Providing remote blue phosphors in an LED lamp

Abstract

Light emitting devices and techniques for using remote blue phosphors in LED lamps are disclosed. An LED lamp is formed by configuring a first plurality of n of radiation sources to emit radiation characterized by a first wavelength, the first wavelength being substantially violet, and configuring a second plurality of m of radiation sources to emit radiation characterized by a second wavelength, the second wavelength also being substantially violet. Aesthetically-pleasing white light is emitted as the light from the radiation sources interacts with various wavelength converting materials (e.g., deposits of red-emitting materials, deposits of yellow/green-emitting materials, etc.) including a blue-emitting remote wavelength converting layer configured to absorb at least a portion of the radiation emitted by the first plurality of radiation sources. The remote wavelength converting layer emits wavelengths ranging from about 420 nm to about 520 nm.

Description

FIELD

The present disclosure relates generally to light emitting devices and, more particularly, to techniques for using remote blue phosphors in lamps comprising light emitting devices.

BACKGROUND

Legacy LED light bulbs and fixtures use blue-emitting diodes in combination with phosphors or other wavelength-converting materials emitting red, and/or green, and/or yellow light. The combination of blue emitting LEDs and red-emitting and green- and/or yellow-emitting materials is intended to aggregate to provide a spectrum of wavelengths, which spectrum is perceived by a human as white light. However, although the resulting spectrum is intended to be perceived by a human as white light, many human subjects report that the light is significantly color-shifted. The reported color shifting makes such legacy LED lamps and fixtures inappropriate for various applications. Various attempts to improve upon legacy techniques have proven ineffective and/or inefficient.

Further, uses of green- and/or yellow-emitting materials in the exterior structure of a lamp that can be seen by a user are often regarded as undesirable, especially because the aesthetics of interior lighting has traditionally been based on a white or near-white exterior structure (e.g., as in the case of a legacy, incandescent, “Edison” bulb).

In some legacy LED lamps, blue LEDs are used in conjunction with down-converting phosphors embedded in an encapsulant, which encapsulant is disposed directly atop or in close proximity to the violet LEDs. However short wavelength light (e.g., blue light) is known to degrade the materials used in encapsulants, thus limiting the useful lifetime of the lamp.

SUMMARY

An improved approach involving the use of LEDs emitting wavelengths other than the legacy blue-emitting LEDs is provided herein.

In a first aspect, LED lamps are provided comprising: a first plurality of n radiation sources configured to emit radiation characterized by a first wavelength, the first wavelength being substantially violet; a second plurality of m radiation sources configured to emit radiation characterized by a second wavelength, the second wavelength being substantially violet; and a first wavelength converting layer configured to absorb at least a portion of the radiation emitted by the first plurality of radiation sources, the first wavelength converting layer having an emission wavelength ranging from about 420 nm to about 520 nm.

In a second aspect, LED lamps are provided comprising: a first plurality of n radiation sources configured to emit radiation characterized by a first wavelength, the first wavelength being substantially blue; and a second plurality of m radiation sources configured to emit radiation characterized by a second wavelength, the second wavelength being substantially violet; and a first wavelength converting layer configured to absorb at least a portion of radiation emitted by the second plurality of radiation sources, the first wavelength converting layer having an emission wavelength ranging from about 500 nm to about 750 nm.

In a third aspect, LED lamps with an outer surface having a white appearance under ambient light are provided, comprising: a light source; an outer surface, the outer surface positioned to form a remote structural member; a first wavelength converting layer disposed on the remote structural member, the first wavelength converting layer configured to absorb at least a portion of radiation emitted by the light source, the first wavelength converting layer having an emission wavelength ranging from about 420 nm to about 520 nm; and a second wavelength converting layer disposed on the remote structural member, the second wavelength converting layer having an emission wavelength ranging from about 490 nm to about 630 nm.

BRIEF DESCRIPTION OF THE DRAWINGS

FIG. 1A is a diagram illustrating an LED lamp having a base to provide a mount point for a light source, according to some embodiments.

FIG. 1B is a diagram illustrating construction of a radiation source comprised of light emitting diodes, according to some embodiments.

FIG. 1C is a diagram illustrating an optical device embodied as a light source constructed using an array of LEDs, according to some embodiments.

FIG. 1D is a diagram illustrating an apparatus with a down-converting member having a phosphor mix, according to an embodiment of the disclosure.

FIG. 1E is a side view illustrating a remote blue phosphor dome for generating white light, according to an embodiment of the disclosure.

FIG. 1F is a top view illustrating a chip-array-based apparatus with phosphors disposed on a surface of a heat sink, according to an embodiment of the disclosure.

FIG. 2A is a diagram illustrating an optical device having phosphor materials disposed directly atop an LED device or in very close proximity to an LED device, according to an embodiment of the present disclosure.

FIG. 2B is a diagram illustrating an optical device having red, green, and violet radiation sources, according to an embodiment of the present disclosure.

FIG. 3A is a diagram illustrating a conversion process, according to some embodiments.

FIG. 3B is a diagram illustrating a conversion process, according to some embodiments.

FIG. 4 is a graph illustrating a light process chart by phosphor material, according to some embodiments.

FIG. 5 is an illustration of an LED lamp comprising light source, according to an embodiment of the present disclosure.

FIG. 6 is a diagram illustrating an optical device embodied as a light source constructed using an array of LEDs in proximity to remote down-converting member having a phosphor mix, according to an embodiment of the disclosure.

FIG. 7 is a diagram showing relative absorption strengths, according to an embodiment of the disclosure.

FIG. 8 depicts a block diagram of a system to perform certain functions for manufacturing an LED lamp, according to an embodiment of the disclosure.

FIG. 9A depicts a system to perform certain functions of an LED lamp, according to an embodiment of the disclosure.

FIG. 9B depicts a spectrum of a light process in ambient light, according to an embodiment of the disclosure.

FIG. 9C depicts a spectrum of a light process, according to an embodiment of the disclosure.

FIG. 9D depicts a chromaticity chart, according to embodiments of the disclosure.

DETAILED DESCRIPTION OF THE DISCLOSURE

Various types of phosphor-converted (pc) light-emitting diodes (LEDs) have been proposed in the past. Conventional pc LEDs include a blue LED with various phosphors (e.g., in yellow and red combinations, in green and red combinations, in red and green and blue combinations). Various attempts have been made to combine the blue light-emissions of the blue LEDS with phosphors to provide color control.

