DE10058529A1 - Control method for gas discharge light source e.g. liquid crystal display rear illumination light source, controls light source current dependent on light source temperature - Google Patents

Abstract

The light source control method measures the ambient temperature of the light source (7,7'), for determining a light source temperature, with corresponding control of the operating current for the gas discharge light source, e.g. for providing a controlled temperature increase from the switching on of the light source up to the required operating temperature. An Independent claim for display device in an automobile is also included.

Description

State of the art

The invention is based on a control method for a light source according to the genus of the main claim. Out DE 198 31 822 A1 discloses gas discharge light sources in the form of cold cathode tubes for backlighting one To use liquid crystal display device. To the Temperature dependence of the brightness of cold cathode tubes to compensate for this, the ambient temperature of the Cold cathode tube measured and the energy supply to the Cold cathode tube is compared to an energy supply in the Normal operation increases when the ambient temperature is one Falls below the limit. The measurement of Ambient temperature or the operating temperature can on the cold cathode tube itself or on one of these remote location. A temperature of Wall of the cold cathode tube, however, is not determined. Usually this temperature is over Sensors determined directly on the cold cathode tube.

Advantages of the invention

The control method according to the invention with the features The main claim has the advantage that a  Light source temperature from a measured Ambient temperature determined and from this a current through the Light source, preferably a gas discharge light source, in Dependence on the light source temperature is determined, without a temperature sensor directly on the Gas discharge light source must be arranged. hereby it is avoided that performance losses as a result of Scattering capacities of one arranged at the light source Sensors occur. By determining the The light source temperature can be determined by the Gas discharge light source driven current on the actual temperature conditions in the light source be coordinated. It is also advantageous that the Determination of the light source temperature from the Ambient temperature a subsequent installation of a Temperature sensor in a device in which the control method according to the invention is operated, is possible if there is a temperature reference between Ambient temperature and the light source temperature determined and saved.

By the measures listed in the subclaims advantageous further developments and improvements of the The control method specified in the main claim is possible. It is particularly advantageous when the Gas discharge light source the particular one Light source temperature based on the ambient temperature to a light source temperature in an operating state adapt. It is particularly advantageous here Temperature curve during the switch-on process using a Realize low pass that is electronically simple can be reproduced. The temperature curve over time at is like switching on a gas discharge light source a jump function that go through a low pass Has. The parameters of the low pass, capacity and  Resistance, can in the heat capacity and the Thermal conductivity of a wall of the light source adjusted so that the low pass is heating the light source can represent type-specific.

The light source current is also advantageous to control according to a stored characteristic, since an optimal assignment for every temperature between the light source temperature and that by the Gas discharge light source driven electricity can be taken can. It is particularly advantageous in addition to the Increasing the current at low temperatures also a Lowering the current at high light source temperatures make. This can create a temperature dependency of brightness for both high temperatures and low temperatures can be compensated.

It is also advantageous to remove the temperature sensor from to arrange the light source, especially on one PCB, because of this a light electrical Contacting the temperature sensor is possible.

It is also advantageous to dim the light source and the Dimming must be taken into account when determining the temperature, since in the case of a strongly dimmed light source, heating takes place more slowly than with a light source with a full nominal brightness of the light source is operated.

It is also advantageous to use the method according to the invention in a display device in a motor vehicle use because motor vehicles have large temperature fluctuations are exposed to e.g. B. between strong sunlight and frost, and therefore one used there Gas discharge light source in a wide temperature range must be ready for use.  

drawing

Embodiments of the invention are shown in the drawing and explained in more detail in the following description. In the drawings Fig. 1 shows an inventive display instrument in a motor vehicle, Fig. 2 shows a first procedure according to the invention, Fig. 3 shows a second procedure according to the invention, Fig. 4, a determination according to the invention the light source temperature after switching on of the gas discharge light source, Fig. 5, a characteristic curve according to the invention for the light source current.

Description of the embodiment

The control method according to the invention is for a A variety of gas discharge light sources can be used. Especially with cold cathode tubes, especially with Cold cathode fluorescent tubes, the brightness is special strongly dependent on the temperature. The Cold cathode fluorescent tubes can be used both for Backlighting of liquid crystal displays as well Illumination of any other displays, such as B. Pointer indicators can be used. Here is the use of the method according to the invention in particular for such Applications useful in those with strong Temperature fluctuations can be expected, e.g. B. in one Vehicles or in mobile devices, e.g. B. mobile computers. In the following the method according to the invention is for a Use in a display instrument in a motor vehicle explained.

