JP3417174B2 - Electromagnetic focus circuit - Google Patents

Description

Detailed Description of the Invention

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a CRT (cathode-ray tube) used in a television receiver or a projection display device.
The electromagnetic focus circuit of.

[0002]

2. Description of the Related Art In recent years, high-definition television, clear vision,
Or, in order to obtain high image quality in the display of computer information processing, improvement of the focus circuit of the CRT is desired.
The present invention provides improvements in electromagnetic focus circuits. Electromagnetic focusing circuits are used, for example, for CRTs in projection display devices that require very large electron beam current densities. FIG. 21 shows a conventional electromagnetic focusing circuit. The class A amplifier 94 amplifies the difference between the focus current signal S3 and the voltage of the current detection resistor 96 in class A, and supplies the focus current I to the focus coil 95.

Here, the focus current I is shown below. E = A (S3-RI). ． ． ． ． ． ． ． ． ． (1) Here, E: output voltage of class A amplifier 94 A: amplification degree of class A amplifier 94 R: resistance of current detection resistor 96 I = E / (2ΠjfL + R). ． ． ． ． ． ． ． (2) Here, L is the inductance of the focus coil 95 j is the imaginary part f is the frequency (1) (2), and I (2ΠjfL + R) / A = S3-RI. ． ． (3) In (3), A = ∞ and I = S3 / R
． ． ． ． ． ． (4) That is, the focus current I is the focus current signal S3.
Proportional to.

FIG. 22A shows a focus current signal S3.
Indicates. (B) shows the focus coil voltage. (C)
Indicates the focus current i. The focus coil voltage (b) is equal to Ldi / dt.

[0005]

In various cases, in recent years, the horizontal frequency has been increased in order to obtain high image quality of multi-horizontal sweep. Since di / dt is proportional to the horizontal frequency, the focus coil voltage increases in proportion to the horizontal frequency. Therefore, the supply voltage to the class A amplifier 94 that outputs the focus coil voltage must be increased at least in proportion to the increase of the horizontal frequency. This, of course, increases the power consumption in the Class A amplifier 94. More recently, the flattening of the CRT surface or the C
The difference in the length of the electron beam between the center and the peripheral edge of the CRT is increasing due to the concave shape of the CRT surface for shortening the projection distance at the RT or the increase of the deflection angle accompanying the downsizing of the CRT. This requires a larger focus current, resulting in a further increase in power consumption in the Class A amplifier 94. However, it is difficult for the conventional electromagnetic focus circuit to significantly reduce power consumption.

[0006]

In order to solve the above-mentioned problems, an electromagnetic focusing circuit for a CRT according to the present invention has a power source having a positive electrode and a negative electrode, a focus having a first terminal and a second terminal. A coil and a first coupled between the positive electrode of the power source and the first end of the focus coil.
Switching means, second switching means coupled between the negative electrode of the power supply and the first terminal of the focus coil, and between the positive electrode of the power supply and the second terminal of the focus coil. A third switching means coupled to the fourth switching means coupled between the negative electrode of the power supply and the second terminal of the focus coil; And a switching control means for turning on or off each of the switching means.

[0007]

BEST MODE FOR CARRYING OUT THE INVENTION The electromagnetic focusing circuit of the present invention is
It is composed of a combination of many switching means. The switching control means turns each switching means on or off individually so that a current similar to the parabolic waveform current that achieves desired focusing flows in the focus coil in synchronization with the horizontal sweep. Energy is provided to the focus coil from the power supply when the focus current is increased. However, when the focus current is reduced, energy is returned from the focus coil to the power supply by the flywheel current. Therefore, the focus current is supplied with a small loss.

According to a first aspect of the present invention, there is provided a power source having a positive electrode and a negative electrode, a focus coil having a first terminal and a second terminal, a positive electrode of the power source and a first electrode of the focus coil. First switching means coupled between the terminals, second switching means coupled between the negative electrode of the power supply and the first terminal of the focus coil, positive electrode of the power supply and focus Second of coil
Third switching means coupled between the two terminals of the power source, and fourth switching means coupled between the negative electrode of the power supply and the second terminal of the focus coil;
An electromagnetic focus circuit having switching control means for turning on or off each of the switching means in accordance with a command instructing the current of the focus coil, and has the following actions.

In the embodiment of the present invention according to claim 1, for example, as shown in FIG. 1, an electromagnetic focusing circuit composed of a combination of four switching means is approximated to a parabolic waveform in the following steps. Provides a trapezoidal electric current. In the first embodiment of the present invention, as shown in FIG. 11, a trapezoidal focus current approximate to a parabolic waveform is provided by a combination of ON / OFF of four switching means. Here, the periods (1) to (4) in FIG. 11D are as follows.

(Period 1) Focus current is zero. (Period 2) The focus coil is connected to the power supply. The focus current increases linearly from zero with some slope.
During this period, the power supply supplies energy to the focus coil. (Period 3) The power supply is disconnected from the focus coil,
The focus coil is short-circuited. The focus current during this period is a flywheel current generated by energy stored in the inductance of the focus coil and circulating in the short circuit. Since the loss of the short circuit is small, the attenuation of the focus current is small.

(Period 4) The power supply is inserted in the short circuit in the direction opposite to the flywheel current. The focus current for this period is a flywheel current that is continuous from period 3 initially, but decreases linearly towards zero with some slope. This flywheel current flows against the supply voltage of the power supply while charging the power supply during the decrease.
Thus, a trapezoidal current is generated. During this period, the focus coil returns energy to the power supply and low power consumption is realized.

