Abstract: A light source unit comprises a support for supporting a lamp unit, e.g., a gas discharge lamp or the like. The lamp unit has longitudinal and transversal fiduciary surfaces and the support has guide rails for guiding the lamp unit as it is inserted transversely with the longitudinal fiduciary surfaces sliding along a reference surface until transversal fiduciary surfaces engage one or more stops. The support may comprise a first part for supporting the lamp unit, a second part for supporting a light guide, and at least first and second light baffles between the first part and the second part, the first and second baffles each having an aperture for passing only a portion of light from the lamp unit incident upon the baffle, the arrangement being such that light from the lamp unit must pass through the apertures in both baffles to be incident upon the light guide.

Abstract: In a light delivery system comprising a lightguide coupled to an optical apparatus for delivering substantially uniform light to a predetermined plane within the apparatus, images of non-uniformities caused by imperfections at or near an outlet end of the lightguide are displaced away from the predetermined plane. The image displacement may be performed by a lens adjacent the end of the lightguide, or integral therewith, or by a suitably formed plug or end cap of a liquid lightguide.

Abstract: The present invention provides an artificial member (80, 210) which mimics the absorbance spectrum of a body part and includes the spectral components of blood analytes. The artificial member comprises a light scattering and reflecting material, and has a chamber portion comprising one or more chambers (90, 100, 220). The artificial member is configured to be reproducibly received in a measuring receptor which receptor is operatively connected to a non-invasive monitoring device.

Abstract: A system and method for measuring radiation. In one embodiment, a radiometer includes an inlet port, a light sensor operatively coupled to the inlet port, and a direction sensor adapted to detect the orientation of the inlet port. In another aspect, a radiometer has a base, a housing pivotally mounted to the base, an aperture in the housing, a radiation sensor in communication with the aperture, and a direction sensor adapted to detect the orientation of the housing relative to the base. In yet another aspect, a radiometer has a housing including at least one aperture, and a radiation sensor adapted to detect the irradiance and direction of origin of radiation entering the aperture. A method is disclosed for detecting the irradiance of radiant energy from a source in at least two dimensions. The method involves the steps of providing a radiometer of the present invention and positioning the radiometer in the path of radiant energy emitted from the source.

Abstract: The present invention provides an artificial member (80, 210) which mimics the absorbance spectrum of a body part and includes the spectral components of blood analytes. The artificial member comprises a light scattering and reflecting material, and has a chamber portion comprising one or more chambers (90, 100, 220). The artificial member is configured to be reproducibly received in a measuring receptor which receptor is operatively connected to a non-invasive monitoring device.

Abstract: The present invention provides an artificial member (80, 210) which mimics the absorbance spectrum of a body part and includes the spectral components of blood analytes. The artificial member comprises a light scattering and reflecting material, and has a chamber portion comprising one or more chambers (90, 100, 220). The artificial member is configured to be reproducibly received in a measuring receptor which receptor is operatively connected to a non-invasive monitoring device.

Abstract: A method and system for curing reactive material. The system includes a generator capable of generating radiation, a power supply operatively coupled to the generator, and an emitter adapted to emit the generated radiation onto the material. The system also includes a temperature sensor capable of detecting the temperature of the material a controller adapted to control the power level of radiation emitted. The system also preferably includes a masking unit for shaping the emitted radiation to substantially match the profile dimensions of the reactive material. In one embodiment, the method includes the steps of generating radiation within the absorption spectrum of the reactive material; shaping the generated radiation to substantially match the dimensions of the reactive material; and emitting said shaped radiation onto the reactive material.