Abstract: A highly efficient, lightweight solid state lighting panel is disclosed that has multiple LED sources, and emits a substantially uniform light intensity between said sources. The light from these sources is directed towards a highly reflective, diffusive, backing. These LED sources are placed between the reflector and a partially transmissive, partially reflective output coupler to form a cavity. The LEDs, which are mounted to printed circuit boards to form strips, can be either attached to the inner surface of the diffuser with adhesive, or suspended on a thermally dissipative structure within the cavity. By optimizing the reflector to have as high of a reflectance value as possible (>95%) along with a output diffuser with about 50% transmission and 50% reflection, one can obtain cavity transmissions higher than 90%. The output from this disclosed design is more pleasant to look at than those with LEDs that directly illuminate the diffuser, causing hotspots.

Abstract: A highly efficient, lightweight solid state lighting panel is disclosed that has multiple LED sources, and emits a substantially uniform light intensity between said sources. The light from these sources is directed towards a highly reflective, diffusive, backing. These LED sources are placed between the reflector and a partially transmissive, partially reflective output coupler to form a cavity. The LEDs, which are mounted to printed circuit boards to form strips, can be either attached to the inner surface of the diffuser with adhesive, or suspended on a thermally dissipative structure within the cavity. By optimizing the reflector to have as high of a reflectance value as possible (>95%) along with a output diffuser with about 50% transmission and 50% reflection, one can obtain cavity transmissions higher than 90%. The output from this disclosed design is more pleasant to look at than those with LEDs that directly illuminate the diffuser, causing hotspots.

Abstract: Laser energy produced by a laser operating In the mid-infrared region (approximately 2 micrometers) Is delivered by an optical fiber in a catheter to a surgical site for biological tissue removal and repair. Disclosed laser sources which have an output wavelength in this region include: Holmium-doped Yttrium Aluminum Garnet (Ho:YAG), Holmium-doped Yttrium Lithium Fluoride (Ho:YLF), Erbium-doped YAG, Erbium-doped YLF and Thulium-doped YAG. For tissue removal, the lasers are operated with relatively long pulses at energy levels of approximately 1 joule per pulse. For tissue repair, the lasers are operated in a continuous wave mode at low power. Laser output energy is applied to a silica-based optical fiber which has been specially purified to reduce the hydroxyl-ion concentration to a low level. The catheter may be comprised of a single optical fiber or a plurality of optical fibers arranged to give overlapping output patterns for large area coverage.

Abstract: Laser energy produced by a laser operating in the mid-infrared region (approximately 2 micrometers) is delivered by an optical fiber in a catheter to a surgical site for biological tissue removal and repair. Disclosed laser sources which have an output wavelength in this region include: Holmium-doped Yttrium Aluminum Garnet (Ho:YAG), Holmium-doped Yttrium Lithium Fluoride (Ho:YLF), Erbium-doped YAG, Erbium-doped YLF and Thulium-doped YAG. For tissue removal, the lasers are operated with relatively long pulses at energy levels of approximately 1 joule per pulse. For tissue repair, the lasers are operated in a continuous wave mode at low power. Laser output energy is applied to a silica-based optical fiber which has been specially purified to reduce the hydroxyl-ion concentration to a low level. The catheter may be comprised of a single optical fiber or a plurality of optical fibers arranged to give overlapping output patterns for large area coverage.

Abstract: Laser energy produced by a laser operating in the mid-infrared region (approximately 2 micrometers) is delivered by an optical fiber in a catheter to a surgical site for biological tissue removal and repair. Disclosed laser sources which have an output wavelength in this region include: Holmium-doped Yttrium Aluminum Garnet (Ho:YAG), Holmium-doped Yttrium Lithium Fluoride (Ho:YLF), Erbium-doped YAG, Erbium-doped YLF and Thulium-doped YAG. For tissue removal, the lasers are operated with relatively long pulses at energy levels of approximately 1 joule per pulse. For tissue repair, the lasers are operated in a continuous wave mode at low power. Laser output energy is applied to a silica-based optical fiber which has been specially purified to reduce the hydroxyl-ion concentration to a low level. The catheter may be comprised of a single optical fiber or a plurality of optical fibers arranged to give overlapping output patterns for large area coverage.