Title of Invention

A PLASMA ELECTRODE-LESS LAMP AND METHOD OF FABRICATING A PLASMA ELECTRODE-LESS LAMP

Abstract Described is a plasma electrode-less lamp. The device comprises an electromagnetic resonator and an electromagnetic radiation source conductively connected with the electromagnetic resonator. The device further comprises a pair of field probes, the field probes conductively connected with the electromagnetic resonator. A gas-fill vessel is formed from a closed, transparent body, forming a cavity. The gas-fill vessel is not contiguous with (detached from) the electromagnetic resonator and is capacitively coupled with the field probes. The gas-fill vessel further contains a gas within the cavity, whereby the gas is induced to emit light when electromagnetic radiation from the electromagnetic radiation source resonates inside the electromagnetic resonator, the electromagnetic resonator capacitively coupling the electromagnetic radiation to the gas, which becomes a plasma and emits light.
Full Text [0001] EXTERNAL RESONATOR/CAVITY ELECTRODE-LESS PLASMA LAMP
AND METHOD OF EXCITING WITH RADIO-FREQUENCY ENERGY
[0002] PRIORITY CLAIM
[0003] The present invention is a non-provisional patent application, claiming the
benefit of priority of U.S. Provisional Application No. 60/723,144, filed on October
04,2005, entitled, "External Resonator/Cavity Electrode-less Plasma Lamp and
Method of Exciting with Radio-Frequency Energy."
[0004] FIELD OF INVENTION
[0005] The field of the present invention relates to devices and methods for generating
light, more particularly to the field of plasma lamps, and still more particularly to
plasma lamps driven by a radio-frequency source without the use of internal
electrodes or surrounding dielectric bodies that enhance electromagnetic field
coupling. Additionally, the field of the present invention relates to devices and
methods where the lamp is not incorporated or a subset of a microwave resonator, a
cavity or a waveguide, in particular the lamp and resonator or cavity structure are
not geometrically contiguous.
[0006] BACKGROUND OF INVENTION
[0007] Plasma lamps provide extremely bright, broadband light, and are useful in
applications such as projection systems, industrial processing, and general
illumination. The typical plasma lamp manufactured today contains a mixture of gas
and trace substances that are excited to form a plasma. Plasma interaction with the
trace substance (Selenium or other) gives rise to light in the UV, visible, and near
infrared portions of the electromagnetic spectrum. Gas ionization resulting in
plasma formation is accomplished by passing a high-current through closely-spaced
electrodes contained within the vessel that is the gas fill reservoir. This
arrangement, however, suffers from electrode deterioration due to sputtering, and
therefore exhibits a limited lifetime.

[0008]
[0009] Electrode-less plasma lamps driven by microwave sources have been disclosed
in the prior art For example, both U.S. Patent Number 6.617.806B2 (Kirkpatrick
et. al.) and US Patent Application Number US2001/0035720A1 (Guthrie et. al.)
disclose similar basic configurations of a gas fill encased either in a bulb or a sealed
recess within a dielectric body forming a waveguide, with microwave energy being
provided by a source such as a magnetron and introduced into the waveguide and
heating the plasma resistively. U.S. Patent Number 6,737,809B2 (Espiau et. al.)
discloses a somewhat different arrangement whereby the plasma-enclosing bulb and
the dielectric cavity form a part of a resonant microwave circuit with a microwave
amplifier to provide the excitation.
[00010] In each of the embodiments described above, a dielectric or metal/dielectric
waveguiding body forming—whether deliberately or unwittingly—a resonant cavity
surrounding the bulb containing the plasma is used. The driving microwave energy
is introduced into the waveguide body using various probing means well-known to
those skilled in the art of microwave engineering. The waveguide body surrounding
the bulb brings with it a host of difficulties including wasted light, lamp size related
to resonance or excitation frequency, manufacturing obstacles, and related costs.
These obstacles are overcome by the approach presented herein.
[00011] SUMMARY OF INVENTION
[00012] This invention provides distinct advantages over electrode-less plasma lamps in
the background art. Firstly, using an external resonator or cavity structure enables
lamp operation at frequencies well below lGHz, lowering lamp cost and extending
the range of lamp applications. Removal of the lamp from the dielectric waveguide
body furthermore allows increased light harvesting, a serious drawback of the
approaches previously discussed in the art. Finally, by removing the fundamental
compromise between dimensions of the dielectric waveguide body and operating
frequency, it is possible to substantially reduce lamp size to again extend the

