. They are arranged near the panel of the tube and near the neck respectively, and the panel side compensation coil generates a magnetic field for canceling the purity rotation due to the external magnetic field in the tube axis direction, and the neck side compensation coil generates the side by the external magnetic field. A magnetic field is generated to cancel the vertical beam mis-convergence change.

In a color cathode ray tube display device according to an eighth aspect of the present invention, a color cathode ray tube is provided with a compensating coil supplied with a current by a current supply circuit that outputs a current of a magnitude and a direction according to the output of the user control means. The deflection coil side compensation coil is disposed near the panel of the tube, near the deflection yoke, and near the neck, and the panel side compensation coil generates a magnetic field for canceling the purity rotation due to the external magnetic field in the tube axis direction. To generate a magnetic field for canceling the raster rotation by the external magnetic field, and a neck side compensating coil for generating a magnetic field for canceling the vertical crack misconvergence change of the side beam by the external magnetic field.

[0020]

According to the present invention, the current supply circuit outputs the current in the direction proportional to the strength of the external magnetic field in the tube axis direction and corresponding to the polarity thereof, based on the output of the magnetic detection element. Then, the neck side compensating coil is supplied with a current by the current supply circuit to generate a magnetic field for canceling the vertical beam misconvergence change of the side beam due to the external magnetic field.

The current supply circuit according to the second aspect of the invention is
Based on the output of the magnetic detection element, a current is output in a direction proportional to the strength of the external magnetic field in the tube axis direction and corresponding to its polarity.
Then, the deflection yoke side compensating coil generates a magnetic field for canceling the raster rotation due to the external magnetic field, and the neck side compensating coil generates the side beam due to the external magnetic field by being supplied with the current by the current supply circuit. A vertical magnetic field is generated to cancel the vertical convergence misconvergence change.

The current supply circuit according to the invention of claim 3 is
Based on the output of the magnetic detection element, a current is output in a direction proportional to the strength of the external magnetic field in the tube axis direction and corresponding to its polarity.
Then, a current is supplied by this current supply circuit, the panel side compensating coil generates a magnetic field for canceling the purity rotation by the external magnetic field, and the neck side compensating coil generates the side beam by the external magnetic field. A magnetic field is generated to cancel the vertical convergence misconvergence change.

The current supply circuit according to the invention of claim 4 is
Based on the output of the magnetic detection element, a current is output in a direction proportional to the strength of the external magnetic field in the tube axis direction and corresponding to its polarity.
Then, when the current is supplied by the current supply circuit, the panel side compensation coil generates a magnetic field for canceling the purity rotation due to the external magnetic field, and the deflection yoke side compensation coil is subjected to the raster rotation due to the external magnetic field. The neck side compensation coil generates a magnetic field for canceling the vertical beam misconvergence change of the side beam due to the external magnetic field.

The current supply circuit according to the invention of claim 5 is
A current having a magnitude and direction corresponding to the output of the user control means operated by the user is output. Then, when the current is supplied by the current supply circuit, the panel side compensation coil generates a magnetic field for canceling the purity rotation due to the external magnetic field, and the deflection yoke side compensation coil is subjected to the raster rotation due to the external magnetic field. Generates a magnetic field for canceling.

The current supply circuit according to the invention of claim 6 is
A current having a magnitude and direction corresponding to the output of the user control means operated by the user is output. Then, the deflection yoke side compensating coil generates a magnetic field for canceling the raster rotation due to the external magnetic field, and the neck side compensating coil generates the side beam due to the external magnetic field by being supplied with the current by the current supply circuit. A vertical magnetic field is generated to cancel the vertical convergence misconvergence change.

The current supply circuit according to the invention of claim 7 is
A current having a magnitude and direction corresponding to the output of the user control means operated by the user is output. Then, a current is supplied by this current supply circuit, the panel side compensating coil generates a magnetic field for canceling the purity rotation by the external magnetic field, and the neck side compensating coil generates the side beam by the external magnetic field. A magnetic field is generated to cancel the vertical convergence misconvergence change.

The current supply circuit according to the invention of claim 8 is
A current having a magnitude and direction corresponding to the output of the user control means operated by the user is output. Then, when the current is supplied by the current supply circuit, the panel side compensation coil generates a magnetic field for canceling the purity rotation due to the external magnetic field, and the deflection yoke side compensation coil is subjected to the raster rotation due to the external magnetic field. The neck side compensation coil generates a magnetic field for canceling the vertical beam misconvergence change of the side beam due to the external magnetic field.