According to a second aspect of the present invention, a power source having a positive electrode and a negative electrode, a focus coil having a first terminal and a second terminal, a positive electrode of the power source and a first electrode of the focus coil are provided. A first switching means coupled between the terminals, a second switching means coupled between the negative electrode of the power supply and a second terminal of the focus coil, and a cathode having a first switching means of the focus coil. A first diode coupled to one terminal and an anode coupled to the negative electrode of the power supply; and a cathode coupled to a positive electrode of the power source and an anode coupled to a second terminal of the focus coil. 2 and the switching control means for turning on or off each of the switching means in accordance with a command instructing the current of the focus coil. An electromagnetic focus circuit which includes the door, as represented by the embodiment of the present invention shown in FIG. 2, to simplify the circuit, two diodes first
It is used as a replacement for the two switching means of the embodiment.

According to a third aspect of the present invention, a power source having a positive electrode and a negative electrode, a focus coil and a reactor connected in series having a first terminal and a second terminal, a positive electrode of the power source, and the reactor. First switching means coupled between the focus coil connected in series and the first terminal of the reactor; and between the negative electrode of the power supply, the focus coil connected in series and the second terminal of the reactor. Second switching means coupled to the positive electrode of the power supply, the focus coil connected in series, and the second of the reactor
A third switching means coupled between the terminals of the power source, a fourth switching means coupled between the negative electrode of the power supply, the focus coil connected in series, and the second terminal of the reactor; An electromagnetic focus circuit comprising a switching control means for turning on or off each of the switching means in accordance with a command instructing a current of the focus coil, wherein a reactor is connected in series to the focus coil in order to obtain a better focus. Inserted in.

The present invention according to claim 4 is the electromagnetic focus circuit according to claim 3, wherein the reactor is a saturable reactor, and a better focus can be obtained. First
A capacitor having a terminal and a second terminal, a power source having a positive electrode and a negative electrode connected in series connected to the capacitor in parallel, and a current control means for controlling a charging current flowing from the power source to the capacitor. , The first terminal and the second
A focus coil having a terminal, a first switching means coupled between a positive electrode of the power supply and a first terminal of the capacitor, and a negative electrode of the power supply and a first terminal of the capacitor. A second switching means coupled to the power source, a third switching means coupled between the positive electrode of the power source and the second terminal of the capacitor, a negative electrode of the power source and the second terminal of the capacitor. An electromagnetic focus circuit comprising: a fourth switching means coupled between the terminals of the above; and a switching control means for turning on or off each of the switching means in accordance with a command instructing a current of the focus coil. As represented by the embodiment of the present invention shown in FIG. 4, the parabolic wave is approximated by utilizing the charge and discharge of the capacitor.

According to a fifth aspect of the present invention, a power source having a positive electrode and a negative electrode, a focus coil having a first terminal and a second terminal, a positive electrode of the power source and a first focus coil are provided. First switching means coupled between the terminals, second switching means coupled between the negative electrode of the power source and the first terminal of the focus coil, positive electrode of the power source and the A third switching means coupled between the second terminal of the focus coil, the negative electrode of the power supply and the second of the focus coil
A fourth switching means coupled between the terminals, switching control means for turning on or off each of the switching means in accordance with a command instructing a current of the focus coil, and a supply voltage of the power supply. And a supply voltage control means for changing the supply voltage, which has means for changing the supply voltage in addition to the configuration of claim 1.

The present invention is the electromagnetic focus circuit according to claim 6 , wherein the supply voltage control means changes the power supply voltage in response to the peak of the current of the focus coil. In order to stabilize the focus current, as represented by the embodiment of the present invention,
The supply voltage is changed according to the focus current.

According to the present invention , a power source having a positive electrode and a negative electrode, a focus coil having a first terminal and a second terminal, and a positive electrode of the power source and a first terminal of the focus coil are coupled. First switching means,
Second switching means coupled between the negative electrode of the power supply and the first terminal of the focus coil; and a second switching means coupled between the positive electrode of the power supply and the second terminal of the focus coil. Switching means of No. 3, fourth switching means coupled between the negative electrode of the power supply and the second terminal of the focus coil, and each of the switching means according to a command instructing a current of the focus coil. 6 is an electromagnetic focus circuit including switching control means for individually turning on and off, supply voltage control means for changing the supply voltage of the power source, and current detection means for detecting the current of the focus coil. In order to stabilize the focus current, the supply voltage is set to the focus current as represented by the embodiment of the present invention shown in FIG. It is changed in response.

The present invention according to claim 6 provides a power supply having a positive electrode and a negative electrode, a focus coil having a first terminal and a second terminal, and a positive electrode of the power supply and a first terminal of the focus coil. A second switching means coupled between the negative electrode of the power supply and the second terminal of the focus coil, and a cathode of the first focus means of the focus coil. A second diode having a cathode coupled to the positive electrode of the power supply and an anode coupled to the second terminal of the focus coil. And a switching control means for turning on or off each of the switching means in accordance with a command instructing the current of the focus coil. Power is an electromagnetic focus circuit which includes a supply voltage control means for varying the supply voltage, to stabilize the focus current, supply voltage is changed corresponding to the focus current.

According to the present invention , a power source having a positive electrode and a negative electrode, a focus coil having a first terminal and a second terminal, and a positive electrode of the power source and a first terminal of the focus coil are coupled. First switching means, second switching means coupled between the negative electrode of the power supply and the second terminal of the focus coil, and a cathode coupled to the first terminal of the focus coil. A first diode whose anode is coupled to the negative electrode of the power supply, a second diode whose cathode is coupled to the positive electrode of the power supply and whose anode is coupled to the second terminal of the focus coil; Switching control means for turning on or off each of the switching means in accordance with a command for instructing a coil current, and a supply voltage of the power supply A supply voltage control means for varying said an electromagnetic focus circuit which includes a current detection means for detecting a current of the focus coil, in order to stabilize the focus current, supply voltage is changed corresponding to the focus current.