applications range. Moreover, in addition to these three substantial advantages,
these lamps still form bright, spectrally stable sources that exhibit energy efficiency
and prolonged lifetimes. Rather than incorporating the gas fill (lamp) as a subset of
the dielectric waveguiding body, the lamp is capacitively driven by an external
resonant circuit that delivers the required field to the gas fill to sustain the plasma.
[00013] Briefly, the lamp includes an amplified RF source operating in the frequency
range between approximately 10MHz to 10GHz and emitting powers approximately
as great as 10W. The lamp further includes an external resonator in the
embodiment of a lumped circuit or dielectric cavity (an example of which might be
a can resonator), which follows the RF source and is intended to provide the
necessary potential drop to sustain the plasma. In its simplest implementation the
resonant circuit comprises a parallel resistor, capacitor, inductor network, but is not
limited to this configuration, and all other configurations are meant for inclusion by
extension. The lamp further includes a closed vessel; the approximate diameter of
the vessel might be 6 mm, but, as can be appreciated by one of ordinary skill in the
art, this size varies depending on the application. This closed vessel contains the
gas fill. Portions of the outside walls of the vessel can be coated or in intimate
mechanical contact with a metallic layer used to capacitively couple the RF energy
to the plasma.
[00014] An outline for producing light with the lamp includes, but is not limited to, the
steps: a) RF/microwave energy is directed at a resonator, which is not
geometrically contiguous with (detached from) the glass fill, the resonator may be
in the form of a lumped circuit or distributed structure; b) field probes situated at
positions where the field strength is maximum in the resonator direct the RF energy
to the bulb; and c) the RF energy is capacitively coupled to the plasma through the
metallic contacts on the gas fill vessel.

[00015] In one aspect, the lamp comprises an electromagnetic resonator and an
electromagnetic radiation source conductively connected with the electromagnetic
resonator. A first field probe and second field probe are conductively connected
with the electromagnetic resonator. The lamp also includes a gas-fill vessel not
contiguous with (detached from) the electromagnetic resonator with a closed,
transparent body. The transparent body has an outer surface and an inner surface,
the inner surface forming a cavity. The gas fill vessel is capacitively coupled with
the first field probe and the second field probe. A fiuorophor is contained within the
cavity of the gas-fill vessel. The fiuorophor fluoresces when electromagnetic
radiation from the electromagnetic radiation source resonates inside the
electromagnetic resonator, which capacitively couples the electromagnetic radiation
to the fiuorophor.
[00016] In another aspect, the lamp includes a first conductor and a second conductor
that form a transmission line. Each conductor has a conductor probe end
conductively connected with a field probe and a conductor vessel end connected
with the gas fill vessel. Thus the transmission line formed by the two conductors
capacitively couples electromagnetic radiation into the gas-fill vessel.
[00017] In yet another aspect, the first conductor and the second conductor are
constructed and arranged to impedance-match the electromagnetic resonator to the
gas-fill vessel.
[00018] In yet another aspect, the lamp includes an impedance-matching network. The
impedance-matching network conductively connects the first field probe with the
gas fill vessel and the second field probe with the gas-fill vessel. Thus the
impedance-matching network enables a substantially maximal amount of energy to
be transferred to the gas-fill vessel when energy is stored in the electromagnetic
resonator.

[00019] In yet another aspect, the gas-fill vessel contains a gas. The electromagnetic
resonator capacitively couples the electromagnetic radiation to the fluorophor by
inducing the gas to become a plasma, which then transfers energy to the fluorophor,
causing the fluorophor to fluoresce.
[00020] In yet another aspect, the electromagnetic radiation source is a tunable
oscillator, which is tuned to maximize light output
[00021 ] In yet another aspect, the electromagnetic resonator is a lumped circuit
comprising lumped circuit components.
[00022] In yet another aspect, the electromagnetic resonator is a distributed structure.
[00023] In yet another aspect, the electromagnetic resonator comprises both lumped
circuit components and distributed structures.
[00024] In yet another aspect, the electromagnetic resonator is tunable, whereby the
electromagnetic resonator is tuned to maximize light output
[00025] In yet another aspect, the gas-fill vessel includes a covered portion of its outer
surface. A refractory veneer is connected with the covered portion of the outer
surface of the gas-fill vessel, and a conductive veneer is connected with the
refractory veneer so that the refractory veneer is between the covered portion and
the conductive veneer. Either the first field probe or the second field probe is
conductively connected with the conductive veneer. In this aspect, the refractory
veneer acts as a diffusion barrier between the gas-fill vessel and the conductive
veneer.
[00026] In yet another aspect, the outer surface of the gas-fill vessel's transparent body
includes a reflective portion and a non-reflective portion. Emitted light is made to

