1. A discharge lamp ballast comprising:
an inverter circuit including first and second pairs of four switching elements in a full bridge configuration, and a resonant circuit having a resonant frequency connected between output terminals of the switch pairs, the inverter circuit further adapted to output AC power for driving a discharge lamp; and
a control circuit adapted to control switch states of the switching elements and thereby to generate the output AC power,
wherein the control circuit during a starting operation is adapted to control the inverter switching elements for a predetermined time so as to make an operating frequency of the output AC power sufficiently close to the resonant frequency of the resonant circuit, wherein a high voltage is generated for igniting the discharge lamp, and
the control circuit is further adapted to control the inverter switching elements in the starting operation so as to periodically and alternately repeat a state of
turning on the switching elements in one of the first or second sets of switching elements, respectively, and
turning off the switching elements in the other set, respectively, and a state of turning on only one of the switching elements in the other set and turning off the remaining three switching elements, respectively,
wherein a DC component is generated in the output voltage during the starting operation.
2. The discharge lamp ballast of claim 1, wherein the control circuit at a predetermined point during the starting operation is adapted to interchange switching operations between the first and second sets of switching elements, and
the control circuit is further adapted to control the inverter in a transient operation between each interchange of switching operations, each transient operation further comprising gradually lowering the output voltage for a predetermined period of time.
3. The discharge lamp ballast of claim 2, wherein the transient operation further comprises alternately and periodically turning on the first and second sets of switching elements, and an on-duty of one of the respective sets of switching elements is made higher than an on-duty of the other set of respective switching elements.
4. The discharge lamp ballast of claim 2, wherein the transient operation further comprises periodically and cyclically repeating a state of turning on the switching elements in one of the sets of switching elements and turning off the switching elements in the other set, a state of turning on the switching elements in the other set and turning off the respective switching elements in the one set, and a state of turning on one of the switching elements in the other set and turning off the remaining three switching elements, respectively.
5. The discharge lamp ballast of claim 2, wherein the transient operation further comprises turning off the switching elements in one of the sets of switching elements, maintaining one of the switching elements in the other set in an ON state and periodically turning on and off the other of the switching elements in the other set.
6. The discharge lamp ballast of claim 1, wherein the control circuit is adapted to control the inverter in the starting operation so as to periodically and cyclically repeat a state of turning on the switching elements in one of the first or second sets of switching elements, respectively, and turning off the switching elements in the other set, respectively, a state of turning on only one of the switching elements in the one set and turning off the remaining three switching elements, respectively, and a state of turning on only one of the switching elements in the other set and turning off the remaining three switching elements, respectively.
7. The discharge lamp ballast of claim 1, wherein the control circuit is adapted to gradually change the operating frequency of the inverter within a predetermined sweep frequency range including the resonant frequency of the resonant circuit in the starting operation.
8. The discharge lamp ballast of claim 7, wherein the control circuit is adapted to gradually decrease the operating frequency of the inverter from an upper limit frequency of the sweep frequency range to a lower limit frequency thereof in the starting operation.
9. The discharge lamp ballast of claim 7, wherein the control circuit is adapted to change the operating frequency of the inverter a plurality of times in the starting operation, and between each of the plurality of changes in the operating frequency the control circuit is further adapted to maintain the operating frequency of the inverter at a frequency lower than the upper limit frequency of the sweep frequency range and higher than the lower limit frequency of the sweep frequency range for a predetermined period of time.
10. The discharge lamp ballast of claim 7, wherein the control circuit is adapted to control the inverter so as to invert the polarity of the DC component of the output voltage at least once during the starting operation.
11. The discharge lamp ballast of claim 7, wherein the control circuit is adapted to detect lighting of the discharge lamp and subsequently to control the inverter to superimpose spike components on the output current.
12. A method of operating a discharge lamp ballast comprising an inverter circuit having four switches arranged in a full bridge configuration, a resonant circuit having a resonant frequency and a control circuit, the method comprising:
(a) adjusting the operating frequency of the inverter switching elements within a predetermined sweep frequency range during a starting operation having a predetermined time duration, the frequency range including the resonant frequency of the resonant circuit wherein a high voltage is generated near the resonant frequency for igniting the discharge lamp during the starting operation; and
(b) further during the starting operation, periodically and alternately repeating a state of turning on a first set of the four switching elements positioned diagonally with respect to each other, and turning off a second set of the four switching elements positioned diagonally with respect to each other, and a state of turning on only one of the second set of switching elements and turning off the remaining three switching elements, respectively, so as to generate a DC component in the output voltage during the starting operation.
13. The method of claim 12, further comprising the step of:
(c) interchanging the switching operations in step (b) between the first and second sets of switching elements at a predetermined time during the starting operation.