[0028]

【Example】

Example 1. An embodiment of the present invention will be described below with reference to the drawings. 1 is a side sectional view showing a color cathode ray tube display device according to an embodiment of the present invention. In addition,
The same members as those of the conventional color cathode ray tube display device shown in FIG. 9 are designated by the same reference numerals and the description thereof will be omitted. In FIG. 1, reference numeral 11 is wound around the neck 1d of the CRT 1 and receives the current from the current supply circuit 3 as an input to cancel the vertical beam splitting misconvergence change of the side beam due to the external magnetic field in the tube axis direction of the CRT 1. This is a neck side compensation coil that generates a magnetic field. The number of turns of the neck side compensation coil 11 is determined based on experiments and the like so that the vertical crack misconvergence change of the side beam can be compensated by the current from the current supply circuit 3.

Next, the operation will be described. First, the polarity and strength of the external magnetic field acting in the tube axis direction of the CRT 1 detected by the magnetic detection element 2 are converted into an electric signal and input to the current supply circuit 3. The current supply circuit 3 supplies a current proportional to the strength of the magnetic field to the neck side compensation coil 11 according to the electric signal from the magnetic detection element 2. Then, the neck side compensating coil 11 generates a compensating magnetic field that sufficiently cancels the magnetic field that causes the vertical splitting misconvergence change of the side beam.

Therefore, according to the apparatus of this embodiment, the CR
Optimal compensation for vertical beam misconvergence change of the side beam due to the external magnetic field in the tube axis direction of T1 can be automatically performed. In this embodiment, there is no need for compensation because there is a sufficient margin for the raster rotation and the purity rotation with respect to the external magnetic field in the tube axis direction of the CRT 1, but there is no need for compensation due to side beam vertical crack misconvergence changes. This is effective when you want to compensate for the deterioration of quality.

Example 2. Next, an embodiment of the invention of claim 2 will be described with reference to FIG. The same members as those of the color cathode ray tube display device according to the first embodiment shown in FIG. 1 are designated by the same reference numerals and the description thereof will be omitted. In FIG. 2, reference numeral 10 is wound around the deflection yoke 5 of the CRT 1 and receives the current from the current supply circuit 3 as an input to generate a magnetic field for canceling the raster rotation by the external magnetic field in the tube axis direction. It is a coil for compensation.

The number of coil turns of the deflection yoke side compensation coil 10 is determined as follows. First, since the deflection yoke side compensation coil 10 is wound around the outer periphery of the panel side separator flange 6 of the deflection yoke 5 of the CRT 1 in this case, it mainly has a raster rotation compensation function as described above. Therefore, the number of turns of the deflection yoke side compensation coil 10 is determined by experiments or the like so that the raster rotation is compensated by the current from the current supply circuit 3. In addition, each compensation coil 10 for the current supply circuit 3,
The connection form of 11 may be either serial or parallel.

Next, the operation will be described. First, the polarity and strength of the external magnetic field acting in the tube axis direction of the CRT 1 detected by the magnetic detection element 2 are converted into an electric signal and input to the current supply circuit 3. In the current supply circuit 3, a current proportional to the strength of the magnetic field is supplied to each of the compensation coils 10 and 11 according to the electric signal from the magnetic detection element 2. Then, of the external magnetic field, the magnetic field for generating the raster rotation is completely canceled by the magnetic field generated in the deflection yoke side compensating coil 10. Further, the neck side compensation coil 11 is
Independently of the deflection yoke side compensating coil 10, a compensating magnetic field that sufficiently cancels the magnetic field that causes vertical crack misconvergence change of the side beam is generated.

Therefore, according to the apparatus of this embodiment, the single current supply circuit 3 simultaneously and optimally compensates the raster rotation and the side beam vertical crack misconvergence change due to the external magnetic field in the tube axis direction of the CRT 1. It can be done automatically. In this embodiment, there is no need to compensate for the external magnetic field in the axial direction of the CRT 1 in terms of purity, but there is no need for compensation, but screen quality due to raster rotation and side beam vertical crack misconvergence changes. This is effective when you want to compensate for the decrease in

Example 3. Next, an embodiment of the invention of claim 3 will be described with reference to FIG. In FIG. 3, 9 is a CRT
1 is a panel-side compensating coil that is wound around the panel 1b and receives a current from the current supply circuit 3 as an input to generate a magnetic field for canceling the purity rotation due to the external magnetic field in the tube axis direction.

The number of coil turns of each compensation coil is determined as follows. First, the panel side compensation coil 9
Is wound around the panel 1a of the CRT 1 and therefore has the compensation function for both the purity rotation and the raster rotation as described above. However, here, focusing only on the compensation of the purity rotation, the number of turns of the panel side compensation coil 9 is optimally selected by experiments or the like so that the current from the current supply circuit 3 compensates the purity rotation. Next, the neck side compensating coil 11 determines the number of turns so that the vertical crack misconvergence change of the side beam can be compensated by the current from the current supply circuit 3. The compensation coils 9 and 11 may be connected to the current supply circuit either in series or in parallel.

