DE19732163A1 - Horizontal scan driver stage - Google Patents

Abstract

The horizontal scan driver stage includes a scan coil (5) connected in parallel with a diode (3). A current flows, in this circuit, during a first part of a line scan phase,in which the scan current lies between a negative maximal value and zero. A nearly linear rise of the scan current is made possible by providing a circuit (7) in parallel to the scan coil, which diverts a current caused through a forward over-voltage on the diode during the first part of the line scan phase. The circuit consists preferably of a clamping diode (8) and a parallel circuit of a discharge capacitor (10) and a discharge resistor.

Description

The invention relates to a horizontal deflection stage with a a deflection coil connected in parallel, through which an Ab during a first part of a line scrolling phase steering current between a negative maximum value and the value Zero flows.

Known horizontal deflection levels usually include one Switching transistor, which with a horizontal frequency Rectangular pulse signal can be controlled, further to this Switching transistor components connected in parallel in the form a forward diode, a return capacitor and one Series connection of deflection coil and tangent capacitor. The horizontal frequency control of the horizontal deflection stage generates a deflection current that is a horizontal deflection of an electron beam in a picture tube. In a Return phase, in which the switching transistor blocks, falls initially during a first part of the rewind phase high reverse voltage on the forward diode and the deflection current decreases from a positive maximum value to that Value zero. The deflection current flows through the deflection coil and charges the return condenser, which is during a second part of the return phase via the deflection coil discharges. During this second part of the rewind phase increases the negative deflection current from zero to a nega tive maximum value and the return diode remains ge locks. The reverse voltage decreases and during the  The transition to a first part of a run-up phase is the Hinnddiode conductive, initially for a short Period builds up a forward overvoltage on this diode, which is much higher than their forward voltage. This causes a change in the largely linear current increases and causes a speed change of the elec electron beam and thus a change in brightness on the Illuminated screen of the picture tube, which is annoying as a darker, verti kaler stripe is visible on the screen. Furthermore The steep flanks of the forward span de-energize steering coil to vibrate in the natural resonance range, what to additional annoying vertical stripes on the screen.

These disorders can be avoided by the dark duty time is increased. Because of the shortened time to However, the display of the image content is then higher Pixel frequency required.

The present invention has for its object a To create a horizontal deflection stage of the type mentioned at the beginning, which enables an almost linear increase in the deflection current light.

This object is achieved in that means for the deflection coil are connected in parallel, which one through a forward Overvoltage on the trailing diode during the first part of the Derive line current caused current.  

In one embodiment of the invention, the by the downward voltage at the forward diode caused by a current derived circuit technical means derived.

In a further embodiment of the invention, that the means an active control and a discharge comprise capacitor, wherein the active control element Control signal for discharging the discharge capacitor can be supplied is, the power loss in the discharge means is reduced.

Based on the drawing, in which an embodiment of the Er invention is illustrated, the following are the inventions dung, their configurations and advantages explained in more detail.

Show it

Fig. 1 is a block diagram of a horizontal deflection stage and

Fig. 2 shows the time course of a deflection current and a diode return voltage.

In Fig. 1, 1 denotes a horizontal deflection stage, which consists essentially of a switching transistor 2 , a forward diode 3 , a flyback capacitor 4 and a series circuit formed from a horizontal deflection coil 5 and a tangent capacitor 6 , both the forward diode 3 and the return capacitor 4 and the series circuit are connected in parallel to the switching transistor 2 . The switching transistor 2 can be controlled with a horizontal-frequency rectangular pulse signal Rs, from which the horizontal deflection stage 1 generates a deflection current which causes a horizontal deflection of an electron beam in a picture tube, not shown here. The deflection coil 5 are connected in parallel with tel 7 , which derive a current caused by a forward overvoltage on the forward diode 3 during the first part of a line trailing phase. These means 7 essentially comprise a clamping diode 8 , a damping resistor 9 , a discharge capacitor 10 and a passive or active element 11 . In a simple embodiment, the element 11 is passive and consists of a discharge resistor. A better performance balance is achieved with an active element 11 , a control signal 12 being required to discharge the discharge capacitor 10 during a return phase of the deflection current following the forward phase.

In the following, reference is made to FIG. 2, in which the time profile of a deflection current I _{abl is shown} in FIG. 2a and the ideal profile of the diode return voltage over time is shown in FIG. 2b.

At a point in time t1, the horizontal-frequency right-hand corner pulse signal Rs ( FIG. 1) switches on the switching transistor 2 and causes the deflection current I _abl in a second part of a trailing phase between the point in time t1 and a point in time t2 via the tangent capacitor 6 and, which is charged in a basic state the deflection coil 5 to a positive maximum value _pmax I increases from the value zero. At the time t2, the right corner pulse signal Rs blocks the switching transistor 2 and the tangent capacitor 6 is discharged via the deflection coil 5 and the return capacitor 4 , which charges up, the deflection current I _abl during this first part of the return phase between the time t2 and one Time t3 reduced from the positive maximum value I _pmax to the value zero. Furthermore, during this phase a high reverse voltage Us drops across the forward diode 3 , which decreases to zero during the second part of the reverse phase between the time t3 and a time t4. In this phase, the return capacitor 4 discharges via the deflection coil 5 , the negative deflection current I _abl increasing from the value zero to a negative maximum value I _nmax . During the transition to the first part of the forward phase, which begins at time t4 and ends at time t5, the diode 3 becomes conductive, a forward overvoltage U _FWD initially building up on the forward diode 3 . The current caused by this forward overvoltage U _FWD flows through the clamping diode 8 , the damping resistance 9 , the discharge capacitor 10 and the tangent capacitor 6 , whereby the "rapid" voltage change has no effect on the deflection coil 5 . The increase in the deflection current I _abl remains essentially linear and decreases from the negative maximum value I _nmax to the value zero. The discharge capacitor 10 is discharged by the element 11 during the following return phase from a time t6 and can in turn be charged at the beginning of the next supply phase.

Claims (3)

1. Horizontal deflection stage ( 1 ) with a forward diode ( 3 ) connected in parallel with a deflection coil ( 5 ), via which a deflection current (I _abl ) flows between a negative maximum value and the value zero during a first part of a line trailing phase, characterized in that the deflection coil ( 5 ) Means ( 7 ) are connected in parallel, which derive a current caused by a forward overvoltage (U _FWD ) on the forward diode ( 3 ) during the first part of the line trace phase. 2. Horizontal deflection stage ( 1 ) according to claim 1, characterized in that the means ( 7 ) comprise a clamping diode ( 8 ) and this clamping diode ( 8 ) connected in parallel, which has a discharge capacitor ( 10 ) and an unloading resistor. 3. Horizontal deflection stage according to claim 1, characterized in that the means ( 7 ) comprise an active control element and a discharge capacitor ( 10 ), the active control element being able to be supplied with a control signal for discharging the discharge capacitor ( 10 ).