JPH0531251B2 - - Google Patents

Description

DETAILED DESCRIPTION OF THE INVENTION Field of the Invention The present invention relates to a deflection yoke suitable for driving a display picture tube in random scanning.

2. Description of the Related Art Generally, in a deflection yoke attached to a television picture tube, a sawtooth wave current is supplied to each of its horizontal deflection coil and vertical deflection coil.
A so-called raster scan is performed. On the other hand, display picture tubes used in computer terminal equipment and the like are sometimes driven using a random scanning method to display figures consisting of predetermined straight lines, circular arcs, etc. in accordance with computer output.

Problems to be Solved by the Invention However, when applying a random scanning method using a general deflection yoke equipped with a horizontal deflection coil and a vertical deflection coil having different inductances and DC resistances, especially when displaying diagonal lines, Since the path of the electron beam is different between the outward stroke and the return stroke, what should be displayed as a single straight line becomes a double line with a hysteresis loop, making it very difficult to see.

To explain this phenomenon in more detail, as shown in FIG. ′)
can be considered as connected in series (the capacitance is ignored because it is extremely small, L=L', R=R').
When it is desired to display a straight line on the fluorescent surface of the picture tube, a rectangular wave drive voltage as shown in Figure 6a is applied to the picture tube, and the horizontal deflection coil and vertical deflection coil are Sawtooth wave currents as shown in b and c are respectively supplied.

The current i (ampere) flowing through the deflection coil is expressed as i=i ₀ exp (−R/L·t)−A (1). Here, L is the inductance (Henry) of the coil, R is the DC resistance (ohm) of the coil, t is time (seconds), and i ₀ and A are constants.

When the time constant T _H (=L _H /R _H ) of the horizontal deflection coil and the time constant T _V (=L _V /R _V ) of the vertical deflection coil are equal (T _H =T _L ), the current waveform is the seventh The result is as shown in FIG. 7A, and the diagonal line displayed on the fluorescent surface becomes a straight line as shown in FIG. 7B. However, in the general case where T _H < T _V , the current waveform is as shown in Figure 7c, and on the fluorescent surface there is a double line of hysteresis loop as shown in Figure 7d. will be displayed.

The loop width d when the diagonal line is 45° with respect to the horizontal axis x of the fluorescent surface is large, and this loop width d
An approximate calculation of is as follows. That is, if ΔI is the difference between the horizontal deflection coil current and vertical deflection coil current, I is the current required to scan the entire length of a straight line, and K is the constant, then ΔI/I=K[exp(-1/T _V・t) -exp(-1/T _H・
t)] ...(2) Since ΔI is maximum at the center of the straight line, when t = 1/4f ...(3) (f is the scanning frequency (Hz)), ΔI/I _nax = K[exp( −1/T _V・1/4f)−exp(−
1/T _H・1/4f)]...(4) If we perform Taylor expansion and take only the first-order term, ΔI/I _nax ≒K(1/T _H -1/T _V )1/4f...(5 ) The loop width d is, assuming the horizontal length of the straight line is H (mm), d=√2・H・ΔI/I _nax ≒K√2/4・T _V −T _H /T _H
・T _V・H・1/f (mm)……(6) Since T _H ≒T _V , if one of them is T and the difference is ΔT, then d=K ₀・(ΔT/T)・H/T・1/f (mm)……(7) Here, K ₀ is a constant, but in short, the loop width d is the time constant difference expressed in the form of a ratio ( _TV −
T _H )/T. Further, it is proportional to the length of the straight line, and inversely proportional to the time constant T and scanning frequency f of the coil.

SUMMARY OF THE INVENTION An object of the present invention is to provide a deflection yoke that can display linear oblique lines on the fluorescent surface of a picture tube even when a random scanning method is applied while using a conventional deflection coil.

Means for Solving the Problems According to the present invention, a correction resistor or a correction coil is connected to at least one of the horizontal deflection coil and the vertical deflection coil to make the substantial time constants of both the deflection coils substantially equal.

Effect: With this configuration, it is possible to display a linear diagonal line on the fluorescent surface of the picture tube of a random scanning type display device without making any changes to the coils themselves of both deflection coils.