According to some embodiments of the present disclosure, a substantially white light lamp is formed by combining wavelength-converting material that emits substantially blue light (e.g., phosphors) with LEDs that emit red, green, and/or violet (but not blue) light. In some embodiments, the combination is provided in a form factor to serve as an LED light source (e.g., a light bulb, a lamp, a fixture, etc.).

As disclosed herein, the use of green- and/or yellow-emitting materials in the exterior structure of a lamp that can be seen by a user is often regarded as undesirable, especially because the aesthetics of interior lighting has been based on a white or near-white exterior structure (e.g., as in the case of a legacy, incandescent, “Edison” bulb). In addition to the herein-described utility, one aspect that influences the design of more desirable embodiments is a human's perception of aesthetics. Many of the LED systems disclosed herein comprise of an LED lamp having an exterior structure such as a “bulb”, or “dome”, or encasement, or glass portion, or outer surface, etc. that, when viewed in natural light (e.g., in sunlight, in interior lighting settings, in ambient light, etc.) appear as a substantially white “bulb”, or “dome” or “outer surface”. Still further, the use blue-emitting wavelength-converting materials in the fabrication of the aforementioned substantially white bulb, or dome results in imparting optical scattering properties to the dome, such that the dome appears as “soft white”.

In addition to the aesthetics that consequently result from the herein-described embodiments, such embodiments exhibit exceptionally high efficiency in terms of perceived optical wattage with respect to electrical power consumed. For example, most humans report that perceived light output (e.g., brightness, candlepower, lumens, etc.) is substantially more determined by the presence of yellow and/or green light as compared to the presence of blue light. Some human subjects report that added light in the wavelength range of green and/or yellow is up to five times more perceptible than is added light in the wavelength range of blue light.

Table 1 shows an example of various LED pump and phosphor emitting peak wavelengths that could be utilized to generate white light according to embodiments provided by the present disclosure.

	TABLE 1
			Yellow/
		Blue	Green	Red
	Emission Peak	450	530	620
	(nm)
	LED Pump	400-420	415-435	415-435
	(nm)

In addition to the aforementioned benefits of combining wavelength-converting material (e.g., phosphors) that emits substantially blue light with LEDs that emit violet, and/or red, and/or green light, it is known that longer wavelengths (e.g., red, and/or green light) do not cause degradation of silicone and other materials used in lamps. Thus, configuring LED lamps that avoid the use of blue-emitting LEDs (or other short-wavelength colors) in close proximity to any silicone encapsulants has a desirable effect on the longevity of such LED lamps.

FIG. 1A is a diagram illustrating an LED lamp 100 having a base to provide a mount point for a light source, according to some embodiments. It is to be appreciated that an LED lamp 100, according to the present disclosure, can be implemented for various types of applications. As shown in FIG. 1A, a light source (e.g., the light source 142) is a part of the LED lamp 100. The LED lamp 100 includes a base member 151. The base member 151 is mechanically connected to a heat sink 152, and the heat sink is mechanically coupled to a remote structural member 155 (e.g., a bulb or a dome). In certain embodiments, the base member 151 is compatible with a conventional light bulb socket and is used to provide electrical power (e.g., using an AC power source) to one or more radiation emitting devices (e.g., one or more instances of light source 142). In certain embodiments, the base member 151 is compatible with an MR-16 socket and is used to provide electrical power (e.g., using an AC power source) to the one or more radiation emitting devices (e.g., one or more instances of light source 142). The base member 151 can conform to any of a set of standards for the base. For example Table 2 gives standards (see “Designation”) and corresponding characteristics.

TABLE 2
	Base
	Diameter		IEC 60061-1
	(Crest of		standard
Designation	thread)	Name	sheet
E05	5 mm	Lilliput Edison Screw	7004-25
		(LES)
E10	10 mm	Miniature Edison Screw	7004-22
		(MES)
E11	11 mm	Mini-Candelabra Edison	(7004-6-1)
		Screw (mini-can)
E12	12 mm	Candelabra Edison Screw	7004-28
		(CES)
E14	14 mm	Small Edison Screw (SES)	7004-23
E17	17 mm	Intermediate Edison Screw	7004-26
		(IES)
E26	26 mm	[Medium] (one-inch)	7004-21A-2
		Edison Screw (ES or MES)
E27	27 mm	[Medium] Edison Screw	7004-21
		(ES)
E29	29 mm	[Admedium] Edison Screw
		(ES)
E39	39 mm	Single-contact (Mogul)	7004-24-A1
		Giant Edison Screw (GES)
E40	40 mm	(Mogul) Giant Edison	7004-24
		Screw (GES)

Additionally, the base member 151 can be of any form factor configured to support electrical connections, which electrical connections can conform to any of a set of types or standards. For example Table 3 gives standards (see “Type”) and corresponding characteristics, including mechanical spacings between a first pin (e.g., a power pin) and a second pin (e.g., a ground pin).

TABLE 3
		Pin center
Type	Standard	to center	Pin diameter	Usage
G4	IEC 60061-1	4.0	mm	0.65-0.75	mm	MR11 and other
	(7004-72)					small halogens
						of 5/10/20 watt
						and 6/12 volt
GU4	IEC 60061-1	4.0	mm	0.95-1.05	mm
	(7004-108)
GY4	IEC 60061-1	4.0	mm	0.65-0.75	mm
	(7004-72A)
GZ4	IEC 60061-1	4.0	mm	0.95-1.05	mm
	(7004-64)
G5	IEC 60061-1	5	mm			T4 and T5
	(7004-52-5)					fluorescent tubes
G5.3	IEC 60061-1	5.33	mm	1.47-1.65	mm
	(7004-73)
G5.3-	IEC 60061-1
4.8	(7004-126-1)
GU5.3	IEC 60061-1	5.33	mm	1.45-1.6	mm
	(7004-109)
GX5.3	IEC 60061-1	5.33	mm	1.45-1.6	mm	MR16 and other
	(7004-73A)					small halogens
						of 20/35/50 watt
						and 12/24 volt
GY5.3	IEC 60061-1	5.33	mm
	(7004-73B)
G6.35	IEC 60061-1	6.35	mm	0.95-1.05	mm
	(7004-59)
GX6.35	IEC 60061-1	6.35	mm	0.95-1.05	mm
	(7004-59)
GY6.35	IEC 60061-1	6.35	mm	1.2-1.3	mm	Halogen 100 W
	(7004-59)					120 V
GZ6.35	IEC 60061-1	6.35	mm	0.95-1.05	mm
	(7004-59A)
G8		8.0	mm			Halogen 100 W
						120 V
GY8.6		8.6	mm			Halogen 100 W
						120 V
G9	IEC 60061-1	9.0	mm			Halogen 120 V
	(7004-129)					(US)/230 V (EU)
G9.5		9.5	mm	3.10-3.25	mm	Common for
						theatre use,
						several variants
GU10		10	mm			Twist-lock
						120/230-
						volt MR16
						halogen
						lighting of 35/50
						watt, since
						mid-2000s
G12		12.0	mm	2.35	mm	Used in theatre
						and single-end
						metal halide
						lamps
G13		12.7	mm			T8 and T12
						fluorescent tubes
G23		23	mm	2	mm
GU24		24	mm			Twist-lock for
						self-ballasted
						compact
						fluorescents,
						since 2000s
G38		38	mm			Mostly used for
						high-wattage
						theatre lamps
GX53		53	mm			Twist-lock for
						puck-shaped
						under-cabinet
						compact
						fluorescents,
						since 2000s

