The present invention related to gas discharge laser systems operating at very high repetition rates of about 6 kHz and above and requiring certain modifications to solid state pulse power systems for supplying power to the electrodes for creating the gas discharges at very high current/voltage and very high pulse repetition rates.
As shown schematically in
Such a pulsed power circuit may include, as illustrated in
The output of the inverter 24 can be stepped up to about 800 volts in a step-up transformer 26. The output of transformer 26 can be converted to 800 volts DC by a rectifier 28, which can include, e.g., a standard bridge rectifier circuit and a filter capacitor 34. The power supply module 20 can be used to take the DC output of a source 10, e.g., to charge, e.g., an 5.1 μF charging capacitor C0 in the commutator module 50 as directed by a control board (not shown), which can, e.g., control the operation of the power supply module 20 to set this voltage. Set points, e.g., within the HV source 10 or power supply control board(s) (not shown) can be provided by a laser system control board (not shown). In the discussed embodiment, e.g., pulse energy control for the laser system can be provided by regulating the voltage supplied by the set of the power source 10 to the power supply module 20 and the power supply module 20 to C0 42 in the commutator module 50.
The electrical circuits in commutator module 50 and compression head module 60 may, e.g., serve to amplify the voltage and compress the pulses of electrical energy stored on charging capacitor C0 42 by the power supply 18, including the source 10 and power supply module 20 module 20, e.g., to provide 800-1200 volts to charging capacitor C0, which during the charging cycle can be isolated from the down stream circuits, e.g., by a solid state switch 46, which actually may comprise a plurality, e.g., two or three, solid state switches in parallel, e.g., in order to reduce the current flow through each.
The commutator module 40, which can comprise, e.g., the charging capacitor C0, which can be, e.g., a bank of capacitors connected in parallel to provide a total capacitance of, e.g., 5.1 μ.F, along with the voltage divider 44, in order to, e.g., provide a feedback voltage signal to the HV power source 10 or power supply module 20 control board (not shown) which can be used by control board to limit the charging of charging capacitor C0 42 to a voltage (so-called “control voltage”), which, e.g., when formed into an electrical pulse and compressed and amplified in the commutator 40 and compression head 50, can, e.g., produce the desired discharge voltage on a peaking capacitor Cp 82 and across electrodes 83,84 in the lasing cavity chamber 80.
As is known in the art, e.g., for a laser system operating at around 4 kHz, and also for a laser system operating at around 6 kHz or above, such a circuit 50, 60, 80 may be utilized to provide pulses in the range of 3 or more Joules and greater than 14,000 volts at pulse rates of 4,000 or more pulses per second. In such a circuit, e.g., at 4 kHz and above, about 160 microseconds may be required for DC power source 10 and power supply module 20 to charge the charging capacitor C0 42 to, e.g., between about 800-1200 volts. At 6 kHz and above the charging time is reduced to about 100 microseconds, and so forth as pulse repetition rate increases.
Charging capacitor C0-42, therefore, can, e.g., be fully charged and stable at the desired voltage provided the voltage and current applied to the charging capacitor C0 42 in the amount of time allowed by the pulse repetition rate can be accomplished. For example, when a signal from a commutator control board (not shown) is provided, e.g., to close the solid state switch 46, which, e.g., initiates a very fast step of converting the 3 Joules of electrical energy stored on charging capacitor C0 42 into, e.g., a 14,000 volt or more charge on peaking capacitor Cp 82 for creating a discharge across the electrodes, 83, 84, provided the charging capacitor C0 has been adequately charged within the time allotted by the pulse repetition rate of the laser system.
The solid state switch 46 may be, e.g., an IGBT switch, or other suitable fast operating high power solid state switch, e.g., an SCR, GTO, MCT, high power MOSFET, etc. A 600 nH charging inductor L0 48 can be placed in series with the solid state switch 46 and employed, e.g., to temporarily limit the current through the solid state switch 46 while it closes to discharge the charge stored on charging capacitor C0 42 onto a first stage capacitor C1 52 in the commutator module, 50 e.g., forming a first stage of pulse compression in the commutator module 50.
