The invention relates to a method and an electronic operating device for operating a gas discharge lamp including a gas discharge lamp burner and a first and a second electrode, wherein the electrodes have a nominal electrode separation in the gas discharge lamp burner before their first activation and said nominal separation is correlated to the lamp voltage.
In recent times, use of gas discharge lamps instead of incandescent bulbs is growing as a result of their high efficiency. In terms of operation, high pressure discharge lamps are more difficult to handle than low pressure discharge lamps in this case, and the electronic operating devices for these lamps are therefore more expensive.
High pressure discharge lamps are usually operated by means of a low-frequency square-wave current, also known as intermittent direct current operation. In this case, an essentially square-wave current having a frequency of usually 50 Hz to several kHz is applied to the lamp. The lamp commutates with each oscillation between positive and negative voltage, because the current direction also changes and the current is therefore briefly at zero. This operation ensures that the electrodes of the lamp are uniformly loaded in spite of quasi-direct current operation.
Gas discharge lamps are successfully used for display systems, for example, because they can generate a high luminance which can be subsequently processed by an inexpensive lens system. Display systems and their lighting apparatus are described in the publications U.S. Pat. No. 5,633,755 and U.S. Pat. No. 6,323,982, for example. Display systems such as DLP projectors (DLP: digital light processing) include a lighting apparatus having a light source whose light is directed onto a DMD chip (DMD: digital mirror device). The DMD chip microscopically includes small tilting mirrors, which either direct the light onto the projection surface if the associated pixel is to be turned on, or direct the light away from the projection surface, e.g. onto an absorber, if the associated pixel is to be switched off. Each mirror therefore acts as a light valve which controls the light level of a pixel. These light valves are generally known as DMD light valves. For the purpose of generating colors in the case of a lighting apparatus which emits white light, a DLP projector includes a filter wheel, for example, which is arranged between lighting apparatus and DMD chip and contains filters of various colors, e.g. red, green and blue. By means of the filter wheel, light of the currently desired color is sequentially transmitted from the white light of the lighting apparatus.
The color temperature of such display systems is normally dependent on the spectrum locus of the light of the lighting apparatus. This usually changes according to the operating parameters of the light sources of the lighting apparatus, e.g. voltage, current intensity and temperature. Furthermore, depending on the light sources used in the lighting apparatus, the ratio between current intensity and light level is not necessarily linear. Consequently, a change of the current intensity also results in a change of the spectrum locus of the light of the light source, and hence in a change of the color temperature of the display system.
Furthermore, the color depth of the display system is limited by the minimal ON-time of a pixel. In order to increase the color depth, it is possible to implement e.g. dithering, wherein individual pixels are switched using a lower frequency than the regular frequency of 1/60 Hz. However, this usually results in noise which is visible to a human observer.
The contrast ratio of the display system is defined by the ratio of the maximal light level resulting from fully opened light valves to minimal light level resulting from fully closed light valves. In order to increase the contrast ratio of a display system, the minimal light level resulting from fully closed light valves can be further reduced by means of a mechanical screen, for example. However, a mechanical screen requires space in the lighting apparatus or the display system, increases the weight of the lighting apparatus or the display system, and also represents an additional potential source of interference. High pressure discharge lamps such as those used in such display systems can also be operated in a dimmed mode, though the dimmed operating mode raises problems with regard to the electrode temperature and the arc root in the high pressure discharge lamp.
The arc root is generally problematic when alternating current is used for operation of a gas discharge lamp. When alternating current is used for operation, a cathode becomes an anode and an anode conversely becomes a cathode during commutation of the operating voltage. The cathode-anode transition is not problematic in principle, since the temperature of the electrode does not have any effect on its anodic operation. In the case of the anode-cathode transition, the ability of the electrode to supply a sufficiently high current is dependent on its temperature. If this is too low, the electric arc changes during the commutation, usually following a zero crossing, from a concentrated arc root operating mode to a scattered arc root operating mode. This change is accompanied by an interruption in the light output, which is often visible and can be perceived as flickering.