According to a seventh aspect of the present invention, a first power supply having a positive electrode and a negative electrode, and a first power supply having a first electrode and a second electrode are connected to the negative electrode of the first power supply. A second power supply, a focus coil having a first terminal and a second terminal, and first switching means coupled between the positive electrode of the first power supply and the first terminal of the focus coil. A second switching means coupled between the negative electrode of the first power supply and the first terminal of the focus coil; a positive electrode of the first power supply and a second terminal of the focus coil. A third switching means coupled between the second power supply and a fourth switching means coupled between the negative electrode of the first power supply and the second terminal of the focus coil; The first terminal of the focus coil and the first terminal of the focus coil. An electromagnetic focus circuit comprising a fifth switching means coupled between terminals and a switching control means for turning on or off each of the switching means in accordance with a command instructing a current of the focus coil. Yes, it has the following effects.

That is, as represented by the embodiment shown in FIG. 7, the second power supply is inserted in series with the focus coil during the period 2 of the first embodiment, and the flywheel current during the period 2 is increased. Is changed by the second power supply. The present invention according to claim 8 provides a first power supply having a positive electrode and a negative electrode, and a second power supply having a positive electrode and a negative electrode, the negative electrode being connected to the negative electrode of the first power supply. A power supply, a focus coil having a first terminal and a second terminal, and the first coil
First switching means coupled between the positive electrode of the power source and the first terminal of the focus coil, and between the negative electrode of the first power source and the first terminal of the focus coil. Second switching means, a third switching means coupled between the positive electrode of the first power supply and the second terminal of the focus coil, the negative electrode of the first power supply, and the third switching means. A fourth switching means coupled between the second terminals of the focus coil,
The positive electrode of the second power source and the first of the focus coil
Switching means coupled between the terminals of the focus coil, a sixth switching means coupled between the positive electrode of the second power supply and the second terminal of the focus coil, The electromagnetic focus circuit includes switching control means for turning on or off each of the switching means in accordance with a command for instructing the current, and has the following actions.

That is, as represented by the embodiment of the present invention shown in FIG. 8, the focus current is further provided by further including the second power source, the fifth switching means, and the sixth switching means. Is approximated by the parabolic waveform that achieves the desired focusing. 9. The present invention according to claim 9, wherein the first power source has a positive electrode and a negative electrode, and the second power source has a positive electrode and a negative electrode, and the negative electrode is connected to the negative electrode of the first power source. A focus coil having a first terminal and a second terminal; first switching means coupled between the positive electrode of the first power supply and the first terminal of the focus coil; 1
Second switching means coupled between the positive electrode of the power source and the second terminal of the focus coil, and between the negative electrode of the first power source and the second terminal of the focus coil. Third switching means, a fourth switching means coupled between the positive electrode of the second power supply and the first terminal of the focus coil, and a cathode having a first terminal of the focus coil. A first diode having an anode coupled to the negative electrode of the first power supply and a cathode coupled to the positive electrode of the second power supply and an anode coupled to the second terminal of the focus coil. And a second diode and a switching control means for turning on or off each of the switching means in accordance with a command instructing the current of the focus coil. An electromagnetic focus circuit with bets, has the following effects.

That is, as represented by the embodiment of the present invention shown in FIG. 9, two diodes are used as replacements for two switching means in order to simplify the circuit. The present invention according to claim 10 has a power source having a positive electrode and a negative electrode, a first focus coil having a first terminal and a second terminal, a first terminal and a second terminal, and A second focus coil cooperating with the first focus coil for focusing; first switching means coupled between a positive electrode of the power supply and a first terminal of the first focus coil. A second switching means coupled between a negative electrode of the power supply and a first terminal of the first focus coil, a positive electrode of the power supply and a second terminal of the first focus coil. A first switching means coupled between a negative electrode of the power source and a second terminal of the first focus coil; Of coil Switching control means for turning on or off each of the switching means individually according to a command for instructing a flow, a current detection means for detecting a current of the first focus coil, and a command for the first focus coil current. An electromagnetic focus circuit having the second focus coil current control means for supplying a current corresponding to the difference between the value and the detection value of the current detection means to the second focus coil, and has the following actions.

That is, as represented by the embodiment of the present invention shown in FIG. 10, a current corresponding to the difference between the trapezoidal waveform and the parabolic waveform is applied to the second focus coil so that desired focusing is realized. Supplied. (First Embodiment of the Invention) FIG. 1 shows a first embodiment of the present invention. In FIG. 1, a power supply having a positive electrode and a negative electrode
The supply voltage of the (power source) 1 is set to be large enough to supply the focus current and set corresponding to the horizontal frequency. The switching control means 7 is
In order to generate an appropriate focus current to be supplied to the focus coil 6 having the first terminal and the second terminal,
The horizontal signal S1 is used as a time reference to individually turn on or off the first switching means 2, the second switching means 3, the third switching means 4 and the fourth switching means 5.

FIG. 11 is a diagram showing the voltage-current waveform and the switching period in the first embodiment. here,
(A) to (d) show the following. (A) Desired waveform of focus current (b) Waveform of focus current (c) Voltage waveform of focus coil (d) On / off period of switching means The on / off period of each switching means is shown in FIG. 11 (d). One cycle of the focus current is the sum of the periods (1) to (4). By turning on / off each switching means, the focus coil voltage (focus c
oil voltage) is applied across the focus coil 6. As mentioned earlier, the focus coil voltage is L
It is equal to di / dt. Conversely speaking, the focus current flowing through the focus coil 6 is the integral of the focus coil voltage. Therefore, the focus current is (b)
Is. (A) is a desired parabolic waveform as the focus current. The trapezoidal focus current shown in (b) is trying to approximate the parabolic waveform shown in (a).