FIG. 1B is a diagram illustrating construction of a radiation source 120 comprising LED devices.

In certain embodiments, the LED devices (e.g., LED device 115₁, LED device 115₂) emit substantially only red and/or green and/or violet (but not blue) light. The substantially only red and/or green and/or violet emitting LED devices represent one configuration, and other configurations are reasonable and envisioned.

As shown in FIG. 1B, the radiation source 120 is constructed on a submount 111 upon which submount is a layer of sapphire or other optional insulator 112, upon which are disposed one or more conductive contacts (e.g., conductive contact 114₁, conductive contact 114₂), arranged in an array where each conductive contact is spatially separated from other conductive contacts by an isolation gap. Further disposed atop the submount or atop the insulator are one or more deposits (e.g., deposit 153₁, deposit 153₂) of wavelength-modifying material configured to modify the color of the light generated by LED devices. Various mixes of colors can be achieved using a deposit (e.g., deposit 153₁, deposit 153₂) of wavelength-modifying material disposed in proximity to the radiation sources.

FIG. 1B shows LED devices in a linear array, however other array configurations are possible, for example, as described herein. As shown, atop the conductive contacts are LED devices (e.g., LED device 115₁, LED device 115₂). The LED device is but one possibility for a radiation source, and other radiation sources are possible and envisioned, for example a radiation source can be a laser device.

In certain embodiments, the devices and packages disclosed herein include at least one non-polar or at least one semi-polar radiation source (e.g., an LED or laser) disposed on a submount. The starting materials can comprise polar gallium nitride containing materials.

The radiation source 120 is not to be construed as conforming to a specific drawing scale, and in particular, many structural details are not included in FIG. 1B so as not to obscure understanding of the embodiments. The isolation gap serves to facilitate shaping of materials formed in and around the isolation gap, which formation can be by one or more additive processes, or by one or more subtractive processes, or both.

It is to be appreciated that the radiation sources illustrated in FIG. 1B can output light in a variety of wavelengths (e.g., colors) according to various embodiments of the present disclosure. Depending on the application, color balance can be achieved by modifying color generated by LED devices and/or configuring and using wavelength-modifying material (e.g., a phosphor material).

In certain embodiments, color balance can be achieved by modifying the color of the light generated by LED devices by using a deposit (e.g., deposit 153₁, deposit 153₂) of wavelength-modifying material disposed in proximity to the radiation source.

In certain embodiments, the phosphor material may be mixed with an encapsulant such as a silicone material (e.g., encapsulating material 118₁, encapsulating material 118₂) or other encapsulant that distributes phosphor color pixels (e.g., pixel 119₁, pixel 119₂) within a thin layer atop and/or surrounding any one or more faces of the LED devices in the array of LED devices. Other embodiments for providing color pixels can be conveniently constructed using techniques that form deposits of one or more wavelength-modifying materials.

As is known in the art, silicone degrades more quickly when exposed to a high flux of higher-energy photons (e.g., shorter wavelength light). Thus, embodiments that employ lower energy radiation sources (e.g., red or green LEDs) reduce the rate of degradation of the silicone components of an LED lamp. Embodiments employing red and green LEDs are further discussed herein.

FIG. 1C is a diagram illustrating an optical device 150 embodied as a light source 142 constructed using an array of LED devices (e.g., LED device 115₁, LED device 115₂, LED device 115_N, etc.) juxtaposed with a remotely-located instance of a remote structural member 155, the remote structural member 155 having instances of wavelength converting materials (e.g., pixels, deposits) distributed upon or within the volume 156 of the remote structural member 155, which volume is bounded by a remote structural member inner surface 161 and a remote structural member outer surface 163, according to certain embodiments.

In addition to the wavelength converting materials distributed upon or within the volume 156 of the remote structural member 155, some embodiments include deposits of wavelength converting materials (e.g., deposit 153₁, deposit 153₂, deposit 153₃, deposit 153₄, deposit 153₅, etc.) disposed in close proximity to the LED devices. As shown, wavelength-modifying material (e.g., deposit 153₁, deposit 153₂, deposit 153₃, deposit 153₄, deposit 153₅, etc.) can be disposed and distributed in a variety of configurations, including being deposited in a cup structure, or being deposited in a layer disposed atop the LED device.

Individually, and together, these color pixels modify the color of light emitted by the LED devices. For example, the color pixels are used to modify the light from LED devices to appear as white light having a uniform broadband emission (e.g., characterized by a substantially flat emission of light throughout the range of about 380 nm to about 780 nm), which is suitable for general lighting.

In various embodiments, color balance adjustment is accomplished by using pure color pixels, mixing phosphor material, and/or using a uniform layer of phosphor over LED devices, and/or using pixels distributed in a location substantially remote from the LED device, For example, in various embodiments, color balance adjustment is accomplished by using pixels (e.g., blue-emitting pixels) distributed in a location substantially remote from the LED devices (e.g., the blue-emitting pixels being distributed upon or within the volume 156 of the remote structural member 155).

In certain embodiments, wavelength converting processes are facilitated by using one or more pixilated phosphor wavelength-modifying layers (e.g., see FIG. 1D, infra). For example, the pixilated phosphor wavelength-modifying layers can include color patterns. The color patterns of the phosphors disposed within the wavelength-modifying layer may be predetermined based on the measured color balance of the aggregate emitted light. In certain embodiments, an absorption plate is used to perform color correction. In some situations, the absorption plate comprises color absorption material. For example, the absorbing and/or reflective material can be plastic, ink, die, glue, epoxy, and others.