Next, the operation will be described. First, the polarity and strength of the external magnetic field acting in the tube axis direction of the CRT 1 detected by the magnetic detection element 2 are converted into an electric signal and input to the current supply circuit 3. The current supply circuit 3 supplies a current proportional to the strength of the magnetic field to each of the compensation coils 9 and 11 in accordance with the electric signal from the magnetic detection element 2. Then,
Since the panel side compensating coil 9 is wound with an appropriate number of coil turns determined in advance, a compensating magnetic field that sufficiently cancels the pure rotation due to the external magnetic field in the tube axis direction of the CRT 1 is provided. generate. Further, the neck side compensating coil 11 independently of the panel side compensating coil 9 generates a compensating magnetic field that sufficiently cancels the magnetic field that causes vertical crack misconvergence change of the side beam.

Therefore, according to the apparatus of the present embodiment, the single current supply circuit 3 simultaneously and optimally compensates the purity rotation and the side beam vertical crack misconvergence change due to the external magnetic field in the tube axis direction of the CRT 1. It can be done automatically. In this embodiment, the raster rotation has a sufficient margin with respect to the external magnetic field in the tube axis direction of the CRT 1, so that it is not necessary to compensate, but the screen quality due to the purity rotation and the side beam vertical crack misconvergence change. This is effective when you want to compensate for the decrease in

Example 4. Next, an embodiment of the invention of claim 4 will be described with reference to FIG. In FIG. 4, 9 is a CRT
The panel side compensating coil 10 is wound around the panel 1b of FIG. 1 and receives a current from the current supply circuit 3 to generate a magnetic field for canceling the purity rotation due to the external magnetic field in the tube axis direction. A deflection yoke side compensating coil wound around the deflection yoke 5 and generating a magnetic field for canceling the raster rotation by the external magnetic field in the tube axis direction by receiving the current from the current supply circuit 3 as input, 11 is the CR
For neck side compensation, which is wound around the neck of T and which receives a current from the current supply circuit as an input to generate a magnetic field for canceling vertical beam splitting misconvergence change of the side beam due to the external magnetic field in the tube axis direction. It is a coil.

The number of coil turns of each compensation coil is determined as follows. First, the panel side compensation coil 9
Is wound around the panel 1a of the CRT 1 and therefore has the compensation function for both the purity rotation and the raster rotation as described above. However, here, focusing only on the compensation of the purity rotation, the number of turns of the panel side compensation coil 9 is optimally selected by experiments or the like so that the current from the current supply circuit 3 compensates the purity rotation. Next, since the deflection yoke side compensation coil 10 is wound around the outer periphery of the panel side separator flange 6 of the deflection yoke 5 of the CRT 1 in this case, it mainly has a raster rotation compensation function as described above. Therefore, the number of turns of the deflection yoke side compensation coil 10 is determined so that the remaining raster rotation that cannot be compensated by the panel side compensation coil 9 is compensated by the current from the current supply circuit 3. Finally, the neck side compensating coil 11 determines the number of turns so that the vertical crack misconvergence change of the side beam can be compensated by the current from the current supply circuit 3. The compensation coils 9, 10, 11 may be connected to the current supply circuit either in series or in parallel.

Next, the operation will be described. First, the polarity and strength of the external magnetic field acting in the tube axis direction of the CRT 1 detected by the magnetic detection element 2 are converted into an electric signal and input to the current supply circuit 3. In the current supply circuit 3, a current proportional to the strength of the magnetic field is supplied to each of the compensation coils 9, 10, 11 in accordance with the electric signal from the magnetic detection element 2. Then, since the panel-side compensating coil 9 is wound with a predetermined appropriate number of coil turns, compensation for sufficiently canceling out the purity rotation due to the external magnetic field in the tube axis direction of the CRT 1 is performed. Generate a magnetic field.

Here, the magnetic field generated by the panel side compensation coil 9 affects the raster rotation as well as the purity rotation, but since the number of coil turns is adjusted to compensate for the purity rotation, the panel side compensation coil 9 is used. The magnetic field that causes the raster rotation remains uncompensated. However, the deflection yoke side compensation coil 10 has a determined number of turns so that the remaining raster rotation that cannot be compensated by the panel side compensation coil 9 can be compensated by the current from the current supply circuit 3. The magnetic field that causes this raster rotation is completely canceled by the magnetic field generated in the deflection yoke side compensating coil 10. Further, the neck side compensation coil 11 is
Panel side compensation coil 9, deflection yoke side compensation coil 1
Independently of 0, a compensating magnetic field that sufficiently cancels the magnetic field that causes vertical beam misconvergence change of the side beam is generated.