Embodiment FIG. 1 shows an equivalent circuit of a parallel type deflection yoke embodying the present invention. The difference from the conventional equivalent circuit of the deflection yoke shown in FIG. 5 is that a correction resistor R _S is connected in series with the parallel connection of the coil portions C and C'. FIG. 2 is an equivalent circuit diagram of an embodiment in which the present invention is applied to a series type deflection yoke, in which a correction resistor R _S is connected in series with a series connection body of coil portions C and C'.

Figure 3 shows the measured values of the loop width d when the relationship between the practical time constant of the horizontal deflection coil and the practical time constant of the vertical deflection coil was variously changed.
The characteristics of the deflection coil used and the values of various correction resistors R _S added thereto are as follows.

Horizontal deflection coil inductance L _H ……0.6×
10 ^-3 (Henry) DC resistance of horizontal deflection coil R _H ……0.55 (ohm) Time constant of horizontal deflection coil T _H ……1.09×10 ^-3 (sec) Inductance of vertical deflection coil L _V ……0.6×
10 ^-3 (Henry) DC resistance of vertical deflection coil R _V ...0.46 (ohm) Vertical deflection coil time constant T _V ...1.30×10 ^-3 (sec) Correction resistor connected in series with vertical deflection coil
R _S ...0.09 (ohm), 0.07 (ohm), 0.05 (ohm) Deflection frequency is f = 1 (KHz), f = 3 (KHz), f
= 4 (KHz), and the horizontal length H of the display diagonal line was 153 mm using a 10-inch picture tube. This corresponds to the maximum practical amplitude.

The maximum allowable value for the loop width d in a typical display device is 0.2 mm. Therefore, even in low-speed scanning at a scanning frequency f=1 KHz, a time constant difference of ±3% is allowed. In other words, the correction resistance R _S added in this example is 0.07
It is sufficient to use one with ~0.09 ohm.
However, in a display device that requires high resolution, it is desirable that the loop width d be close to 0, so it is desirable to set the scanning frequency f = 3KHz or more, and the scanning frequency in a practical high-resolution display device is usually 3KHz or more. It is.

Therefore, it is only necessary to suppress the difference between the time constant T _H of the horizontal deflection coil and the time constant of the vertical deflection coil within ±3%, and by adding a correction resistor to at least one of both deflection coils. It will be a good thing.

Figure 4 shows differential coils Cd, Cd, and Cd for correcting axis deviation for horizontal and vertical deflection coil portions C and C', respectively.
In this example, the time constant is (L+
Ld)/(R+Rd). However, Ld indicates the inductance (Henry) of the differential coil, and Rd indicates the DC resistance (ohm) of the differential coil. In this case, the wire diameter and number of turns of the differential coils Cd and Cd' are selected to appropriate values, that is, the DC resistance and inductance are set to appropriate values, so that both the horizontal and vertical deflection coils are effectively A specific numerical example is as follows.

[Horizontal deflection]

Inductance L of horizontal deflection coil...0.6×
10 ^-3 (Henry) DC resistance R of horizontal deflection coil...0.55 (ohm) Inductance Ld of differential coil... (6 to 15)
×10 ^-6 (Henry) DC resistance Rd of differential coil……0.02 (ohm) [Vertical deflection] Inductance L of vertical deflection coil……0.6×
10 ^-3 (Henry) DC resistance R of vertical deflection coil...0.46 (ohm) Inductance Ld of differential coil... (6 to 15)
×10 ^-6 (Henry) DC resistance Rd of differential coil...0.11 (ohm) Effects of the Invention Since the present invention is configured as described above, the deflection coil itself can be changed even in a display device using the random scanning method. Straight diagonal lines can be displayed clearly without adding

[Brief explanation of the drawing]

1 and 2 are equivalent circuit diagrams showing embodiments of the present invention, FIG. 3 is a time constant difference-loop width characteristic diagram for explaining the operation and effects of the present invention, and FIG. 4 is a diagram of the present invention. An equivalent circuit diagram of another embodiment of the invention, FIG. 5 is an equivalent circuit diagram of a conventional deflection coil, a to c of FIG. Figures a to d are diagrams for comparing and explaining current waveforms and image patterns when the time constants of the horizontal and vertical deflection coils are equal and different. C, C'... Deflection coil part, R _S ... Correction resistor.

Claims (1)

[Claims] 1. A deflection yoke characterized in that a correction resistor or a correction coil is connected to at least one of a horizontal deflection coil and a vertical deflection coil, so that the substantial time constants of both deflection coils are made substantially equal.