Ideally therefore, the lamp is operated in concentrated arc root operating mode, since the arc root in this case is very small and therefore very hot. As a consequence of this, less voltage is required here due to the higher temperature at the small root point, in order to be able to supply sufficient current. An electrode tip which has a uniform shape and whose surface is not fissured supports the concentrated arc root operating mode and hence safer and more reliable operation of the gas discharge lamp.
In the following, commutation is considered to be the process in which the polarity of the voltage of the gas discharge lamp alternates, and in which a significant change in current or voltage therefore occurs. In the case of an essentially symmetrical operating mode of the lamp, the voltage zero or current zero occurs in the middle of the commutation time. It should be noted in this context that the voltage commutation usually always occurs more quickly than the current commutation.
The inner end of the lamp electrode, said inner end projecting into the discharge space of the gas discharge lamp burner, is referred to below as an electrode end. A needle or peak-shaped raised part which is positioned on the electrode end, and whose end is used as a root point for the electric arc, is referred to as an electrode tip.
The variation or distortion of the electrodes over the entire service life represents a significant problem of high pressure discharge lamps. In this case, the shape of the electrode changes from the ideal shape to an increasingly fissured surface, particularly at the inner end of the electrode. Moreover, there is a risk of producing electrode tips that are not arranged in the center of the relevant electrode. The discharge arc always forms from electrode tip to electrode tip. If a plurality of electrode tips of approximately equal validity are present on an electrode, this can result in arc jumping and hence to flickering of the lamp. Electrode tips which grow non-centrically will degrade the optical image, since the lens system of a projector or a light (in which such a discharge lamp is installed) is configured relative to a specific position of the discharge arc, and in particular is adjusted relative to the initial state of the electrodes and the discharge arc. In certain cases, the electrode tips can grow unevenly, such that the electric arc is no longer arranged centrally in the burner vessel, but is shifted axially. This likewise degrades the optical image of the overall system. By contrast, the fissuring results in an increase of the original electrode separation and therefore also affects the lamp voltage. As this increases proportionally relative to the separation, it can result in premature service life shutdown, since this usually occurs when the lamp voltage exceeds a predetermined threshold value. In summary, this results in a reduction in the lamp service life and in the quality of the light emitted from the lamp.
The prior art does not currently disclose any solutions to these problems. Merely for the sake of completeness, reference is made to WO 2007/045599 A1. While the problem giving cause to the present invention occurs at the end of the lamp service life, the cited publication addresses a problem which occurs within the first three hundred operating hours. Tip growth can occur during this period, resulting in a reduction of the electrode separation. This causes the lamp voltage to decrease, such that the current to be supplied by an electronic operating device must be increased in order to achieve a constant power. Since electronic operating devices are naturally configured for a specific maximum current, this results in problems. In order to avoid an increase of the current configuration for the continuous operation and the resulting occurrence of additional costs, the cited publication proposes that a current pulse be applied to the electrodes, such that the electrode tips which have grown are fused back. In this way, the separation of the electrodes can be increased again, the lamp voltage increased, and the required current therefore decreased. By contrast, however, the present invention addresses the problem of conserving the electrodes in an optimal state, as far as possible over the entire service life of the gas discharge lamp, wherein the electrodes have a relative separation which corresponds as far as possible to the original separation that is present in a new lamp, and wherein the surface of the electrode ends remains smooth and has tips which grow centrically, forming a defined root point for the arc. The teaching of WO 2007/045599 A1 does not therefore solve the problem cited above.
The object of the invention is to disclose a method and an electronic operating device for operating a gas discharge lamp including a gas discharge lamp burner and a first and a second electrode, wherein the electrodes have a nominal electrode separation in the gas discharge lamp burner before their first activation, and the gas discharge lamp no longer exhibits the above cited problem when the electronic operating device is operating using the method according to the invention. The invention likewise addresses the problem of specifying a projector which features such an electronic operating device.