Therefore, according to the apparatus of this embodiment, the single current supply circuit 3 optimally compensates the raster rotation, the purity rotation, and the side beam vertical crack misconvergence change due to the external magnetic field in the tube axis direction of the CRT 1. Can be performed simultaneously and automatically.

Example 5. Next, an embodiment of the invention of claim 5 will be described with reference to FIG. A characteristic of this embodiment is that a user control means 12 is provided instead of the magnetic detection element 2. The user control means 12 is, for example, a volume whose resistance value changes, a push button, or the like, and a CRT.
It is provided so that the user who is the user of 1 can operate it. Further, in this embodiment, the neck side compensation coil 11 is not provided.

Next, the operation will be described. When an external magnetic field in the tube axis direction acts on the CRT 1, the user judges the change of the image (purity rotation, raster rotation) due to this external magnetic field and operates the user control means 12. A current having a magnitude and direction corresponding to a signal from the control means 12 is supplied to each compensation coil 9,
10 are supplied respectively. Then, since the panel-side compensation coil 9 is wound with a predetermined appropriate number of coil turns, the operation amount and operation direction of the user control means 12 depend on the polarity and strength of the external magnetic field. If so, a compensating magnetic field that sufficiently cancels out the purity rotation due to the external magnetic field in the tube axis direction of the CRT 1 is generated.

Here, the magnetic field generated by the panel side compensation coil 9 affects the raster rotation as well as the purity rotation, but since the number of coil turns is adjusted to compensate for the purity rotation, the panel side compensation coil 9 is The magnetic field that causes the raster rotation remains uncompensated. However, the deflection yoke side compensation coil 10 has a determined number of turns so that the remaining raster rotation that cannot be compensated by the panel side compensation coil 9 can be compensated by the current from the current supply circuit 3. The magnetic field that causes this raster rotation is completely canceled by the magnetic field generated in the deflection yoke side compensating coil 10.

Therefore, according to the apparatus of this embodiment, one current supply circuit 3 simultaneously performs optimum compensation of raster rotation and purity rotation by the external magnetic field in the tube axis direction of the CRT 1 by one user control means 12. Can be done. It should be noted that this embodiment does not require compensation for the side beam vertical crack misconvergence change with respect to the external magnetic field in the tube axis direction of the CRT 1, but compensation is not necessary, but screen quality due to purity rotation and raster rotation is not necessary. This is effective when you want to compensate for the decrease in

Example 6. Next, an embodiment of the invention of claim 6 will be described with reference to FIG. The same members as those of the color cathode ray tube display device according to the fifth embodiment shown in FIG. 5 are designated by the same reference numerals and the description thereof will be omitted. A characteristic of this embodiment is that the panel side compensation coil 9 is not provided, but the deflection yoke side compensation coil 10 and the neck side compensation coil 11 are provided.

Next, the operation will be described. When an external magnetic field in the tube axis direction acts on the CRT 1, the user determines the image change (raster rotation, vertical beam misconvergence change of the side beam) due to this external magnetic field, and operates the user control means 12 to supply the current. In the circuit 3, a current having a magnitude and a direction corresponding to the signal from the user control means 12 is supplied to each of the compensation coils 10 and 11.

Then, the deflection yoke side compensation coil 10
The number of turns is determined so that it can be compensated by the current from the current supply circuit 3, so that the magnetic field that causes this raster rotation is completely canceled by the magnetic field generated in the deflection yoke side compensating coil 10. Further, the neck side compensating coil 11 generates a compensating magnetic field, which is independent of the deflection yoke side compensating coil 10, so as to sufficiently cancel the magnetic field that causes vertical crack misconvergence change of the side beam.

Therefore, according to the apparatus of the present embodiment, one current supply circuit 3 provides one optimum compensation for the raster rotation and the side beam vertical crack misconvergence change due to the external magnetic field in the tube axis direction of the CRT 1. It can be performed simultaneously by the user control means 12. In this embodiment, there is no need to compensate for the external magnetic field in the axial direction of the CRT 1 in terms of purity, but there is no need for compensation, but screen quality due to raster rotation and side beam vertical crack misconvergence changes. This is effective when you want to compensate for the decrease in

Example 7. Next, an embodiment of the invention of claim 7 will be described with reference to FIG. A characteristic of this embodiment is that the deflection yoke side compensation coil 10 is not provided, but the panel side compensation coil 9 and the neck side compensation coil 11 are provided.