The details of the focus current in each period will be described below. (Period 1): Only the first switching means 2 is turned on. The focus coil voltage and focus current are zero. (Period 2): The first switching means 2 and the fourth switching means 5 are turned on. The supply voltage is applied to the focus coil 6 through the first switching means 2 and the fourth switching means 5. The focus current linearly increases with a certain gradient from zero so that the induced voltage Ldi / dt of the focus coil 6 becomes equal to the supply voltage. This increasing current approximates the desired parabolic waveform shown in (a). During this period, the power supply 1 supplies energy to the focus coil 6.

(Period 3): The first switching means 2 is turned off and the second switching means 3 is turned on. Focus coil, fourth switching means 5 and second
A short circuit formed by the switching means 3 is formed. The focus current during this period is the focus coil 6
The flywheel current is generated by the energy stored in the inductance of and circulates in the short circuit. Since the loss of the short circuit is small, the focus current is attenuated little during this period.

(Period 4): The fourth switching means 5 is turned off and the third switching means 4 is turned on. As a result, the power source 1 is connected to the focus coil 6 in the reverse direction. The focus current for this period is a flywheel current that is continuous from period 3 initially, but decreases linearly towards zero with some slope. This flywheel current flows against the supply voltage of the power supply while charging the power supply during the decrease. This reduced current approximates the desired parabolic waveform shown in (a). During this period the focus coil returns energy to the power supply by charging it with a flywheel current. This results in low power consumption.

(Second Embodiment of the Invention) FIG. 2 shows a second embodiment of the present invention. The second embodiment is obtained by replacing the second switching means 3 and the third switching means 4 in which the flywheel current of the first embodiment flows with a first diode 10 and a second diode 11. To be
Since this replacement has no effect on the flywheel current, the operation of the second embodiment is the same as that of the first embodiment.

FIG. 12 is a diagram showing a voltage / current waveform and a switching period in the second embodiment. here,
(A) to (f) show the following. (A) Desired waveform of focus current (b) Waveform of focus current (c) Voltage waveform of focus coil (d) On / off period of switching means (e) Voltage waveform of diode 10 (f) Voltage waveform of diode 11 Each switching means The on / off period of is shown in FIG. As a result, the voltage shown in (c) is applied to the focus coil 6. Since the voltage of the focus coil is equal to Ldi / dt as described above, the focus current shown in (b) flows through the focus coil 6. (A) is a desirable waveform of the focus current.
The focus current shown in (b) approximates the desired parabolic waveform shown in (a). (E) shows the voltage of the first diode 10. (F) shows the voltage of the second diode 11.

The replacement of the switching means through which the flywheel current flows with a diode can be usefully applied to other embodiments of the present invention. (Embodiment 3 of the Invention) FIG. 3 shows a third embodiment of the present invention. In the third embodiment, a saturable reactor (saturable-c) is connected in series with the focus coil 6 of the first embodiment.
ore reactor) 20 is connected to obtain. The third embodiment is
Other than the curvature of the focus current, it is the same as in the first embodiment.

FIG. 13 is a diagram showing a voltage / current waveform and a switching period in the third embodiment, and (a) to (d) show the following. (A) Desired waveform of focus current (b) Waveform of focus current (c) Voltage waveform of focus coil (d) On / off period of switching means The on / off period of each switching means is shown in FIG. 13 (d). As a result, the voltage indicated by (c) is applied to the focus coil 6 and the saturable reactor 20 connected in series. If the inductance of the series connection is constant, the focus current is linear as in the previous embodiments. However, since the inductance of the saturable reactor 20 decreases as the current increases, the curved focus current shown in (b) flows through the series connection of the focus coil 6 and the saturable reactor 20. (A) is a desirable parabolic waveform of the focus current. The focus current shown in (b) more closely approximates the desired parabolic waveform shown in (a) than the previous embodiment.

(Fourth Embodiment of the Invention) FIG. 4 shows a fourth embodiment of the present invention. In the fourth embodiment, the current control means 24 is connected in series to the power supply 1 of the first embodiment,
Further, it is obtained by connecting the capacitor 25 in parallel to the series connection. The capacitor 25 is charged by the power supply 1 through the current control means 24 according to the control signal S2. Further, the capacitor 25 outputs a focus current and is charged with the flywheel current of the focus coil 6. That is, the capacitor 25 is equivalently a power supply. The fourth embodiment is the same as the first embodiment except that the supply voltage can be changed by the control signal S2.

FIG. 14 is a diagram showing a voltage / current waveform and a switching period in the fourth embodiment, and (a) to (d) show the following. (A) Desired waveform of focus current (b) Waveform of focus current (c) Voltage waveform of focus coil (d) On / off period of switching means The on / off period of each switching means is shown in FIG. 14 (d). As a result, the voltage indicated by (c) is applied to the focus coil 6. The three waveforms corresponding to changes in the capacitor voltage are shown superimposed. As a result, the focus current shown in (b) flows through the focus coil 6. (A) is a desirable parabolic waveform of the focus current. The focus current shown in (b) approximates the desired parabolic waveform shown in (a). With this configuration, focusing accuracy can be improved.

(Fifth Embodiment of the Invention) FIG. 5 shows a fifth embodiment of the present invention. The fifth embodiment is obtained by adding a current detection resistor 38, a current detection circuit 39, and a supply voltage control means 13, which are connected in series and serve as a current detection means, to the focus coil 6 of the first embodiment. . The current detection circuit 39 detects a value corresponding to the peak of the focus current. The output of the current detection circuit 39 is sent to the supply voltage control means 13 through a signal transmission means such as a photocoupler, and the supply voltage is controlled so that the focus current is stabilized.

FIG. 15 is a diagram showing a voltage / current waveform and a switching period in the fifth embodiment.
(B) shows the following. (A) Output voltage waveform of current detection resistor 38 (b) Output voltage waveform of current detection circuit 39 The fifth embodiment is the same as the first embodiment except the stabilization of the focus current.