reflect from the reflective portion and escape through the non-reflective portion,
forcing the light to escape into a substantially smaller solid angle.
[00027] Finally, the present invention also comprises a method for forming and using the
device. The method for forming the device comprises a plurality of acts of forming
and attaching the various parts as described herein.
[00028] BRIEF DESCRIPTION OF THE DRAWINGS
[00029] The objects, features and advantages of the present invention will be apparent
from the following detailed descriptions of the various aspects of the invention in
conjunction with reference to the following drawings, where:
[00030] FIG. 1 is a generalized schematic of the proposed invention, an RF source drives
a resonator, which, in turn, drives a gas-fill vessel not geometrically contiguous
with (detached from) the resonator;
[00031 ] FIG. 2a is a lumped Resistor/Inductor/Capacitor (RLC) electrode-less plasma
lamp driven by an RF source, as opposed to being a subset of an RF oscillator;
[00032] FIG. 2b is a lumped RLC electrode-less plasma lamp driven by a(n) Radio
Frequency (RF) source; the RLC resonator is composed of tunable elements
controlled by a tuning circuit, with feedback providing information to the tuning
circuit, which, in turn, tunes the resonator to maximize the RF energy delivered to
the gas-fill vessel;
[00033] FIG. 3 depicts an electrode-less plasma lamp driven by sampling the field in the
dielectric resonator of a Dielectric Resonator Oscillator (DRO);

[00034] FIG. 4a is a gas-fill vessel which includes end caps that act as diffusion barriers,
where ends are defined by the metallic electrodes (direction of the RF field across
the gas-fill vessel); and
[00035] FIG. 4b is a gas-fill vessel—with diffusion barrier ends—in a configuration for
increased light harvesting; one vessel wall includes an optical reflector made from a
suitably reflective and non-absorptive material.
[00036] DETAILED DESCRIPTION
[00037] The present invention relates to a plasma lamp and, more particularly, to a
plasma lamp without electrodes and having a gas-fill vessel that is not contiguous
with (detached from) any RF/microwave cavities or resonators. The following
description is presented to enable one of ordinary skill in the art to make and use the
invention and to incorporate it in the context of particular applications. Various
modifications, as well as a variety of uses in different applications will be readily
apparent to those skilled in the art, and the general principles defined herein may be
applied to a wide range of embodiments. Thus, the present invention is not
intended to be limited to the embodiments presented, but is to be accorded the
widest scope consistent with the principles and novel features disclosed herein.
[00038] In the following detailed description, numerous specific details are set forth in
order to provide a more thorough understanding of the present invention. However,
it will be apparent to one skilled in the art that the present invention may be
practiced without necessarily being limited to these specific details. In other
instances, well-known structures and devices are shown in block diagram form,
rather than in detail, in order to avoid obscuring the present invention.
[00039] The reader's attention is directed to all papers and documents which are filed
concurrently with this specification and which are open to public inspection with
this specification, and the contents of all such papers and documents are

incorporated herein by reference. All the features disclosed in this specification,
(including any accompanying claims, abstract, and drawings) may be replaced by
alternative features serving the same, equivalent or similar purpose, unless expressly
stated otherwise. Thus, unless expressly stated otherwise, each feature disclosed is
one example only of a generic series of equivalent or similar features.
[00040] Furthermore, any element in a claim that does not explicitly state "means for"
performing a specified function, or "step for" performing a specific function, is not
to be interpreted as a "means" or "step" clause as specified in 35 U.S.C. Section
112, Paragraph 6. In particular, the use of "step of or "act of in the claims herein
is not intended to invoke the provisions of 35 U.S.C. 112, Paragraph 6.
[00041] Please note, if used, the labels left, right, front, back, top, bottom, forward,
.reverse, clockwise and counter clockwise have been used for convenience purposes
only and are not intended to imply any particular fixed direction. Instead, they are
used to reflect relative locations and/or directions between various portions of an
object.
[00042] (1) Glossary
[00043] Before describing the specific details of the present invention, a glossary is
provided in which various terms used herein and in the claims are defined. The
glossary provided is intended to provide the reader with a general understanding of
the intended meaning of the terms, but is not intended to convey the entire scope of
each term. Rather, the glossary is intended to supplement the rest of the
specification in more accurately explaining the terms used.
[00044] Distributed Structure- The term "distributed structure" as used with respect to
this invention refers to an RF/microwave structure, the dimensions of which are