The problem in respect of the method is solved according to the invention by means of a method for operating a gas discharge lamp including a gas discharge lamp burner and a first and a second electrode, wherein the electrodes have a nominal electrode separation in the gas discharge lamp burner before their first activation and said nominal separation is correlated to the lamp voltage, including the following steps:
As a result of the length of the DC voltage phase being dependent on the lamp voltage, good control accuracy can be achieved and the shaping of the electrodes is particularly efficient. In this case, the length of the DC voltage phase is preferably between 2 ms and 500 ms, and the length between the DC voltage phases is preferably between 180 s and 900 s. The time durations can be precisely specified within this range depending on the lamp type, in order to ensure particularly efficient shaping of the electrodes.
In a further preferred embodiment, the length of the DC voltage phases is determined by the change or the rise in the lamp voltage during these DC voltage phases. In case the rise criterion is not satisfied, a maximal duration of the DC voltage phases can be predetermined, wherein said maximal duration can again depend on e.g. the lamp voltage as in the previous embodiment. As a result of this measure, the accuracy with which the electrodes can be regulated is clearly increased and the likelihood of excessive energy input is thereby reduced.
If the predefined separation of the DC voltage phases is between 180 s and 900 s, the electrodes are not excessively loaded and the service life of the gas discharge lamp is not adversely affected.
An upper lamp voltage threshold is preferably between 60 V and 110 V, and a lower lamp voltage threshold is preferably between 45 V and 85 V, in particular between 55 V and 75 V. The lamp voltage thresholds can be precisely specified within this range depending on the lamp type, in order that the method can be optimized for this lamp type.
The operation of the gas discharge lamp using an alternating current, onto whose half-waves is modulated a pulse of higher current intensity, said pulse having a length of between 50 μs and 1500 μs, facilitates the shaping of the electrodes by means of the inventive method and makes said method even more efficient.
The length of the DC voltage phase can preferably be adjusted by virtue of a half-wave of the applied alternating current consisting of a plurality of partial half-waves, wherein some or all of the commutations between two half-waves are reversed again by means of a further commutation occurring shortly thereafter.
As a result of this measure, it is possible to generate DC voltage phases whose length is a multiple of a partial half-wave. By means of statistical distribution of various lengths of the DC voltage phases, it is possible on average to generate any chosen lengths of the DC voltage phases, and the energy input into the electrodes can therefore be accurately controlled. The current can only flow in one direction during the DC voltage phases, or else the polarity is reversed once in the DC voltage phase and the current flows in both directions during the DC voltage phases. The energy input can be equally distributed in each direction as part of this activity, or else the energy input can be preferentially in one current direction, such that one lamp electrode is heated more than the other. If the current only flows in one direction during a DC voltage phase, it can flow in the other direction during the following DC voltage phase. Combinations can also be conceived in which the current flows in one direction during the first two DC voltage phases, and the current flows in the other direction during the following two DC voltage phases. Provision can also be made here for preferential energy input into one electrode, whereby e.g. the current flows in one direction during the first two DC voltage phases, the current flows in the other direction during the third DC voltage phase, and the current flows in the first direction again during the fourth and fifth DC voltage phases. If the various partial half-waves of a half-wave apply different current intensities to the gas discharge lamp, the method can be refined further, and the desired average energy input can be introduced into the electrode in a shorter time.
The problem in respect of the electronic operating device is solved according to the invention by means of an electronic operating device which performs a method in accordance with one or more of the features cited above. By virtue of this measure, the operating device is able optimally to maintain the gas discharge lamp.
The problem in respect of the projector is solved according to the invention by means of a projector including an electronic operating device, wherein the projector is designed to project an image during the execution of the inventive method in such a way that the execution of the method is not apparent from the image. By virtue of this measure, the method can be executed at any time without affecting the live operation, and therefore the lamp can be maintained at any time.
Further advantageous developments and embodiments of the inventive method and of the inventive electronic operating device for operating a gas discharge lamp are derived from further dependent claims and from the following description.