By using this configuration, the peak of the current flowing through the focus coil 6 can be accurately detected by directly detecting the current flowing through the focus coil 6 by the current detecting resistor 38. (Sixth Embodiment of the Invention) FIG. 6 shows a sixth embodiment of the present invention. In the sixth embodiment, the current detection resistor 38 and the current detection circuit 3 which are connected in series to the power supply of the first embodiment.
9 and supply voltage control means 13 are added.
The current detection circuit 39 detects the focus current. The output of the current detection circuit 39 is sent to the supply voltage control means 13 through a signal transmission means such as a photocoupler, and the supply voltage is controlled so that the focus current is stabilized.

FIG. 16 is a diagram showing a voltage / current waveform and a switching period in the sixth embodiment.
(B) shows the following. (A) Output voltage waveform of the current detection resistor 38 (b) Output voltage waveform of the current detection circuit 39 The sixth embodiment is the same as the first embodiment except the stabilization of the focus current.

With this configuration, the output of the current detection circuit 39 can directly control the supply voltage control means 13, so that the circuit scale can be reduced. (Seventh Embodiment of the Invention) FIG. 7 shows a seventh embodiment of the present invention. The seventh embodiment is obtained by adding the second power supply 51 that provides a variable supply voltage and the fifth switching means 8 to the first embodiment.

FIG. 17 is a diagram showing the voltage-current waveform and the switching period in the seventh embodiment, and (b) to (d) show the following. (B) Focus current waveform (c) Focus coil voltage waveform (d) ON / OFF period of switching means The ON / OFF period of each switching means is shown in FIG. 17 (d). The fifth switching means 8 is turned on only during the flywheel period when the power supply 1 is cut off. The variable supply voltage of the second power supply 51 is the fifth switching means 8
Is applied to the focus coil 6 only when is ON. As a result, the voltage indicated by (c) is applied to the focus coil 6. When the second power supply 51 is connected with the polarity shown in FIG. 17, the voltage of the second power supply 51 is directly applied to the focus coil 6 and the focus current increases while the switching means 8 is ON. The second power source 51 is shown in FIG.
If the polarity is reversed, the second power source 51
Is applied to the focus coil 6 in the reverse direction,
The focus current decreases while the switching means 8 is ON. The three waveforms corresponding to the change in the variable supply voltage of the second power supply 51 are shown in an overlapping manner. As a result, the focus current shown in (b) flows through the focus coil 6.

Therefore, by controlling the second power source 51, it is possible to correct the balance of the left and right focus of the CRT. (Eighth Embodiment of the Invention) FIG. 8 shows an eighth embodiment of the present invention. In the eighth embodiment, the second power source 60 and the fifth
Switching means 8 and sixth switching means 9
Is obtained by adding to the first embodiment. Second power source 6
The supply voltage of 0 is higher than that of the power supply 1. Second power source 60
The negative terminal of is connected to the negative terminal of the power supply 1. The fifth switching means 8 is coupled between the plus terminal of the second power supply 60 and one terminal of the focus coil 6. The sixth switching means 9 is coupled between the positive terminal of the second power supply 60 and the other terminal of the focus coil 6.

FIG. 18 is a diagram showing a voltage / current waveform and a switching period in the eighth embodiment, and (a) to (d) show the following. (A) Desired waveform of focus current (b) Waveform of focus current (c) Voltage waveform of focus coil (d) On / off period of switching means The on / off period of each switching means is shown in FIG. 18 (d). As a result, the voltage shown in (c) is applied to the focus coil 6, and the focus current shown in (b) flows through the focus coil 6. The focus current shown in (b) approximates the desired parabolic waveform shown in (a).

By using this structure, the accuracy of focusing can be improved. (Ninth Embodiment of the Invention) FIG. 9 shows a ninth embodiment of the present invention. The ninth embodiment is obtained by replacing the second switching means 3 and the sixth switching means 9 in which the flywheel current of the eighth embodiment flows with the first diode 10 and the second diode 11. To be Since this replacement has no effect on the flywheel current, the operation of the ninth embodiment is the same as that of the eighth embodiment.

FIG. 19 is a diagram showing a voltage / current waveform and a switching period in the ninth embodiment, and (a) to (f) show the following. (A) Desired waveform of focus current (b) Waveform of focus current (c) Voltage waveform of focus coil (d) On / off period of switching means (e) Voltage waveform of diode 10 (f) Voltage waveform of diode 11 Each switching means The on / off period of is shown in FIG. As a result, the voltage shown in (c) is applied to the focus coil 6, and the focus current shown in (b) flows through the focus coil 6. The focus current shown in (b) approximates the desired focus current shown in (a). (E) is the first diode 1
Indicates a voltage of 0. (F) shows the voltage of the second diode 11.

By using the diode 10 and the diode 11 as the switching means, the circuit configuration of the switching control means can be simplified. (Embodiment 10 of the Invention) FIG. 10 shows a tenth embodiment of the present invention. The focus current is detected by the current detection resistors 81 and 99. The voltage of the current detection resistor 81 is shown in FIG. The voltage of the current detection resistor 99 is shown in (c). The voltage of the current detection resistor 81 is provided to the switching means 89. The voltage of the current detection resistor 99 is provided to the switching means 89 through the inverter 88. The switching control means 87 uses the horizontal signal S1.
Corresponding to, a selection command for instructing whether to select the voltage of the current detection resistor 81 or the voltage of the current detection resistor 99 is output to the switching means 89.

FIG. 20 is a diagram showing a voltage / current waveform and a switching period in the tenth embodiment.
To (e) show the following. (A) Desired waveform of focus current (b) Voltage waveform of current detection resistor 81 (c) Voltage waveform of current detection resistor 99 (d) Focus current waveform (e) Difference between desired focus current and actual focus current Thus, The trapezoidal waveform focus current shown in (d) is input to one terminal of the subtraction amplifier 90. The subtraction amplifier 90 outputs the difference (e) between the parabolic waveform (a) and the trapezoid (d) that realizes the desired focusing. The class A amplifier 91 outputs a current corresponding to (e) to the second focus coil 92. The class A amplifier 91 uses the voltage of the current detection resistor 93 to generate the second focus coil 92.
Feedback control the current of. A desired focusing is realized by the sum of the focusing by the first focus coil 6 and the focusing by the second focus coil 92.

