Classifications

• • G—PHYSICS
  • G02—OPTICS
  • G02B—OPTICAL ELEMENTS, SYSTEMS OR APPARATUS
  • G02B19/00—Condensers, e.g. light collectors or similar non-imaging optics
  • G02B19/0033—Condensers, e.g. light collectors or similar non-imaging optics characterised by the use
  • G02B19/0047—Condensers, e.g. light collectors or similar non-imaging optics characterised by the use for use with a light source
  • G02B19/0052—Condensers, e.g. light collectors or similar non-imaging optics characterised by the use for use with a light source the light source comprising a laser diode
  • G02B19/0057—Condensers, e.g. light collectors or similar non-imaging optics characterised by the use for use with a light source the light source comprising a laser diode in the form of a laser diode array, e.g. laser diode bar
• • G—PHYSICS
  • G02—OPTICS
  • G02B—OPTICAL ELEMENTS, SYSTEMS OR APPARATUS
  • G02B19/00—Condensers, e.g. light collectors or similar non-imaging optics
  • G02B19/0004—Condensers, e.g. light collectors or similar non-imaging optics characterised by the optical means employed
  • G02B19/0028—Condensers, e.g. light collectors or similar non-imaging optics characterised by the optical means employed refractive and reflective surfaces, e.g. non-imaging catadioptric systems
• • G—PHYSICS
  • G02—OPTICS
  • G02B—OPTICAL ELEMENTS, SYSTEMS OR APPARATUS
  • G02B19/00—Condensers, e.g. light collectors or similar non-imaging optics
  • G02B19/0033—Condensers, e.g. light collectors or similar non-imaging optics characterised by the use
  • G02B19/009—Condensers, e.g. light collectors or similar non-imaging optics characterised by the use for use with infrared radiation
• • H—ELECTRICITY
  • H01—ELECTRIC ELEMENTS
  • H01S—DEVICES USING THE PROCESS OF LIGHT AMPLIFICATION BY STIMULATED EMISSION OF RADIATION [LASER] TO AMPLIFY OR GENERATE LIGHT; DEVICES USING STIMULATED EMISSION OF ELECTROMAGNETIC RADIATION IN WAVE RANGES OTHER THAN OPTICAL
  • H01S5/00—Semiconductor lasers
  • H01S5/40—Arrangement of two or more semiconductor lasers, not provided for in groups H01S5/02 - H01S5/30
  • H01S5/4025—Array arrangements, e.g. constituted by discrete laser diodes or laser bar
• • H—ELECTRICITY
  • H01—ELECTRIC ELEMENTS
  • H01S—DEVICES USING THE PROCESS OF LIGHT AMPLIFICATION BY STIMULATED EMISSION OF RADIATION [LASER] TO AMPLIFY OR GENERATE LIGHT; DEVICES USING STIMULATED EMISSION OF ELECTROMAGNETIC RADIATION IN WAVE RANGES OTHER THAN OPTICAL
  • H01S5/00—Semiconductor lasers
  • H01S5/005—Optical components external to the laser cavity, specially adapted therefor, e.g. for homogenisation or merging of the beams or for manipulating laser pulses, e.g. pulse shaping
• • H—ELECTRICITY
  • H01—ELECTRIC ELEMENTS
  • H01S—DEVICES USING THE PROCESS OF LIGHT AMPLIFICATION BY STIMULATED EMISSION OF RADIATION [LASER] TO AMPLIFY OR GENERATE LIGHT; DEVICES USING STIMULATED EMISSION OF ELECTROMAGNETIC RADIATION IN WAVE RANGES OTHER THAN OPTICAL
  • H01S5/00—Semiconductor lasers
  • H01S5/40—Arrangement of two or more semiconductor lasers, not provided for in groups H01S5/02 - H01S5/30
  • H01S5/4012—Beam combining, e.g. by the use of fibres, gratings, polarisers, prisms

Definitions

• the invention relates to the field of laser illumination and more particularly to producing illumination lines for use in imaging and other applications.
• Diode lasers are used in many imaging applications as convenient and low-cost sources of radiation. Material processing applications may make use of suitably coupled diode laser radiation to change the nature or character of a workpiece. Image recording and display systems may use laser diodes to provide illumination for an optical system.
• a monolithic array of laser diode emitters may be used to illuminate a multi-channel light valve.
• a light valve generally has a plurality of individually addressable modulator sites; each site producing a beam or channel of imagewise modulated light.