comparable to the wavelength of the frequency source. This could be a length of a
transmission line or a resonator.
[00045] Feedback-induced Oscillations- The term "feedback-induced oscillations" as
used with respect to this invention refers to feeding back (in an additive
sense/substantially in-phase) part of the output power of an amplifier back into the
input of the amplifier with sufficient gain on the positive-feedback to make the
amplifier oscillate.
[00046] Fluorescence - The term "fluorescence" as used with respect to this invention
refers to the emission of radiation associated with the relaxation of an atom or
molecule from an excited energy level to a lower (usually ground state) level.
[00047] Fluorophor- The term "fluorophor" as used with respect to this invention refers
to a material that undergoes fluorescence (see above definition of fluorescence).
[00048] Lumped Circuit- The term "lumped circuit" as used with respect to this
invention refers to a circuit comprising actual resistors, capacitors and inductors as
opposed to, for example, a transmission line or a dielectric resonator (circuit
components that are comparable in size to the wavelength of the RF source).
[00049] Lumped Parallel Oscillator- The term "lumped parallel oscillator" as used with
respect to this invention refers to resistors, capacitors, and inductors that are
connected in parallel to form a resonator.
[00050] Parasitics- The term "parasitics" as used with respect to this invention refers to
non-idealities in the components, in this case, used to distribute energy. These are
"extra" resistances, capacitances and inductances of the components that effectively
waste the power of the RF/microwave source.

[00051 ] Refractory- The term "refractory" as used with respect to this invention refers to
a material having the ability to retain its physical shape and chemical identity when
subjected to high temperatures.
[00052] (2) Specific Aspects
[00053] FIG. 1 illustrates a general/generic embodiment of the electrode-less lamp. An
electromagnetic resonator 110 is driven by an electromagnetic radiation source 120,
the radiation being in the microwave/RF portions of the electromagnetic spectrum.
The RF/microwave energy stored in the electromagnetic resonator 110 gives rise to
large electric fields, which are sampled by a field first field probe 140 and second
field probe 150. As can be appreciated by one of ordinary skill in the art, it does not
matter which of the field probes is designated "first" or "second." Subsequently the
electric field is distributed to the gas-fill vessel 130, which is not geometrically
contiguous with (detached from) the electromagnetic resonator 110. The gas-fill
vessel 130 includes a cavity 160 that contains a gas. The gas transitions into a
plasma state under the presence of the RF energy; this gas is normally a noble gas
but is not limited to one of the noble gases. Subsequent energy transfer between the
plasma and the fluorophor (light emitter), also included in the gas-fill vessel 130,
gives rise to intense visible, UV, or infrared radiation, usable in a multitude of
lighting applications.
[00054] In one embodiment, the RF/microwave electromagnetic radiation source 120
comprises an energy source followed by several stages of amplification so that the
overall power delivered to the electromagnetic resonator 110 is in the 10 to 200W
range, although powers outside this range might be necessary depending on the
application and would also be accessible with this invention. Although the
electromagnetic radiation source 120 is shown as an agglomeration of solid state
electronics, it may also comprise other sources known to one of ordinary skill in the
art. In another embodiment, the RF/microwave electromagnetic radiation source
120 comprises an RF/microwave oscillator. Feedback between the amplification

stages 210 and the electromagnetic resonator 110 is used to build up a sustained RF
energy source that drives the electromagnetic resonator 110 and consequently the
gas-fill vessel 130.
[0005 5] The electromagnetic resonator 110 can be embodied as a distributed
RF/microwave structure, such as a can resonator, or as a lumped circuit, such as a
parallel RLC network. In the case of a distributed resonator, the RF/microwave
electric field varies in amplitude as a function of position within it In this case, the
first and second field probes 140 and 150 are positioned so as to sample the
maximum field amplitude within the electromagnetic resonator. For a lumped
parallel resonator the field is independent of position along it and first and second
field probes 140 and 150 can be placed arbitrarily. The electromagnetic resonator
110 has a distinctive frequency behavior enabling energy storage over a limited
frequency range. In the case of a distributed structure this frequency range is
determined by geometry and material parameters, whereas in the case of a lumped
resonator, this same frequency of operation is determined by circuit topology and
component values.
[00056] As can be appreciated by one of ordinary skill in the art, plasma lamp operation
substantially near 100MHz enables RF energy distribution with minimal impact
from parasitics, which are non-idealities in the components used to distribute
energy. These parasitics are typically a function of frequency and increase in
severity with increasing frequency. Additionally, by operating at a lower frequency,
lamp cost can be reduced enabling penetration of this technology into the existing
lamp socket markets. However, operation in this frequency range places a
constraint on lamp geometry/material parameters in order to effectively couple RF
energy into the plasma, thereby limiting the range of applications. As operational
frequency is increased this constraint is relaxed enabling the use of smaller light
bulbs, In particular as high-frequency, high-power amplifiers mature, dropping