In certain embodiments, the phosphor particles are embedded in a reflective matrix (e.g., the matrix formed by conductive contacts). Such phosphor particles can be disposed on the substrate by deposition. In certain embodiments, the reflective matrix comprises silver or other suitable material. Alternatively, one or more colored pixilated reflector plates (not shown) are provided to adjust aggregate color balance of the light emitted from LED devices aggregated with light emitted from wavelength-modifying materials. In certain embodiments, materials such as aluminum, gold, platinum, chromium, and/or others are deposited to provide color balance.

FIG. 1D is a diagram illustrating an apparatus 160 with a down-converting member having a phosphor mix. As shown, the down-converting member includes a plurality of wavelength-modifying layers (e.g., wavelength-modifying layer 162₁, wavelength-modifying layer 162₂), the wavelength-modifying layers comprising phosphor materials. The phosphor materials are excited by radiation emitted by light source 142. The combination of the colors of the light emissions from the radiations sources and the light emissions from the wavelength-modifying layers and the light emissions from the blue-emitting wavelength conversion materials disposed in or on the dome (e.g., remote structural member 155) produce white-appearing light.

In certain embodiments, the apparatus 160 may be present in embodiments of an LED lamp of the present disclosure. In certain embodiments, of an LED lamp the apparatus 160 may be absent, or, one or more layers of phosphor materials may disposed directly atop an LED device, or otherwise overlaying an LED device in very close proximity to the LED device. For example, an encapsulant can be used to distribute phosphor materials within the encapsulant, and the encapsulant can be disposed in a manner overlaying LED device, and where the encapsulant is disposed in very close proximity to the LED device.

FIG. 1E is a side view 180 illustrating another embodiment having a remote blue phosphor dome for generating white light. As shown, a light source 142 comprises radiation sources that emit some combination of red light and green light and violet light (but not blue light), which radiation sources are provided for radiating light toward a dome (e.g., remote structural member 155). In this embodiment the remote blue phosphor dome (e.g., remote structural member 155) is shaped like a conventional light bulb, which shape is not only aesthetically pleasing, but also the shape serves to produce light that is substantially omni-directional in intensity.

The combination of the colors of the light emissions from the radiation sources produces white-appearing light. For example, the embodiment as shown in side view 180 can comprise violet LEDs in combination with yellow-emitting and/or green-emitting down-converting materials as disposed in encapsulants, or as disposed in deposits 153₁ and 153₂. Additionally, blue-emitting down-converting materials disposed in or on the dome, which blue-emitting down-converting materials absorb violet emissions. The combination of emissions from these sources results in an aggregate color tuning that produces a white-appearing light.

In certain embodiments, the combination of the colors of the light emissions from the radiations sources produces white-appearing light. For example violet LEDs, can be configured in combination with yellow-emitting and/or green-emitting down-converting materials as disposed in encapsulants, and yellow-emitting and/or green-emitting down-converting materials as disposed in or on the dome, which yellow-emitting and/or green-emitting down-converting materials disposed in or on the dome can be mixed with blue-emitting down-converting materials also disposed in or on the dome. The combination of emissions from these sources results in an aggregate color tuning that produces a white-appearing light.

The selected embodiments of bulbs having a remote blue phosphor dome for generating white light are merely exemplary. Other bulb types are envisioned and possible. Table 4 list a subset of possible bulb types for LED lamps.

TABLE 4
Bulb Types for Lamps
Bulb
Category     Type
Incandescent A-Shape
             Candle Bulb
             Globe
             Bulged Reflector
             B-Type
             BA-Type
             G-Type
             J-Type
             S-Type
             SA-Type
             F-Type
             T-Type
             Y-Type
Fluorescent  T-4
             T-5
             T-8
             T-12
             Circline
ANSI         ANSI C
             ANSI G
Halogen      A-Type
             Aluminum Reflector
             Post Lamps (e.g., BT15)
             MR
             PAR
             Bulged Reflector
HID          ED-Type
             ET-Type
             B-Type
             BD-Type
             T-Type
             E-Type
             A-Type
             BT-Type
CFL          Single Twin Tube
             Double Twin Tube
             Triple Twin Tube
             Spiral

FIG. 1F is a top view 190 illustrating a light source 142 apparatus with phosphors disposed on a surface of a heat sink. As shown, wavelength converting materials 153₁, 153₂, and 153₃ are disposed atop the heat sink 152₂ in a pattern around the light source 142.

FIG. 2A is a diagram illustrating an optical device 200 having phosphor materials disposed directly atop an LED device, or in very close proximity to an LED device. In embodiments wherein portions of the final white light spectrum are contributed by direct emission from radiation sources, it is desirable to avoid interaction of such direct emission with any wavelength converting materials (e.g., down-conversion materials, phosphors, wavelength-modifying layers, pixels, etc.). For example, for violet-emitting radiation sources in which the emission is being combined with other radiation sources that are pumping to longer wavelength down-conversion media (e.g., to make broader spectrum light), the down-conversion media can be isolated from the optical path of the violet-emitting LEDs. And, providing such an isolation (e.g., using an isolation barrier) increases efficiency as there are losses (e.g., backscattered light into an LED chip) associated with down-conversion. Instead, in certain embodiments, optical means (e.g., an isolation barrier) are provided to reflect light from the radiation sources toward the desired optical far-field such that the reflected light does not substantially interact with down-conversion media.

One such embodiment is shown in FIG. 2A. As shown, LEDs are placed into recessed regions in a submount (e.g., substrate or package) such that they are optically isolated from one another. Further, light from the violet direct-emitting LEDs 203 does not substantially interact with the encapsulated down-conversion media and, instead, is substantially directed into the desired final emission pattern of the entire lamp (e.g., toward the dome). Conversely, light from the down-converted LEDs (e.g., down-converting LED 204₁, down-converting LED 204₂) is converted locally and directed to the final emission pattern. In addition to providing efficient light collection from the direct-emitting LEDs, this design avoids cascading down-conversion events (e.g., violet down-converted to green, green down-converted to red) which can unnecessarily reduce overall efficiency since quantum yields of down-conversion media are less than 100%.

Light from the individual LEDs are combined together in the far field to provide a uniform broadband emission which is a combination of light from the direct-emitting and down-converting LED chips.