• An image is formed by selectively activating the channels while scanning them over an image receiver.
• channels For high quality imaging it is usually necessary that channels be uniform in their imaging characteristics. This requirement presents a difficult challenge for system designers since the illumination from a laser diode is highly astigmatic with poor overall beam quality. Consequently optical systems for gathering and formatting the light output seek to overcome the inherent limitations of the diode laser output in order to produce useable illumination.
• US Patent 5,517,359 to Gelbart describes a method for imaging the radiation from a laser diode array having multiple emitters onto a linear light valve.
• the optical system superimposes the radiation line from each emitter at the plane of the light valve, thus forming a single combined illumination line.
• the superimposition provides some immunity from emitter failures (either partial or full). In the event of such a failure, while the output power is reduced, the uniformity of the line is not severely impacted.
• a good laser diode array can have emitters that are more than 20% non-uniform in the slow axis. When the radiation from a plurality of emitters is combined, some of the non-uniformities may offset each other but commonly 10-15% non-uniformity remains. Some light valves can accommodate this non-uniformity by balancing the output from each channel by attenuating output from channels that are more strongly illuminated. This however represents wastage of up to 15% of the useful light output since it is not possible to amplify weak channels.
• US patent 6, 137,631 to Moulin describes a means for mixing the radiant energy from a plurality of emitters in a laser diode array.
• the mixing means comprises a plurality of reflecting surfaces placed at or downstream from a point where the laser radiation has been focused.
• the radiant energy entering the mixing means is subjected to multiple reflections, which makes the output distribution of the emerging radiant energy more uniform.
• Laser diode arrays having nineteen or more 150 ⁇ m emitters are now available with total power output of around 50W at a wavelength of 830 run. While efforts are constantly underway to provide higher power, material and fabrication techniques still limit the power that can be achieved for any given configuration.
• a first aspect of the invention provides a light valve illuminator comprising at least one laser array, each of the at least one laser array is operable for emitting a corresponding plurality of radiation beams, and a light pipe.
• the light pipe is defined by two reflecting surfaces which are spaced apart and oppose one another.
• the light pipe has an input end and an output end. The input end is operable to receive the corresponding plurality of radiation beams from each of the at least one laser array. Portions of any given corresponding plurality of radiation beams do not overlap at the input end with other portions of the same corresponding plurality of radiation beams. Additionally, a portion of one corresponding plurality of radiation beams will not overlap at the input end with a portion of another corresponding plurality of radiation beams.
• Each respective portion of the corresponding plurality of laser beams is less than the total of the corresponding plurality of radiation beams.
• Another aspect of the invention provides a method for coupling a plurality of radiation beams from one or more laser arrays onto a light valve.
• a plurality of radiation beams from each of the one or more laser arrays is emitted into a light pipe.
• the light pipe has an input end, an output end and a pair of spaced apart opposing reflecting surfaces therebetween.
• portions of any given corresponding plurality of radiation beams do not overlap at the input end with other portions of the same corresponding plurality of radiation beams.
• a portion of one corresponding plurality of radiation beams does not overlap at the input end with a portion of another corresponding plurality of radiation beams.
• each respective portion of the corresponding plurality of laser beams is less than the total of the corresponding plurality of radiation beams.
• the output end of the light pipe is imaged onto the light valve.
• an illumination system comprises at least two lasers, each laser capable of producing a radiation beam, and a light pipe for combining the radiation beams from the lasers into a composite illumination line.
• a position sensor is located downstream of the light pipe for monitoring the position of the radiation beams and generating a position feedback signal.
• FIG. 1 is a perspective view of an illumination system according to the present invention
• FIG. 2- A is a plan view of the illumination system of FIG. 1 ;
• FIG. 2-B is a side view of the illumination system of FIG. 1 ;
• FIG. 3 is a plan view of a light pipe
• FIG. 4 is a plan view of another embodiment of a light pipe
• FIG. 5-A is a perspective view of a beam pointing control system
• FIG. 5-B is a schematic diagram of a beam pointing servo system
• FIG. 6-A is a plan view of a light pipe illumination system
• FIG. 6-B is a phase space plot of the output from the light pipe shown in FIG. 6-A;
• FIG. 7- A is a perspective view of an alternative embodiment of a beam pointing control system.
• FIG. 7-B is a plan view of the detector shown in FIG. 7-A.
