WO2013092287A1 - Electronic ballast for a gas discharge lamp - Google Patents

Abstract

The invention relates to an electronic ballast (1) for a gas discharge lamp (24) with an evaluation and control unit (10), a DC-to-DC converter circuit (5), which is electrically connected to a DC voltage source (3) and has a first transformer (5.1) and a first switching element (T1), which actuates the evaluation and control unit (10) via pulse width modulation, and a full-bridge circuit (30), whose inputs (Z1, Z2) are electrically connected to the DC-to-DC converter circuit (5), and whose outputs (Z-, Z+) are electrically connected to a starting circuit (20), which comprises a spark gap (22) for producing an arcing current and a second transformer (26), wherein a primary coil (26.1) of the second transformer (26) is electrically connected to the spark gap (22), and a secondary coil (26.2) of the second transformer (26) is electrically connected to the gas discharge lamp (24), wherein the spark gap (22) is struck when a starting voltage is reached and an arcing current is produced, which induces a high-voltage pulse for starting the gas discharge lamp (24) in the secondary coil (26.2) of the second transformer (26), wherein the gas discharge lamp (24), after starting, is supplied energy for maintaining the current flow. According to the invention, the evaluation and control unit (10) detects an intermediate circuit voltage (Z1) at a first input of the full-bridge circuit (30) and regulates this intermediate circuit voltage during a prestarting phase via the pulse width modulation of the first switching element (T1) in the DC-to-DC converter circuit (5) to a predetermined value, which is sufficient for striking the spark gap (22) and for producing the arcing current, wherein the evaluation and control unit (10), after starting of the gas discharge lamp (24), adjusts the collapsing intermediate circuit voltage (Z1) at the first input of the full-bridge circuit (30) by increasing the switch-on duration of the pulse width modulation of the first switching element (T1) in the DC-to-DC converter circuit (5) within a predetermined time period and makes available the energy for maintaining the current flow through the gas discharge lamp (24).

Description

 Description title

 Electronic ballast for a gas discharge lamp prior art

The invention relates to an electronic ballast for a gas discharge lamp according to the preamble of independent claim 1.

For the operation of gas discharge lamps, an electronic Vorschaltgerat is required, which provides the necessary for ignition and operation voltages and currents. The ignition of the gas discharge lamp is typically at a very high voltage in the range of 20 to 25 kV to generate an arc between the electrodes of the gas discharge lamp. Immediately after this ignition, it is extremely important that the arc does not go out again. Therefore, immediately after ignition, the ballast must provide sufficient energy to sustain the current flow in the form of the arc. If this fails, the arc extinguishes and the burner has to be ignited again. This critical phase after ignition is referred to generally and in the present application as takeover. The energy needed for a successful takeover must be provided only a few microseconds after ignition for a period of about 300μ8. Therefore, today in many ballasts a trick circuit is used, which consists of a boost capacitor, which is connected via a series resistor to the intermediate circuit voltage. The boost capacitor of the trick circuit is charged during the pre-ignition via the series resistor, whereby the boost capacitor absorbs the energy required for the takeover. After ignition, the voltage breaks down through the arc, releasing the energy stored in the boost capacitor over a period of approximately 300μ8. In the utility model DE 20 2006 006 444 U1 an electronic ballast is described, which is electrically connected to a high-pressure discharge lamp and a power source. The described electronic ballast comprises a power source control circuit electrically connected to the power source for driving the power source, supplying electrical power to the electronic ballast, a DC-DC converter circuit electrically connected to the power source, and a first transformer and a low-voltage switching element, a microprocessor electrically connected to each of the current source control circuit and the low-voltage switching element in the DC-DC converter circuit, a full-bridge circuit electrically connected to the DC-DC converter circuit and the microprocessor, respectively, and an ignition circuit, which has a low-frequency voltage doubler rectifier circuit electrically connected to the full bridge circuit, an energy storage capacitor, a spark gap and a second transformer electrically connected to the HID lamp. Here, when the current is turned on by the current source control circuit, the microprocessor outputs a low-frequency pulse-width-modulated signal to the low-voltage switching element, and the first transformer of the DC-DC converter circuit then outputs a DC voltage of medium height. The full-bridge circuit converts the intermediate-level DC voltage supplied by the DC-DC converter circuit into a low-frequency AC voltage. The low-frequency voltage doubling rectifier circuit receives the low-frequency rectangular pulse supplied from the full-bridge circuit and outputs a high DC voltage to charge the energy storage capacitor, in which case that the

Energy storage capacitor is charged so that the ignition voltage of the spark gap is exceeded, the spark gap is turned on and a resulting high voltage, which is induced in the secondary winding of the second transformer, the HID lamp ignites.