For the first stage of pulse generation and compression, the charge on charging capacitor C0 can be switched onto a capacitor, e.g., a 5.7 μF capacitor C1, e.g., in about 4 μs. A saturable inductor L1 54 can hold off the voltage on capacitor C1 52 until the saturable reactor L1 54 saturates, and then present essentially zero impedance to the current flow from capacitor C1 52, e.g., allowing the transfer of charge from capacitor C1 52 through, e.g., a step up transformer 56, e.g., a 1:25 step up pulse transformer, in order to charge a capacitor Cp-1 62 in the compression head module 60, with, e.g., a transfer time period of about 400 ns, comprising a second stage of compression.
The design of pulse transformer 56 is described in a number of prior patents assigned to the common assignee of this application, including, e.g., U.S. Pat. No. 5,936,988. For example, such a transformer 56 is an extremely efficient pulse transformer, transforming, e.g., a 800 volt 5000 ampere, 400 ns pulse to, e.g., a 20,000 volt, 200 ampere 400 ns pulse, which, e.g., is stored very temporarily on compression head module capacitor Cp-1 62, which may also be, e.g., a bank of capacitors. The compression head module 60 may, e.g., further compress the pulse. A saturable reactor inductor Lp-1 64, which may be, e.g., about a 125 nH saturated inductance, can, e.g., hold off the voltage on capacitor Cp-1 62 for approximately 400 ns, in order to, e.g., allow the charge on Cp-1 62 to flow, e.g., in about 100 ns, onto a peaking capacitor Cp 82, which may be, e.g., a 10.0 nF capacitor located, e.g., on the top of a laser chamber and which peaking capacitor Cp 82 is electrically connected in parallel with the laser system electrodes 83, 84.
This transformation of a, e.g., 400 ns long pulse into a, e.g., 100 ns long pulse to charge peaking capacitor Cp 82 can make up, e.g., the second and last stage of compression. About 100 ns after the charge begins flowing onto peaking capacitor Cp 82 (which may be a bank of capacitors in parallel) mounted on top of and as a part of the laser chamber in the laser chamber module, the voltage on peaking capacitor Cp 82 will have reached, e.g., about 20,000 volts and a discharge between the electrodes begins. The discharge may last, e.g., about 50 ns, during which time, e.g., lasing occurs within the resonance chamber of the, e.g., excimer laser.
According to aspects of an embodiment of the present invention may comprise operation of laser systems requiring, e.g., precisely controlled electrical potentials in the range of about 12,000 V to 20,000 V be applied between the electrodes at around 6,000 Hz and above (i.e., at intervals of about 166 micro seconds). As indicated above in known magnetic switch pulse power systems the charging capacitor bank C0 42 can be is charged to a precisely predetermined control voltage and the discharge can be produced by closing the solid state switch 46 which can then allow the energy stored on the charging capacitor C0 42 to ring through the magnetic compression-amplification circuitry 50, 60 and 80 to produce the desired potential across the electrodes 83, 84. The time between the closing of the switch 46 to the completion of the discharge is only a few microseconds, (i.e., about 5 microseconds) but the charging of C0 42 can require a time interval much longer than 166 microseconds. It is known, however, to reduce the charging time, e.g., by using a larger power supply. Alternatively, using power supplies in parallel can reduce the charging time. For example, it has bee shown that one is able to operate at around 4,000 Hz, e.g., by using three prior art power supplies such as those shown illustratively as element 18 in
In such an embodiment, one may also utilize the same basic design as in the prior art shown in
A standard dc power supply 200 having a 208 VAC/90 amp input and an 800 VDC 50 amp output may be used. The power supply 200 may be a dc power supply adjustable from approximately 600 volts to 800 volts. The power supply 200 may be attached directly to a storage capacitor C-1202, in a resonant charger 220, which may be, e.g., a 1033 μF capacitor. When the power supply 200 is enabled it turns on and regulates a constant voltage on the C-1 capacitor 202. The performance of the system is somewhat independent of the voltage regulation on C-1202. The power supply 200 may be, e.g., a constant current, fixed output voltage power supply such as is available from Elgar, Universal Voltronics, Kaiser and EMI.