• Figure 1 shows an embodiment of the invention wherein radiation from two laser arrays 10 and 12 is directed onto a light pipe 20.
• Light pipe 20 is defined by a pair of reflecting surfaces 22 that are substantially perpendicular to the system plane.
• the system plane is defined as the plane that is parallel to the XZ plane.
• Light pipe 20 is tapered from its input end 24 to its output end 26.
• the output end 26 of the light pipe 20 is the region between the downstream terminuses of the reflecting surfaces 22.
• the pair of laser arrays 10 and 12 preferably comprises a pair of laser diode arrays, each of which has a plurality of emitters 14.
• Emitters 14 are commonly referred to as stripe emitters since they are very narrow in one direction (typically 1 ⁇ m) and elongated in the other direction (typically greater than 80 ⁇ m for a multimode laser).
• the elongated sides of the emitter stripes lie in the system plane.
• the Y axis is commonly referred to as the "fast axis” since the laser radiation diverges very quickly in that direction
• the X axis is commonly referred to as the “slow axis” since the laser radiation diverges comparatively slowly in that direction (around 8° included angle divergence in the slow axis compared to around 30° included angle divergence for the fast axis).
• Each emitter 14 in each of the laser arrays 10 and 12 produces an output beam that is single transverse mode in the fast axis and multiple transverse mode in the slow axis.
• a microlens 16 is positioned in front of each emitter 14 in order to gather the radiation from emitters 14.
• Microlenses 16 may be sliced from circular aspheric lenses using a pair of spaced apart diamond saw blades (as described in commonly assigned US Patent 5,861,992 to Gelbart).
• the output end 26 of light pipe 20 is optically coupled by lenses 28, 30 and 32 onto a light valve 34, thereby allowing the output end 26 to be imaged onto light valve 34.
• Light valve 34 has a plurality of modulator sites 36.
• An aperture stop 29 is placed between lenses 28 and 30.
• the modulator sites 36 of light valve 34 may be imaged onto an intended target using an optical imaging system (not shown).
• the laser arrays 10 and 12 are preferably
• toed-in slightly to towards central axis 18.
• the toe-in can be accomplished optically using a cylindrical lens (not shown) having power in the system plane.
• the cylindrical lens can be located between the Microlenses 16 and the light pipe input end 24.
• FIG. 1, FIG. 2-A and FIG. 2-B The operation of the illumination system is described in relation to FIG. 1, FIG. 2-A and FIG. 2-B.
• radiation from the emitters 14 of laser arrays 10 and 12 is astigmatic.
• An anamorphic imaging system is used to illuminate light valve 34. The propagation of radiation in the fast and slow axes should thus be considered separately.
• any specific radiation beam emitted by a corresponding emitter will, at the input end of the light pipe, not overlap in the slow scan direction with all of the other radiation beams emitted by all of the other emitters, regardless of whether the other emitters are part of the same laser array or any other laser array. It is worth noting that radiation from a given emitter 14 may be collected by more than one microlens 16 and directed into the input end 24 of light pipe 20.
• each of radiation beams 40a and 42a represent the beams emitted from emitters 14 as observed in different planes.
• Each microlens 16 gathers the radiation 40a from a single emitter 14 and focuses it to a waist at a point 44.
• Point 44 is downstream of the output end 26 of light pipe 20 and is between lenses 28 and 30 in this embodiment of the invention.
• the location for the waist is chosen to limit the power density on optical surfaces.
• the waist is imaged on to light valve 34 by cylindrical lens 32.
• emitters 14 need not be focused to produce a waist before cylindrical lens 32 but rather, could produce a virtual waist after cylindrical lens 32. Cylindrical lens 32 then images the virtual waist onto the light valve 34.
• Optical element 28 is a cylindrical lens having no optical power in the fast axis. Aperture 29 similarly has no effect on the fast axis propagation of the radiation.
• Element 30 is a spherical field lens.
• Element 32 is a cylindrical lens with optical power in the fast axis for focusing beams 40c into a narrow line 46 on light valve 34.
• Light pipe 20 combines and mixes the radiation beams from emitters 14 on laser arrays 10 and 12 and produces an output radiation at the output end 26.
• the operation of the light pipe 20 is described in relation to FIG. 3.
• Emitters 14 produce radiation beams that are gathered and focused by microlenses 16 as previously described.
• Two representative beams 60 and 62 are shown in FIG. 3 although it should be understood that each emitter produces such a beam.
