Abstract:
A frequency compensation circuit influences an X-radiation protection (XRP) circuit in a high voltage regulator circuit for a cathode ray tube (CRT) to operate properly under varying frequencies of voltage energizing a high voltage transformer. The frequency compensation circuit includes an input to a source of first voltage related to a high voltage output of the high voltage regulator circuit, a voltage source generator responsive to a high voltage generator frequency of the CRT. A voltage controlled circuit is responsive to the voltage source generator for controlling conveyance of the first voltage to the XRP circuit so that a relatively constant proportion of the high voltage output is reported to the XRP circuit under varying high voltage generator frequencies.

Description:
BACKGROUND 
     This invention relates generally to video displays for multiple video modes and, more particularly, to x-ray protection for cathode ray tube displays. 
     Protection against generation of harmful X-radiation from a cathode ray tube (CRT) includes an X-ray protection (XRP) circuit that compares a sense voltage, representative of an ultor voltage, against a reference voltage. Generation of the ultor voltage is disabled when the sense voltage is greater than the reference voltage. Accuracy of the XRP circuit to disable generation of the ultor voltage at a proper level relies on the sense voltage maintaining a predetermined relationship to the ultor voltage. This relationship is influenced by the relationship between beam current and ultor voltage. As indicated by the high voltage versus beam current curves  15  or  16  in FIG. 1, the slope or impedance is steeper at low beam current than at high beam current. 
     In monitor or CRT display applications the beam current and ultor voltage are maintained below the CRT&#39;s isodose curve. The isodose curve defines variations in ultor voltage and corresponding beam current at an anode of the CRT for a relatively constant level of X-radiation by the CRT. The isodose curve is a trip curve in that when beam current and ultor voltage are above the isodose curve the XRP circuit disables generation of the ultor voltage. As observed from FIG. 1, isodose curves  11  and  12  define high voltage VHV in kilovolts (kV) versus beam current (Ib) in microamps for X-radiation levels of 0.5 mR/hr (milliroentgen per hour) and 0.1 mR/hr, respectively. The CRT is operated so that its ultor voltage and corresponding beam current coincide below a particular isodose trip curve to avoid a particular level of X-radiation. Although reduced light output has, in the past, been acceptable in computer monitor applications, in television applications maximum light output is the goal and the high voltage is regulated to operate the CRT as close as possible to its isodose curve and improve the focus at high beam currents. 
     In a television or monitor a secondary winding, conventionally referred to as an X-ray protection winding, on the high voltage transformer develops a voltage VXRP as the primary of the transformer is driven by a pulse voltage waveform at a particular frequency related or synchronized to the video signal&#39;s horizontal scan frequency. The voltage VXRP develops with an amplitude that is proportional to the ultor voltage applied to a CRT&#39;s anode. The relationship between the ultor voltage and XRP voltage remains relatively constant over a given range of beam current when the transformer is driven by a pulse at a constant frequency. 
     Various video signal modes have different horizontal frequencies that require different high voltage generator frequencies at which the transformer is energized. High voltage generators incorporating scan-independent high voltage systems can have variable generating frequencies. The standard definition NTSC signal, high definition ATSC signal, and computer generated SVGA signal have the following respective horizontal frequencies, 15.734 kHz (1H), 33.670 kHz (2.14H), and 37.880 kHz (2.4H). Selection to a higher horizontal frequency signal will require driving the high voltage transformer with a pulse voltage waveform at a higher frequency. For example, in the NTSC broadcast signal mode, the high voltage generator is synchronized to the horizontal scan frequency but operated at 2H or 31.468 kHz, and in the SVGA monitor mode the high voltage generator is locked to the 37.880 kHz (2.4H) video signal frequency. 
     The high voltage transformer which develops the ultor voltage and voltage VXRP operates with a frequency dependent impedance. As frequency of the voltage energizing the transformer increases the inductive coupling to the secondary winding developing the ultor voltage becomes much more lossy than the inductive coupling to the secondary winding developing the voltage VXRP. Known frequency dependent transformer losses in the inductive couplings between the primary winding and secondary windings may include losses due to inter-winding capacitance and eddy current effects. Energy is dissipated during the charge and discharge of inter-winding capacitance between winding layers of the transformer. At a greater energizing frequency the effects of inter-winding capacitance are more pronounced. Also, at higher frequencies known skin effects occur in which conductors appear to have a higher AC resistance from current crowding at the surface of the conductor. With multiple winding conductors skin effects are more pronounced at greater energizing frequencies. Although these and other types of known transformer losses will vary with transformer construction, the losses will be greater with increases in frequency at which the transformer is energized. 