As can be appreciated, as shown in FIG. 2A the embodiment of optical device 200 can be used in an LED lamp comprising a first set of radiation sources configured to emit radiation characterized by a substantially violet wavelength (e.g., violet direct-emitting LEDs 203) and a second set of radiation sources configured to emit radiation characterized by a second wavelength, the second wavelength being longer than 450 nm. Further, the light emitted from violet direct-emitting LEDs 203 and the light emitted from the second set of radiation sources (e.g., down-converting LED 204₁, down-converting LED 204₂) is incident on the remote blue phosphors in or on the dome in an LED lamp, and thus a color-tuned (e.g., white) light is perceived.

The aforementioned remote blue phosphors can be phosphors (see list, below) or other wavelength-modifying materials that serve to absorb at least a portion of radiation emitted by the first set of radiation sources.

FIG. 2B is a diagram illustrating an optical device 250 having red, green, and violet radiation sources. In the embodiment of FIG. 2B, the same benefits pertaining to disposition of radiation sources in proximity to isolation barriers are provided by fabrication of the isolation barriers using an additive, rather than subtractive, process. In an additive processes, the barrier is formed by techniques such as overmolding, deposition/lithography/removal, attachment of a barrier mesh, etc. In subtractive processes, the recesses are formed by techniques such as deposition/lithography/removal and other techniques well known in the art. FIG. 2B shows down-converting (rec) LED chip 204₁, direct-emitting LED chip 203, down-converting (green) LED chip 204₂ overlying a submount with barriers between the chips.

The radiation sources can be implemented using various types of devices, such as light emitting diode devices or laser diode devices. In certain embodiments, the LED devices are fabricated from gallium and nitrogen submounts, such as a GaN submount. As used herein, the term GaN submount is associated with Group III nitride-based materials including GaN, InGaN, AlGaN, or other Group III containing alloys or compositions that are used as starting materials. Such starting materials include polar GaN submounts (e.g., submount 111 where the largest area surface is nominally an (h k l) plane wherein h=k=0, and l is non-zero), non-polar GaN submounts (e.g., submount material where the largest area surface is oriented at an angle ranging from about 80-100 degrees from the polar orientation described above toward an (h k l) plane wherein l=0, and at least one of h and k is non-zero), or semi-polar GaN submounts (e.g., submount material where the largest area surface is oriented at an angle ranging from about +0.1 to 80 degrees or 110-179.9 degrees from the polar orientation described above toward an (h k l) plane wherein l=0, and at least one of h and k is non-zero).

FIG. 3A is a diagram illustrating a conversion process 300. As shown, a radiation source 301 is configured to emit radiation at violet, near ultraviolet, or UV wavelengths. The radiation emitted by radiation source 301 is absorbed by the phosphor materials (e.g., the blue phosphor material 302, the green phosphor material 303, and the red phosphor material 304). Upon absorbing the radiation, the blue phosphor material 302 emits blue light, the green phosphor material 303 emits green light, and the red phosphor material 304 emits red light. As shown, a portion (e.g., portion 310₁, portion 310₂) of the emissions from the blue phosphor are incident on the surrounding phosphors, and are absorbed by the green phosphor material and red phosphor material, which emits green and red light, respectively.

FIG. 3B is a diagram illustrating a conversion process 350. As shown, a radiation source 351 is configured to emit radiation at wavelengths that are shorter than wavelengths in the blue spectrum. The radiation emitted by radiation source 351 is reflected by blue light emitting wavelength converting material 352. And, as shown, the radiation emitted by radiation source 353 (longer wavelengths) is transparent to the blue light emitting wavelength converting material 352, and the radiation emitted by radiation source 353 (longer wavelengths) passes through the blue light emitting wavelength converting material 352.

FIG. 4 is a graph illustrating a light process chart 400 by phosphor material. As shown in FIG. 4, radiation with a wavelength of violet, near violet, or ultraviolet from a radiation source is absorbed by the blue phosphor material, which in turn emits blue light. As shown in FIG. 4, each phosphor is most effective at converting radiation at its particular range of wavelength. And, as shown, some of these ranges overlap.

Moreover, as shown, the absorption curves overlap the emission curves to varying degrees. For example, the blue phosphor absorption curve 455 overlaps the blue phosphor emission curve 456 in a wavelength range substantially centered at 430 nm. In certain embodiments, some of the one or more LED devices that are disposed on a light source 142 are configured to emit substantially blue light so that the emitted blue light serves to pump red-emitting and green-emitting phosphors.

It is to be appreciated that embodiments of the present disclosure maintain the benefits of UV- and/or V-pumped pcLEDs while improving conversion efficiency. In one embodiment, an array of LED chips is provided, and is comprised of two groups. One group of LEDs has a shorter wavelength to enable pumping of a blue phosphor material. The second group of LEDs has a longer wavelength which may, or may not, excite a blue phosphor material, but will excite a green or longer wavelength (e.g., red) phosphor material. The combined effect of the two groups of LEDs in the array is to provide light of desired characteristics such as color (e.g., white) and color rendering. Furthermore, the conversion efficiency achieved in some embodiments will be higher than that of the conventional approach. In particular, the cascading loss of blue photons pumping longer-wavelength phosphors may be reduced by localizing blue phosphor to regions near the short-wavelength LEDs. In addition, the longer-wavelength pump LEDs will contribute to overall higher efficacy by being less susceptible to optical loss mechanisms in GaN, metallization, and packaging materials, as described above.

In certain embodiments, a relatively larger number of LED devices that emit wavelengths longer than blue are combined with a relatively smaller number of LED devices that emit wavelengths shorter than blue, and the combination of those radiation sources with a blue-emitting phosphor combine to produce white light.