• Each of beams 60 and 62 should also be understood to include a bundle of rays within the bounds shown for the beam. It should also be further understood that the bounds represented by beams 60 and 62 are shown for the purposes of illustration only and may vary in other preferred embodiments of the invention.
• Beam 60 is reflected at points 66, 68 and 70 by reflective surfaces 22 before reaching the output end 26 of light pipe 20.
• Beam 62 is reflected at points 72 and 74 before reaching output end 26.
• beams 60 and 62 are overlapped and mixed to form part of an output radiation at output end 26. Beams from other emitters 14 will be similarly reflected before reaching output end 26.
• the output radiation will comprise an output composite radiation beam made up of a substantial portion (i.e. accounting for any minor losses in the light pipe 20) of each of the radiation beams emitted from emitters 14.
• the output radiation comprises a uniform composite illumination line extending from the terminus of one reflecting surface 22 to the terminus of the other reflecting surface 22.
• This composite illumination line can be magnified by a suitable optical system to illuminate a light valve. It should be noted that at the output end 26, the plurality of radiation beams emitted from laser array 10 will produce a first illumination line and the plurality of radiation beams emitted from laser array 12 will produce a second illumination line.
• the first and second illumination lines may be spaced apart or at least partially overlapped at output end 26, but in either case they will form the composite illumination line. When spaced apart, the first and second illumination lines can be merged downstream of the light pipe 20. [0025]
• the output end 26 of light pipe 20 is imaged by a cylindrical lens 28 and spherical lens 30 onto light valve 34.
• Output radiation beams 42b leaving the output end 26 of light pipe 20 are essentially telecentric and an aperture 29 is placed at the focus of lens 28.
• the function of the aperture 29 is to block outermost rays that may have undergone too many reflections in the light pipe, and consequently have too great an angle to axis 18 upon leaving output end 26. Such rays, if included may reduce the uniformity of composite illumination beam 42c, particularly at the edges.
• Spherical lens 30 is a field lens, which ensures that beams 42d illuminate light valve 34 telecentrically in the system plane. Telecentric illumination of a light valve ensures that each modulator site is equivalently illuminated.
• the use of light pipe 20 scrambles the radiation beams from the plurality of emitters 14 by the multiple reflections from reflective surfaces 22.
• the scrambling results in a uniform irradiance profile at output end 26.
• the output end 26 of the light pipe 20 may be imaged onto a light valve 34 to provide uniform telecentric illumination of the plurality of modulator sites 36.
• the reflective surfaces 22 of light pipe 20 may be selected for high reflectivity only for radiation polarized in the direction of the fast axis. Radiation that is polarized in other directions will be attenuated through the multiple reflections in light pipe 20. This is an advantage for some light valves that are only able to modulate beams that are polarized in a specific direction. Where beams having other polarization directions are passed through the light valve un-attenuated the achievable contrast can be improved by attenuating beams having polarization directions other than the specific direction. [0028] While the light pipe 20 in the preceding embodiment is tapered, this is not mandated.
• the taper is chosen to suit the a number of factors including the slow axis divergence of the laser emitters, the size of laser arrays 10 and 12, the angle at which the laser arrays are toed in towards axis 18 and any constraints on the length of the light pipe.
• a non-tapered light pipe may be employed if the emitters are highly divergent and/or if there is sufficient space to allow a longer light pipe.
• the reflections for any specific light pipe may be examined in the system plane to predict the number of reflections for any given beam and the resultant uniformity of the output (see for example FIG. 6-A and FIG. 6-B). From a modeling of the phase space, the light pipe length and taper may be optimally chosen for a given situation. In an alternative embodiment shown in FIG.
• a pair of un-microlensed laser arrays 10 and 12 are coupled into a light pipe comprising a pair of parallel reflecting sides 80.
• a radiation beam 82 from an outer emitter is shown. Some of the rays in beam 82 may undergo two reflections before reaching the output end 26 providing some mixing of the emitter contributions at output end 26.
• the radiation from all of the emitters of each laser array is collimated in the fast axis direction using a cylindrical lens immediately following the laser arrays.
• any variation in pointing direction will result in fluctuations in the brightness of the line illumination (brightness is the luminous flux emitted from a surface per unit solid angle per unit of area and is an important parameter in illumination systems). In some applications this will necessitate individually controlling the pointing of each emitter.
• One method to actively control the pointing of a laser beam is to use a moveable a reflective element in the laser path to align the beam with a target located some distance away from the laser source.