In the FIG. 1 is an indicating instrument 1, a so-called combination instrument with a plurality of individual ads shown. On a dial 2 with a printed scale 3 , a pointer 4 is arranged, which moves over the scale 3 , so that a scale value can be displayed on the scale 3 with the pointer 4 . Furthermore, a liquid crystal display 5 is arranged in the display instrument 1 , in which any images, such. B. maps, warnings, warning symbols or graphically represented scales or bar graphs can be displayed. A circuit board 6 is arranged behind the dial 2 , on which cold cathode tubes 7 , 7 ', preferably cold cathode fluorescent tubes, are arranged. The cold cathode tube 7 is used to backlight the dial 2 and the cold cathode tube 7 'is to backlight the liquid crystal display 5 . Furthermore, a control unit 8 for controlling the cold cathode tubes 7 , 7 'is arranged on the printed circuit board. In addition, there is a temperature sensor 9 on the circuit board 6 for determining the temperature on the circuit board 6 or within the display instrument 1 . The temperature sensor 9 is preferably designed as a PTC thermistor, as a thermistor or as a semiconductor temperature sensor. Further electrical components on the circuit board 6 are not shown in FIG. 1 for reasons of clarity of the drawing. The dial 2 preferably assigns a viewer to the display instrument 1 , which is preferably installed in an instrument panel of the motor vehicle. The cold cathode tube 7 and / or the cold cathode tubes 7 can be controlled with the control method according to the invention.

In FIG. 2, a first inventive process sequence is shown. In an off state of the backlight through the cold cathode tubes 7, 7 ', the ambient temperature of the cold cathode tubes 7, 7 by the temperature sensor 9 in a temperature determination 10' determined by a temperature measurement on the printed circuit board. 6 The temperature determination 10 , which is carried out by the control unit 8 by evaluating the temperature sensor 9 , is given to the input of a low-pass filter 11 by a switch 12 making contact with the temperature determination 10 . When the cold cathode tubes 7 , 7 'are switched on, the switch 12 is switched to a second state according to an arrow 13 , in which an added temperature is applied to the input of the low-pass filter 11 , in which the ambient temperature is added to a stored temperature difference 14 . The temperature difference 14 is the difference between the internal light source temperature and the ambient temperature determined by the temperature sensor 9 , which is established in thermal equilibrium during operation. In a preferred embodiment, this temperature difference depends on the ambient temperature. When the switch 12 is switched over, the temperature which is applied to the input of the low-pass filter 11 suddenly increases from the ambient temperature, which is preferably measured continuously, to an addition temperature from the ambient temperature plus the temperature difference 14 . The low-pass filter 11 outputs a light source temperature at which the increase from the ambient temperature to the addition temperature caused by the switching on takes place gradually. A temperature profile is shown in FIG. 4. An output temperature of the low-pass filter is shown on a y-axis 21 opposite an x-axis 20 , which represents the time profile. Up to a switch-on time 22 , the temperature output by the low-pass filter 11 is the ambient temperature 23 . After switching on, the input of the low pass suddenly rises to the addition temperature from the ambient temperature and temperature difference 14 . The abrupt increase is shown by a dashed line 25 . After switching on, the input of the low pass remains at this temperature. The temperature profile after switching on, which is output by the low-pass filter 11 , is represented by a solid line 26 and approaches the addition temperature 24 as a curve. This simulates the gradual heating of the light source after switching on until the light source has reached its operating temperature in thermal equilibrium with the surroundings, which does not change even during continuous operation at a constant ambient temperature. The low pass 11 is preferably implemented digitally in a digital circuit within the control unit 8 . However, implementation with analog components, that is to say a resistor and a capacitor, is also possible. An adaptation to the type of cold cathode tube 7 , 7 'used is carried out by varying the parameters of the low-pass filter 11 , that is to say the value of the resistance and / or the capacitance.