Disclosure of the invention

The electronic ballast according to the invention for a gas discharge lamp with the features of independent claim 1 has the advantage over the prior art that during the pre-ignition phase the desired high intermediate circuit voltage is regulated, so that the collapse of the intermediate After the ignition of the gas discharge lamp, the circuit voltage automatically leads to a positive control reaction. This regulator reaction leads to an increase in the transmitted energy after ignition. The essence of the invention is the elimination of components and takeover of the tasks of the omitted components by existing components. The evaluation and control unit for implementing the voltage regulation is preferably carried out as a digital signal processor. Alternatively, the evaluation and control unit can also be designed as a fast analog controller. As a result, the control speed can advantageously be carried out sufficiently quickly and adapted to the lamp and system properties.

Embodiments of the present invention allow for the elimination or at least a reduction in the size of the boost capacitor. Furthermore, embodiments of the present invention allow for power dissipation and elimination of power resistances. Due to the higher efficiency of the control according to the invention, the boost capacity can be comparatively smaller than in the conventional methods. Another advantage of this circuit is that the boost circuit can be switched off temporarily or permanently, which is particularly advantageous in the commutation phase.

Thus, the controller behavior according to the invention already ensures before the actual detection of the ignition and the possibly necessary switching of the ignition

Regulator behavior for the desired behavior immediately after the ignition of the gas discharge lamp. In circuit topologies that ignite spontaneously and independently when the conditions are met, the exact ignition timing can not be predetermined or controlled. Therefore, it is particularly important for these topologies that the control behavior automatically leads to a correct reaction at the ignition point. Furthermore, the control speed is chosen so large that a reasonably fast response to the ignition can take place, even without really knowing the ignition or changing the control strategy. If the intermediate circuit voltage is regulated in the pre-ignition phase, a high control speed can be used. Immediately after ignition, the fast regulator ensures the collapsing DC link voltage that the controller wants to maintain the voltage and readjusted accordingly. This behavior ensures that the duty cycle increases within a few microseconds and the energy needed to sustain the arc is quickly delivered. The actual required speed and the amount of energy to be provided are adapted to the respective system.

By the above-described control strategy and control speed time is gained for the ignition detection. Since the regulator behaves correctly immediately after ignition, the flow control has more time to detect the ignition of the gas discharge lamp. This time can be used for more filtered signal acquisition of the flow control. In addition, it is possible to observe and plausibility check several signals to reliably detect all cases during the ignition of the gas discharge lamp. If the ignition of the gas discharge lamp has been reliably detected, then the sequence control of the evaluation and control unit can adapt the control strategy or important control parameters to the changed status.

During commutation, the lamp current must inevitably go through zero. In order for the current direction to actually reverse, the arc in the gas discharge lamp must be rebuilt. For this purpose, depending on the life of the burner of the gas discharge lamp, the average electrical operating performance of the gas discharge lamp and the external circumstances, such as vibration loads and changing the burner position, quickly build a large lamp voltage through the DC-DC converter. In this phase, it is desirable to keep the capacitive load of the DC link as low as possible. By reducing or completely eliminating the boost capacitance, this requirement can be ideally met by embodiments of the present invention.

Also in the commutation situation, a fast controller is advantageous, which ensures that the intermediate circuit voltage is quickly rebuilt in order to support the spontaneous reignition of the burner of the gas discharge lamp after commutation. Embodiments of the present invention provide an electronic ballast for a gas discharge lamp, which has an evaluation and control unit, a DC-DC converter circuit which is electrically connected to a DC voltage source and has a first transformer and a first switching element which controls the evaluation and control unit via a pulse width modulation, and a full bridge circuit comprises, whose inputs are electrically connected to the DC-DC converter circuit and whose outputs are electrically connected to an ignition circuit comprising a spark gap for generating an arc current and a second transformer. Here, a primary coil of the second transformer with the spark gap and a secondary coil of the second transformer with the gas discharge lamp is electrically connected, wherein the spark gap ignites upon reaching an ignition voltage and generates an arc current which induces a high voltage pulse for igniting the gas discharge lamp in the secondary coil of the second transformer. After ignition, the gas discharge lamp is supplied with energy to maintain the flow of current. According to the invention, the evaluation and control unit detects an intermediate circuit voltage at a first input of the full bridge circuit and controls it during a Vorzündphase via the pulse width modulation of the first switching element in the DC-DC converter circuit to a predetermined high value, which for igniting the spark gap and generating the spark gap sufficient. Here, the evaluation and control unit controls after the ignition of the gas discharge lamp collapsing DC link voltage at the first input of the full bridge circuit by increasing the duty cycle of the