• the target is commonly a position sensitive detector (PSD) of some type.
• PSD position sensitive detector
• the output from the target is used as a feedback signal to servo the moveable reflective element.
• the laser itself may be moveable, removing the need for an additional reflective element.
• FIG. 5-A a pair of lasers 10 and 12 are coupled into a light pipe 20.
• the radiation from laser 10 is directed downwards onto turning mirror 90, which directs the radiation into light pipe 20.
• Turning mirror 90 is rotatable about axis 92 as indicated by arrow 94.
• the radiation from laser 12, directed upwards onto turning mirror 96 is also directed into the light pipe.
• Turning mirror 96 is rotatable about axis 98. It should be readily apparent that by rotating each of the mirrors 90 and 96, the pointing direction of lasers 10 and 12 can be changed, and consequently, the location of the radiation beams at the output end 26 of light pipe 20 may be adjusted in the Y axis direction.
• FIG. 6-B is a phase space plot of the output end of the light pipe configuration shown in FIG. 6-A. Modeling the laser sources and light pipe reflective surfaces in a mathematical ray tracing simulation produces the plot.
• FIG. 6-A a bundle of rays 110 from lasers 10 and 12 are analyzed with respect to their path through light pipe 20. Three representative rays, 112, 114 and 116 are shown at output end 26. Each ray has a position, x on axis 118 and makes an angle ⁇ with axis 120. The position and angle of each ray exiting light pipe 20 at output end 26 is plotted in FIG. 6-A (as a sine of the angle ⁇ ).
• phase space plot is produced by observing the x and ⁇ values for a multiplicity of rays and plotting these in FIG. 6-A to form regions of density 122.
• rays 112, 114 and 116 are plotted as indicated in FIG. 6-B.
• the phase space plot (FIG 6-B) shows how the illuminated part of the output phase space is made up of contributions from different laser sources.
• the labels alongside the plot are used to indicate which laser has produced a particular portion of the illumination and how many reflections at surfaces 22 were undergone before arriving at the output end 26.
• Some rays have too great an angle (at the positive and negative extremes of the sin ⁇ axis) and would compromise the uniformity of the output end 26 of light pipe 20.
• Illumination contributions outside the extent labeled as "R" on the left hand side of the plot are thus blocked by an aperture to prevent them entering the illumination profile.
• the blocked region generally represents contributions that have undergone too many reflections (in this case more than two reflections).
• Illumination contributions outside region R are clearly identifiable as being from either laser 10 or laser 12. Furthermore, since this part of the illumination line will be blocked anyway, it may be used to monitor the pointing of lasers 10 and 12 without affecting the useful output radiation.
• a pair of position sensitive detectors 124 and 126 is located as shown in order to monitor the position of lasers 10 and 12 and provide feedback to a control system.
• a suitable controller is schematically depicted in FIG. 5-B.
• the "set point" is a desired position for the beam.
• the turning mirror actuator 130 responds to a change in set point by actuating the turning mirror, resulting in a change in physical beam position 132.
• This change in beam position is detected by PSD sensor 134 and fed back to a comparator 136 (as negative feedback). If the beam position 132 is at the desired location, then feedback 138 and the set point will have the same level and the output 140 of comparator 136 will be zero, meaning that there is no further change in the position of turning mirror actuator 130.
• the controller of FIG. 5-B is duplicated for each laser and each laser is individually controlled.
• the laser beams may be adjusted for optimal overlap in the Y axis by adjusting the set point to each of the control loops.
• the output end 26 from light pipe 20 is directed to a beamsplitter 150 located downstream of the light pipe 20.
• Beamsplitter 150 separates the light output into two beams. The bulk of the energy is allowed to pass through beamsplitter 150 as beam 152, which illuminates the light valve (not shown). A smaller portion is split off as beam 154, passes through lens 156, and is directed to a quadrant detector 158. The lens 156 and the positioning of quadrant detector 158 are selected to image the laser arrays 10 and 12 onto detector 158.
• the central region of the plot has contributions from laser 10 above the x axis and laser 12 below the x axis.
• these contributions are shown on quadrant detector 158 as beam 160, corresponding to the contribution from laser 10, and beam 165 corresponding to the contribution from laser 12.
• the lens 156 and detector 158 are aligned so that beam 160 falls on detector segments 170 and 172 and beam 165 falls on detector segments 174 and 176. Changes in pointing will move beams 160 and 165 up and down changing the signals level detected at the various segments. Beam 160 is vertically centered over segments 170 and 172 and hence the signal output from each of these detectors will be the same.
