DE4006542A1 - Magnetic field correction device for CRT - has correction coil supplied with decaying AC signal and magnetic field dependant DC signal - Google Patents

Abstract

The device uses a magnetic field correction coil (13) supplied at one end with an AC voltage provided by a voltage generator (39) exhibiting a decaying voltage amplitude. The opposite end of the coil (13) is supplied with a DC voltage corresponding to the magnetic field detected via a magnetic field sensor (24). The correction coil (13) is wound around the CRT of an image monitor, which may be enclosed by a magnetisable material. Pref. the magnetic field sensor (24) responds to the horizontal component of the earth's magnetisation. USE - For eliminating magnetic field errors.

Description

The invention relates to a magnetic field correction device to correct the influence of an external Magnetic field, such as the earth's magnetic field, on a Katho the beam tube (hereinafter referred to as CRT tube), and the magnetization occurring on the CRT tube.

Fig. 1 is a circuit diagram of a conventional magnetic field correction device which is provided with a correction coil 25 for eliminating eramagnetism, wherein a current flowing in the correction coil 25 is switched by a switch 26 which switches voltages divided by resistors. The switch 26 is operated in such a way that it allows current to flow in the direction of the arrows a and b in the correction coil 25 and generates the magnetic field in the directions of the arrows BH ₁ and BH ₂ . A degaussing coil 29 for loading the magnetization of the CRT tube is connected in series with an AC power source 27 which drives a positive resistor 28 and the degaussing coil 29 .

Fig. 2 (a) and 2 (b) show a ver with the CRT tube provided screen monitor 30 and the CRT tubes image screen 31. BH and BV denote the horizontal and vertical extensions of the earth's magnetism.

The following is how the conventional works Magnetic field correction device explained.

Earth's magnetism is divided into a horizontal component (hereinafter referred to as the BH component) and a vertical component (hereinafter referred to as the BV component). In the screen monitor 30 shown in Fig. 2 (a), the electron beam emitted from an electron emitter (not shown) is diffracted so that it scans the CRT tube screen area 31, thereby generating images. The CRT tube 31 is relatively far from the electron emitter and is directly exposed to the atmosphere so that it tends to be affected by terrestrial magnetism.

It is assumed that the screen monitor 30 shown in FIGS. 2 (a) and 2 (b) undergoes a change of direction. In the position shown in Fig. 2 (a), with respect to the CRT tube screen area 31, the BH component acts upward to the screen area. In this state, according to the Fleming three-finger rule (left-hand rule), the image plane is rotated to the left by the BH component and shifted to the right by the BV component. Then, from the position shown in Fig. 2 (b) with respect to the CRT screen area 31, the BH component of the earth magnetism acts horizontally, while the BV component acts in the upward direction as in Fig. 2 (a). In the two positions shown in FIGS. 2 (a) and 2 (b), the BV component likewise represents an impairment of the operation of the CRT tube 31 .

With respect to the BV component, the image plane is rotated in the position shown in FIG. 2 (a) (hereinafter referred to as north-south horizontal magnetic field) and in the position shown in FIG. 2 (b) (hereinafter referred to as east-west horizontal magnetic field) vertically offset. Under the influence of the east-west horizontal magnetic field, the electron beam is moved to a lesser extent than under the influence of the north-south horizontal magnetic field, so that the following description only concerns the north-south horizontal magnetic field, which is caused by the BH component is represented.

The CRT electron beam displaced under the influence of the BH component does not strike the provided phosphor point of the CRT tube screen area 31 precisely, which causes the color clarity to suffer. To eliminate the influence of the BH component, it is only necessary that a magnetic field corresponding to the BH component is applied in the opposite direction. Therefore, a method is frequently used in which the correction coil 25 shown in FIG. 1 is wound around the CRT tube and a direct current is sent through the correction coil 25 .

If a direct current flows in the direction of arrow a in the arrangement shown in FIG. 1, the magnetic field is generated in the direction of arrow BH ₁ . Conversely, if the direct current flows in the direction of arrow b , the magnetic field is generated in the direction of arrow BH ₂ , so that the intensive action of the BH component can be eliminated by appropriate selection of the direction and the size of the direct current. The direction and magnitude of the direct current are selected by the switch 26 .

In order to remove the magnetism which acts on metal material located on the CRT tube, an alternating current is conducted from the alternating current source 27 to the demagnetizing coil 29 . The initially cold positive resistor 28 has a relatively low resistance, which causes a strong alternating current to flow in the demagnetizing coil 29 , but the positive resistor 28 generates heat, due to which its resistance is increased, and the current flowing through the resistor 28 is converged, thereby demagnetizing the metal material.

