EP1738619A1

EP1738619A1 - Electronic lamp ballast comprising a digital control system for controlling dimming processes

Info

Publication number: EP1738619A1
Application number: EP05732151A
Authority: EP
Inventors: Axel Pilz; Andreas Huber
Original assignee: Patent Treuhand Gesellschaft fuer Elektrische Gluehlampen mbH
Current assignee: Osram GmbH
Priority date: 2004-04-13
Filing date: 2005-04-08
Publication date: 2007-01-03
Also published as: WO2005101922A1; DE102004018371A1; JP2007533086A

Abstract

The invention relates to an electronic lamp ballast that can be used to perform dimming processes using digital nominal value settings. According to the invention, the nominal value settings are smoothed in order to obtain continuous dimming processes.

Description

Electronic ballast with digital control of dimming processes

Technical field

The invention relates to an electronic ballast, a lighting system comprising this ballast and an associated control unit, and an operating method for the ballast and the lighting system. Specifically, it is about the internal or external digital control of dimming processes of a light-generating element operated by the ballast.

State of the art

It is known per se, with the aid of electronic ballasts for light-generating elements, that is to say lamps of all kinds, but also LEDs and other light-generating electronic components, dimming processes, d. H. perform more or less continuous changes in light output over time. On the one hand, this applies, for example, to the operation of low-voltage halogen incandescent lamps with electronic transformers, and on the other hand to low-pressure discharge lamps, in particular energy-saving lamps and for other applications.

It is also known per se to control electronic ballasts, which are part of lighting systems, with digital control signals. In recent times, a system summarized under the name "DALI" (Digital Addressable Lighting Interface) has become known in which the ballasts cannot be switched and dimmed by switching or influencing the supply, but by independent digital control signals.

Presentation of the invention

The present invention is based on the problem of specifying an improved ballast and a corresponding lighting system and an operating method which are designed for digital control of dimming processes.

The invention is directed, on the one hand, to an electronic ballast for a light-generating element with a dimming device for dimming the light-generating element, in which the dimming process can be carried out by changing digital setpoints over time, characterized by a low-pass filter device for low-pass filtering the temporal change in the setpoints and smoothing temporal stages as a result of the digital representation of the target values

and a lighting system comprising this ballast and a control device for digital control of the ballast, which control device is designed to output the external digital signals, and corresponding operating methods. Preferred configurations are specified in the dependent claims.

The basic idea of the invention is based on the observation that, due to the limited resolution of the digital control, in particular within the framework of the DALI system, a time-graded course of setpoints is ultimately specified for dimming processes. On the one hand, this concerns the case of an external specification of the setpoints by external control signals. It can be as are perceived as disruptive that the correspondingly controlled ballast also follows this setpoint specification in chronological order.

On the other hand, however, the invention also relates to an internal generation of the digital setpoints, either as a result of an external specification of other data for a dimming process or also in the case of ballasts which are used individually and are not integrated in a lighting system. Then the ballast itself is controlled by the operator, for example by pressing a button, corresponding mains interruptions or the like. The ballast also internally generates digital setpoints for dimming processes, which creates the same problem.

The inventors therefore propose to carry out low-pass filtering in the ballast in order to smooth the course of the setpoint over time. This ensures the continuous temporal development familiar from analogue controlled dimming processes. On the other hand, a suitable design of the filter characteristics ensures that the desired time course is essentially adhered to, ie that there is no significant change in the total dimming time. In individual cases, it can be taken into account when designing whether a quick response in the case of desired light jumps or optimal smoothing with slow dimming processes is in the foreground.

In a preferred embodiment of the invention, the low-pass filter device can be controlled, so that this adaptation is not fixed in the ballast, but can be changed. This can happen in particular in that the ballast is designed to record the speed of the change over time and to set the filter characteristic automatically accordingly. Favorable compromises can therefore be made in advance for the respective speeds of the dimming process, whereupon the ballast selects the filter characteristic suitable for the corresponding dimming processes. Of course, you can also work in a "class division" so that This means that a specially adapted filter characteristic is not selected for each conceivable temporal progression, but rather the temporal progression combined into specific groups is assigned to corresponding filter characteristics.

The low-pass filter device can be designed analogously and can obtain different filter characteristics, for example, by switching resistors or capacitors. A controlled resistor, for example a field effect transistor, can also be used as a variable resistor.

In the context of the invention, however, preference is given to a digital-electronic implementation of the filter device, in particular as a computing algorithm in a programmable circuit, for example a microcontroller. Of course, a digital electronic implementation in "hardware", for example as an ASIC, can also take place. A so-called recursive low-pass filter, which is known to the person skilled in the art from the literature, is particularly suitable as the operating algorithm for the digital-electronic low-pass filtering. For example, reference is made to the book "Signalverarbeitung" by Elmar Schrüfer, Hanser-Verlag, Vienna, 1990.

The above-mentioned detection of the speed of the time course of the dimming process can take place, for example, via a differentiating element, which in turn can be implemented using analog technology, but also, and preferably, digitally electronically. In turn, implementation as a computing algorithm in a microcontroller is preferably considered.