Any of the wavelength conversion materials discussed herein can be ceramic or semiconductor particle phosphors, ceramic or semiconductor plate phosphors, organic or inorganic downconverters, upconverters (anti-stokes), nanoparticles, and other materials which provide wavelength conversion. Some examples are listed as follows:

(Sr_n,Ca_1−n)₁₀(PO₄)₆*B₂O₃:Eu²⁺ (wherein 0≦n≦1)

(Ba,Sr,Ca)₅(PO₄)₃(Cl,F,Br,OH):Eu²⁺,Mn²⁺

(Ba,Sr,Ca)BPO₅:Eu²⁺,Mn²⁺

Sr₂Si₃O₈*2SrCl₂:Eu²⁺

(Ca,Sr,Ba)₃MgSi₂O₈:Eu²⁺, Mn²⁺

BaAl₈O₁₃:Eu²⁺

2SrO*0.84P₂O₅*0.16B₂O₃:Eu²⁺

(Ba,Sr,Ca)MgAl₁₀O₁₇:Eu²⁺,Mn²⁺

K₂SiF₆:Mn⁴⁺

(Ba,Sr,Ca)Al₂O₄:Eu²⁺

(Y,Gd,Lu,Sc,La)BO₃:Ce³⁺,Tb³⁺

(Ba,Sr,Ca)₂(Mg,Zn)Si₂O₇:Eu²⁺

(Mg,Ca,Sr,Ba,Zn)₂Si_1−xO_4−2x:Eu²⁺ (wherein 0≦x≦0.2)

CaMgSi₂O₆:Eu²⁺

(Ca,Sr,Ba)MgSi₂O₆:Eu²⁺

(Sr,Ca,Ba)(Al,Ga)₂S₄:Eu²⁺

(Ca,Sr)₈(Mg,Zn)(SiO₄)₄Cl₂:Eu²⁺,Mn²⁺

Na₂Gd₂B₂O₇:Ce³⁺,Tb³⁺

(Sr,Ca,Ba,Mg,Zn)₂P₂O₇:Eu²⁺,Mn²⁺

(Gd,Y,Lu,La)₂O₃:Eu³⁺,Bi³⁺

(Gd,Y,Lu,La)₂O₂S:Eu³⁺,Bi³⁺

(Gd,Y,Lu,La)VO₄:Eu³⁺,Bi³⁺

(Ca,Sr)S:Eu²⁺,Ce³⁺

(Y,Gd,Tb,La,Sm,Pr,Lu)₃(Sc,Al,Ga)_5−nO_12−3/2n:Ce³⁺ (wherein 0≦n≦0.5)

ZnS:Cu+,Cl⁻

(Y,Lu,Th)₃Al₅O₁₂:Ce³⁺

ZnS:Cu⁺,Al³⁺

ZnS:Ag⁺,Al³⁺

ZnS:Ag⁺,Cl⁻

(Ca, Sr) Ga₂S₄:Eu²⁺

SrY₂S₄:Eu²⁺

CaLa₂S₄:Ce³⁺

(Ba,Sr,Ca)MgP₂O₇:Eu²⁺,Mn²⁺

(Y,Lu)₂WO₆:Eu³⁺,Mo⁶⁺

CaWO₄

(Y,Gd,La)₂O₂S:Eu³⁺

(Y,Gd,La)₂O₃:Eu³⁺

(Ba,Sr,Ca)_nSi_nN_n:Eu²⁺ (where 2n+4=3n)

Ca₃(SiO₄)Cl₂:Eu²⁺

(Y,Lu,Gd)_2−nCa_nSi₄N_6+nC_1−n:Ce³⁺, (wherein 0≦n≦0.5)

(Lu,Ca,Li,Mg,Y) α-SiAlON doped with Eu²⁺ and/or Ce³⁺

(Ca,Sr,Ba)SiO₂N₂:Eu²⁺,Ce³⁺

(Sr,Ca)AlSiN₃:Eu²⁺

CaAlSi(ON)₃:Eu²⁺

Sr₁₀(PO₄)₆Cl₂:Eu²⁺

(BaSi)O₁₂N₂:Eu²⁺

M(II)_aSi_bO_cN_dCe:A wherein (6<a<8,8<b<14,13<c<17,5<d<9,0<e<2) and M(II) is a divalent cation of (Be,Mg,Ca,Sr,Ba,Cu,Co,Ni,Pd,Tm,Cd) and A of (Ce,Pr,Nd,Sm,Eu,Gd,Tb,Dy, Ho,Er,Tm,Yb,Lu,Mn,Bi,Sb)

SrSi₂(O,Cl)₂N₂:Eu²⁺

(Ba,Sr)Si₂(O,Cl)₂N₂:Eu²⁺

LiM₂O₈:Eu³⁺ where M=(W or Mo)

For purposes of the application, it is understood that when a phosphor has two or more dopant ions (i.e., those ions following the colon in the above phosphors), this is to mean that the phosphor has at least one (but not necessarily all) of those dopant ions within the material. That is, as understood by those skilled in the art, this type of notation means that the phosphor can include any or all of those specified ions as dopants in the formulation. Further, it is to be understood that nanoparticles, quantum dots, semiconductor particles, and other types of materials can be used as wavelength converting materials.

FIG. 5 is an illustration of an LED system 500 comprising an LED lamp 510, according to some embodiments. The LED lamp 510 is configured such that the total emission color characteristic of the LED lamp is substantially white in color.

The LED system 500 is powered by an AC power source 502, to provide power to a rectifier module 516 (e.g., a bridge rectifier) which in turn is configured to provide a rectified output to an array of radiation emitting devices (e.g., a first array of radiation emitting devices, a second array of radiation emitting devices) comprising a light source 142. A control module 505 is electrically coupled to the first array and second array of radiation emitting devices; and a signal compensating module 514 electrically coupled to the control module 505, the signal compensating module being configured to generate compensation factors based on the signaling of the control module. As shown, the rectifier module 516 and the signal compensating module (and other components) are mounted to a printed circuit board 503. Further, and as shown, the printed circuit board 503 is electrically connected to a power pin 515 mounted within a base member 151, and the base is mechanically coupled to a heat sink 152.

The embodiments disclosed herein can be operated using alternating current that is converted to direct current (as in the foregoing paragraphs), or can be used using alternating current without conversion. Some embodiments deliver DC to power pin 515.

FIG. 6 is a diagram illustrating an optical device embodied as a light source constructed using an array of LEDs in proximity to remote down-converting member having a phosphor mix, according to certain embodiments of the disclosure.

As shown, the embodiment of FIG. 6 depicts an LED lamp comprising a light source 142, which light source is formed of an array having a first plurality of “n” of radiation sources configured to emit radiation characterized by a first wavelength, the first wavelength being substantially violet, and a second plurality of “m” of radiation sources configured to emit radiation characterized by a second wavelength, the second wavelength being substantially violet. The remote structural member 155 serves to support a wavelength converting layer configured to absorb at least a portion of radiation emitted by the first plurality of radiation sources, where the wavelength converting layer has a wavelength emission ranging from about 420 nm to about 520 nm. As shown in FIG. 6, remote structural member 155 includes remote structural member outer surface 163, volume 156, and remote structural member inner surface 161.