Pulse width modulation of the first switching element in the DC-DC converter circuit within a predetermined period of time and provides the energy to maintain the flow of current through the gas discharge lamp available. Thereby, the arc generated in the gas discharge lamp can be maintained.

The measures and refinements recited in the dependent claims advantageous improvements of the independent claim 1 electronic ballast for a gas discharge lamp are possible. It is particularly advantageous that the predetermined period of time for readjusting the intermediate circuit voltage at the first input of the full bridge circuit is in the range of 1 to 5 s. As a result, a sufficiently fast control process can be implemented to provide the energy required to maintain the current flow through the gas discharge lamp or arc in the gas discharge lamp after ignition.

In an advantageous embodiment of the ballast according to the invention, a voltage detected at a second input of the full bridge circuit via a shunt resistor can be evaluated for determining the current flow through the gas discharge lamp. By determining the current flow, the control behavior can be improved in an advantageous manner.

In a further advantageous embodiment of the ballast according to the invention, an analog-to-digital converter in the evaluation and control unit can convert the detected analog values of the voltages at the inputs of the full-bridge circuit into corresponding digital values within 500ns. This fast analog-to-digital conversion enables the desired control speed to be implemented.

In a further advantageous embodiment of the ballast according to the invention, the DC-DC converter circuit can comprise as an additional energy store a boost capacitor with an additional circuit, which provides a part of the energy for maintaining the current flow through the gas discharge lamp. In one possible embodiment, the additional circuit may include a second switching element, which controls the evaluation and control unit to bridge a connected in series with the boost capacitor series resistance. In this case, the evaluation and control unit switches the second switching element in the Vorzündphase and Nachzündphase the gas discharge lamp to bridge the series resistance conductive and during a commutation of the gas discharge lamp, the evaluation and control unit switches the second switching element blocking to decouple the boost capacitor , As a result, during the pre-ignition phase and the post-ignition phase of the gas discharge lamp, the power loss can be reduced since no current flows through the series resistor. During the commutation phase is the Series resistor effective and decouples the boost capacitor to reduce the capacitive loading of the DC link.

In an alternative possible embodiment, the additional circuit may comprise a second switching element, which controls the evaluation and control unit to switch an additional inductance in series with the boost capacitor. Here, the evaluation and control unit switches the second switching element in the Nachzündphase over a predetermined period of time with a predetermined frequency alternately conductive and blocking. The additional inductance allows the energy for the takeover to be used selectively when needed. This is achieved by turning the power transistor on and off for a specific duration and frequency. The predetermined period of time is, for example, in the range of 1 to 5 ms, and the predetermined frequency is, for example, in the range of 10 to 100 kHz.

In a further advantageous embodiment of the ballast according to the invention, the DC-DC converter circuit can be operated as a quasi-resonant converter with a variable in the range of 250 to 1000kHz frequency. In order to determine an exact value for the frequency of the pulse width modulation, in addition, the output signal of the first switching element can be detected and evaluated.

An embodiment of the invention is illustrated in the drawings and will be explained in more detail in the following description. In the drawings, like reference numerals designate components that perform the same or analog functions.

Brief description of the drawings

Fig. 1 shows a schematic block diagram of an embodiment of an electronic ballast for a gas discharge lamp according to the invention.

FIG. 2 shows a schematic block diagram of an embodiment of an ignition circuit with a gas discharge lamp, which is controlled by the electronic ballast according to the invention from FIG. 1. 3 shows a schematic block diagram of a first exemplary embodiment of an additional circuit for the electronic ballast according to the invention from FIG. 1.

4 shows a schematic block diagram of a second exemplary embodiment of an additional circuit for the electronic ballast according to the invention from FIG. 1.