[0047]

According to the electromagnetic focus circuit of the CRT of the present invention, the power consumption can be significantly reduced.

[Brief description of drawings]

FIG. 1 is a diagram showing a first embodiment of an electromagnetic focusing circuit of the present invention.

FIG. 2 is a diagram showing a second embodiment of an electromagnetic focusing circuit of the present invention.

FIG. 3 is a diagram showing a third embodiment of an electromagnetic focusing circuit of the present invention.

FIG. 4 is a diagram showing a fourth embodiment of an electromagnetic focusing circuit of the present invention.

FIG. 5 is a diagram showing a fifth embodiment of an electromagnetic focusing circuit of the present invention.

FIG. 6 is a diagram showing a sixth embodiment of an electromagnetic focusing circuit of the present invention.

FIG. 7 is a diagram showing a seventh embodiment of an electromagnetic focusing circuit of the present invention.

FIG. 8 is a diagram showing an eighth embodiment of the electromagnetic focusing circuit of the present invention.

FIG. 9 is a diagram showing a ninth embodiment of an electromagnetic focusing circuit of the present invention.

FIG. 10 is a diagram showing a tenth embodiment of an electromagnetic focusing circuit of the present invention.

FIG. 11 is a diagram showing a voltage / current waveform and a switching period according to the first embodiment.

FIG. 12 is a diagram showing a voltage / current waveform and a switching period according to the second embodiment.

FIG. 13 is a diagram showing a voltage / current waveform and a switching period in the third embodiment.

FIG. 14 is a diagram showing a voltage / current waveform and a switching period according to the fourth embodiment.

FIG. 15 is a diagram showing a voltage / current waveform and a switching period according to the fifth embodiment.

FIG. 16 is a diagram showing a voltage / current waveform and a switching period in the sixth embodiment.

FIG. 17 is a diagram showing a voltage / current waveform and a switching period according to the seventh embodiment.

FIG. 18 is a diagram showing a voltage / current waveform and a switching period according to the eighth embodiment.

FIG. 19 is a diagram showing a voltage / current waveform and a switching period according to the ninth embodiment.

FIG. 20 is a diagram showing a voltage / current waveform and a switching period according to the tenth embodiment.

FIG. 21 is a diagram showing a conventional electromagnetic focus circuit.

FIG. 22 is a diagram showing voltage / current waveforms of a conventional electromagnetic focus circuit.

[Explanation of symbols]

1 power supply (first power supply) 2 First switching means 3 Second switching means 4 Third switching means 5 Fourth switching means 6 Focus coil 7 Switching control means 8 Fifth switching means 9 Sixth switching means 10 First diode 11 Second diode 13 Supply voltage control means 20 Saturable reactor 24 Current control means 25 capacitors 38 Current detection resistor 39 Current detection circuit 40 Signal transmission means 51, 60 Second power supply

Claims (10)