In some embodiments, the wavelength converting layer comprises one or more of the following:

• • (Ca, Sr, Ba)MgSi₂O₆:Eu²⁺
  • Ba₃MgSi₂O₈:Eu²⁺
  • Sr₁₀(PO₄)₆C₁₂:Eu²⁺

In certain embodiments, LED lamp comprises “n” radiation sources configured to emit radiation characterized by a range of about 380 nm to about 435 nm. Further, certain embodiments are configured such that the wavelength converting layer comprises blue-emitting down-converting materials disposed in or on the remote structural member (as shown, the remote structural member forms a dome).

The light source 142 can comprise radiation source encapsulating material (e.g., encapsulating material 602₁, encapsulating material 602₂) that overlays at least some of the first plurality of radiation sources and possibly the second plurality of radiation sources, where the encapsulating material comprises silicone and/or epoxy material, and where at least some of the down-converting material serves to absorb radiation emitted by the second plurality of radiation sources. Of course, the number “m” and the number “n” can be varied such that a ratio (m:n) describes the relative mix of the radiation sources. For example, the ratio of the number m to the number n (m:n) can be greater than the ratio 2:1. Or, strictly for example, the ratio of the number m to the number n (m:n) is about 3:1. In various configurations as depicted in FIG. 7, the total emission color characteristic of the LED lamp is substantially white in color.

In certain embodiments, the wavelength converting layer as is distributed upon or within the volume and has a relative absorption strength of less than 50% of a peak absorption strength of the first wavelength converting layer when measured against the wavelength emitted by the second plurality of radiation sources.

Other configurations are reasonable and envisioned. For example:

• • configurations where the down-converting material emits radiation with a wavelength longer than about 460 nm and shorter than about 600 nm.
  • configurations where down-converting material disposed on the m radiation sources emits radiation with a wavelength longer than about 550 nm and shorter than about 750 nm.
  • configurations where the m radiation sources consist of k and l sources such that k+l=m, and the k sources have an encapsulating material
  • configurations where an additional down-converting material is disposed in or on the remote structural member (e.g., other than blue-emitting down-converting material).

In certain configurations down-converting material is disposed on a portion of the lamp such that the radiation from either the m or n radiation sources is not absorbed without first undergoing either an optical scattering or optical reflection. It is also possible that the down-converting material (e.g., the additional down-converting material) is substantially excited by the first down-converting material disposed on the remote structural member.

Even still more light process can occur within the practice of the embodiments, namely, processes where the additional down converting materials have a peak emission wavelength ranging from about 580 nm to about 680 nm. And/or where the down-converting material has an emission full-width at half maximum spectra less than about 80 nm, and/or where the down-converting material has an emission full-width at half maximum spectra less than about 60 nm, or less than about 40 nm.

The down-converting material can comprise down-converting material in the form of a quantum dot material.

Other configurations of the LED lamp are possible including embodiments where a first plurality of n of radiation sources are configured to emit radiation characterized as being substantially blue; and a second plurality of m of radiation sources are configured to emit radiation characterized as being substantially violet, and further, where a first wavelength converting layer is configured to absorb at least a portion of radiation emitted by the second plurality of radiation sources, while the first wavelength converting layer has a wavelength emission ranging from about 500 nm to about 750 nm.

FIG. 7 is a diagram 700 showing a relative absorption strength based on measured intensity (e.g., intensity ordinate 710) as a function of wavelength (e.g., wavelength abscissa 720) for a particular spectrum range of light. A relative absorption strength of 50% of a peak absorption strength is shown as covering a range of wavelengths (“P”, as shown) centered about a given peak wavelength (e.g., peak 730).

FIG. 8 depicts a block diagram of a system to perform certain functions for manufacturing an LED lamp. As an option, the present system 800 may be implemented in the context of the architecture and functionality of the embodiments described herein. Of course, however, the system 800 or any operation therein may be carried out in any desired environment. The modules of the system can, individually or in combination, perform manufacturing method steps within system 800. Any method steps performed within system 800 may be performed in any order unless as may be specified in the claims. As shown, FIG. 8 implements a process for manufacturing an LED lamp comprising: providing a first plurality of n of radiation sources configured to emit radiation characterized by a first wavelength, the first wavelength being substantially violet (see step 810), providing a second plurality of m of radiation sources configured to emit radiation characterized by a second wavelength, the second wavelength being substantially violet (see step 820), and providing a first wavelength converting layer configured to absorb at least a portion of radiation emitted by the first plurality of radiation sources, the first wavelength converting layer having a wavelength emission ranging from about 420 nm to about 520 nm (see step 830).

FIG. 9A depicts a system 900 to perform certain functions of an LED lamp. As an option, the present system 900 may be implemented in the context of the architecture and functionality of the embodiments described herein. Of course, however, the system 900 or any operation therein may be carried out in any desired environment.

As shown in FIG. 9A, blue-emitting down-converting materials are disposed on the remote structural member outer surface 163 or within the volume 156 of the remote structural member forming a dome. And, as shown, yellow-emitting wavelength-converting materials are disposed on a remote structural member inner surface 161. Accordingly, the appearance of the dome as viewed in natural light (e.g., sunlight) would be substantially white or cool white. The wavelength converting processes for producing substantially white or cool white color under ambient light conditions are depicted as cool white spectrum 910 in FIG. 9B, according to certain embodiments.

In operation (e.g., when the light source is on), the light source 142 produces incident light from active LEDs (see light source emission spectrum 144), a first portion of the LED emission spectrum incident light is down-converted by the blue-emitting down-converting materials disposed in or on the dome, and a second portion of the incident light is down-converted by yellow-emitting wavelength-converting materials disposed the remote structural member inner surface 161. The combination of the emitted light from the light source 142 and emitted light from the down-converting materials combines to produce a white-appearing light (e.g., the warm white spectrum 920 of FIG. 9C, or the LED lamp emission spectrum, as shown in FIG. 9D).

As disclosed herein, the combination of the colors of the light emissions from the radiations sources and from the wavelength-converting materials produce white-appearing light when the LED lamp is in operation. And, the combination of yellow-emitting and/or green-emitting down-converting materials with blue-emitting down-converting materials on the remote structural member results in an aggregate color tuning that contributes to a white-appearing shade when the LED lamp is not in operation. The whiteness can be tuned by selecting the types and proportions of the yellow-emitting and/or green-emitting down-converting materials with respect to the blue-emitting down-converting materials, and/or with respect to other wavelength-converting materials, including red-emitting down-converting materials.