In this embodiment, the raster rotation has a sufficient margin with respect to the external magnetic field in the direction of the tube axis of the CRT 1, so that compensation is not necessary, but the purity rotation and the side beam vertical crack misconvergence change. This is effective when you want to compensate for the deterioration of screen quality. That is, according to the apparatus of this embodiment, the operation similar to that of Embodiments 5 and 6 allows the single user control means 12 to optimize the purity rotation and the side beam vertical crack misconvergence change due to the external magnetic field in the tube axis direction of the CRT 1. Such compensation can be performed at the same time.

Example 8. Next, an embodiment of the invention of claim 8 will be described with reference to FIG. A characteristic of this embodiment is that the neck side compensation coil 11, the panel side compensation coil 9 and the deflection yoke side compensation coil 10 are all provided.

Next, the operation will be described. When an external magnetic field in the tube axis direction acts on the CRT 1, the user determines the image change (purity rotation, raster rotation, side beam vertical crack misconvergence change) due to this external magnetic field, and operates the user control means 12. In the current supply circuit 3, the compensation coils 9, 10 and 10 are supplied with a current having a magnitude and direction corresponding to the signal from the user control means 12.
11 respectively. Then, since the panel-side compensation coil 9 is wound with a predetermined appropriate number of coil turns, the operation amount and operation direction of the user control means 12 depend on the polarity and strength of the external magnetic field. If so, a compensating magnetic field that sufficiently cancels out the purity rotation due to the external magnetic field in the tube axis direction of the CRT 1 is generated.

Here, the magnetic field generated by the panel side compensation coil 9 affects the raster rotation as well as the purity rotation, but since the number of coil turns is adjusted to compensate for the purity rotation, the panel side compensation coil 9 is The magnetic field that causes the raster rotation remains uncompensated. However, the deflection yoke side compensation coil 10 has a determined number of turns so that the remaining raster rotation that cannot be compensated by the panel side compensation coil 9 can be compensated by the current from the current supply circuit 3. The magnetic field that causes this raster rotation is completely canceled by the magnetic field generated in the deflection yoke side compensating coil 10. Further, the neck side compensation coil 11 is
Panel side compensation coil 9, deflection yoke side compensation coil 1
Independently of 0, a compensating magnetic field that sufficiently cancels the magnetic field that causes vertical beam misconvergence change of the side beam is generated.

Therefore, according to the apparatus of this embodiment, the single current supply circuit 3 optimally compensates the raster rotation, the purity rotation, and the side beam vertical crack misconvergence change due to the external magnetic field in the tube axis direction of the CRT 1. Can be performed simultaneously by one user control means 12.

[0058]

As described above, according to the first aspect of the invention, the current supply for outputting the current in the direction proportional to the strength of the external magnetic field in the tube axis direction and corresponding to the polarity based on the output of the magnetic detection element. Since the compensation coil, which is supplied with current by the circuit, is arranged near the neck to prevent side beam vertical crack misconvergence change, side beam vertical crack misconvergence changes due to the external magnetic field in the tube axis direction. There is an effect that the optimum compensation of can be automatically performed.

According to the second aspect of the invention, the current is supplied by the current supply circuit that outputs the current in the direction proportional to the strength of the external magnetic field in the tube axis direction and corresponding to the polarity based on the output of the magnetic detection element. The compensating coils are arranged near the deflection yoke to prevent raster rotation, and near the neck to prevent side beam vertical crack misconvergence change. There is an effect that the raster rotation and the vertical crack misconvergence change of the side beam due to the external magnetic field in the direction can be optimally compensated simultaneously and automatically.

According to the third aspect of the invention, the current is supplied by the current supply circuit that outputs the current in the direction proportional to the strength of the external magnetic field in the tube axis direction and corresponding to the polarity based on the output of the magnetic detection element. The compensating coils are arranged near the panel for preventing rotation of purity and near the neck for preventing vertical beam misconvergence of side beams. There is an effect that the purity rotation due to the external magnetic field and vertical beam mis-convergence change of side beams can be optimally compensated simultaneously and automatically.

According to the fourth aspect of the invention, the current is supplied by the current supply circuit which outputs the current in the direction proportional to the strength of the external magnetic field in the tube axis direction and corresponding to the polarity based on the output of the magnetic detection element. Since the compensating coil is arranged near the panel for preventing purity rotation, near the deflection yoke for preventing raster rotation, and near the neck for preventing vertical beam misconvergence change of the side beams, respectively. With one current supply system, it is possible to simultaneously and automatically perform the optimum compensation of the raster rotation, the purity rotation, and the side beam vertical crack misconvergence change due to the external magnetic field in the tube axis direction.