(57) [Claims] 1. A power supply having a positive electrode and a negative electrode, a focus coil having a first terminal and a second terminal, and a positive electrode of the power supply coupled to a first terminal of the focus coil. A first switching means, a second switching means coupled between the negative electrode of the power source and the first terminal of the focus coil, and a positive electrode of the power source and a second terminal of the focus coil. A third switching means coupled between them, a fourth switching means coupled between the negative electrode of the power supply and the second terminal of the focus coil, and period 1 to period 4 as one cycle
In the period 1, the first switching means is turned on, the second switching means is turned off, the third switching means is turned off, the fourth switching means is turned off, and the focus coil voltage is 0 (zero). In period 2, the first switching means is turned on, the second switching means is turned off, the third switching means is turned off, the fourth switching means is turned on, the power supply voltage is applied to the focus coil, and the period 3 is applied. The first switching means is off, the second switching means is on, the third switching means is off, the fourth switching means is on, the focus coil is short-circuited between the first terminal and the second terminal, and in the period 4. first switching means off, the second switching means oN, the third switching means oN, the fourth switching Stage off, the reverse polarity the power supply of the period 2 is to focus coils
Apply a voltage, so that the current of the focus coil
An electromagnetic focus circuit having a switching control means for turning on or off each of them according to an instruction to be given . 2. A power supply having a positive electrode and a negative electrode, a focus coil having a first terminal and a second terminal, and a positive electrode of the power supply coupled to the first terminal of the focus coil. First switching means, a second switching means coupled between the negative electrode of the power supply and the second terminal of the focus coil, and a cathode whose anode is coupled to the first terminal of the focus coil. A first diode coupled to the negative electrode of the power supply;
Each scan and a second diode having a cathode an anode coupled to the positive electrode of the power source is coupled to the second terminal of the focus coil, the period 1 to period 4 as 1 cycle
During the period 1, the first switching means is turned on, the second switching means is turned off, the focus coil voltage is 0 (zero), the first switching means is turned on, and the second switching means is turned on in the period 2 . the application of the supply voltage to the focus coil, period 3, the first switching means off, the second switching means oN, shorting the focus coil first terminal and a second terminal, in the period 4 second The first switching means is off, the second switching means is off, and the focus coil has the power source having a polarity opposite to that of the period 2.
Apply a voltage, so that the current of the focus coil
An electromagnetic focus circuit having a switching control means for turning on or off each of them according to an instruction to be given . 3. A power supply having a positive electrode and a negative electrode, a focus coil and a reactor connected in series having a first terminal and a second terminal, a positive electrode of the power supply and the focus coil connected in series. A first switching means coupled between a first terminal of the reactor and a second switching means coupled between the negative electrode of the power supply, the series-connected focus coil and the first terminal of the reactor. Switching means, a positive electrode of the power supply, a third switching means coupled between the series-connected focus coil and a second terminal of the reactor, and a negative electrode of the power supply and the series-connected focus a fourth switching means coupled between the second terminal of the coil and the reactor, the period
Each of the above switching means is defined as one cycle of the interval 1 to the period 4
In period 1, the first switching means is on, the second switching means is off, the third switching means is off, the fourth switching means is off, and the focus coil and the reactor voltage are 0 (zero).
B) In period 2, the first switching means is on, the second switching means is off, the third switching means is off, the fourth switching means is on, the focus coil and the reactor voltage are the power sources.
Voltage is applied, and during the period 3, the first switching means is off, the second switching means is on, the third switching means is off, the fourth switching means is on, the focus coil and the first terminal of the reactor. And the
Terminal 2 is short-circuited , in period 4, the first switching means is off, the second switching means is on, the third switching means is on, the fourth switching means is off, and the focus coil and the reactor are in a period. The opposite of 2
Applying the power supply voltage of polarity, so that the focus
Turn on each one according to the command that indicates the coil current.
Electromagnetic focus circuit with switching control means that turns on or off . 4. The electromagnetic focus circuit according to claim 3, wherein the reactor is a saturable reactor. 5. A power supply having a positive electrode and a negative electrode, a focus coil having a first terminal and a second terminal, and a positive electrode of the power supply and a first terminal of the focus coil. First switching means, a second switching means coupled between the negative electrode of the power supply and the first terminal of the focus coil, a positive electrode of the power supply and a second terminal of the focus coil. the negative electrode and the fourth switching means coupled between the second terminal of the focus coil, the period 1 to period 4 the one period of the third switching means coupled, the power supply during
As for each of the switching means in the period 1, the first switching means is on, the second switching means is off, the third switching means is off, the fourth switching means is off, and the focus coil voltage is 0 (zero). In period 2, the first switching means is turned on, the second switching means is turned off, the third switching means is turned off, the fourth switching means is turned on, the power supply voltage is applied to the focus coil, and the period 3 is applied. The first switching means is off, the second switching means is on, the third switching means is off, the fourth switching means is on, the focus coil is short-circuited between the first terminal and the second terminal, and in the period 4. first switching means off, the second switching means oN, the third switching means oN, the fourth switch Grayed means off, the reverse polarity the power supply of the period 2 to the focus coil
Apply a voltage, so that the current of the focus coil
Switching control means for turning on or off each of them according to a command to be instructed, and the current of the focus coil are
Current detecting means for detecting and current of the focus coil
And a supply voltage control unit that changes the power supply voltage according to the peak of the electromagnetic focus circuit. 6. A power source having a positive electrode and a negative electrode, a focus coil having a first terminal and a second terminal, and a power source coupled to the positive electrode of the power source and the first terminal of the focus coil. First switching means, second switching means coupled between the negative electrode of the power supply and the second terminal of the focus coil, a cathode coupled to the first terminal of the focus coil, and an anode a first diode coupled to the negative electrode of the power supply, a second diode having a cathode an anode coupled to the positive electrode of the power source is coupled to the second terminal of the focus coil, period 1 The period 4 is set as one cycle, and each switch is
In the period 1, the first switching means is turned on, the second switching means is turned off, the focus coil voltage is 0 (zero), the first switching means is turned on, and the second switching means is turned on in the period 2 . the application of the supply voltage to the focus coil, period 3, the first switching means off, the second switching means oN, shorting the focus coil first terminal and a second terminal, in the period 4 second The first switching means is off, the second switching means is off, and the focus coil has the power source having a polarity opposite to that of the period 2.
Apply a voltage, so that the current of the focus coil
Switching control means for turning on or off each of them according to a command to be instructed, and the current of the focus coil are
Current detecting means for detecting and current of the focus coil
And a supply voltage control unit that changes the power supply voltage according to the peak of the electromagnetic focus circuit. 7. A first power supply having a positive electrode and a negative electrode,
A second power supply having a first electrode and a second electrode connected to the negative electrode of the first power supply; a focus coil having a first terminal and a second terminal; A first switching means coupled between a positive electrode of a power source and a first terminal of the focus coil; and a negative switching means coupled between a negative electrode of the first power source and a first terminal of the focus coil. Second switching means, third switching means coupled between the positive electrode of the first power supply and the second terminal of the focus coil, the negative electrode of the first power supply and the focus Fourth switching means coupled between the second terminals of the coil, and fifth switching means coupled between the first terminal of the second power supply and the first terminal of the focus coil. Means and period 1