The power supply 200 may continuously charges the 1033 μ.F capacitor 202 to the voltage level commanded by the control board 204, in the embodiment of
After IGBT switch 206 opens the energy stored in the magnetic field of inductor 208 can transfer to capacitor 42 through a free-wheeling diode (215 in
A second resonant charger system is shown illustratively and in block diagram form by way of example in
Prior to the need for a laser pulse the voltage on capacitor C-1202 can be charged to, e.g., 600-800 volts and switches Q1206, Q2218 and Q3216 may be open. Upon a command from the laser system controller (not shown), the control board 204 can provide a command 206′ to switch Q1206 to close the switch Q1206. At this time current would flow from capacitor C-1202 to charging capacitor Co 42 through the charging inductor L1208, since switch Q2 can be open at this time. A calculator 205 on the control board 204 could be used to evaluate the voltage on C0 42 and the current flowing in inductor L1208, from feedback signals 212, 214, relative to a command voltage set point from the laser. Switch Q1206 can then be opened by a command 206′ from the control board 204 when the voltage on charging capacitor C0 42 plus the equivalent energy stored in inductor L1206 equals the desired command voltage. The calculation is:
Vf=[VC0s2+((L1*IL1s2)/C0)]0.5
where: Vf=a final voltage on C0 after switch Q1206 opens and the current in inductor L1208 goes to zero; VC0s is the starting voltage on C0 when switch Q1206 opens; IL1s is the current flowing through L1 when switch Q1206 opens. After switch Q1206 opens the energy stored in inductor L1208 continues transferring to C0 through diode D2217 until the voltage on C0 approximately equals the command voltage. At this time switch Q2218 can be closed and current stops flowing to charging capacitor C0 42 and is directed through diode D3219. In addition to the “deque” circuit, 218, 219, switch Q3216 and resistor R3240 form a bleed-down circuit to allow additional fine regulation of the voltage on C0 to a target charging voltage.
Switch Q3 of bleed down circuit 216, 240 can be commanded to close, e.g., by the control board 204, e.g., when current flowing through inductor L1208 stops and the voltage on charging capacitor C0 can be bled down to the desired charging voltage. Then switch Q3216 can be opened. The time constant of capacitor C0 42 and resistor R3240 can be selected to be sufficiently fast to bleed down capacitor C0 42 to the commanded charging voltage without being an appreciable amount of the total charge cycle.
As a result, the resonant charger 220 can be configured with three levels of regulation control. Somewhat crude regulation may be provided by the energy calculator and the timing of the opening of switch Q1206 during the charging cycle. As the voltage on C0 nears the target charging voltage value, the deque switch Q2218 may be closed, stopping the resonant charging when the voltage on C0 is at or slightly above the target value. Finally, as a third control over the voltage regulation the bleed-down circuit of switch Q3216 and R3240 can be used to discharge C0 down to the precise target value.
According to aspects of an embodiment of the present invention these known magnetic switch pulsed power supply systems may carry out parallel non-resonant charging, e.g., for operation of laser systems at pulse rates of 4,000 Hz to 6,000 Hz can be accomplished with the prior art charging system technology shown as element 20 in
According to aspects of an embodiment of the present invention the resonant chargers of
A technique for water cooling a step-up transformer is disclosed in U.S. Pat. No. 5,448,580, entitled AIR AND WATER COOLED MODULATOR, issued to Birx, et al on Sep. 5, 1995 disclosing:
A jitter control circuit is discussed in Huang, et al., “Low Jitter And Drift High Voltage IGBT Gate Driver, Proceedings of the 14th IEEE Pulsed Power Conference, Dallas (2003), pp 127-130, Abstract No. 100055.