According to the fifth aspect of the present invention, the compensating coil is supplied with the current by the current supply circuit that outputs the current of the magnitude and direction according to the output of the user control means.
Since it is arranged near the panel for preventing the rotation of the purity and near the deflection yoke for preventing the rotation of the raster, one user control is performed to optimally compensate the raster rotation and the purity rotation by the external magnetic field in the tube axis direction. There is an effect that it can be performed simultaneously by means.

According to the sixth aspect of the invention, the compensating coil is supplied with the current by the current supply circuit for outputting the current of the magnitude and direction according to the output of the user control means,
Raster rotation and side beam vertical cracking to prevent raster rotation and side beam vertical cracking to prevent misconvergence changes are arranged near the neck. There is an effect that the optimum compensation of the misconvergence change can be simultaneously performed by one user control means.

According to the invention of claim 7, there is provided a compensating coil to which a current is supplied by a current supply circuit for outputting a current of a magnitude and a direction according to the output of the user control means,
Since it is arranged near the panel for preventing purity rotation and near the neck for side beam vertical cracking, it is arranged near the neck for preventing convergence change.Therefore, purity rotation due to an external magnetic field in the tube axis direction and side beam vertical cracking error are caused. There is an effect that the optimum compensation of the convergence change can be simultaneously performed by one user control means.

According to the invention of claim 8, the compensating coil is supplied with a current by a current supply circuit for outputting a current of a magnitude and a direction according to the output of the user control means,
Since it is arranged near the panel to prevent purity rotation, near the deflection yoke to prevent raster rotation, and near the neck to prevent vertical crack misconvergence change of the side beams, the external magnetic field in the tube axis direction is arranged. There is an effect that one user control means can simultaneously perform the raster rotation, the purity rotation, and the optimal compensation of the side beam vertical crack misconvergence change.

[Brief description of drawings]

FIG. 1 is a side sectional view showing a color cathode ray tube display device according to an embodiment of the present invention.

FIG. 2 is a side sectional view showing a color cathode ray tube display device according to an embodiment of the present invention.

FIG. 3 is a side sectional view showing a color cathode ray tube display device according to an embodiment of the present invention.

FIG. 4 is a side sectional view showing a color cathode ray tube display device according to an embodiment of the present invention.

FIG. 5 is a side sectional view showing a color cathode ray tube display device according to an embodiment of the present invention.

FIG. 6 is a side sectional view showing a color cathode ray tube display device according to an embodiment of the present invention.

FIG. 7 is a side sectional view showing a color cathode ray tube display device according to an embodiment of the present invention.

FIG. 8 is a side sectional view showing a color cathode ray tube display device according to an embodiment of the present invention.

FIG. 9 is a side sectional view showing a conventional color cathode ray tube display device.

FIG. 10 is a diagram showing an example of raster rotation of a color cathode ray tube display device.

FIG. 11 is a diagram showing an example of a purity rotation of a color cathode ray tube display device.

FIG. 12 is a diagram showing an example of vertical beam misconvergence change of a side beam of a color cathode ray tube display device.

[Explanation of symbols]

 1 Color Cathode Ray Tube (CRT) 1a Electron Gun 1b Panel 1d Neck 2 Magnetic Detection Element 3 Current Supply Circuit 5 Deflection Yoke 9 Panel Side Compensation Coil 10 Deflection Yoke Side Compensation Coil 11 Neck Side Compensation Coil 12 User Control Means

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[Procedure amendment]

[Submission date] June 21, 1994

[Procedure Amendment 1]

[Document name to be amended] Statement

[Name of item to be corrected] 0003

[Correction method] Change

[Correction content]

The CRT 1 comprises a 3-beam type electron gun 1a and a panel 1b, and a deflection yoke 5 is arranged around a funnel 1c between them, and is provided inside the CRT.
It is magnetically shielded by an internal magnetic shield (not shown) provided . The magnetic detection element 2 detects the polarity and strength of the external magnetic field in the tube axis direction of the CRT 1 and outputs an electric signal corresponding to the polarity or strength. For example, a Hall element or the like is used. The current supply circuit 3 receives the electric signal from the magnetic detection element 2 and supplies to the compensation coil 4 a current that is proportional to the strength of the external magnetic field and flows in a direction corresponding to the polarity of the external magnetic field to cancel it. Is. The compensation coil 4 is C
This is for generating a compensating magnetic field that cancels the external magnetic field in the tube axis direction of the CRT 1 by being wound around the panel 1b of the RT1 and being supplied with the current from the current supply circuit 3.