In the case of an external control, an inexpensive alternative to detection using a differentiating element, in particular in the context of the DALI system, is to specify the speed of the upcoming dimming process in the external digital signal, that is to say to transmit the required information about the time profile with this , if or before the actual dimming process begins. Then the ballast can Determine proper filter characteristics either using a calculation algorithm or by looking up the corresponding values in a look-up table.

Brief description of the drawings

The invention is explained in more detail below using an exemplary embodiment. The features disclosed here can also be essential to the invention in other combinations. The above and the following description each relate to both the device category and the method category of the invention, without this being explicitly mentioned in detail. The features are therefore important both for the ballast and for the lighting system and finally also for the operating method.

Figure 1 shows a schematic representation of a lighting system according to the invention.

FIG. 2 shows various timing diagrams of dimming processes to explain the method according to FIG. 3.

Figure 3 shows a schematic diagram of the method according to the invention.

Preferred embodiment of the invention

Figure 1 shows a lighting system according to the invention in a highly schematic representation. A control unit SG sends digital control signals to three electronic ballasts EVG1, EVG2 and EVG3 via signal lines. These are representative of a larger lighting system and control a respective lamp L1, L2 or L3. The ballasts EVG1 - EVG3 are designed in response to digital control signals from the control device SG a dimming function, ie a continuous increase or Decrease the lamp power of the lamp L1, L2 or L3 concerned.

FIG. 2 shows in the upper diagram, numbered a), a typical graded time profile of the setpoint values expressed as relative luminous flux (vertical axis) during a dimming process. The straight line between the horizontal start value level and the horizontal end value level corresponds to a desired continuous course of the dimming process, while the stepped line symbolizes the finite resolution of the digital setpoint values.

The partial diagram b) shows the corresponding stepped transitions in a relatively fast dimming process compared to the diagram a) in relation to the setpoint values. The curve drawn through between the start value and the end value corresponds to a smoothing according to the invention of this staged setpoint specification by means of low-pass filtering. However, it can be seen that the smoothing overall has resulted in a considerable extension of the dimming process to more than twice the time extension.

Partial diagram c) shows a relatively slower dimming process with a smoothing, which, however, does not completely eliminate the steps here due to the time constant of the low pass filter being too short. Although the dimming process will be perceived visually as significantly more continuous due to the smoothing according to partial diagram c), there is still room for improvement.

The partial diagrams d) and e) in turn show the setpoint specification according to the fast dimming process from partial diagram b) or according to the slow dimming process from partial diagram c) with respectively adapted low-pass filtering. A relatively short time constant was selected for sub-diagram d) in order to avoid the significant extension of the dimming process according to sub-diagram b), but to completely filter out the staging of the setpoint specification. Complementary to this, sub-diagram e) shows an extension of the time constant of the low-pass filtering compared to sub-diagram c) and thus also a complete filtering out of the stages with a not significantly increased duration of the dimming process compared to sub-diagram c).

FIG. 2 thus shows overall that the invention at least improves the visual appearance of dimming processes carried out with digital setpoint values. With a corresponding optimization of the low-pass filter characteristic, good compromises can be achieved between optimal step filtering on the one hand and not too extensive expansion of the dimming process on the other hand.

In a variant of the invention, the control unit SG from FIG. 1 already outputs the digital setpoints shown in FIG. 2 in the form of a digital control signal to the ballasts EVG1-3. In this way, an external, stepped setpoint value corresponding to FIG. 2 is smoothed in the respective ballast. An 8-bit representation is used within the DALI system, so that the smoothing results in an effective increase in the bit resolution in the visually visible dimming process.

The setpoint values correspond to digital codes which are assigned to corresponding lamp operating data by a look-up table stored in the respective ballast. This assignment is carried out in such a way that the nonlinear sensitivity of the human eye to brightness is compensated for, so that a consecutive sequence of adjacent setpoint codes ultimately does not produce a linear temporal luminous flux development in the physical sense. Rather, the luminous flux development is actually exponential, in such a way that a linear sensation is created for the eye.

Instead of a transmission of setpoint values in the form of the digital control signals, a transmission of other data to the. Dimming process. For example, in another embodiment 1, the control device SG transmits digital control signals to the ballasts EVG1-3, which contain a final value of the dimming process and an indication of the speed, for example also in the form of the total duration of the dimming process. The digital setpoints shown in FIG. 2 are then generated in the electronic ballast itself. These are then generated within the scope of the exemplary embodiment within the same 8-bit system that is used for the DALI control signals. There is also an assignment to lamp operating parameters via the look-up table mentioned.

Maintaining the DALI 8-bit system within the ballast also has the advantage that, for example, dimming processes that have not been completed and terminated for certain reasons can result in feedback of the ballast to the control unit in a particularly simple manner. Furthermore, the look-up table mentioned above can be used to assign the setpoint codes to the lamp operating parameters without having to recreate them for a ballast-internal system with a higher digital resolution.

