Apparatus and method for improved illumination area fill
First Claim
1. An apparatus for illuminating a surface comprising:
- a light source whose intensity varies as a function of the angles of the light rays radiated form the light source in a three dimensional radiation pattern, and a reflector having an optical aperture, the reflector being proximate to the light source, defining a system angle by the optical aperture of the reflector and allowing directly radiated energy to propagate from the light source through the optical aperture of the reflector to the surface to provide a directly radiated energy distribution pattern on the surface, where the reflector has a defined shape derived from a transfer function, which has as inputs;
the three dimensional radiation pattern of the light source;
beam parameters, including light source-to-surface distance and beam diameter;
system parameters of the reflector including reflector size and optical aperture size of the reflector; and
a desired composite energy distribution on the surface; and
which has as outputs;
an amount of directly radiated energy propagating through the optical aperture of the reflector;
a remainder of the total available radiated energy from the light source less the energy of the light directly radiating to the surface through the reflector optical aperture; and
a calculated position and orientation of each point on the reflector as a function of angle needed to provided the desired composite energy distribution on the surface, which calculation defines the shape of the reflector necessary to provide a reflected energy pattern to overlay the directly radiated energy pattern to form the designer controlled composite energy distribution on the surface.
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Accused Products
Abstract
A reflector for a light source, such as an LED, is provided with a shape which efficiently collects and directs energy to an illumined surface whereby almost 100% of the light is collected and distributed into a designer composite beam. The shape in one embodiment is comprised of three zones beginning with a parabolic surface of revolution at the base of the reflector, followed by a transition or straight conic zone and ending with an elliptical zone. In another embodiment the reflector shape is determined according to a transfer function which allows for arbitrary designer control of the reflected rays at each point on the reflector, which when combined with direct radiation from the source, results in a designer controlled composite beam or illumination. The device is more than 90% energy efficient and allows replacement of higher power, less energy efficient light sources with no loss in illumination intensity.
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Citations
14 Claims
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1. An apparatus for illuminating a surface comprising:
- a light source whose intensity varies as a function of the angles of the light rays radiated form the light source in a three dimensional radiation pattern, and a reflector having an optical aperture, the reflector being proximate to the light source, defining a system angle by the optical aperture of the reflector and allowing directly radiated energy to propagate from the light source through the optical aperture of the reflector to the surface to provide a directly radiated energy distribution pattern on the surface, where the reflector has a defined shape derived from a transfer function, which has as inputs;
the three dimensional radiation pattern of the light source;
beam parameters, including light source-to-surface distance and beam diameter;
system parameters of the reflector including reflector size and optical aperture size of the reflector; and
a desired composite energy distribution on the surface; and
which has as outputs;
an amount of directly radiated energy propagating through the optical aperture of the reflector;
a remainder of the total available radiated energy from the light source less the energy of the light directly radiating to the surface through the reflector optical aperture; and
a calculated position and orientation of each point on the reflector as a function of angle needed to provided the desired composite energy distribution on the surface, which calculation defines the shape of the reflector necessary to provide a reflected energy pattern to overlay the directly radiated energy pattern to form the designer controlled composite energy distribution on the surface. - View Dependent Claims (2, 3, 4, 5, 6, 7, 8, 9, 10)
- a light source whose intensity varies as a function of the angles of the light rays radiated form the light source in a three dimensional radiation pattern, and a reflector having an optical aperture, the reflector being proximate to the light source, defining a system angle by the optical aperture of the reflector and allowing directly radiated energy to propagate from the light source through the optical aperture of the reflector to the surface to provide a directly radiated energy distribution pattern on the surface, where the reflector has a defined shape derived from a transfer function, which has as inputs;
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11. An apparatus for illuminating a surface comprising:
- a light source whose intensity varies as a function of the angles of the light rays radiated form the light source in a three dimensional radiation pattern, and a reflector having a base and an optical aperture, the reflector receiving light from the light source, where the light source is directed toward the base of the optical aperture and is disposed longitudinally forward of the base of the reflector, and where the reflector has a defined shape derived from a transfer function, which has as inputs;
the three dimensional radiation pattern of the light source;
beam parameters, including light source-to-reflector distance, reflector-to-surface distance, and beam diameter;
system parameters of the reflector including reflector size and optical aperture size of the reflector; and
a desired energy distribution on the surface; and
which has as outputs;
an amount of radiated energy propagating through the optical aperture of the reflector; and
a calculated position and orientation of each point on the reflector as a function of angle needed to provide the desired energy distribution on the surface, which calculation defines the shape of the reflector necessary to provide a reflected energy pattern, where the transfer function configures the shape of the reflector to send reflected light from a first portion of the reflector extending from the base of the reflector to a predetermined demarcation on the reflector to an first portion of the energy distribution on the surface which is arbitrarily designer selected, and where the transfer function configures the shape of the reflector to send reflected light from a second portion of the reflector extending from the predetermined demarcation on the reflector to the optical aperture of the reflector to a second portion of the energy distribution on the surface which is arbitrarily designer selected.