their cost, operation substantially near l0GHz 'will facilitate effective light point
sources, which are desirable in many high-end applications.
[00057] FIG. 2A illustrates an embodiment of the plasma electrode-less lamp where the
electromagnetic resonator 110 is a lumped resonator 200. In this case the lumped
resonator 200 comprises a parallel RLC circuit that stores the energy delivered by
the amplification stages 210 and consequently develops a large potential drop. This
implementation is preferred in the lower operating frequency range of the lamp.
RF/microwave energy is delivered to the gas-fill vessel 130, which gives off intense
radiation. In this embodiment amplification stages 210 are driven by an
RF/microwave source 120 at the resonance frequency of the electromagnetic
lumped resonator 200. Lamp operation at frequencies substantially less than 100
MHz enables RF distribution with minimal parasitic impact, which makes the use of
simple cabling to deliver RF energy to the gas-fill vessel feasible.
[00058] FIG. 2B illustrates an embodiment of the plasma electrode-less lamp with a
tunable lumped resonator 240. As with FIG. 2A, the resonator is driven by an
electromagnetic radiation source 120 and amplification stage 210 combination. An
RF/microwave sensor 230 measures the amount of energy not delivered to the gas-
fill vessel 130 and provides feedback to a tuning circuit 220. In turn, the tuning
circuit adjusts the tunable lumped resonator's 240 resonance frequency to maximize
the energy delivered to the gas-fill vessel 130. This enables a reduction in wasted
RF energy and therefore provides enhanced lamp efficiency. Feedback approaches
are not limited to lumped resonators and can be extended to distributed structures.
[00059] FIG 3 illustrates an embodiment of the plasma electrode-less lamp incorporating
a Dielectric Resonant Oscillator (DRO) 330. In this case RF/microwave energy is
sustained through feedback-induced oscillation. The DRO 330 couples energy to
and from the electromagnetic resonator 110 through coupling structures 350 and
360. The sampled RF/microwave field is fed back to the amplification stages 210,

in so doing the sample signal passes through delay elements 340 and loss elements
320. Provided the amplification stages can overcome the loop loss, oscillation will
initiate at a frequency determined by the physical and geometrical properties of the
resonator. First and second field probes 140 and 150 are positioned to sample the
maximum electric field within the electromagnetic resonator 110; the sampled field
is subsequently delivered to the gas-fill vessel 130. As can be appreciated by one of
ordinary skill in the art, by separating the dielectric resonator (electromagnetic
resonator 110) from the bulb (gas-fill vessel 130), the lamp design becomes much
• more flexible. As operating frequency is lowered, the size of the dielectric
resonator needed increases, but by using much higher dielectric constant materials
one can actually maintain or reduce the size of the dielectric resonator without
concern about thermal mismatch between the dielectric resonator material and the
bulb.
[00060] FIG. 4A illustrates one possible embodiment of a gas-fill vessel 130. It
comprises a transparent body 400a with an inner surface 400b and outer surface
400c. The transparent body can be made of quartz or some other suitably
transparent and refractory material. A refractory veneer 420 covers a portion of the
gas-fill vessel 130. This refractory veneer 420 can be made of suitable dielectrics,
non-limiting examples of which include alumina, barium titanium oxide, titanium
oxide, and silicon nitride; the refractory veneer could also be made from a refractory
metal, non-limiting examples of which include tungsten, tantalum and titanium. A
conductive veneer 410 is affixed onto the dielectric veneer 420; the conductive
veneer 410 serves as a metal electrode. Radiation escapes the gas-fill vessel
through the transparent body 400a. RF energy is capacitively coupled to the gas
within the gas-fill vessel 130 through the conductive veneers 410, which act as
metallic electrodes.
[00061 ] FIG. 4B shows a second embodiment of the gas-fill vessel 130, in which it is
formed with a trapezoidal geometry. The gas and fluorophor (light emitter) are