Figure 3 illustrates a simple variant of smoothing. The elements drawn correspond to function blocks of microcontroller programming. The setpoint entering the ballast from the left is fed in the ballast to a low-pass filter TP on the one hand, and to an element designated GE that determines the dimming speed. This exemplary embodiment is an algorithm part that reads the speed of the upcoming dimming process from a digital signal at the beginning of the dimming process. So here the digital control signal already contains the necessary information. Accordingly, a value representing the dimming speed is output and used to set the filter characteristic of the low-pass filter TP. The setpoint specifications can be smoothed accordingly. As an alternative to this, the element GE in FIG. 3 could also represent a differentiating element and allow a conclusion to be drawn about the dimming speed by determining the first derivative. The differentiator provides a signal in the true sense of a differentiation as long as the sampling rate and the calculation rate of the digital algorithm are slower than the step spacing of the setpoint signal. However, the term “differentiator” can also be extended to determine the speed from the height of the steps and the time interval between the steps. The step height does not always have to be the same. Since the adjustment of the low-pass filter TP also only takes place at discrete times in this exemplary embodiment, no difficulties arise from the discontinuous speed determination.

The time constants can be assigned to the dimming speeds within the low-pass filter TP using a simple calculation algorithm, for example, reciprocal value formation and multiplication by a constant. However, the use of a look-up table is preferred here, that is to say the fixed specification of data on the time constant of the low-pass filtering at corresponding dimming speeds.

In another exemplary embodiment, FIG. 3 can also be explained as follows: The setpoint shown is generated by the ballast itself based on a definition of the dimming process given by external control signals, for example via the dimming speed and the final value. This has already been explained with reference to FIG. 1.

In addition, however, the invention also relates to individual ballasts without external control. In this sense, FIG. 3 can be explained as a further exemplary embodiment as follows: The setpoint is generated by the ballast itself after an appropriate command into the ballast for a certain time by an operation, for example by a power interruption or by pressing a button - guesses was entered by the operator himself. Here it is in sin ne the greatest possible compatibility of such ballasts with ballasts designed for DALI lighting systems or identity of the ballasts within the scope of extensive standardization in order to save costs, it is desirable to remain with the 8-bit code mentioned from the DALI controller. In particular, the look-up table mentioned above can still be used.

Claims

claims

1. Electronic ballast (EVG1 - 3) for a light generating element (L1 - 3) with a dimming device for dimming the light generating element (L1 - 3), in which the dimming process can be carried out by changing the time of digital setpoints, characterized by a low-pass filter device (TP) for low-pass filtering the temporal change in the target values and smoothing temporal stages as a result of the digital representation of the target values.

2. Ballast (EVG1 - 3) according to claim 1, wherein the filter characteristic of the low-pass filter device (TP) is controllable.

3. Ballast (EVG1 - 3) according to claim 2, which can detect the speed of the change over time of the setpoints (GE) and adjust the filter characteristics automatically.

4. ballast (EVG1 - 3) according to any one of the preceding claims, wherein the low-pass filter device (TP) is digitally electronic.

5. ballast (EVG1 - 3) according to claim 4, wherein the low-pass filter device (TP) is realized as a recursive low-pass.

6. Ballast (EVG1 - 3) according to claim 4 or 5, in which the low-pass filter device (TP) is implemented in a computing algorithm running in a microcontroller.

7. ballast (EVG1 - 3) according to any one of the preceding claims with a differentiator (GE) for detecting the speed of the change over time of the setpoints.

8. ballast (EVG1 - 3) according to claim 7, wherein the differentiator (GE) is realized digitally.

9. Ballast (EVG1 - 3) according to claim 8, wherein the differentiating element (GE) is implemented in a computing algorithm running in a microcontroller.

10. Ballast according to one of the preceding claims, in which data for the dimming device to be carried out by the dimming device can be specified with an external digital signal.

11. Ballast according to claim 10, wherein the external digital signal specifies setpoints for the dimming process.

12. Ballast according to claim 10, wherein the external digital signal specifies a final value and a duration or speed for the dimming process.

13. Ballast (EVG1 - 3) according to one of the preceding claims, in which the speed of the change in time of the setpoints before the start of the dimming process can be taken from the external digital signal.

14. Lighting system from a ballast (EVG1 - 3) according to one of the preceding claims, at least claim 10, and a control device (SG) for digital control of the ballast (EVG1 - 3), which control device (SG) is designed to output external digital signals.

15. Method for operating a ballast according to one of claims 1 to 13 with a dimming device for dimming the light-generating element (L1-3), in which the dimming process can be carried out by a temporal change in digital setpoints, characterized in that the temporal change in the setpoints is low-pass filtered and the stages are smoothed as a result of the digital representation of the setpoints.

16. Method for operating a lighting system according to claim 14, in which the control device (SG) outputs digital signals for specifying data for dimming processes to be carried out by a dimming device of the ballast (EVG1 - 3), the ballast (EVG1 - 3) receives the digital signals and carries out dimming processes in response to the digital signals, dimming processes being carried out by a temporal change in digital target values, characterized in that the temporal change in the target values is low-pass filtered and the stages are smoothed as a result of the digital representation of the target values.