FIG. 3 illustrates a demagnetization process which is carried out by a demagnetizing current I _C2 flowing in the demagnetizing coil 29 . As mentioned, the demagnetizing current I _C2 is gradually weakened, a hysteresis loop of the CRT tube begins to understand the weakening, and the loop gradually becomes smaller and finally converges at the point of convergence, thereby eliminating the magnetization of the CRT tube. In this case, although a magnetic force H ₁ remains at the starting point and at the convergence point of the hysteresis loop, the magnetic force H ₁ depends on the BH component of the earth magnetism, and the magnetic flux density is larger at the convergence point than at the starting point, whereby the perceived The relative permeability of an inner magnetic shield plate (not shown) arranged in the CRT tube becomes large, which involves the improvement of the shielding effect.

In the conventional magnetic field correction device described, two correction coils 25 for eliminating the influence of earth's magnetism and the demagnetizing coil 29 for eliminating the magnetization of the CRT tube are required, which makes the device expensive to manufacture.

It is the object of the invention to create a magnetic field To create correction device, at the only a single coil simultaneously the function of the cor rectification coil and the demagnetizing coil conventional Licher devices met.

A magnetic field correction is used to solve the problem proposed device that is provided with a first voltage generating device that over their Output connection outputs an AC voltage, the Amplitude is damped with time, a magnetic field sensor for determining the in a predetermined Rich magnetic field (especially the hori zontal component of terrestrial magnetism), a second Voltage generating device that over their off output connection outputs a DC voltage that the Result of the magnetic field sensor determination, and a magnetic field correction coil at their ends with the output terminal of the first voltage generator supply device or the output connection of the second Voltage generating device is connected.

In the magnetic field correction device according to the invention an alternating voltage damping amplitude one end of the magnetic field correction coil is applied, and a voltage that detects that from the magnetic field sensor The magnetic field corresponds to the other end of the magnetic field correction coil, which surrounds the CRT Tube is wrapped. A demagnetization change  current and a magnetic field correction direct current, which the corresponds to the horizontal component of earth's magnetism, flow in the magnetic field correction coil, causing the CRT tube demagnetized and that on the CRT tube Earth magnetism is canceled.

If the influence of one on the CRT tube in an image screen monitor acting magnetic field eliminated should be the influence of the magnet field of a part surrounding the screen monitor (magnetizable material) based on the determ Corrected result of the magnetic field sensor.

The invention provides a magnetic field correction device device that can be produced inexpensively.

The magnetic field correction device according to the invention is used to correct the magnetic field effect kung by the influence of the magnetic field on the Screen monitor surrounding part is corrected.

In the following, an embodiment of the invention in Connection with the drawings explained in more detail.

Show it:

Fig. 1 is a circuit diagram of the conventional rekturvorrichtung Magnetfeldkor,

Fig. 2 (a) and (b) a perspective view and a side view of a screen monitor with CRT tube,

Shows a diagram of the hysteresis characteristic of the magnetic field correcting process to illustrate rekturvorrichtung. 3 in the conventional Magnetfeldkor,

Fig. 4 field correction device is a circuit diagram of the magnet according to the invention,

Fig. 5 is a block diagram of the apparatus magnetic field correction,

Fig. 6 is a waveform diagram of pulses received field correction device by the magnet,

Fig. 7 is a waveform diagram of the current flowing in the magnetic field correction coil of the magnetic field correction device, and

Fig. 8 is a diagram showing the hysteresis characteristic to illustrate the passage Magnetfeldkorrekturvor rekturvorrichtung in the inventive Magnetfeldkor.

As shown in FIG. 4, a DC power source 1 is connected to an on-off switch 2 for supplying the device with the supply voltage, and a transistor 4 is connected with its base to a bias resistor 34 and via a switch 33 to a pulse Oszil lator 3 connected. A PTC thermistor 6 (posistor) and a resistor 7 of a load for the transistor 4 are switched in series with the collector of the transistor 4 , and a smoothing capacitor 8 is connected to the switching point of the transistor 6 and the resistor 7 . A coupling capacitor 5 is connected to the collector of transistor 4 . Transistors 11 and 12 form a complementary switched push-pull amplifier (common mode push-pull amplifier), bias resistors 9 and 10 are connected to the bases of the transistors 11 and 12 , where V ₁ denotes a first signal that the transistors 11th and 12 is supplied. To the emitter node of the Transisto b ren 11 and 12 is one end of a magnetic field correction coil 13 is connected (hereinafter referred to simply as coil 13), the magnetizing coil as Ent in a dual-function and which, like the forth tional degaussing coil to the ( not shown) CRT tube is wound.