Further advantages, features and details of the invention are revealed with reference to the following description of exemplary embodiments and with reference to the drawings, in which identical or functionally identical elements are denoted by means of identical reference signs, and in which:
a shows a graph in which is illustrated the relationship between the lamp voltage and the commutation frequency in a first form of the third embodiment of the operating method;
b shows a graph in which is illustrated the relationship between the lamp voltage and the commutation frequency in a second form of the third embodiment of the operating method;
c shows a curve profile of the lamp current for the second form of the third embodiment of the operating method;
The following explains what a DC voltage phase is: DC voltage phases consist of the omission of some commutations. These omissions are so positioned that the electrodes are only ever loaded alternately in each case, meaning that one electrode acts first as an anode during a DC voltage phase, then, following a pause for normal lamp operation, the other electrode acts as an anode during a DC voltage phase. The frequency per se is not changed. During a positive DC voltage phase, only a first electrode of the gas discharge lamp is ever heated up, and during a negative DC voltage phase, only a second electrode of the gas discharge lamp is ever heated up. Since a positive DC voltage phase only ever acts on the first electrode and a negative DC voltage phase only ever acts on the second electrode of the gas discharge lamp, various states of the gas discharge lamp electrodes can be changed depending on the procedure. In an alternative method, strictly speaking no commutations are omitted, but each “normal” commutation is “reversed” by a further commutation which follows immediately thereupon. This operating model therefore generates pseudo commutations which simulate an omission of a commutation in principle, but actually represent two commutations which are executed rapidly one after the other. This is sometimes necessary for technical reasons, in order that the circuit arrangement for executing the inventive method can be simpler in design. Depending on the length and the resulting energy input of the DC voltage phases, various physical processes can be intensified in the gas discharge lamp burner. The DC voltage phases are therefore created by omitting commutations or by introducing pseudo commutations. In the second variant, they are therefore not DC voltage phases in the strict sense, since the voltage and hence the current direction meanwhile reverses polarity twice per pseudo commutation, and any number of pseudo commutations can occur per ‘DC voltage phase’.
Very long DC voltage phases characterized by high energy input fuse the whole end of the relevant electrode for a short time. During the short period in which the electrode end is molten, the end assumes a spherical or oval shape due to the surface voltage of the electrode material. The electrode tips fuse and are neutralized by the surface voltage of the electrode material. This results in a slight increase of the arc length and therefore the lamp voltage due to the regeneration of the electrode tips.
Short DC voltage phases only cause a surfusion of the electrode tips, such that the shape of the electrode tips can be influenced. This is utilized for the purpose of conserving the electrode tips in the most optimal shape possible over the entire burning life, and for generating a defined centrically positioned tip.
A so-called maintenance pulse can accelerate the tip growth of the electrode tip, and is preferably applied after an extended DC voltage phase in order to allow regrowth, on the oval or round electrode end, of an electrode tip which generates a good arc root point. In this context, a short current pulse which is applied shortly before or after the commutation to the gas discharge lamp in order to heat the electrode is referred to as a maintenance pulse. The length of the maintenance pulse is between 50 μs and 1500 μs long, wherein the current level of the maintenance pulse is greater than during stationary operation. As a result, surfusion of the outer end of the electrode tip is achieved, the thermal inertia thereof having a time constant of approximately 100 μs.