enclosed by quartz side walls of the transparent body 400a. The ends of the
trapezoidal cavity of the gas-fill vessel 130 are capped by a refractory veneer 420
(dielectric diffusion barrier), on which has been deposited a conductive veneer 410
(metallic electrode). The conductive veneer 410 and refractory veneer 420 form
optical surfaces from which light reflects with minimal scattering and absorption.
Additionally the gas-fill vessel 130 has a reflective portion 430, which can be made
by depositing metal or dielectric layers on the quartz side walls of the transparent
body 400a; the reflective portion enhances light harvesting as it exits through the
transparent portion 440 of the gas-fill vessel 130.
[00062] As can be appreciated by one skilled in the art, although the above description
utilized many specific measurements and parameters, the invention is not limited
thereto and is to be afforded the widest scope possible. Additionally, although the
device is described as being used as a lamp which produces visible light for
illumination, it is not intended to be limited to this region of the electromagnetic
spectrum and can be incorporated into a wide array of devices for a large variety of
uses, including uses which require illumination in the ultra-violet and infrared
portions of the electromagnetic spectrum.

CLAIMS
What is claimed is:
1. A plasma electrode-less lamp, comprising:
an electromagnetic resonator;
an electromagnetic radiation source conductively connected with the
electromagnetic resonator;
a first field probe conductively connected with the electromagnetic
resonator;
a second field probe conductively connected with the electromagnetic
resonator;
a gas-fill vessel with a closed, transparent body having an outer surface and
an inner surface, the inner surface forming a cavity, the gas fill vessel detached from
the electromagnetic resonator and capacitively coupled with the first field probe and
the second field probe; and
a fluorophor contained within the cavity of the gas-fill vessel, whereby the
fluorophor fluoresces when electromagnetic radiation from the electromagnetic
radiation source resonates inside the electromagnetic resonator, the electromagnetic
resonator capacitively coupling the electromagnetic radiation to the fluorophor.
2. A plasma electrode-less lamp as set forth in Claim 1, further comprising:
a first conductor with a first conductor probe end conductively connected
with the first field probe and a first conductor vessel end connected with the gas fill
vessel; and
a second conductor with a second conductor probe end conductively
connected with the second field probe and a second conductor vessel end connected
with the gas fill vessel, whereby the two conductors form a transmission line that
capacitively couples electromagnetic radiation into the gas-fill vessel.

3. A plasma electrode-less lamp as set forth in Claim 2, wherein the first conductor
and the second conductor impedance-match the electromagnetic resonator to the
gas-fill vessel.
4. A plasma electrode-less lamp as set forth in Claim 1, further comprising an
impedance-matching network conductively connecting the first field probe with the
gas fill vessel and the second field probe with the gas-fill vessel, whereby the
impedance-matching network enables a substantially maximal amount of energy to
be transferred to the gas-fill vessel when energy is stored in the electromagnetic
resonator.
5. A plasma electrode-less lamp as set forth in Claim 1, further comprising a gas, the
gas contained within the gas-fill vessel, whereby the electromagnetic resonator
capacitively couples the electromagnetic radiation to the fluorophor by inducing the
gas to become a plasma, which then transfers energy to the fiuorophor, causing the
fiuorophor to fiuoresce,
6. A plasma electrode-less lamp as set forth in Claim 1, wherein the electromagnetic
radiation source is a tunable oscillator, whereby the tunable oscillator is tuned to
maximize light output
7. A plasma electrode-less lamp as set forth in Claim 1, wherein the electromagnetic
resonator is a lumped circuit comprising lumped circuit components.
8. A plasma electrode-less lamp as set forth in Claim 1, wherein the electromagnetic
resonator is a distributed structure.
9. A plasma electrode-less lamp as set forth in Claim 1, wherein the electromagnetic
resonator comprises lumped circuit components and distributed structures.