A magnetic field sensor 24 (hereinafter referred to simply as sensor 24 ) for determining the BH component of the earth magnetism acting on the CRT tube can be used as a current output sensor unit, as described in "A magnetic direction sensor" by Ito / Matsumoto in Mitsubishi Denki Technical Report, Vol. 61, No. 8, pp. 81-86, 1987. A current I _{B of} a detection signal from the sensor 24 is converted into a voltage by a current / voltage converter 23 , the output voltage of which is supplied to the bases of transistors 20 and 21 forming a push-pull amplifier. In addition, as a CRT monitor screen surrounding metal plate, after amplification by an operational amplifier 22 to the detection signal, a correction voltage V ₃ for correcting the magnetic field at a portion added I _B. With the emitter node of the transistors 20 and 21 , the base of the transistor 18 is connected to which the output signals of the transistors 20 and 21 are supplied. A resistor 19 is connected to the emitter of transistor 18 , the collector of which is connected to the bases of transistors 14 and 15 which form a push-pull amplifier, with a second signal V ₂ from the collector of transistor 18 to the bases of Transistors 14 and 15 is applied. Furthermore, before voltage resistors 16 and 17 are connected to the bases of the transistors 14 and 15 , and the other end of the coil 13 is connected to the emitter node e of the transistors 14 and 15 , so that in the coil 13 a magnetic field correction current I _C flows, the direction and strength of which are determined in accordance with the potential difference at the two ends of the coil 13 (points b and e ).

FIG. 5 is a block diagram for explaining the operation of the circuit shown in FIG. 4. A first signal output circuit 35 for outputting the first signal V ₁ consists of parts 3 to 10 , 33 and 34 from FIG. 4; a first coil control circuit 36 is formed by transistors 11 and 12 ; a second coil control circuit 37 is formed by transistors 14 and 15 ; and a second signal output circuit 38 for outputting the second signal V ₂ is made up of parts 16 to 21 and 23 . The first signal output circuit 35 and the first coil control circuit 36 form a first voltage generating device 39 , and the second signal output circuit 38 and the second coil control circuit 37 form a second voltage generating device 40 . In addition to these components, FIG. 5 shows the sensor 24 , the operational amplifier 22 and the coil 13 wound around the CRT tube 31 .

The following is the operation of the device explained.

If the switch 33 is turned on with the on-off switch 2 switched on, the transistor 4 is switched on and off by the pulse output from the pulse oscillator 3 , as a result of which a current flows into the posistor 6 and the resistor 7 . Since the posistor 6 is cold in the initial state, its resistance value is small; however, when the resistance due to heat generation becomes large, an increasing voltage drop occurs at the posistor 6 , whereby a pulse is supplied to the collector of the transistor 4 for a predetermined period of time, which gradually attenuates the amplitude, as shown in FIG. 6. The pulse is, after "cutting off" the DC voltage portion by the capacitor 8 , biased by the resistors 9 and 10 and supplied to the bases of the transistors 11 and 12 as the first signal V ₁ , whereby a voltage is applied to the point b , the corresponds to the first signal V ₁ .

The detection signal I _B , which corresponds to the BH component determined by the sensor, is converted into voltage by the current / voltage converter 23 , the value of which is amplified by the push-pull amplifier comprising the transistors 20 and 21 and then the basis of the Transistor 18 is supplied, whereby the second signal V _{2 is} generated, which corresponds to the detection signal I _B and is biased by the resistors 16 and 17 , and changes according to the direction and size of the detection signal (current) I _B.

When the potential of g in the circuit of Fig. 4 at the point (the first signal V ₁₎ is greater than the poten tial h at the point (the second signal V _2), the current I _C flowing in the winding 13 in the sequence of Points abef as a pulse waveform in the positive direction according to FIG. 7. If the potential a point g is smaller than the potential at point h , the current I _{C flows} in the sequence of the points debc as a pulse waveform in the negative direction according to FIG. 7. The direct current pots tialdifference between the points g and h causes the DC component illustrated in Fig. 7 flows as a geomagnetic correction current I _C1 in the coil 13 .

The AC component of the current I _C flowing in the coil 13 works as a demagnetizing current I _C2 . This means that the current I _{C2 is} gradually attenuated, as shown in Fig. 8, so that the hysteresis loop converges towards the zero point and the remaining magnetic flux density is eliminated, and thus the magnetization of the CRT tube is erased. In addition, the earth magnetism correction direct current I _C1 actuates the coil 13 such that it functions like the conventional correction coil 25 , whereby the earth magnetism can be canceled.