Embodiments of the invention

In the trick circuit mentioned above, which consists of a boost capacitor which is connected to the DC link voltage via a series resistor, the boost capacitor is charged via the series resistor during the pre-ignition phase, whereby the boost capacitor is used for the takeover takes up required energy. After ignition, the voltage breaks down through the arc, releasing the energy stored in the boost capacitor over a period of approximately 300μ8. Since the energy is only available for a limited time, during this time, the controller of the DC-DC converter must prepare for the supply of energy for permanent operation of the gas discharge lamp. The series resistor decouples the boost capacitor during the commutation phase, reduces the takeover current to protect the gas discharge lamp, and extends the period of time within which energy can be provided.

The main advantage of the trick circuit is that the energy stored in the boost capacitor can be provided at the right time and quickly without the help of intelligence and that a relatively long reaction time of the regulator to the ignition is sufficient.

The disadvantages of the trick circuit can be seen in that the boost capacitor typically loads the transducer, thereby extending the pre-ignition phase. In addition, the charging current for the boost capacitor flows through the series resistor, causing large losses. Furthermore, the energy required for the takeover requires a large and expensive con- capacitor ahead. In addition, the discharge of the boost capacitor takes place in a relatively short period of about 300μ8, resulting in very large unwanted losses in the series resistance, which must be considered in the dimensioning. Furthermore, the boost capacitor slows the voltage rise during commutation in commutated gas discharge lamps. This can cause the arc to extinguish in the burner of the gas discharge lamp under certain conditions. In addition, the energy of the boost capacitor is not detected by the controller and can lead to an inverse behavior in case of unfavorable controller design.

As can be seen from FIGS. 1 to 4, the exemplary embodiment of an electronic ballast 1 according to the invention for a gas discharge lamp 24 comprises an evaluation and control unit 10 with a driver and / or divider circuit 12, a DC-DC converter circuit 5, which is electrically is connected to a DC voltage source 3 and has a first transformer 5.1 and a first switching element T1, which controls the evaluation and control unit 10 via a pulse width modulation, and a full bridge circuit 30 whose inputs are electrically connected to the DC-DC converter circuit 5 and their Outputs are electrically connected to an ignition circuit 20. The ignition circuit 20 comprises a spark gap 22 for generating an arc current, a gas discharge lamp 24 and a second transformer 26. A primary coil 26.1 of the second transformer 26 is connected to the spark gap 22 and a secondary coil 26.2 of the second transformer 26 is electrically connected to the gas discharge lamp 24. In this case, the spark gap 22 ignites upon reaching an ignition voltage and generates an arc current which induces a high voltage pulse for igniting the gas discharge lamp 24 in the secondary coil 26.2 of the second transformer 26, the gas discharge lamp 24 after ignition with energy to maintain the current flow or the arc becomes.

As can also be seen from FIG. 1, between the DC voltage source 3, which represents a vehicle battery in the illustrated exemplary embodiment, a filter 9 is inserted against electromagnetic interference, which comprises a filter inductance L1 and a filter capacitance C1. The first transformer 5.1 of the DC-DC converter comprised a primary winding N1 and two secondary windings N2 and N3, of which a first secondary winding N2 via a Rectifier circuit D1 and an additional energy storage 14, 14 'to the full bridge circuit 30, and a second secondary winding N3 is connected to a circuit 7 for generating an auxiliary voltage ZH. To generate the auxiliary voltage ZH by increasing the voltage delivered by the second secondary winding N3, the auxiliary circuit 7 comprises three capacitors C2, C3 and C4 and two diodes D2, D3, which are connected in the manner shown. To generate the ignition voltages Z + and Z-, the full-bridge circuit 30 comprises four switching transistors T2, T3, T4 and T5, preferably designed as MOSFETs.