14. The method of claim 13, wherein step (b) comprises:
periodically and cyclically repeating a state of turning on the switching elements in one of the first or second sets of switching elements, respectively, and turning off the switching elements in the other set, respectively, a state of turning on only one of the switching elements in the one set and turning off the remaining three switching elements, respectively, and a state of turning on only one of the switching elements in the other set and turning off the remaining three switching elements, respectively.
15. The method of claim 14, further comprising the step of:
(d) performing a transient operation between each interchange of switching operations, each transient operation further comprising gradually lowering the output voltage for a predetermined period of time by alternately and periodically turning on the first and second sets of switching elements, and making an on-duty of one of the respective sets of switching elements higher than an on-duty of the other set of respective switching elements.
16. The method of claim 14, further comprising the step of:
(d) performing a transient operation between each interchange of switching operations, each transient operation further comprising periodically and cyclically repeating a state of turning on the switching elements in one of the sets of switching elements and turning off the switching elements in the other set, a state of turning on the switching elements in the other set and turning off the respective switching elements in the one set, and a state of turning on one of the switching elements in the other set and turning off the remaining three switching elements, respectively.
17. The method of claim 14, further comprising the step of:
(d) performing a transient operation between each interchange of switching operations, each transient operation further comprising turning off the switching elements in one of the sets of switching elements, maintaining one of the switching elements in the other set in an ON state and periodically turning on and off the other of the switching elements in the other set.
18. A light fixture comprising:
a lamp housing adapted to secure a discharge lamp;
a discharge lamp ballast further comprising an inverter circuit having four switches arranged in a full bridge configuration, a resonant circuit having a resonant frequency and a control circuit; and
a main housing adapted to secure said discharge lamp ballast,
wherein said control circuit of said discharge lamp ballast is adapted during a starting operation having a predetermined time duration to adjust an operating frequency of the inverter switches within a predetermined sweep frequency range including the resonant frequency of the resonant circuit, wherein a high voltage is generated near the resonant frequency for igniting the discharge lamp during the starting operation, and
said control circuit further adapted during the starting operation to periodically and alternately repeat a state of turning on a first set of switching elements positioned diagonally with respect to each other and turning off a second set switching elements positioned diagonally with respect to each other, and a state of turning on only one of the second set of switching elements and turning off the remaining three switching elements, respectively, so as to generate a DC component in the output voltage during the starting operation.
The claims below are in addition to those above.
All refrences to claim(s) which appear below refer to the numbering after this setence.
What is claimed is:
1. An ignition system with an ion current detecting circuit, the system comprising:
an ignition circuit that has an energy accumulating coil, a first switching device disposed in series to the energy accumulating coil for controlling a current therethrough, an ignition coil having a primary coil disposed in parallel to the first switching device and a secondary coil that supplies a secondary current to a spark plug, and a second switching device disposed in series to the primary coil for turning on and off a primary current therethrough;
a current detecting means for detecting a current flowing through the spark plug and outputting a signal indicative of the detected current;
an extracting means for extracting a component within a specific frequency range from the signal detected by the current detecting means; and
a knock detecting means for detecting the knock based on the component extracted by the extracting means.
2. The ignition system with the ion current detecting circuit according to claim 1, wherein the extracting means extracts the component including a higher harmonic component indicative of the knock.
3. The ignition system with the ion current circuit according to claim 1, wherein the extracting means extracts a component at least within 10 to 14 kHz.
4. The ignition system with the ion current detecting circuit according to claim 1, further comprising a current path where the current detected by the current detecting means flows, the current path has a resonance frequency that substantially coincides with a frequency that is extracted by the extracting means.
5. The ignition system with the ion current detecting circuit according to claim 1, wherein the secondary coil has inductance less than 10 henries (H).
6. The ignition system with the ion current detecting circuit according to claim 1, further comprising a control circuit which drives the first and second switching devices so as to provide a multi-spark ignition.
7. The ignition system with the ion current detecting circuit according to claim 6, wherein the control circuit drives the first and second switching devices so that the switching devices turn on and off periodically in an opposed manner.
8. The ignition system with the ion current detecting circuit according to claim 7, wherein the ignition circuit further comprises a condenser disposed in parallel with the first switching device.
9. An ignition system with an ion current detecting circuit for an engine, comprising:
an ignition circuit which has an ignition coil and a driving circuit for driving the ignition coil according to a multi-spark ignition sequence; and
an ion current detecting circuit for detecting an ion current indicative of a knock of the engine, wherein the ignition coil has inductance less than 10 henries (H), and the ion current detecting circuit detects at least a component of the ion current that has a second or higher harmonic frequency of the knock.
10. The ignition system with the ion current detecting circuit for the engine according to claim 9, wherein components providing the ignition circuit and the ion current detecting circuit are designed so that a current path where the ion current flows has a resonance frequency that substantially coincides with the second or higher harmonic frequency detected by the ion current detecting circuit.
11. The ignition system with the ion current detecting circuit for the engine according to claim 9, wherein components providing the ignition circuit and the ion current detecting circuit are designed so that a Q-value of the current path is greater than 1.