- a light source whose intensity varies as a function of the angles of the light rays radiated form the light source in a three dimensional radiation pattern, and a reflector having a base and an optical aperture, the reflector receiving light from the light source, where the light source is directed toward the base of the optical aperture and is disposed longitudinally forward of the base of the reflector, and where the reflector has a defined shape derived from a transfer function, which has as inputs;
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12. An apparatus for illuminating a surface comprising:
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a light source whose intensity varies as a function of the angles of the light rays radiated from the light source in a three dimensional radiation pattern, a reflector having an aperture, the reflector being proximate to the light source, defining a system angle by the aperture of the reflector, and a lens for allowing radiated energy directly from the light source to propagate through the lens to the illuminated surface to provide a directed energy distribution pattern on the illuminated surface, where the reflector has a surface and defined shape derived from a transfer function, which has as inputs; the three dimensional radiation pattern of the light source; beam parameters, including light source-to-surface distance and beam diameter; lens parameters, system parameters of the reflector including reflector size and aperture size of the reflector; and a desired composite energy distribution on the illuminated surface; and
which has as outputs;an amount of directed radiated energy propagating through the lens; a remainder of the total available radiated energy from the light source less the energy of the directed light propagating to the illuminated surface through the lens; and a calculated position and orientation of each point on the surface of the reflector as a function of angle needed to provide the desired composite energy distribution on the illuminated surface, which calculation defines the shape of the reflector necessary to provide a reflected energy pattern to overlay the directed energy pattern to form the designer controlled composite energy distribution on the surface. - View Dependent Claims (13)
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14. An apparatus for illuminating a surface comprising:
- a light source whose intensity varies as a function of the angles of the light rays radiated from the light source in a three dimensional radiation pattern, and means for reflecting light, the means having an optical aperture, and means for reflecting light, the means having an optical aperture, the means being proximate to the light source, defining a system angle by the optical aperture of the means and allowing directly radiated energy to propagate from the light source through the optical aperture of the means to the surface to provide a directly radiated energy distribution pattern on the surface, where the means has a defined shape derived from a transfer function, which has as inputs;
the three dimensional radiation pattern of the light source;
beam parameters, including light source-to-surface distance and beam diameter;
system parameters of the means including means size and optical aperture size of the means; and
a desired composite energy distribution on the surface; and
which has as outputs;
an amount of directly radiated energy propagating through the optical aperture of the means;
a remainder of the total available radiated energy from the light source less the energy of the light directly radiating to the surface through the means optical aperture; and
a calculated position and orientation of each point on the means as a function of angle needed to provide the desired composite energy distribution on the surface, which calculation defines the shape of the means necessary to provide a reflected energy pattern to overlay the directly radiated energy pattern to form the designer controlled composite energy distribution on the surface.
- a light source whose intensity varies as a function of the angles of the light rays radiated from the light source in a three dimensional radiation pattern, and means for reflecting light, the means having an optical aperture, and means for reflecting light, the means having an optical aperture, the means being proximate to the light source, defining a system angle by the optical aperture of the means and allowing directly radiated energy to propagate from the light source through the optical aperture of the means to the surface to provide a directly radiated energy distribution pattern on the surface, where the means has a defined shape derived from a transfer function, which has as inputs;
Specification