As is further apparent from FIG. 2, the ignition circuit 20 comprises, in addition to the spark gap 22 for generating the arc current, the second transformer 26 and the gas discharge lamp 24, an energy store C5 in the form of a capacitor and a discharge resistor R2, via which the energy store C5 follows the ignition of the gas discharge lamp 24 can be completely discharged. The energy store C5 is charged by the ignition voltage Z + at a first output of the full bridge circuit 30 and the auxiliary voltage ZH generated by the auxiliary circuit 7 to a high DC voltage in the range of about 700 to 1000V. To generate the ignition voltage Z + at the first output of the full bridge circuit 30, the evaluation and control unit 10 detects the intermediate circuit voltage Z1 at the first input of the full bridge circuit 30 and regulates this during a Vorzündphase via the pulse width modulation of the first switching element T1 in the DC-DC converter circuit 5 to a predetermined high value, at the same time the additional boost capacitor C in the additional energy storage 14, 14 'is charged to the intermediate circuit voltage Z1 at the first input of the full bridge circuit 30. If the energy storage C5 is charged in the ignition circuit 20 so far that the ignition voltage of the spark gap 22 is exceeded, then ignites the spark gap 22 and generates an arc with a large current flowing through the primary winding 26.1 of the second transformer 26. This will be in the

Secondary winding 26.2 of the second transformer 26 induces a high voltage pulse in the range of about 26kV, which ionizes metals and gases inside the gas discharge lamp 24, causing a visible arc current flow in the gas discharge lamp 24 is generated and emitted light to the outside. According to the invention, the evaluation and control unit 10 detects the DC link voltage Z1 at the first input of the full bridge circuit 30 and controls it during a Vorzündphase via the pulse width modulation of the first switching element T1 in the DC-DC converter circuit 5 to a predetermined high value, which for igniting the Spark gap 22 and sufficient to generate the arc current. After the ignition of the gas discharge lamp 24, the evaluation and control unit 10 regulates the collapsed DC link voltage Z1 at the first input of the full bridge circuit 30 by increasing the duty cycle of the pulse width modulation of the first switching element T1 in the DC-DC converter circuit 5 within a predetermined period of time thereby the energy for maintaining the flow of current through the gas discharge lamp 24 is available. In the illustrated embodiment, the evaluation and control unit 10 is designed to implement the voltage control as a digital signal processor, which is selected so that the predetermined time span for readjusting the DC link voltage Z1 at the first input of

Full bridge circuit 30 is preferably in the range of 1 to 5 s.

As can also be seen from FIG. 1, the evaluation and control unit 10 detects a further voltage Z2 at a second input of the full-bridge circuit 30 via a shunt resistor R1 and evaluates it to determine the

Current flow through the gas discharge lamp 24 off. An analog-to-digital converter, not shown in the evaluation and control unit 10, is designed so that the analog values of the voltages Z1, Z2 detected at the inputs of the full-bridge circuit 30 can be converted into corresponding digital values within 500ns.

As can also be seen from FIG. 1, the DC-DC converter circuit 5 in the illustrated exemplary embodiment comprises the boost capacitor C with the additional circuit 14.1, 14.1 'as an additional energy store 14, 14'. The additional energy storage 14, 14 'provides part of the energy for maintaining the flow of current through the gas discharge lamp 24 directly after the ignition process.

As can also be seen from FIGS. 1 and 3, the additional circuit 14. 1 in a first exemplary embodiment comprises a second switching element T designed as a MOSFET, which activates the evaluation and control unit 10 in order to produce a

Series to Boost capacitor C connected series resistance R to be bridged CKEN. The evaluation and control unit 10 switches the second switching element T in the pre-ignition phase and in the Nachzündphase the gas discharge lamp 24 to bridge the series resistor R conductive to reduce the power loss. During a commutation phase of the gas discharge lamp 24, the evaluation and control unit 10 switches the second switching element blocking to decouple the boost capacitor C from the intermediate circuit voltage Z1 at the input of the full bridge circuit 30.

As is further apparent from FIGS. 1 and 4, the additional circuit 14.1 'in a second exemplary embodiment likewise comprises a second switching element T designed as a MOSFET, which activates the evaluation and control unit 10 in order to provide an additional inductance L in series with the boost capacitor C. turn. The evaluation and control unit 10 switches the second switching element T in the Nachzündphase over a predetermined period of time with a predetermined frequency alternately conductive and blocking to provide additional energy to maintain the current flow through the gas discharge lamp 24 after the ignition phase. Here, the predetermined period of time is preferably in the range of 1 to 5 ms, and the predetermined frequency is preferably in the range of 400 to 600 kHz.