In a first embodiment of the method according to the invention, the lamp is subjected at regular intervals to a DC voltage phase whose length is always dependent on the lamp voltage. The intervals between two DC voltage phases are also dependent on the lamp voltage. The method uses the characteristic curve VT as per
In the case of a very low lamp voltage, which normally occurs in the case of a new gas discharge lamp, and which relates to the left-hand part of the characteristic curve VT, extended DC voltage phases are applied to the gas discharge lamp in order to melt down the grown electrode tips and prevent the electrode separation from becoming too small. The lower the lamp voltage, the longer the DC voltage phases. The DC voltage phases are applied to the lamp below a minimal lamp voltage. The range of the minimal lamp voltage varies between 45 V-85 V depending on the lamp type, in particular between 55 V-75 V. In the context of the gas discharge lamp in the present embodiment, the minimal voltage is 65 V. Extended DC voltage phases are therefore applied to the gas discharge lamp burner below 65 V. In the preferred embodiment, the length of the DC voltage phases is 40 ms at 65 V, wherein the DC voltage phases become longer as the voltage decreases, thereby reaching a length of 200 ms at 60 V. The length of the DC voltage phases can vary between 5 ms and 500 ms depending on the lamp type. The DC voltage phases are applied to the gas discharge lamp at regular intervals. The intervals are dependent on the lamp voltage, but are not shorter than 180 s. In the preferred embodiment, the duration between two DC voltage phases (off-time OT) as shown in
At an optimal lamp voltage in the central region of the characteristic curve VT, only very short DC voltage phases are applied to the gas discharge lamp, which only briefly fuse the electrode tips and therefore conserve their shape. The rate of occurrence of the DC voltage phases is minimal in this region. The length of the DC voltage phases is approximately 40 ms in the preferred embodiment. The length of the DC voltage phases can be between 0 ms and 200 ms depending on the lamp type. In many lamp types, the DC voltage phases can also be omitted completely in this region.
As the gas discharge lamp becomes older, so the lamp voltage increases, this being caused by the burning back of the electrodes and the associated longer electric arc. In the case of older lamps, there is a high risk that the electrode end is fissured, and the electrode tips can no longer grow centrically. Long and energy-rich DC voltage phases are therefore applied to the gas discharge lamp burner, lightly surfusing the electrode ends and thereby generating an electrode surface which is as smooth as possible. This can be considered as polishing the shape of the electrode end. The DC voltage phases are also applied to the gas discharge lamp with increasing frequency as the lamp voltage increases, this being indicated by the curve OT. Above an upper voltage threshold, the parameters can be held constant. The duration of the DC voltage phases varies in the preferred embodiment from 40 ms at 75 V to 200 ms at 110 V lamp voltage of the gas discharge lamp burner. In this case, the duration of the DC voltage phases can vary from 2 ms to 500 ms depending on the lamp type. The time span between two DC voltage phases in the present embodiment is 180 s at 60 V lamp voltage, then rises to 600 s at 65 V lamp voltage, and falls to 300 s at 110 V lamp voltage. The time span between two DC voltage phases can vary between 180 s and 900 s depending on the lamp type. In summary, it can be stated that the duration of the DC voltage phases increases when the lamp voltage increases, wherein the DC voltage phases are applied to the gas discharge lamp more frequently in the case of increasing lamp voltage and in the case of very low lamp voltage.
In a second embodiment of the method, the length of the DC voltage phases is not controlled via a characteristic curve, instead the length of the DC voltage phases is regulated via the lamp voltage in the DC voltage phase itself. The above described curve VP shows the maximal voltage change of the lamp voltage in the DC voltage phase as a function of the lamp voltage. The voltage change is measured during the DC voltage phase. For this, the circuit arrangement which executes the method features a measuring apparatus, which can measure the lamp voltage before the DC voltage phase, and particularly the change of the lamp voltage during a DC voltage phase. The change of the lamp voltage during the DC voltage phase is evaluated in respect of an interrupt criterion, and the DC voltage phase is terminated when the interrupt criterion is reached.
In the method described below, a DC voltage phase which previously always consisted of a positive phase for the first electrode and a negative phase for the second electrode, is divided into these two phases in order to treat different states of the two lamp electrodes. In a first form of the second embodiment, which is suitable for equalizing an asymmetrical electrode geometry, the length of the DC voltage phase for the previously calculated voltage rise is determined for the first electrode, and is applied to the second electrode in an inverse DC voltage phase following thereupon.