• Beam 165 illuminates more of segment 174 than 176 and hence the signals from these segments will not be the same.
• beam 165 can be centered and aligned with beam 160. In this manner the beam pointing may be actively controlled. It should be readily apparent however that it is not necessary that the beams be centered over the detector segments. In practice both beams may be offset by some amount as needed. The offsets need not even be identical since the beam pointing may be adjusted to an external diagnostic system and the beams 160 and 165 may have different offset targets according to which they are controlled.
• the quadrant detector provides a convenient format for controlling two beams on a single element, it may be replaced by a pair of position sensitive detectors, wherein one of the detectors is employed for each beam.
• the radiation is formed into a narrow line at the light valve but this is not mandated. In general the radiation line is formatted to suit the light valve and the radiation may be spread over a wider area.
• embodiments described herein show the lasers emitting in a common plane, the lasers could also be disposed to emit in a different plane. In this case the light pipe still mixes the beams in the slow axis direction, the combination of the beams in the fast axis occurring after the light pipe.
• preferred embodiments of the invention may employ two or more lasers, wherein each of the lasers is an individual laser beam.
• each of the two or more lasers may each comprise a laser array made up of a plurality of laser elements.
• alternative embodiments of the invention may incorporate a single laser array comprising a plurality of lasers. Accordingly, laser arrays that are laser diode arrays will be made up of a plurality of laser diodes.
• a microlens is preferably positioned in front of each emitter in the diode arrays.
• microlens elements may also be used such as the monolithic micro-optical arrays produced by Lissotschenko Mikrooptik (LIMO) GmbH of Dortmund, Germany.
• LIMO produces a range of fast axis and slow axis collimators that may be used alone or in combination to format the radiation from laser diode arrays.
• Laser arrays other than laser diode arrays may also be employed as a source.
• the arrays may be formed using a plurality of fiber coupled laser diodes with the fiber tips held in spaced apart relation to each other, thus forming an array of laser beams.
• the output of such fibers may likewise be coupled into a light pipe and scrambled to produce a homogeneous illumination line.
• the fibers could also be a plurality of fiber lasers with outputs arrayed in fixed relation.
• Preferred embodiments of the invention employ infrared lasers. Infrared diode laser arrays employing 150 ⁇ m emitters with total power output of around 50W at a wavelength of 830 nm, have been successfully used in the present invention. It will be apparent to practitioners skilled in the art that alternative lasers including visible light lasers are also employable in the present invention.
• the light pipe may be produced using a pair of reflective mirrors as described herein, but this is not mandated.
• the light pipe may also be fabricated from a transparent glass solid that has opposing reflective surfaces for reflecting the laser beams.
• a suitable solid would have the same shape as the area between the reflective mirrors shown in the drawing figures, (i.e. wedge shaped).
• the surfaces may be coated with a reflective layer or the light pipe may rely on total internal refraction to channel the laser beams toward the output end of the light pipe.
• optical path from the output end to the light valve has been shown to lie substantially along the system plane.
• Alternate embodiments of the invention may employ one or more optical elements such as mirrors between the light pipe and the light valve so as to permit the positioning of the light valve on a plane offset from the system plane or to position the light valve on a plane that is at an angle to the system plane. These alternate positions of the valve, may advantageously allow for a more compact imaging system.

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• Physics & Mathematics (AREA)
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• Optics & Photonics (AREA)
• Condensed Matter Physics & Semiconductors (AREA)
• Electromagnetism (AREA)
• Health & Medical Sciences (AREA)
• Toxicology (AREA)
• Semiconductor Lasers (AREA)
• Lasers (AREA)
• Non-Portable Lighting Devices Or Systems Thereof (AREA)

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• 2005
  • 2005-01-21 US US11/038,188 patent/US7209624B2/en not_active Expired - Fee Related
  • 2005-01-28 JP JP2006549820A patent/JP4693786B2/ja not_active Expired - Fee Related
  • 2005-01-28 CN CN200580003504.8A patent/CN100549762C/zh not_active Expired - Fee Related
  • 2005-01-28 EP EP05706427A patent/EP1725903A4/en not_active Withdrawn
  • 2005-01-28 WO PCT/CA2005/000101 patent/WO2005073784A1/en not_active Ceased

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