A method and apparatus for operating a very high repetition gas discharge laser system magnetic switch pulsed power system is disclosed, which may comprise a solid state switch, a charging power supply electrically connected to one side of the solid state switch; a charging inductor electrically connected to the other side of the solid state switch; a deque circuit electrically in parallel with the solid state switch comprising a deque switch; a peaking capacitor electrically connected to the charging inductor, a peaking capacitor charging control system operative to charge the peaking capacitor by opening the deque switch and leaving the solid state switch open and then shutting the solid state switch. The solid state switch may comprise a plurality of solid state switches electrically in parallel. The peaking capacitor charging control system may be operative to charge the peaking capacitor by leaving the deque switch open until substantially all of the electrical energy stored in the charging inductor has been removed before shutting the solid state switch. The very high repetition gas discharge laser system magnetic switch pulsed power system may comprise a solid state switch; a charging power supply electrically connected to one side of the solid state switch; a charging inductor electrically connected to the other side of the solid state switch; a peaking capacitor electrically connected to the charging inductor, a delay circuit operative to charge the peaking capacitor with electrical energy stored in the charging inductor prior to shutting the solid state switch. The very high repetition gas discharge laser system magnetic switch pulsed power system may comprise a step-up transformer comprising a plurality of winding pucks each comprising a turn primary winding around a secondary winding; each of the plurality of pucks contained in at least two separate sections of primary winding pucks laid out on a step-up transfer mounting board at angles to each other generally forming an L or a U or an O shaped compilation having a first and a second end; a cooling plate having a plurality of sections each respectively in thermal contact with a respective one of the at least two separate sections of the primary winding pucks; the cooling plate may comprise a plurality of cooling channels arranged in at least one grouping of a pair of channels extending in a flow direction from the first end to the second end and returning to the first end, from a cooling fluid inlet at the first end to a cooling fluid outlet at the first end. The cooling channels may comprise a channel internal to the cooling plate. The cooling channel may be formed in at least a first half of the cooling plate and the first half of the cooling plate is joined to a second half of the cooling plate. The cooling channel may comprise a cooling fluid duct contained in a cooling fluid duct passage groove formed in a surface of the cooling plate. The cooling fluid duct may comprise thermally conductive tubing. The very high repetition gas discharge laser system magnetic switch pulsed power system may comprise a step-up transformer comprising a plurality of winding pucks each comprising a turn primary winding around a secondary winding; a void space between an internal surface of each respective primary winding puck and an insulation sleeve on the secondary winding; and insulation fluid in the void space. The insulation fluid may comprise a dielectric gas, e.g., a noble gas, e.g., N2, or a dielectric liquid, e.g., a dielectric oil. The very high repetition gas discharge laser system magnetic switch pulsed power system may comprise a solid state switch anti-jitter and anti-drift circuit which may comprise an optoisolator circuit spanning the boundary between the high voltage side of the circuit and the low voltage side of the circuit, which may comprise an opto-transmitter on the low voltage side of the circuit and an opto-receiver on the high voltage side of the circuit. The circuit may comprise a comparator in series with the opto-receiver and the solid state switch between the opto-receiver and the solid state switch. The opto-transmitter may be connected to a trigger input signal and the comparator may be connected to an MOSFET driver circuit.
According to aspects of an embodiment of the present invention an issue to address is that the peak current in the charging inductor of a resonant charger (“RC”) module, e.g., 220 shown illustratively in
In order to deal with this, applicants have proposed the implementation a circuit, shown schematically and partly in block diagram form in
In this manner, the operation of the known resonant charger circuit, e.g., as shown in
Turning now to
The circuit 246 may also comprise an optocoupler 258 connected across the low voltage to high voltage transition of the circuit 246, the high voltage side being connected to a DC/DC converter 270, a model THI-2421, made by TRACO ELECTRONIC AG, Switzerland, which can, e.g., convert a DC voltage supplied by a DC power supply 272 to the DC voltage connected, e.g., to the collector of the IGBT 46, providing a positive rail 274 to negative rail 276 voltage on the emitter 249 of the IGBT 46 when the IGBT switch 46 is shut.
The circuit 246 may also comprise a resistor 282, which may be a 1670 ohm resistor, connected between the positive rail 274 and common ground 249 and two zener diodes 284 in parallel, e.g., a model 1N4734A, made by ON Semiconductor, U.S.A. connected between the negative rail 276 and common ground 249. The circuit 246 may also comprise a capacitor, e.g., a 100 μF 290 connected to the positive rail 274 and the IGBT emitter 249 and a capacitor, e.g., a 100° F. capacitor.