For example, an LED lamp can be configured such that a first amount p of first wavelength converting material is selected and a second amount q of second wavelength converting material is selected such that the total amount and ratio (first amount p:second amount q) are sufficient to provide a white shade under natural light. Moreover, the same amount and ratio (first amount p:second amount q) serves to provide an LED lamp emission that has a warm white emission spectrum when combined with the LED source emission internal to the lamp (e.g., emissions from the light source 142). The warm white emission spectrum is exemplified in the warm white spectrum 920 as shown in FIG. 9C.

FIG. 9D depicts a chromaticity chart 960. The figure depicts black body loci (also called Planckian loci), which black body loci represent colors (as shown) through a range from deep red through orange, yellowish white, warm white, white, and cool white.

At least some of a range of shades throughout the black body loci are tunable by the relative measures of colors (e.g., red, green/yellow, blue). In the disclosed embodiments of LED lamps, color tuning to achieve a particular (e.g., desired) white shade of the LED lamp under conditions of ambient lighting can be accomplished by selecting the relative amounts of wavelength-emitting materials. Similarly, when those relative amounts of wavelength-emitting materials are excited by the light source 142, the aggregate LED lamp emission corresponds to a particular (e.g., desired) white light color, such as depicted by the warm white lamp emission spectrum (as shown).

As one specific example, an LED lamp can be configured to achieve a particular white shade by selecting a first amount p of first wavelength converting material (e.g., a blue phosphor) and selecting a second amount q of second wavelength converting material (e.g., a yellow phosphor). In certain cases, a third wavelength converting material (e.g., a red phosphor) can be mixed in to achieve the desired tunable white shade. The amounts p and q are selected to achieve (1) the desired (e.g., cool white) shade of the LED lamp under ambient light conditions, and (2) the desired LED lamp emission spectrum when the LED lamp is in operation (e.g., when the light source is on and its emission is combined with the remote phosphor emission).

In certain embodiments, various pattern and/or arrangement for different radiation sources can be used. The above description and illustrations should not be taken as limiting the scope of the present disclosure which is defined by the appended claims.

Claims

1. An LED lamp comprising: a first plurality of n radiation sources configured to emit radiation characterized by a first wavelength, the first wavelength being substantially violet;a second plurality of m radiation sources configured to emit radiation characterized by a second wavelength, the second wavelength being substantially violet; anda first wavelength converting layer configured to absorb at least a portion of the radiation emitted by the first plurality of radiation sources, the first wavelength converting layer having an emission wavelength ranging from about 420 nm to about 520 nm.

2. The LED lamp of claim 1, wherein the first wavelength is in a first range from about 380 nm to about 435 nm.

3. The LED lamp of claim 1, wherein first wavelength converting layer comprises blue-emitting down-converting materials disposed in or on a remote structural member, the remote structural member forming a dome.

4. The LED lamp of claim 1, further comprising an encapsulating material overlaying the first plurality of radiation sources and the second plurality of radiation sources, the encapsulating material comprising a material selected from silicone, epoxy, and a combination thereof.

5. The LED lamp of claim 1, wherein the first plurality of radiation sources and the second plurality of radiation sources comprises a light emitting diode.

6. The LED lamp of claim 1, wherein a ratio of m to n (m:n) is greater than 2:1.

7. The LED lamp of claim 1, wherein a total emission color characteristic of the LED lamp is substantially a white color.

8. The LED lamp of claim 1, wherein a ratio of m to n (m:n) is about 3:1.

9. The LED lamp of claim 1, further comprising a rectifier module.

10. The LED lamp of claim 1, further comprising a base.

11. The LED lamp of claim 1, wherein the first wavelength converting layer is characterized by a relative absorption strength of less than 50% of a peak absorption strength of the first wavelength converting layer at the wavelength emitted by the second plurality of radiation sources.

12. The LED lamp of claim 1, wherein the second plurality of radiation sources is configured with an encapsulating material comprising at least one down-converting material configured to absorb at least a portion of the radiation emitted by the second plurality of radiation sources.

13. The LED lamp of claim 12, wherein the at least one down-converting material emits radiation with a wavelength longer than about 460 nm and shorter than about 600 nm.

14. The LED lamp of claim 12, wherein the at least one down-converting material emits radiation with a wavelength longer than about 550 nm and shorter than about 750 nm.

15. The LED lamp of claim 12, wherein the second plurality of radiation sources comprise k+l sources, wherein k+l=m; and the k sources comprise an encapsulating material comprising the at least one down-converting material that emits radiation with a wavelength longer than about 460 nm and shorter than about 600 nm.

16. The LED lamp of claim 12, wherein the second plurality of radiation sources comprise k+l sources, wherein k+l=m, and the 1 sources comprise an encapsulating material comprising at least one down-converting material that emits radiation with a wavelength longer than about 550 nm and shorter than about 750 nm.

17. The LED lamp of claim 12, comprising a second down-converting material disposed on a remote structural member.

18. The LED lamp of claim 12, comprising a second down-converting material disposed on a portion of the lamp such that the radiation from one of the first radiation sources and the second radiation source is not absorbed without first undergoing either an optical scattering or optical reflection.

19. An LED lamp comprising: a first plurality of n radiation sources configured to emit radiation characterized by a first wavelength, the first wavelength being substantially blue; anda second plurality of m radiation sources configured to emit radiation characterized by a second wavelength, the second wavelength being substantially violet; anda first wavelength converting layer configured to absorb at least a portion of radiation emitted by the second plurality of radiation sources, the first wavelength converting layer having an emission wavelength ranging from about 500 nm to about 750 nm.

20. The LED lamp of claim 19, wherein the first wavelength converting layer comprises down-converting materials disposed in or on a remote structural member, the remote structural member forming a dome.

21. An LED lamp with an outer surface having a white appearance under ambient light, comprising: a light source;an outer surface, the outer surface positioned to form a remote structural member;a first wavelength converting layer disposed on the remote structural member, the first wavelength converting layer configured to absorb at least a portion of radiation emitted by the light source, the first wavelength converting layer having an emission wavelength ranging from about 420 nm to about 520 nm; anda second wavelength converting layer disposed on the remote structural member, the second wavelength converting layer having an emission wavelength ranging from about 490 nm to about 630 nm.

22. The LED lamp of claim 21, wherein a first amount p of the first wavelength converting material and a second amount q of the second wavelength converting material are selected in a ratio p:q to provide a white appearance under ambient light.