[Procedure Amendment 2]

[Document name to be amended] Statement

[Correction target item name] 0004

[Correction method] Change

[Correction content]

Next, the operation will be described. The electron beam emitted from the electron gun 1a scans the panel 1b while being deflected by the magnetic field formed by the deflection yoke 5, and causes the phosphor coated on the panel 1b to emit light to form an electronic image on the panel 1b. Display it. At this time, provided inside the CRT1
The internal magnetic shield cuts off the effects of magnetic fields other than the external magnetic field in the axial direction of the tube connecting the panel 1b and the electron gun 1a in the external magnetic field such as the earth magnetism, and the adverse effect caused by this magnetic field (the panel 1b hit by the electron beam). Position change).

[Procedure 3]

[Document name to be amended] Statement

[Correction target item name] 0008

[Correction method] Change

[Correction content]

Here, the raster rotation means that the entire screen to be scanned rotates with respect to an appropriate position. Purity rotation means that the electron beam 8 that has passed through a shadow mask (not shown) rotationally moves (right rotation in this case) with respect to the phosphor 7 of the panel 1a to cause mislanding as shown by a dotted line in FIG. Is. When this purity rotation occurs, the electron beam 8 impinges only on the portion of the phosphor 7 indicated by the diagonal lines in FIG. 11, and only this portion emits light. In addition, misconvergence change means that each
Is caused by the bombs striking different points on the panel 1a.
A change in sconvergence . in this case,
For example, the red beam 8R and the blue beam 8B are vertically displaced as shown in FIG.

[Procedure amendment 4]

[Document name to be amended] Statement

[Correction target item name] 0010

[Correction method] Change

[Correction content]

[0010]

Since the conventional color cathode ray tube display device is constructed as described above,
With a single compensation coil wound around the panel,
As described above, since only the raster rotation and the purity rotation can be changed, there has been a problem that vertical beam misconvergence correction of the side beam cannot be performed. Also,
Even if the raster rotation and the purity rotation are corrected, the specifications (number of turns, etc.) of the compensation coil 4 can be set only once, so
Only the best adjustment, focusing on one, or the compensatory compromise between the two, was insufficiently corrected. Therefore, there is a problem in that color misregistration on the screen, raster rotation, or a defect in purity may occur depending on the state of an external magnetic field such as the earth's magnetism.

[Procedure Amendment 5]

[Document name to be corrected] Drawing

[Correction target item name] All drawings

[Correction method] Change

[Correction content]

[Figure 1]

[Fig. 2]

[Figure 3]

[Figure 4]

[Figure 5]

[Figure 6]

[Figure 7]

[Figure 8]

[Figure 9]

[Figure 10]

FIG. 11

[Fig. 12]

Claims (8)