The output of the low pass is given to a characteristic curve evaluation 15 . In the characteristic curve evaluation 15 , a current to be driven by the gas discharge light source is assigned to a temperature value. In FIG. 5, an example of a characteristic is shown. A light source temperature is plotted on an x-axis 30 . In contrast, a light source current is plotted on a y-axis 31 . A characteristic curve 32 is entered in this field, which represents the light source current as a function of the light source temperature. In a first, medium temperature range 33 , which is preferably between approximately 15 ° C. and 65 ° C., the cold cathode tube 7 , 7 'is operated with a normal current 34 , which is provided by a manufacturer of the cold cathode tube 7 , 7 ' for a desired brightness of the light source under normal conditions, e.g. B. 20 ° C, is specified. In a second temperature range 35 , which is below the first temperature range 33 and thus z. B. is below a temperature value of 15 ° C, the current which is driven through the cold cathode tubes 7 , 7 'is increased, preferably linearly starting from the normal current 34th In a third temperature range 36 , which is above the first temperature range 33 and thus z. B. is above a temperature value of 65 ° C, the light source current is preferably reduced linearly with the temperature in order to be able to reduce the light source temperature. The light source current determined in the characteristic curve evaluation 15 is output in each case to the cold cathode tubes 7 , 7 ', preferably via a high-voltage supply not shown in the drawing.

FIG. 3 shows a second exemplary embodiment for a control method according to the invention. Here and in the following, the same reference symbols also denote the same steps. In addition to the control method described in FIG. 2, dimming of the cold cathode tubes 7 , 7 'is possible here. In the control unit 8 , a microcontroller is preferably implemented in software. Dimming determination 16 arranged, which receives signals from an ambient light sensor 17 and / or a dimming button 18 . Depending on the ambient light or on an actuation of the dimming button 18 , which enables a user to change the brightness of the liquid crystal display 5 or the backlighting of the dial 2 , the dimming determination 16 determines an interruption in the light source current, a so-called pulse width modulation. This interruption takes place periodically, the period length being substantially greater than a period length of the alternating current frequency with which the cold cathode tubes 7 , 7 'are preferably operated. The power supply is interrupted by the dimming determination 16 after the characteristic curve evaluation 15 by a switch 19 . Since a strongly dimmed light source heats up more slowly, or only reaches a lower temperature compared to the surroundings than a light source controlled with maximum power, the temperature difference 14 between the temperature of the printed circuit board 6 and the light source temperature with the dimming ratio caused by is multiplied 40 the dimming determination 16 is determined, multiplied. This simulates slower heating of the cold cathode tubes when dimming. If the cold cathode tube 7 , 7 'z. B. dimmed by 75% compared to its full brightness, the temperature difference, which is stored for the full operating power, is reduced to 25% of this value. The multiplication 40 can be adapted to the type of cold cathode tube 7 , 7 'used, so that in the case mentioned a reduction to 50% of the stored temperature difference is also possible.

Claims (10)

1. Control method for a light source, preferably a gas discharge light source, wherein an ambient temperature of the light source is measured, characterized in that a light source temperature is determined from the ambient temperature and that a current through the light source is determined as a function of the light source temperature. 2. Control method according to claim 1, characterized characterized that a determination of Light source temperature is made by after the Turning the light source on is preferably a gradual one Increase the light source temperature based on the Ambient temperature up to an operating temperature of Light source is determined. 3. Control method according to claim 2, characterized characterized that when you turn on a sum of one Ambient temperature and a temperature difference of Light source to the ambient temperature during continuous operation is put on a low pass. 4. Control method according to one of the preceding Claims, characterized in that a  Light source current depending on a stored Temperature-current characteristic curve is determined. 5. Control method according to one of the preceding Claims, characterized in that the Light source current at temperatures below a first Temperature value is increased. 6. Control method according to one of the preceding Claims, characterized in that the Light source current at temperatures above a second Temperature value is lowered. 7. Control method according to one of the preceding Claims, characterized in that the Ambient temperature of the gas discharge light source with a sensor is measured that is remote from the Light source, preferably on a circuit board, is arranged. 8. Control method according to one of the preceding Claims, characterized in that the Light source brightness is changed, preferably by a pulse width modulation. 9. Control method according to claim 8, characterized characterized that the light source temperature in Dependence on the change in brightness determined becomes. 10. Display device in a motor vehicle with a gas discharge light source, characterized in that the gas discharge light source ( 7 , 7 ') can be operated according to a control method according to one of the preceding claims.