     To compensate for the increased loss in inductive coupling producing the ultor voltage and maintain a relatively constant ultor voltage, as frequency increases the pulse voltage driving the primary winding of the transformer is boosted to maintain the ultor voltage relatively constant. Since the inductive coupling to the secondary winding developing the voltage VXRP is not as lossy as that for developing the ultor voltage, voltage VXRP increases as the primary voltage energizing the transformer is increased to maintain the ultor voltage level. As a result, voltage VXRP increases relative to the ultor voltage and cannot be used directly to monitor and determine fault levels in ultor voltage over changes in frequency. 
     SUMMARY 
     In accordance with an inventive arrangement there is provided a high voltage circuit comprising: a high voltage generator; first means for developing a first signal representative of the high voltage; second means for developing a second signal indicative of a frequency of operation of the high voltage generator; and third means coupled to the first and second means and responsive to the second signal indicative of the frequency of operation for detecting a fault operation of the high voltage generator in accordance with the frequency of operation. 
     In accordance with a different inventive arrangement there is provided a cathode ray tube display operable under varying transformer energizing frequencies. The display includes a high voltage transformer having a primary winding for being energized by a voltage at the transformer energizing frequency and a secondary winding comprising a tertiary winding for supplying a high voltage to provide an anode accelerating potential to a cathode ray tube and a protection winding for developing a voltage that is in proportion to the high voltage, the proportion to the high voltage changing according to changes in the transformer energizing frequency. The display further includes a protection circuit responsive to changes in the transformer energizing frequency for disabling normal energization of the primary winding when the proportion of high voltage exceeds a reference voltage as the transformer energizing frequency changes. 
     In accordance with another inventive arrangement there is provided a high voltage power supply circuit for supplying a high voltage to provide anode accelerating potential in a cathode ray tube. The power supply circuit includes a transformer with primary winding and secondary winding including both a tertiary winding and protection winding; a generator circuit for energizing the primary winding with a pulse voltage at a generator frequency to produce both the high voltage across the tertiary winding and a protection voltage across the protection winding in proportion to the high voltage, proportion of the protection voltage to the high voltage varying with changes in the generator frequency; and a protection circuit responsive to changes in the generator frequency for developing a sense voltage from the protection voltage that is representative of the high voltage over variations in the generator frequency. 
    
    
     DRAWINGS 
     FIG. 1 is a graph of CRT isodose curves  11 ,  12  at two different X-radiation levels, power curves  13 ,  14  under normal operation and power curves  15 ,  16  representing trip levels under fault conditions, where the X-ray protection circuit is adjusted by an inventive frequency compensation circuit; and 
     FIG. 2 is a circuit schematic of a high voltage power supply circuit for a CRT display employing an X-ray protection circuit with an inventive frequency compensation adjustment. 
    
    
     DESCRIPTION OF THE PREFERRED EMBODIMENT 
     An X-ray protection (XRP) circuit for a single video mode application detects a voltage VXRP that is constant in proportion to the ultor voltage, over a given range of beam current level. The constant relationship between the voltage VXRP and ultor voltage permits use of the voltage VXRP detected to indirectly monitor the level of ultor voltage and disable generation of the ultor voltage when a threshold is exceeded. In a multiple video scan frequency application an increase in frequency of voltage energizing the transformer is accompanied by an increase in voltage VXRP relative to the ultor voltage. As this frequency increases the transformer&#39;s losses are more pronounced and the voltage energizing the transformer is boosted to maintain a relatively constant ultor voltage. Voltage VXRP increases as the primary voltage is increased to maintain the ultor voltage constant. As a result, voltage VXRP increases relative to the ultor voltage and cannot be directly sensed to monitor and disable generation of the ultor voltage when a threshold level is surpassed by the voltage VXRP. 
     An exemplary high voltage power supply circuit  20  according to FIG. 2 employs an XRP circuit  23  that includes an inventive frequency compensation circuit  24  to control coupling of a voltage VDCXRP to a fault comparator circuit  25  so that a sensed voltage VSXRP at a terminal  77  is representative of an ultor or high voltage VHV developed by a secondary winding T 1   b , over increases in frequency of the voltage energizing primary inding T 1   a  of a high voltage transformer. The high voltage power supply circuit  20  is depicted with exemplary circuit component values in which resistor values are in ohms unless designated with “k” indicating kilo-ohms, and capacitor values are in microfarads designated with “uF” and in nanofarads designated with “nF”. 
     A conventional high voltage regulator  30  supplies a voltage +B HVR, filtered by capacitor C 704 , to primary winding T 1   a . The +B HVR voltage is pulsed by controlled switching of an FET transistor Q 700  to energize primary winding T 1   a . When current in primary winding T 1   a  is switched off energy in winding T 1   a  is inductively transferred to secondary windings T 1   b  and T 1   c  which develop a DC high voltage VHV and a pulse voltage VXRP, respectively. High voltage VHV, commonly referred to as ultor voltage, is applied to ultor terminal U of the CRT comprising a capacitive load UCAP and variable impedance load RVHB. Resistive load RVHB varies in accordance with changes in image brightness displayed by the CRT. 
