An LED lighting device (6) having an LED (8) emitting white light and optical filter means (12) suitable for filtering the white light emitted by the LED (8). The optical filter means comprise at least two optical filters (12) that have different transmission coefficients and that are positionable to filter the light emitted by the LED (8) individually. The lighting device (6) includes a power supply unit (10) suitable for delivering different power supply currents to the LED (8) depending on whether one or the other of the optical filters (12) is positioned to filter the light from the LED (8), so as to modify the color temperature of the light emitted by the LED (8).

An LED lighting device (6) having an LED (8) emitting white light and optical filter means (12) suitable for filtering the white light emitted by the LED (8). The optical filter means comprise at least two optical filters (12) that have different transmission coefficients and that are positionable to filter the light emitted by the LED (8) individually. The lighting device (6) includes a power supply unit (10) suitable for delivering different power supply currents to the LED (8) depending on whether one or the other of the optical filters (12) is positioned to filter the light from the LED (8), so as to modify the color temperature of the light emitted by the LED (8).

The present invention provides a lamp cover comprising (1) a thermoplastic resin having a visible light transmissivity of 50% or higher measured in a form of a plate-like molded body having a thickness of 2 mm according to JIS R 3106, (2) a composite tungsten oxide, (3) at least one material selected from the group consisting of a metal soap, an antioxidant, and a first selective wavelength absorbing material having a maximum absorption wavelength within a range of 200 to 350 nm, whose content is 0.03% by mass or more based on a total content (100% by mass) of the components (1) to (4), and (4) a second selective wavelength absorbing material having a maximum absorption wavelength within a range of 450 to 550 nm.

A short wavelength infrared (SWIR) energy emitting system or material for producing SWIR energy from an emission source emitting electromagnetic energy. The SWIR energy system or material comprises a phosphor material, an electromagnetic energy blocking member, a substrate for delivering the system or material to an electromagnetic energy emission source, and optionally, a securing member. The SWIR energy system or material may be in the form of a tape, sheet, or other laminar material capable of producing short wave infrared emission when excited at wavelengths shorter than that of the emission.

A short wavelength infrared (SWIR) energy emitting system or material for producing SWIR energy from an emission source emitting electromagnetic energy. The SWIR energy system or material comprises a phosphor material, an electromagnetic energy blocking member, a substrate for delivering the system or material to an electromagnetic energy emission source, and optionally, a securing member. The SWIR energy system or material may be in the form of a tape, sheet, or other laminar material capable of producing short wave infrared emission when excited at wavelengths shorter than that of the emission.

An electro-optic element includes a first substantially transparent substrate defining a first surface and a second surface. A second substantially transparent substrate defines a third surface and a fourth surface. A primary seal is disposed between the first and second substrates. The seal and the first and second substrates define a cavity. An electro-optic material is positioned within the cavity. A transflective coating having a transmittance of between about 15% and about 60% in a visible wavelength band is positioned on at least one of the second and third surfaces. The transflective coating includes a first layer including an absorbing material, a second layer, a third layer including a low index metal and a fourth layer. The second and fourth layers include at least one of a dielectric material and a transparent conducting oxide.

An optical filter has a substrate, a refractive index adjusting layer on the substrate, a characteristic improving layer having a stress adjustment function on the refractive index adjusting layer, and an optical multilayer film on the characteristic improving layer, wherein the refractive index adjusting layer is constituted by one to three layers, and the characteristic improving layer is a single-layer film whose physical film thickness is 600 nm or more. The optical filter whose substrate has small warpage and which has a good spectral characteristic is provided.

Apparatuses and methods for improving the accuracy of an analyte sensor are disclosed. The sensor may include a photodetector and a low angle sensitive (LAS) optical filter. The photodetector may be configured to convert received light into current indicative of the intensity of the received light. The LAS optical filter may be configured to prevent light having a wavelength outside a band pass region from reaching the photodetector and to pass light having a wavelength within the band pass region to the photodetector. The percentage of light passing through the LAS optical filter may decrease as the angle of incidence of the light increases.

A lighting assembly having a mounting structure, an LED mounted on the mounting structure, an optical device optically coupled to the LED, and a support structure for connecting the optical device to the mounting structure. The LED is enclosed within a space formed by the mounting structure, the support structure, and the optical device. The support structure absorbs thermal energy to reduce an operating temperature of the optical device. The optical device may be formed from a first material and the support structure may be formed from a different, second material.

A lighting assembly having a mounting structure, an LED mounted on the mounting structure, an optical device optically coupled to the LED, and a support structure for connecting the optical device to the mounting structure. The LED is enclosed within a space formed by the mounting structure, the support structure, and the optical device. The support structure absorbs thermal energy to reduce an operating temperature of the optical device. The optical device may be formed from a first material and the support structure may be formed from a different, second material.