In a second form, which acts symmetrically on both electrodes, the length of the DC voltage phases for each electrode is calculated from the voltage rise during the DC voltage phases. The level of the voltage rise is identical for both DC voltage phases in this context.
In a third form, individual electrode shaping is effected in order to center the light arc in the burner axis. The following method steps are executed in the third form:
In the first step, the length of the electrode tip is calculated according to the relation:
In a second step, the duration or the voltage rise of the DC voltage phase for the desired displacement of the electrode core is calculated proportionally relative to the individual length of the electrode tip:
For an asymmetrical electrode geometry in accordance with the first form, it applies that:
For a symmetrical electrode geometry in accordance with the second form, it applies that:
The third form of the second embodiment of the method offers new advantages, which the previous methods according to the prior art cannot provide. By virtue of the possibility of asymmetrical introduction of energy into the respective electrodes, it becomes possible to center the electrode system core and keep it in its centered position throughout the service life. By virtue of the centered position of the electrode core within the burner vessel, a more stable and effective light yield can be produced by the optical system, which is computed relative to a defined electrode position. The discharge arc remains at the focal point throughout the service life of the lamp. By virtue of the arc root points always being situated centrically on the electrode, an average maximal separation of the discharge arc from the burner vessel wall is produced throughout the service life, effectively reducing any denitrification of the burner vessel. In an advanced optical system, it would also be conceivable for the optical system to optimize and therefore maximize its overall efficiency by means of a control loop in which the electrode shaping mechanism is included.
It is naturally also possible to conceive of a method in which the first embodiment and the second embodiment are used in combination, in order to conserve the electrodes and the electrode tips in an optimal state. An advantageous combination could make provision for using a method of the second embodiment, in which the length of the DC voltage phase is determined by means of the lamp voltage change during this DC voltage phase, in the case of lamp voltages below the lower lamp voltage threshold, and for using a method of the first embodiment, in which the length of the DC voltage phase is calculated or is predetermined by means of a characteristic curve, in the case of lamp voltages above the upper lamp voltage threshold.
The DC voltage phases are therefore composed of half-waves of the normal operating frequency, and therefore the highest operating frequency is always a whole-number multiple or a fractional rational multiple of the frequency of the DC voltage phases.
In a third embodiment of the method, a continuous adaptation of the operating frequency takes place as a function of the lamp voltage. The method can be operated in various forms in this case. In a first form of the third embodiment, as illustrated in
In order to ensure optimal operation of the gas discharge lamp, however, a fixed operating frequency should always be maintained for a specific lamp voltage. In the present example, assuming a lamp voltage between 0 V and 50 V, a lamp current having an operating frequency of e.g. 100 Hz is applied to the gas discharge lamp. However, since the operating frequency can only assume a small number of discrete frequency values as a result of the aforementioned outline conditions, the adaptation of the operating frequency to the lamp voltage is rather approximate. The highest operating frequency is the frequency at which a commutation is carried out at every possible commutation time point. This frequency is the highest frequency that can be represented in the system. The possible commutation time points, which are predetermined by the above mentioned outline conditions relating to e.g. a color wheel, are also referred to as commutation points as mentioned previously.
In a second form of the third embodiment of the method, the operating frequency of the gas discharge lamp is continuously adapted with reference to a characteristic curve. The characteristic curve of a preferred embodiment is illustrated in
a) to d) show the state of the front parts of the electrodes at different stages of the execution of the method.
While projectors are a preferred application of discharge lamps and hence of the method, the method nonetheless relates to all types of discharge lamps, including e.g. Xenon car lights in particular. It is again pointed out that the electronic operating devices previously used for operating a discharge lamp need not be exposed to a higher load for the purpose of executing the method, since the current-time integral is critical, and therefore a lower current is simply applied for longer if applicable.