Above with the ~ period 4 one cycle in each switching unit a period 1 first switching means ON, the second switching means off, the third switching means is turned off and the fourth switching means is turned off and the The switching means 5 is off, the focus coil voltage is 0 (zero), the first switching means is on in the period 2 , the second switching means is off, the third switching means is off, and the fourth switching means is ON, the fifth switching means is OFF, the first power supply voltage is applied to the focus coil , the first switching means is OFF, the second switching means is OFF, and the third switching means is OFF in the period 3 . , fourth switching means oN, the fifth switching means is turned on, applying the second supply voltage to said focus coil, the period First switching means in 4 off, the second switching means ON, the third switching means ON, the fourth switching means is turned off and the fifth switching means is turned off, is the focus coil and period 2 Is the first of opposite polarity
Apply the power supply voltage of the focus coil
Turns each on or off according to the current command
An electromagnetic focus circuit having switching control means. 8. A first power supply having a positive electrode and a negative electrode,
A second power supply having a positive electrode and a negative electrode, the negative electrode being connected to the negative electrode of the first power supply; a first terminal and a second
A focusing coil having a terminal, a first switching means coupled between a positive electrode of the first power source and a first terminal of the focusing coil, a negative electrode of the first power source and the focus. Second switching means coupled between the first terminals of the coil and third switching means coupled between the positive electrode of the first power supply and the second terminal of the focus coil. A fourth switching means coupled between the negative electrode of the first power supply and the second terminal of the focus coil;
Fifth switching means coupled between the positive electrode of the power source and the first terminal of the focus coil, and between the positive electrode of the second power source and the second terminal of the focus coil. 6th switching means and period
1, period 2 first half, period 2 second half, period 3, period 4 first half, period
The second half of the period is set as one cycle and each switching means is set as a period.
In 1, the first switching means is on, the second switching means is off, the third switching means is off, the fourth switching means is off, the fifth switching means is off, the sixth switching means is off, The focus coil voltage is 0 (zero), in the first half of the period 2, the first switching means is on, the second switching means is off, the third switching means is off, the fourth switching means is on, and the fifth switching means is on. Means is off, sixth switching means is off, the first power supply voltage is applied to the focus coil, the first switching means is off, the second switching means is off, and the third switching is in the latter half of the period 2. means off, the fourth switching means oN, the fifth switching means is turned on, the sixth switching means is turned off, the Applying the second power supply voltage to Okasukoiru, period 3, the first switching means off, the second switching means ON, the third switching means is turned off and the fourth switching means ON, fifth Switching means is off, the sixth switching means is off, the focus coil first terminal and second terminal are short-circuited , the first switching means is off, and the second switching means is on in the first half of the period 4 . The third switching means is off, the fourth switching means is off, the fifth switching means is off, the sixth switching means is on, and the focus coil has the opposite polarity to the latter half of the period 2.
A second power supply voltage is applied, and in the latter half of the period 4, the first switching means is off, the second switching means is on, the third switching means is on, the fourth switching means is off, and the fifth switching means is on. OFF, the sixth switching means is OFF, and the focus coil has the polarity opposite to that in the first half of the period 2.
The focus coil is applied so that a first power supply voltage is applied.
ON or OFF according to the command that directs the
An electromagnetic focus circuit having switching control means for turning off . 9. A first power supply having a positive electrode and a negative electrode,
A second power source having a positive electrode and a negative electrode, the negative electrode being connected to the negative electrode of the first power source; the first terminal;
A focus coil having a terminal, a first switching means coupled between a positive electrode of the first power supply and a first terminal of the focus coil, a positive electrode of the first power supply and the focus Second switching means coupled between the second terminals of the coil, and third switching means coupled between the negative electrode of the first power supply and the second terminal of the focus coil. Fourth switching means coupled between the positive electrode of the second power supply and the first terminal of the focus coil, a cathode coupled to the first terminal of the focus coil and an anode of the first A first diode coupled to the negative electrode of the second power source, and a second diode having a cathode coupled to the positive electrode of the second power source and an anode coupled to the second terminal of the focus coil. And a diode, period 1, period 2 before
Half, period 2 latter half, period 3, period 4 first half, period 4 latter half 1
In the period 1, the first switching means is turned on, the second switching means is turned off, the third switching means is turned off, the fourth switching means is turned off, and the focus coil voltage is 0 (zero). ), In the first half of the period 2, the first switching means is on, the second switching means is off, the third switching means is on, the fourth switching means is off, and the focus coil is supplied with the first power supply voltage. In the second half of the application period, the first switching means is off, the second switching means is off, the third switching means is on, the fourth switching means is on, and the second power supply voltage is applied to the focus coil. applied, the first switching means in the period 3 is turned off, the second switching means off, the third switching means o , Fourth switching means off, the focus coil first terminal and shorting a second terminal, the period 4 half the first switching means is turned off and the second switching means off, the third switching means OFF, the fourth switching means is OFF, and the focus coil has the opposite polarity to the latter half of the period 2.
A second power supply voltage is applied. In the latter half of the period 4, the first switching means is off, the second switching means is on, the third switching means is off, the fourth switching means is off, and the focus coil is in the period. 2 The opposite polarity to the first half
Apply a first power supply voltage, the focus carp as
ON or OFF according to the command that directs the
An electromagnetic focus circuit having switching control means for turning off . 10. A power source having a positive electrode and a negative electrode, and a first power source.
A first focus coil having a first terminal and a second terminal, and a second focus coil having a first terminal and a second terminal and cooperating with the first focus coil for the focusing. A first coupled between the positive electrode of the power source and the first terminal of the first focus coil
Switching means, second switching means coupled between the negative electrode of the power supply and the first terminal of the first focus coil, the positive electrode of the power supply and the first
Switching means coupled between the second terminals of the focus coils of the first and fourth switching means coupled between the negative electrode of the power supply and the second terminals of the first focus coil of Means and one cycle from period 1 to period 4
As for each of the switching means in the period 1, the first switching means is on, the second switching means is off, the third switching means is off, the fourth switching means is off, and the focus coil voltage is 0 (zero). In period 2, the first switching means is turned on, the second switching means is turned off, the third switching means is turned off, the fourth switching means is turned on, the power supply voltage is applied to the focus coil, and the period 3 is applied. The first switching means is off, the second switching means is on, the third switching means is off, the fourth switching means is on, the focus coil is short-circuited between the first terminal and the second terminal, and in the period 4. first switching means off, the second switching means oN, the third switching means oN, the fourth switch Grayed means off, the reverse polarity the power supply of the period 2 to the focus coil
Apply a voltage, so that the current of the focus coil
Switching control means for turning on or off each of them in accordance with a command to be instructed, current detection means for detecting a current of the first focus coil, command value of the first focus coil current and current detection An electromagnetic focus circuit comprising: the second focus coil current control means for supplying a current corresponding to the difference between the detection values of the means to the second focus coil.