Provided is an excimer lamp light source device that achieves low cost and avoids the occurrence of narrowly-defined contracted discharge by adopting a lamp bulb having a simple structure and of the type in which a discharge current is passed in a tube axis direction.

The excimer lamp light source device includes: an excimer lamp that has a pair of external electrodes configured to induce an electric discharge in a discharge space of a lamp bulb and to cause a discharge current to flow in a tube axis direction of the lamp bulb, and that generates UV light in the discharge space by the discharge; and an inverter having a transformer equipped with a secondary winding to which the external electrodes are connected in order to apply a high-voltage alternating current to the excimer lamp, the inverter supplying power lower than power that causes a linear discharge.

Provided is an excimer lamp light source device that achieves low cost and avoids the occurrence of narrowly-defined contracted discharge by adopting a lamp bulb having a simple structure and of the type in which a discharge current is passed in a tube axis direction.

The excimer lamp light source device includes: an excimer lamp that has a pair of external electrodes configured to induce an electric discharge in a discharge space of a lamp bulb and to cause a discharge current to flow in a tube axis direction of the lamp bulb, and that generates UV light in the discharge space by the discharge; and an inverter having a transformer equipped with a secondary winding to which the external electrodes are connected in order to apply a high-voltage alternating current to the excimer lamp, the inverter supplying power lower than power that causes a linear discharge.

A microwave excited ultraviolet lamp system with a data logging and retrieval circuit and method for operating the same. The data logging and retrieval circuit stores operational data in a cache memory using a FIFO data storage protocol. The contents of the cache memory are periodically copied to a larger removable memory so that the removable memory contains a relatively long historical record of the system operational parameters. The data logging and retrieval circuit includes a data port configured to load the contents of the cache memory into an external device when the device is coupled to the data port. A second data port allows the external device to supply power to the data logging and retrieval circuit so that data may be retrieved when the internal power supply is malfunctioning. Data stored in the removable memory may be protected so that it may only be accessed by authorized personnel.

A microwave excited ultraviolet lamp system with a data logging and retrieval circuit and method for operating the same. The data logging and retrieval circuit stores operational data in a cache memory using a FIFO data storage protocol. The contents of the cache memory are periodically copied to a larger removable memory so that the removable memory contains a relatively long historical record of the system operational parameters. The data logging and retrieval circuit includes a data port configured to load the contents of the cache memory into an external device when the device is coupled to the data port. A second data port allows the external device to supply power to the data logging and retrieval circuit so that data may be retrieved when the internal power supply is malfunctioning. Data stored in the removable memory may be protected so that it may only be accessed by authorized personnel.

A discharge lamp includes a discharge tube containing electrodes, and base sections. The base sections have terminals for connecting to external power lines, and internal power lines for connecting the terminals to the electrodes within the discharge tube. Information generation devices that generates information to be output to outside are provided within the base sections. Superimposition circuits that superpose the information, generated by the information generation devices, on the internal power lines within the base sections are also provided within the base sections. The information generation devices include sensors and generate information based on output of the sensors. A receiving circuit extracts and receives the information, superposed on the internal power lines, from the external power lines connected to the internal power lines. Thus, information generated on the discharge lamp side can be transmitted to outside with a simple construction.

A discharge lamp includes a discharge tube containing electrodes, and base sections. The base sections have terminals for connecting to external power lines, and internal power lines for connecting the terminals to the electrodes within the discharge tube. Information generation devices that generates information to be output to outside are provided within the base sections. Superimposition circuits that superpose the information, generated by the information generation devices, on the internal power lines within the base sections are also provided within the base sections. The information generation devices include sensors and generate information based on output of the sensors. A receiving circuit extracts and receives the information, superposed on the internal power lines, from the external power lines connected to the internal power lines. Thus, information generated on the discharge lamp side can be transmitted to outside with a simple construction.

A power supply system for driving a light source includes a transformer including a primary winding and a plurality of secondary windings including an output bias winding, a control bias winding, and an RF bias winding, the output bias winding being electrically coupled to and configured to supply electrical power to the light source, a control circuit electrically coupled to and configured to receive electrical power from the control bias winding; and an RF communication circuit electrically coupled to and configured to receive electrical power from the RF bias winding.

A power supply system for driving a light source includes a transformer including a primary winding and a plurality of secondary windings including an output bias winding, a control bias winding, and an RF bias winding, the output bias winding being electrically coupled to and configured to supply electrical power to the light source, a control circuit electrically coupled to and configured to receive electrical power from the control bias winding; and an RF communication circuit electrically coupled to and configured to receive electrical power from the RF bias winding.

An electronic ballast with a single stage circuit structure includes a detection device for detecting a voltage, current, and phase of an AC input power source; a rectifier bridge; a full bridge inverter circuit; and an inverter controlling circuit. When an output terminal of the full bridge inverter circuit is connected to the gas discharge lamp as a load, the electronic ballast further includes a series resonant capacitor Cs and a series resonant inductor L. By additionally providing the series resonant capacitor Cs and the series resonant inductor L to the electronic ballast, a zero-crossing point of a unidirectional sinusoidal direct current is able to effectively solve the HID extinguishing problem due to under-voltage thereof. Since a conduction angle of the entire unidirectional sinusoidal half wave of the HID is increased, the PF value is effectively increased and the harmonics is effectively reduced.

An electronic ballast with a single stage circuit structure includes a detection device for detecting a voltage, current, and phase of an AC input power source; a rectifier bridge; a full bridge inverter circuit; and an inverter controlling circuit. When an output terminal of the full bridge inverter circuit is connected to the gas discharge lamp as a load, the electronic ballast further includes a series resonant capacitor Cs and a series resonant inductor L. By additionally providing the series resonant capacitor Cs and the series resonant inductor L to the electronic ballast, a zero-crossing point of a unidirectional sinusoidal direct current is able to effectively solve the HID extinguishing problem due to under-voltage thereof. Since a conduction angle of the entire unidirectional sinusoidal half wave of the HID is increased, the PF value is effectively increased and the harmonics is effectively reduced.