Since the CRT screen monitor is surrounded by a metal plate, the magnetic field acting on the sensor 24 does not correspond to terrestrial magnetism. In order to correct this state, the current / voltage converter 23 is supplied with a correction voltage V ₃ via the operational amplifier 22 , which is added to the voltage generated by the conversion of the detection signal I _B.

From Fig. 8 it can be seen that since the magnetic force H ₁ corresponding to the earth's magnetism is erased by the earth's magnetism correction current I _C1 and the magnetization of the CRT tube by the demagnetization current I _C2 , the convergence point of the hysteresis loop can serve as the zero point. so that a full permanent magnetic field correction is carried out.

In the embodiment described here, the transistor 18 is used to determine the potential at point h of FIG. 4, it being possible to use a resistor instead of the transistor 18 for this purpose.

Claims (13)

1. Magnetic field correction device for correcting the influence of a magnetic field on an object, characterized by
a first voltage generating device ( 39 ) which outputs an AC voltage via its output connection, the amplitude of which is damped over time,
a magnetic field sensor ( 24 ) for determining the magnetic field running in a predetermined direction,
a second voltage generating device ( 40 ) which, via its output connection, outputs a DC voltage which corresponds to the detection result of the magnetic field sensor ( 24 ), and
a magnetic field correction coil ( 13 ) which is connected at its ends to the output terminal of the first voltage generating device ( 39 ) and to the output terminal of the second voltage generating device ( 40 ). 2. Magnetic field correction device according to claim 1, characterized in that the magnetic field sensor ( 24 ) determines the magnetic field generated by the earth's magnetism. 3. Magnetic field correction device according to claim 1, characterized in that the magnetic field sensor ( 24 ) determines the horizontal component of the magnetic field generated by geomagnetic. 4. Magnetic field correction device according to one of claims 1 to 3, characterized in that the magnetic field correction coil ( 13 ) around a cathode ray tube ( 31 ) of a screen monitor ( 30 ) is wound. 5. Magnetic field correction device according to one of claims 1 to 4, characterized in that the screen screen monitor ( 30 ) of magnetizable material is to give. 6. Magnetic field correction device according to claim 5, characterized in that a device ( 22 , 23 ) corrects the influence of the magnetic field on the magnetizable material when the magnetic field sensor ( 24 ) determines the magnetic field generated by terrestrial magnetism. 7. Magnetic field correction device for correcting the influence of a magnetic field on an object, characterized by
a first signal output circuit ( 35 ) which outputs a first signal ( V ₁ ), the amplitude of which is gradually attenuated for a predetermined period of time,
a first coil control circuit ( 36 ) which outputs a voltage via its output terminal which corresponds to the first signal ( V ₁ ),
a magnetic field sensor ( 24 ) for determining the magnetic field running in a predetermined direction, a second signal output circuit ( 38 ) which via its output connection outputs a second signal ( V ₂ ) which corresponds to a detection signal of the magnetic field sensor ( 24 ),
a second coil control circuit ( 37 ) which outputs a voltage via its output connection which corresponds to the second signal ( V ₂ ),
a magnetic field correction coil ( 13 ) connected at its ends to the output terminal of the first coil control circuit ( 36 ) and the output terminal of the second coil control circuit ( 37 ). 8. A magnetic field correction device according to claim 7, characterized in that the first signal output circuit ( 35 ) is provided with a transistor ( 4 ), a pulse oscillator ( 3 ) connected to the base of the transistor ( 4 ) and one with the collector of the transistor ( 4 ) connected posistor ( 6 ). 9. Magnetic field correction device according to claim 7 or 8, characterized in that the first coil control circuit ( 36 ) is provided with two transistors ( 11 , 12 ) which form a push-pull amplifier. 10. Magnetic field correction device according to one of claims 7 to 9, characterized in that the second signal output circuit ( 38 ) is provided with a push-pull amplifier for amplifying the detection signal of the magnetic field sensor ( 24 ) and with a transistor ( 18 ), the base of which is fed to the output of the push-pull amplifier. 11. Magnetic field correction device according to one of claims 7 to 10, characterized in that the second coil control circuit ( 37 ) is provided with two transistors ( 20 , 21 ) which form a push-pull amplifier. 12. Magnetic field correction device according to one of claims 7 to 11, characterized in that the magnetic field sensor ( 24 ) determines the horizontal component of the magnetic field generated by geomagnetic. 13. Magnetic field correction device according to one of claims 7 to 12, characterized in that the magnetic field correction coil ( 13 ) around a cathode ray tube ( 31 ) of a screen monitor ( 30 ) is wound.