     The high voltage VHV developed by secondary winding T 1   b  is fed back to the regulator  30  so that the +B HVR voltage can be varied for changes in load to maintain a relatively constant high voltage VHV. Load changes presented by the variable resistive load RVHB of the CRT cause changes in beam current Ibeam through secondary winding T 1   b . A conventional automatic beam current limiter (ABL)  28  operates to limit beam current Ibeam through the ultor terminal U to the CRT&#39;s anode. The ABL  28  clamps beam current Ibeam at a maximum DC current level. When a high level of beam current Ibeam is drawn through secondary winding T 1   b , the sampled beam current voltage across a capacitor C 700  and a resistor  702  is reduced and is coupled to ABL  28  by a resistor R 700  to cut back beam current. 
     Switching of transistor Q 700  is controlled by push-pull operation of transistors Q 703  and Q 704  in high voltage generator circuit  22 . The +12 V regulated supply is dropped across a voltage divider comprising resistors R 745 , R 723  and R 724  to bias set the base terminals of transistors Q 703  and Q 704  and bring diode D 700  into forward conduction. Voltage drops across resistors R 706  and R 709  stabilize push-pull operation as temperature variation of base-emitter voltages in either Q 703  or Q 704  does not cause current to rise very rapidly. 
     Transistor Q 700  is driven with a square wave of approximately 50% of the period, locked to horizontal scan frequency by a conventional phase-lock loop circuit (Horiz_PLL)  29 , that generates a pulse waveform BP. The Horiz_PLL synchronizes operation of the high voltage generator circuit  22  to the horizontal scan frequency. The Horiz_PLL timing is modified by a frequency offset voltage fov provided by a digital-to-analog converter (DAC)  34 . The DAC  34  is responsive to a microprocessor (μp)  33  communicating over an IIC a digital signal over an bus indicative of a user selected (SEL) video mode. For example, changing from an ATSC high definition mode to an SVGA monitor mode changes the horizontal scan frequency from 33.670 kHz (2.14H) to 37.880 kHz (2.4H), thereby increasing the voltage fov to adjust the Horiz_PLL  29  so that switching of transistor Q 700  is changed from 33.670 kHz and locked to 37.880 khz. In NTSC mode, however, transistor Q 700  is driven at 31.968 kHz (2H) while the Horiz_PLL is locked to the broadcast scan frequency of 15734.26 kHz (1H), which is too low to generate the desired high voltage VHV. 
     As the high voltage VHV is developed by the secondary winding T 1   b  a voltage VXRP is developed by the other secondary winding T 1   c  inductively coupled to primary winding T 1   a . For a constant frequency at which primary winding T 1   a  is energized the high voltage VHV and pulse VXRP generally maintain a constant relationship to each other, over a given beam current level range, as the inductive coupling relationships between primary winding T 1   a  and secondary windings T 1   b  and T 1   c  remain constant. This generally constant relationship allows the voltage VXRP to be representative of the high voltage VHV. 
     The secondary voltage VXRP is filtered and rectified, by the combination of resistor R 903 , capacitor C 901  and diode CR 901 , to provide a half-wave voltage VDCXRP to the XRP circuit  23 . The XRP circuit  23  operates to disable operation of the high voltage generator circuit  22  when the high voltage VHV reaches a fault level. The XRP circuit  23  comprises an inventive frequency compensation circuit  24 , a fault comparator circuit  25 , and a latch circuit  26 . The comparator circuit  25  detects a fault operation of the high voltage generator circuit  22  by detecting a fault level in the high voltage VHV and enables the latch circuit  26  to disable the high voltage generator circuit  22  from energizing the transformer TI. A portion of the voltage VDCXRP is dropped across resistor R 915  of the frequency compensation circuit  25  to provide a sense voltage VSP at terminal  66  coupled to the fault comparator circuit  25 . 
     Under a constant frequency at which winding T 1   a  is energized the voltage VDCXRP, and also the sense voltage VSXRP, maintains a generally constant relationship with the high voltage VHV, over a given range of beam current Ibeam level. Transistor Q 901  which is normally off operates as the XRP circuit  23  switch to disable generation of high voltage VHV. The rectified sense voltage VSXRP is filtered by capacitor C 905 , divisionally dropped across resistors R 901  and R 902 , and coupled to the emitter leg of transistor Q 901 , which includes diode D 900  and resistor R 900 . If the high voltage VHV begins to increase than voltage VXRP, as well as voltage VDCXRP and sense voltage VSXRP, increases proportionally and continues to be representative of the high voltage VHV level. It is noted that at low beam currents, the proportion does change somewhat relative to high beam currents Ibeam. 