10. A plasma electrode-less lamp as set forth in Claim 1, wherein the electromagnetic
resonator is tunable, whereby the electromagnetic resonator is tuned to maximize
light output.
11. A plasma electrode-less lamp as set forth in Claim 10, wherein the electromagnetic
resonator is a lumped circuit comprising lumped circuit components.
12. A plasma electrode-less lamp as set forth in Claim 10, wherein the electromagnetic
resonator is a distributed structure.
13. A plasma electrode-less lamp as set forth in Claim 10, wherein the electromagnetic
resonator comprises lumped circuit components and distributed structures.
14. A plasma electrode-less lamp as set forth in Claim 1, further comprising:
a covered portion of the outer surface of the gas-fill vessel;
a refractory veneer connected with the covered portion of the outer surface
of the gas-fill vessel; and
a conductive veneer connected with the refractory veneer so that the
refractory veneer is between the covered portion and the conductive veneer, and the
first field probe or the second field probe is conductively connected with the
conductive veneer, whereby the refractory veneer acts as a diffusion barrier between
the gas-fill vessel and the conductive veneer.
15. A plasma electrode-less lamp as set forth in Claim 1, wherein the outer surface of
the transparent body includes a reflective portion and a transparent portion, whereby
light is made to reflect from the reflective portion and escape through the
transparent portion, forcing the light to escape into a substantially smaller solid
angle than it would if the reflective portion were absent.
16. A method of fabricating a plasma electrode-less lamp, comprising acts of:

forming an electromagnetic resonator;
conductively connecting an electromagnetic radiation source with the
electromagnetic resonator;
conductively connecting a first field probe with the electromagnetic
resonator;
conductively connecting a second field probe with the electromagnetic
resonator;
forming a gas-fill vessel with a closed, transparent body, the transparent
body having an outer surface and an inner surface, the inner surface forming a
cavity, the gas fill vessel further being formed such that it is detached from the
electromagnetic resonator and capacitively coupling the gas-fill vessel with the first
field probe and the second field probe; and
inserting a fluorophor within the cavity of the gas-fill vessel, whereby the
fluorophor fluoresces when electromagnetic radiation from the electromagnetic
radiation source resonates inside the electromagnetic resonator, the electromagnetic
resonator capacitively coupling the electromagnetic radiation to the fluorophor.
17. A method as set forth in Claim 16, further comprising acts of:
forming a first conductor with a first conductor probe end and a first
conductor vessel end;
conductively connecting the first field probe with the first conductor probe
end;
connecting the gas fill vessel with the first conductor vessel end;
forming a second conductor with a second conductor probe end and a second
conductor vessel end;
conductively connecting the second field probe with the second conductor
probe end; and
connecting the gas fill vessel with the second conductor vessel end, whereby
the two conductors form a transmission line that capacitively couples
electromagnetic radiation into the gas-fill vessel.

18. A method as set forth in Claim 17, wherein the first conductor and the second
conductor are formed such that they impedance-match the electromagnetic
resonator to the gas-fill vessel.
19. A method as set forth in Claim 16, further comprising acts of forming an
impedance-matching network, the impedance matching network being formed such
that it conductively connects the first field probe with the gas fill vessel and
conductively connects the second field probe with the gas-fill vessel, whereby the
impedance-matching network enables a substantially maximal amount of energy to
be transferred to the gas-fill vessel when energy is stored in the electromagnetic
resonator.
20. A method as set forth in Claim 16, further comprising acts of inserting a gas into
the gas-fill vessel, whereby the electromagnetic resonator capacitively couples the
electromagnetic radiation to the fluorophor by inducing the gas to become a plasma,
which then transfers energy to the fluorophor, causing the fluorophor to fluoresce.
21. A method as set forth in Claim 16, further comprising acts of:
forming the gas-fill vessel such that its outer surface has a covered portion;
connecting a refractory veneer with the covered portion of the outer surface
of the gas-fill vessel;
connecting a conductive veneer with the refractory veneer so that the
refractory veneer is between the covered portion and the conductive veneer; and
conductively connecting the first field probe or the second field probe with
the conductive veneer, whereby the refractory veneer acts as a diffusion barrier
between the gas-fill vessel and the conductive veneer.
22. A method as set forth in Claim 16, further comprising acts of:

forming the outer surface of the transparent body is formed such that it includes
a reflective portion and a transparent portion; and
covering the reflective portion with a reflective material, whereby light is made
to reflect from the reflective portion and escape through the transparent portion,
forcing the light to escape into a substantially smaller solid angle than it would if
the reflective portion were absent.
23. A method of fabricating a plasma electrode-less lamp, comprising acts of:
conductively connecting an electromagnetic radiation source with an
electromagnetic resonator;
conductively connecting a first field probe with the electromagnetic
resonator;
conductively connecting a second field probe with the electromagnetic
resonator;
inserting a fluorophor within a gas-fill vessel, the gas-fill vessel arranged
such that it is detached from the electromagnetic resonator, whereby the fluorophor
fluoresces when electromagnetic radiation from the electromagnetic radiation
source resonates inside the electromagnetic resonator, the electromagnetic resonator
capacitively coupling the electromagnetic radiation to the fluorophor.
24. A method as set forth in Claim 23, further comprising acts of:
conductively connecting a first conductor having a first conductor probe end
and a first conductor vessel end with a first field probe, specifically connecting the
first conductor probe end with the first field probe;
conductively connecting a second conductor having a second conductor
probe end and a second conductor vessel end with a first field probe, specifically
connecting the second conductor probe end with the second field probe;
connecting the gas fill vessel with the second conductor vessel end, whereby
the two conductors form a transmission line that capacitively couples
electromagnetic radiation into the gas-fill vessel.

25. A method as set forth in Claim 24, wherein the first conductor and the second
conductor are connected with the gas-fill vessel such that they impedance-match the
electromagnetic resonator to the gas-fill vessel.
26. A method as set forth in Claim 23, further comprising acts of conductively
connecting the first field probe with the gas fill vessel via an impedance-matching
network and conductively connecting the second field probe with the gas-fill vessel
via the impedance-matching network, whereby the impedance-matching network
enables a substantially maximal amount of energy to be transferred to the gas-fill
vessel when energy is stored in the electromagnetic resonator.
27. A method as set forth in Claim 23, further comprising acts of inserting a gas into
the gas-fill vessel, whereby the electromagnetic resonator capacitively couples the
electromagnetic radiation to the fluorophor by inducing the gas to become a plasma,
which then transfers energy to the fluorophor, causing the fluorophor to fluoresce.
28. A method as set forth in Claim 23, further comprising acts of:
connecting a refractory veneer with a covered portion of the outer surface of
the gas-fill vessel;
connecting a conductive veneer with the refractory veneer so that the
refractory veneer is between the covered portion and the conductive veneer; and
conductively connecting the first field probe or the second field probe with
the conductive veneer, whereby the refractory veneer acts as a diffusion barrier
between the gas-fill vessel and the conductive veneer.
29. A method as set forth in Claim 23, further comprising acts of:
covering a reflective portion of the transparent body with a reflective material,
whereby light is made to reflect from the reflective portion and escape through the

transparent portion, forcing the light to escape into a substantially smaller solid
angle than it would if the reflective portion were absent.

Described is a plasma electrode-less lamp. The device comprises an electromagnetic resonator
and an electromagnetic radiation source conductively connected with the electromagnetic resonator. The device further comprises a pair of field probes, the field probes conductively connected with the electromagnetic resonator. A
gas-fill vessel is formed from a closed,
transparent body, forming a cavity. The gas-fill vessel is not contiguous with (detached from) the electromagnetic resonator and is capacitively coupled with the field probes. The gas-fill vessel further contains a gas within the
cavity, whereby the gas is induced to emit light when electromagnetic radiation from the electromagnetic radiation source resonates inside the electromagnetic resonator, the electromagnetic resonator capacitively coupling the electromagnetic radiation to the gas, which becomes a plasma and emits light.

Documents:

http://ipindiaonline.gov.in/patentsearch/GrantedSearch/viewdoc.aspx?id=+sOc/Jb+ubbugInfY1b9gg==&loc=wDBSZCsAt7zoiVrqcFJsRw==


Patent Number 280039
Indian Patent Application Number 1572/KOLNP/2008
PG Journal Number 06/2017
Publication Date 10-Feb-2017
Grant Date 08-Feb-2017
Date of Filing 22-Apr-2008
Name of Patentee TOPANGA TECHNOLOGIES
Applicant Address 21212 VANOWEN STREET CANOGA PARK,CA 91303,UNITED STATES OF AMERICA
Inventors:
# Inventor's Name Inventor's Address
1 ESPIAU, FREDERICK, M. 21549 SUMMIT TRAIL, TOPANGA, CA 90290
2 MATLOUBIAN, MEHRAN 4813 GLORIA AVE., ENCINO, CA 91436
PCT International Classification Number H01J 65/04
PCT International Application Number PCT/US2006/038787
PCT International Filing date 2006-10-04
PCT Conventions:
# PCT Application Number Date of Convention Priority Country
1 60/723144 2005-10-04 U.S.A.