To further improve the control behavior, the DC-DC converter circuit 5 can be operated in conjunction with the evaluation and control unit 10 as a quasi-resonant converter with a variable in the range of 250 to 1000kHz frequency. For implementation as a quasi-resonant converter, the evaluation and control unit 10 additionally detects an output signal of the first switching element T1 in order to obtain an accurate value for the frequency of the

Pulse width modulation to determine and determine the correct trigger points for the switching operations. Embodiments of the present invention provide an electronic ballast for a gas discharge lamp, by which the power loss can be reduced. In addition, due to the higher efficiency of the electronic ballast according to the invention, the boost capacitance may be comparatively smaller than in the case of known electronic ballasts, or even completely eliminated.

Claims

claims

1 . Electronic ballast for a gas discharge lamp with an evaluation and control unit (10), a DC-DC converter circuit (5) which is electrically connected to a DC voltage source (3) and a first transformer (5.1) and a first switching element (T1) , which controls the evaluation and control unit (10) via a pulse width modulation, and a full bridge circuit (30) whose inputs are electrically connected to the DC-DC converter circuit (5) and whose outputs are electrically connected to an ignition circuit (20), which comprises a spark gap (22) for generating an arc current and a second transformer (26), wherein a primary coil (26.1) of the second transformer (26) with the spark gap (22) and a secondary coil (26.2) of the second transformer (26) the gas discharge lamp (24) is electrically connected, wherein the spark gap (22) ignites upon reaching an ignition voltage and generates an arc current which in the secondary coil (26.2) of the second transformer (26) induces a high-voltage pulse for igniting the gas discharge lamp (24), wherein the gas discharge lamp (24) is supplied with energy after ignition to maintain the current flow, characterized in that the evaluation and control unit (10) detects an intermediate circuit voltage (Z1) at a first input of the full bridge circuit (30) and during a Vorzündpha- se via the pulse width modulation of the first switching element (T1) in the DC-DC converter circuit (5) to a predetermined high value controls, which is sufficient for igniting the spark gap (22) and for generating the arc current, wherein the evaluation and control unit (10) after the ignition of the gas discharge lamp (24) the collapsing DC link voltage (Z1) at the first input of the full bridge circuit (30) by increasing the duty cycle of the pulse width modulation of the first switching element (T1) in the DC-DC converter circuit (5) inn readjusted within a predetermined period of time and provides the energy for maintaining the flow of current through the gas discharge lamp (24).

Ballast according to claim 1, characterized in that the predetermined period of time for readjusting the intermediate circuit voltage (Z1) at the first input of the full bridge circuit (30) in the range of 1 to 5 s.

Ballast according to claim 1 or 2, characterized in that at a second input of the full bridge circuit (30) via a shunt resistor (R1) detected voltage (Z2) for determining the current flow through the gas discharge lamp (24) is evaluable.

Ballast according to one of claims 1 to 3, characterized in that an analog-to-digital converter in the evaluation and control unit (10) the detected analog values of the voltages (Z1, Z2) at the inputs of the full bridge circuit (30) within 500ns converted into corresponding digital values.

Ballast according to one of claims 1 to 4, characterized in that the DC-DC converter circuit (5) as an additional energy store (14, 14 ') comprises a boost capacitor (C) with an additional circuit (14.1, 14.1'), which a portion of the energy to maintain the flow of current through the gas discharge lamp (24) provides.

Ballast according to claim 5, characterized in that the additional circuit (14.1) comprises a second switching element (T), which controls the evaluation and control unit (10) to a in series with the boost capacitor (C) connected series resistor (R) bridging, wherein the evaluation and control unit (10) the second switching element (T) in the Vorzündphase and Nachzündphase the gas discharge lamp (24) to bypass the series resistor (R) turns conductive and during a commutation of the gas discharge lamp (24) turns off, to decouple the boost capacitor (C).

Ballast according to claim 5, characterized in that the additional circuit (14.1 ') comprises a second switching element (T), which controls the evaluation and control unit (10) to an additional inductance (L) in series with the boost capacitor (C) switch, wherein the evaluation and control unit (10) the second switching element (T) in the Nachzündphase over a predetermined period of time with a predetermined frequency alternately turns on and off.

8. ballast according to claim 7, characterized in that the predetermined period of time is in the range of 1 to 5 ms.

9. ballast according to claim 7 or 8, characterized in that the predetermined frequency is in the range of 10 to 100 kHz.

10. ballast according to one of claims 1 to 9, characterized in that the DC-DC converter circuit (5) is operable as a quasi-resonant converter with a variable frequency in the range of 250 to 1000kHz.