     If the sense voltage VSXRP increases enough, in correspondence with an increase in high voltage VHV, to drop a voltage Vcomp, between divider resistors R 901  and R 902 , above a reference voltage Vref developed across zener diode D 900 , resistor R 900  and emitter-base junction of transistor Q 901 , than transistor Q 901  is switched on. Collector current from Q 901  is voltage divided between resistor pair R 906  and R 907  to turn on transistor Q 902  in latch circuit  26 . 
     With transistor Q 902  turned on, voltage developed between resistors R 746  and R 723  in the high voltage generator circuit  22  is drawn across resistor R 908  and capacitor C 904  to bias transistor Q 903  on, while the emitter leg of transistor Q 902  dissipates current in resistor R 912 . As transistor Q 903  turns on it provides a low impedance path through C 902  to the reference potential for the base drive signal from the Horiz_PLL  29 . As a result, switching of transistor Q 700  ceases and generation of high voltage VHV is disabled. Once transistors Q 902  and Q 903  are switched on they remain on until the regulated supply voltage +12V is removed. Alternatively, the XRP circuit can change the frequency of horizontal operation to make the CRT not viewable. 
     A problem with conventional XRP circuits, without the inventive frequency compensation circuit  24 , occurs when the frequency at which the transformer is energized varies. At greater energizing frequencies, transformer losses discussed above increase and the voltages VXRP, VDCXRP and VSXRP increase relative to the high voltage VHV. If the fault comparator circuit  25  is configured to detect a proper fault level in the high voltage VHV based on a certain relationship between sense voltage VSXRP and high voltage VHV, then increasing the energizing frequency will produce an increase in VSXRP relative to VHV and may cause premature or nuisance tripping by the XRP circuit. Conversely, decreasing the energizing frequency will reduce the sense voltage VSXRP relative to the high voltage VHV and may result in operation of the XRP circuit  23  with a disabling or trip curve above an isodose curve level. 
     Adjustment by the XRP circuit  23  to changes in frequency at which primary winding T  1  a is energized is accomplished with an exemplary inventive frequency compensation circuit  23 . The compensation circuit shown is a common-emitter type transistor circuit with gain controlled by emitter current from transistor Q 905  through resistor R 919 . As frequency changes the frequency offset voltage fov changes accordingly to bias transistor Q 905  as needed. If the frequency increases, for example, than the offset voltage fov will increase, and in tandem with an increased voltage VDCXRP dropped between voltage divider resistors R 916  and R 917  the fov will bias transistor Q 905  to draw more collector current Ic. In response to increased collector current Ic a greater amount of voltage VDCXRP is dropped across resistor R 915  so as to provide a sense voltage VSXRP in proportion to and representative of the high voltage VHV 
     Without the frequency compensation, sense voltage VSXRP would be higher relative to the high voltage VHV and the fault comparator circuit would prematurely detect a high voltage VHV fault. In the case of an increase in frequency, for example, without adjusting the dissipation of VDCXRP across resistor R 915 , trip curves  15  or  16  (FIG. 1) might reside lower than as shown and cause nuisance tripping. In the case of a decrease in frequency, without adjusting the dissipation of VDCXRP across resistor R 915 , sense voltage VSXRP will decrease relative to the high voltage VHV and place trip curves  15  or  16  higher than shown in FIG. 1, and possibly above isodose curve  12 . 
     At whatever frequency and corresponding relationship between high voltage VHV and sense voltage VSXRP the fault comparator circuit  25  is configured for proper high voltage VHV fault detection, the inventive frequency compensation circuit  24  adjusts coupling of the voltage VDCXRP to the comparator circuit  25  to provide over varying frequencies a sense voltage VSXRP in proper relationship to the high voltage VHV. 
     The above frequency compensation is applicable to high voltage generators that incorporate both horizontal scan driven high voltage systems or scan-independent driven high voltage systems. Also, the present frequency compensation can be applied to other situations where transformer pulse amplitudes do not frequency track high voltage. 
     For CRT applications involving multiple transformer energizing frequencies in which voltage operation is significantly below the CRT&#39;s isodose curve, the XRP circuit can be operated to detect an ultor voltage fault, i.e. when ultor or high voltage at a corresponding beam current is above the CRT&#39;s normal operating point, at the lowest frequency of operation. At higher transformer energizing frequencies the XRP circuit can detect an ultor voltage fault at a lower ultor voltage than at a lower frequency. For smaller CRT&#39;s, such as those used in projection televisions and smaller multimedia monitors, the desired high voltage operative point can be very close to the CRT&#39;s isodose curve and variation in the ratio of ultor voltage to voltage VXRP can be minimized.