[Claims] 1. A color cathode ray tube for deflecting an electron beam emitted from an electron gun by a deflection yoke to display an image on a panel, and a polarity of an external magnetic field acting in a tube axis direction connecting the electron gun and the panel. A magnetic detection element that detects the strength, converts the strength into an electric signal and outputs the electric signal, and a current supply circuit that inputs the electric signal and outputs a current in a direction proportional to the strength of the external magnetic field and corresponding to the polarity thereof. And a magnetic field that is wound around the neck of the color cathode ray tube and receives the current from the current supply circuit as an input to cancel the vertical beam splitting misconvergence change due to the external magnetic field in the tube axis direction. A color cathode ray tube display device having a neck side compensation coil. 2. A color cathode ray tube for deflecting an electron beam emitted from an electron gun by a deflection yoke to display an image on a panel, and a polarity of an external magnetic field acting in a tube axis direction connecting the electron gun and the panel. A magnetic detection element that detects the strength, converts the strength into an electric signal and outputs the electric signal, and a current supply circuit that inputs the electric signal and outputs a current in a direction proportional to the strength of the external magnetic field and corresponding to the polarity thereof. And a deflection yoke side compensator that is wound around the deflection yoke of the color cathode ray tube and generates a magnetic field for canceling raster rotation due to an external magnetic field in the tube axis direction by inputting a current from the current supply circuit. Coil and a coil around the neck of the color cathode ray tube and receives the current from the current supply circuit as an input to cause vertical side beam mis-convergence variation due to an external magnetic field in the tube axis direction. A cathode ray tube display device having a neck side compensating coil for generating a magnetic field for canceling the deterioration. 3. A color cathode ray tube for deflecting an electron beam emitted from an electron gun by a deflection yoke to display an image on a panel, and a polarity of an external magnetic field acting in a tube axis direction connecting the electron gun and the panel. A magnetic detection element that detects the strength, converts the strength into an electric signal and outputs the electric signal, and a current supply circuit that inputs the electric signal and outputs a current in a direction proportional to the strength of the external magnetic field and corresponding to the polarity thereof. And a panel side compensating coil that is wound around the panel of the color cathode ray tube and that generates a magnetic field for canceling the purity rotation due to the external magnetic field in the tube axis direction by receiving the current from the current supply circuit as an input. And is wound around the neck of the color cathode ray tube to cancel the vertical beam misconvergence change of the side beam due to the external magnetic field in the tube axis direction by using the current from the current supply circuit as an input. And a neck side compensation coil for generating a magnetic field for the color cathode ray tube display device. 4. A color cathode ray tube for deflecting an electron beam emitted from an electron gun by a deflection yoke to display an image on a panel, and a polarity of an external magnetic field acting in a tube axis direction connecting the electron gun and the panel. A magnetic detection element that detects the strength, converts the strength into an electric signal and outputs the electric signal, and a current supply circuit that inputs the electric signal and outputs a current in a direction proportional to the strength of the external magnetic field and corresponding to the polarity thereof. And a panel side compensating coil that is wound around the panel of the color cathode ray tube and that generates a magnetic field for canceling the purity rotation due to the external magnetic field in the tube axis direction by receiving the current from the current supply circuit as an input. And a deflection coil that is wound around the deflection yoke of the color cathode ray tube and that generates a magnetic field for canceling the raster rotation due to the external magnetic field in the tube axis direction by receiving the current from the current supply circuit as an input. And a coil for compensating the side of the color cathode ray tube, which is wound around the neck of the color cathode ray tube and receives the current from the current supply circuit as an input to strike a vertical beam misconvergence change of the side beam due to an external magnetic field in the tube axis direction. A color cathode ray tube display device having a neck side compensation coil for generating a magnetic field for erasing. 5. A color cathode ray tube for deflecting an electron beam emitted from an electron gun by a deflection yoke to display an image on a panel, and a user control means operable by a user,
A current supply circuit for inputting an electrical signal from the user control means and outputting a current according to the operation amount and direction of the user control means, and the current supply circuit wound around the panel of the color cathode ray tube. A coil for compensating the panel side, which generates a magnetic field for canceling the purity rotation due to the external magnetic field in the tube axis direction by inputting the current from the input, and is wound in the vicinity of the deflection yoke of the color cathode ray tube to supply the current. A color cathode ray tube display device comprising: a deflection yoke side compensating coil which receives a current from a circuit as an input and generates a magnetic field for canceling raster rotation due to an external magnetic field in the tube axis direction. 6. A color cathode ray tube for deflecting an electron beam emitted from an electron gun by a deflection yoke to display an image on a panel, and a user control means operable by a user.
A current supply circuit for inputting an electrical signal from the user control means and outputting a current according to the operation amount and direction of the user control means, and a current supply circuit wound around the deflection yoke of the color cathode ray tube to supply the current. A deflection yoke side compensating coil for generating a magnetic field for canceling raster rotation due to an external magnetic field in the tube axis direction with a current from a circuit as an input, and the current wound around the neck of the color cathode ray tube. A color cathode ray tube display device comprising: a neck side compensating coil that receives a current from a supply circuit as an input and generates a magnetic field for canceling longitudinal crack misconvergence change of a side beam due to an external magnetic field in the tube axis direction. 7. A color cathode ray tube for deflecting an electron beam emitted from an electron gun by a deflection yoke to display an image on a panel, and a user control means operable by a user.
A current supply circuit for inputting an electric signal from the user control means and outputting a current according to the operation amount and direction of the user control means, and the current supply circuit wound around the panel of the color cathode ray tube. A panel side compensating coil for generating a magnetic field for canceling the purity rotation due to the external magnetic field in the tube axis direction by inputting a current from the tube, and the current supply circuit wound around the neck of the color cathode ray tube. And a neck side compensation coil for generating a magnetic field for canceling vertical crack misconvergence change of the side beam due to the external magnetic field in the tube axis direction as an input. 8. A color cathode ray tube for deflecting an electron beam emitted from an electron gun by a deflection yoke to display an image on a panel, and a user control means operable by a user.
A current supply circuit for inputting an electrical signal from the user control means and outputting a current according to the operation amount and direction of the user control means, and the current supply circuit wound around the panel of the color cathode ray tube. A coil for compensating the panel side for generating a magnetic field for canceling the purity rotation due to the external magnetic field in the tube axis direction with the current from the input, and wound around the deflection yoke of the color cathode ray tube, and supplying the current. A deflection yoke side compensating coil for generating a magnetic field for canceling raster rotation due to an external magnetic field in the tube axis direction with a current from a circuit as an input, and the current wound around the neck of the color cathode ray tube. A magnet for canceling the vertical beam splitting misconvergence change of the side beam due to the external magnetic field in the tube axis direction by inputting the current from the supply circuit. Color cathode ray tube display apparatus provided with a neck-side compensating coil for generating.