A conductive structure comprising: a plurality of conductive devices; a first conductive spring sheet, comprising a first connecting point; and a second conductive spring sheet, comprising a second connecting point. Each of the conductive devices comprises a first conductive end and a second conductive end. The second conductive end is connected to the second connecting point, and the first conductive end is connected to the first connecting point corresponding to the second connecting point to which the second conductive end is connected.

A conductive structure comprising: a plurality of conductive devices; a first conductive spring sheet, comprising a first connecting point; and a second conductive spring sheet, comprising a second connecting point. Each of the conductive devices comprises a first conductive end and a second conductive end. The second conductive end is connected to the second connecting point, and the first conductive end is connected to the first connecting point corresponding to the second connecting point to which the second conductive end is connected.

Described herein is a device and a method for generating radiation, in particular pulsed radiation, specifically within the infrared spectral range. Also described herein is a computer program product which includes executable instructions for performing the method. The device for generating radiation includes at least one radiation emitting element, where the radiation emitting element is designated for generating radiation upon being heated by an electrical current; a mount, where the mount carries the at least one radiation emitting element, and where the mount or a portion thereof is movable; and a heat sink, where the heat sink is designated for cooling the mount and the at least one radiation emitting element being carried by the mount upon being touched by the mount. The device, the method, and the computer program product can be used in a spectroscopic application.

Described herein is a device and a method for generating radiation, in particular pulsed radiation, specifically within the infrared spectral range. Also described herein is a computer program product which includes executable instructions for performing the method. The device for generating radiation includes at least one radiation emitting element, where the radiation emitting element is designated for generating radiation upon being heated by an electrical current; a mount, where the mount carries the at least one radiation emitting element, and where the mount or a portion thereof is movable; and a heat sink, where the heat sink is designated for cooling the mount and the at least one radiation emitting element being carried by the mount upon being touched by the mount. The device, the method, and the computer program product can be used in a spectroscopic application.

Described herein is a device and a method for generating radiation, in particular pulsed radiation, specifically within the infrared spectral range. Also described herein is a computer program product which includes executable instructions for performing the method. The device for generating radiation includes at least one radiation emitting element, where the radiation emitting element is designated for generating radiation upon being heated by an electrical current; a mount, where the mount carries the at least one radiation emitting element, and where the mount or a portion thereof is movable; and a heat sink, where the heat sink is designated for cooling the mount and the at least one radiation emitting element being carried by the mount upon being touched by the mount. The device, the method, and the computer program product can be used in a spectroscopic application.

Described herein is a device and a method for generating radiation, in particular pulsed radiation, specifically within the infrared spectral range. Also described herein is a computer program product which includes executable instructions for performing the method. The device for generating radiation includes at least one radiation emitting element, where the radiation emitting element is designated for generating radiation upon being heated by an electrical current; a mount, where the mount carries the at least one radiation emitting element, and where the mount or a portion thereof is movable; and a heat sink, where the heat sink is designated for cooling the mount and the at least one radiation emitting element being carried by the mount upon being touched by the mount. The device, the method, and the computer program product can be used in a spectroscopic application.

An embodiment provides a lamp apparatus, including: at least one filament; an amount of amalgam; a heat-sink assembly connected to the lamp apparatus; and at least one control circuit comprising a heating element and a temperature measurement element connected to the at least one filament, wherein the control circuit varies the electrical power delivered to the heating element, thereby controlling an internal temperature of the lamp apparatus relative to a temperature set point. Other aspects are described and claimed.

An embodiment provides a lamp apparatus, including: at least one filament; an amount of amalgam; a heat-sink assembly connected to the lamp apparatus; and at least one control circuit comprising a heating element and a temperature measurement element connected to the at least one filament, wherein the control circuit varies the electrical power delivered to the heating element, thereby controlling an internal temperature of the lamp apparatus relative to a temperature set point. Other aspects are described and claimed.

An embodiment provides a lamp apparatus, including: at least one filament; an amount of amalgam; a heat-sink assembly connected to the lamp apparatus; and at least one control circuit comprising a heating element and a temperature measurement element connected to the at least one filament, wherein the control circuit varies the electrical power delivered to the heating element, thereby controlling an internal temperature of the lamp apparatus relative to a temperature set point. Other aspects are described and claimed.

An embodiment provides a lamp apparatus, including: at least one filament; an amount of amalgam; a heat-sink assembly connected to the lamp apparatus; and at least one control circuit comprising a heating element and a temperature measurement element connected to the at least one filament, wherein the control circuit varies the electrical power delivered to the heating element, thereby controlling an internal temperature of the lamp apparatus relative to a temperature set point. Other aspects are described and claimed.