The fifth embodiment relates to an operating method which can be executed in conjunction with an operating device for the additional purpose of improving the image quality in a lighting apparatus in addition to the electrode shaping. The lighting apparatus 10 according to the exemplary embodiment in
The lighting apparatus 10 according to
The light curve 3 in the exemplary embodiment according to
The first segment SR of the light curve in
Adjoining the first segment SB is a second segment SR, which is assigned to the color red and has a duration of tR. During a first time interval tR1 of the time interval tR, the light level of the lighting apparatus 10, 11 is briefly approximately 150%, while the light level in a second time interval tR2, which immediately follows the first time interval tR1 and with this forms the time interval tR, is approximately 105%. The time interval tR1 is clearly shorter than the time interval tR2 here. The time interval tR1 is approximately 100 μs in this case, while the time interval tR2 is approximately 1200 μs in this case.
Adjoining the second segment SR is a third segment SG, which is assigned to the color green and has a duration tG of likewise approximately 1300 μs. Like the time interval tR, the time interval tG is also divided into two time intervals tG1 and tG2, wherein the first time interval tG1 is clearly longer than the second time interval tG2. The first time interval tG1 is approximately 1200 μs in this case, while the second time interval tG2 of the green segment has a duration of approximately 100 μs. During the first time interval tG1, the light curve 3 has a constant value of approximately 85%, briefly dropping to a value of approximately 45% for the time interval tG2.
After expiry of these three segments SR, SG, SB, there follows an essentially periodic repetition of these three segments SR. SG, SB, wherein the arrangement of the short time intervals tR1, tG2 within the segments, in which the light level is clearly higher or lower relative to the remainder of the segment SR. SG, differs from the periodicity. Those short time intervals of the light curve 3 in which the illuminance is significantly lower are used to increase the color depth as described above in the general description. Those short segments within which the illuminance is significantly higher are maintenance pulses, these being used as described above for stabilizing the electrodes of the gas discharge lamps.
The light curve of the exemplary embodiment according to
The individual segments SY, SG, SM, SS, SC, SB are again assigned time intervals tY, tG, tM, tR, tC, tB, which are each divided into two or three time intervals tY1, tY2, tG1, tG2, tM1, tM2, tM3, tR1, tR2, tC1, tC2, tC3, tB1, tB2 one of said time intervals being clearly longer than the other in each case. These time intervals are referred as “long time intervals” in the following. The values of the light levels in the long time intervals of the individual segments can be seen in the table in
The segment sizes of the different colors are not identical, this being evident from the table in
In connection with a light curve 3 whose segments SR, SG, SB are assigned to the colors red, green and blue, as shown by way of example in
The functions of the individual time intervals within the segments SR, SG, SB are explained by way of example in greater detail below with reference to
In the same way as the light curve 3 according to
By way of example, the light curve 3 according to
The light curve 3 according to
The characteristic curve for current intensity/illuminance in the exemplary embodiment according to
By means of the characteristic curve for current intensity/illuminance, which can also be stored in the operating device 2 of the lighting apparatus 10, 11, the brightness of the light source 1, 1R, 1G, 1B of the lighting apparatus 10, 11 can be maintained at the illuminance that is predetermined by the light curve 3 in the event of a change of lamp operating parameters, e.g. the current intensity. The correlation via the characteristic curve allows the parameter in the light curve to be directly converted into an alternating current for the gas discharge lamp. In this case, the various plateaus of the light curve are converted into respective partial half-waves, the commutation points being selected by the operating device 2 with reference to synchronization parameters of a video electronics module in the lighting apparatus 10.
The circuit that is illustrated in
The circuit diagram is merely schematic and not all control and sensor lines are shown.
The invention is not limited by the description referring to the exemplary embodiments. Rather, the invention includes every novel feature and every combination of features, including in particular every combination of features in the claims, even if this feature or this combination is not itself explicitly specified in the claims or in the exemplary embodiments.
Number | Date | Country | Kind |
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10 2009 006 338.2 | Jan 2009 | DE | national |
Filing Document | Filing Date | Country | Kind | 371c Date |
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PCT/EP2010/050311 | 1/13/2010 | WO | 00 | 9/13/2011 |