Such a circuit 246, e.g., with a high speed optocoupler 258, e.g., a model HCPL-2611#020 which can be obtained from AGILENT TECHNOLOGIES, U.S. A., an ultrafast MOSFET driver 254, e.g., a model 1×DD404PI, which can be obtained from IXYS CORPORATION, U.S.A. and the fast switching MOSFETs, e.g., model IRFU5305, and IRFU4105, which can be obtained from INTERNATIONAL RECTIFIER, U.S.A., can be utilized to insure, e.g., minimum jitter, turn on delay, turn on time, turn off time, turn-off delay, turn on/off drift and power loss from the receipt of a trigger input signal 259 to the shutting of the IGBT 46 and the application of the voltage on charging capacitor C0 42 onto capacitor C1 52 through inductor L0 48, as illustrated in the circuit of
In operation, e.g., the circuit 246 provides a fully isolated gate driver operable up to relatively high Cpk discharge pulse rates, e.g., around 4000 pulses per second, using the high isolation voltage optocoupler 258, and optoisolator, and the DC/DC converter 270 to isolate the trigger signal 259 from the high voltage side of the circuit 246. The resistor 282 and zener diode 284 can provide voltage regulation to generate the positive rail 274 and reference ground 259. The outputs of the N-channel MOSFET 250 and P-channel MOSFET 252 may be connected common drain for rail to rail output to the IGBT gate 248 and emitter 249, e.g., to ensure reliable operation. The IGBT 46 gate driver 254 may be mounted, close to, e.g., directly on top of the IGBT 46 to minimize inductances. The resistor 254, which may be, e.g., a 100 ohm resistor, in parallel with a diode, e.g., a Schottky, e.g., a model IN5818, made by ON SEMICONDUCTOR, U.S.A. may serve, e.g., to reduce the power loss due to cross conduction of the two MOSFETs 250, 252, e.g., during turn of and turn on periods. When the trigger in signal 259 is low or no trigger in signal 259 exists, the output of the IGBT gate 248 and emitter 249 may be maintained at negative rail, e.g., in order to make sure that the IGBT 46 is off and will not turn on due to electrical noise in the circuit 246. Series gate resistors, e.g., between the MOSFETs 250, 252 outputs to the IGBT gate 248, though such gate resistors (not shown) could be employed. Capacitors 290, 292 may be used to store energy in charging and discharging the IGBT gate 248.
According to aspects of am embodiment of the present invention, as illustrated schematically and partly in block diagram form in
Together the optical transmitter 260 and optical receiver 262, e.g., at higher operating pulse repetition rates, e.g., at about 6 kHz and above may be employed to provide a better voltage isolation between the high voltage side and the low voltage side, because the voltage isolation can be scaled by the length of the optical fiber cable between optical transmitter and optical receiver (as compared with the optocoupler 258 in
Turning now to
In operation, e.g., the first cooling channel 302a upstream of the cooling fluid inlet 210 would contain the coldest water circulating through the cooling fluid system and the cooling channel 302b the hottest water circulating through the cooling water system to the cooling fluid outlet 212, the second coolest fluid of the incoming water stream would be in the cooling channel 304a and the third hottest outlet fluid would be flowing in the outlet cooling channel 304b. Similarly the third coolest inlet cooling fluid and the second hottest outlet cooling fluid would be flowing, respectively in inlet cooling channel 306a and outlet cooling channel 306b, and the fourth coolest inlet cooling water would be flowing in the inlet cooling channel 308a, and the fourth hottest cooling fluid would be flowing in the outlet cooling channel 308b. In this manner approximately on average each section 302, 304, 306 and 308 would have about the same capacity to transfer heat away from its adjoining transformer 56 section 56a, 56b, 56c and 56d. In this arrangement also, e.g., the coolest water entering through cooling fluid input, e.g., from a coolant fluid supply conduit 320, in the cold plate section 302 may serve to also provide some heat removal from the proximate section 308, which, e.g., may be the coolant plate 300 section over the hottest portion 56d of the step-up transformer 56.
It will be understood that the cooling fluid may be a liquid or a gas, though a liquid is preferred and water is used according to aspects of an embodiment of the present invention. In addition, it will also be understood that the cooling channels may be formed to make a plurality of loops around and back through the respective number of sections of the cold plate 300, either from the same single coolant fluid inlet 310 to the same coolant fluid outlet 312 or from a plurality of such coolant inlets and outlets, on pair for each loop of inlet and outlet channels, or a combination thereof. It will also be understood that the coolant channels, e.g., cooling channel 302a, cooling channel 302b. cooling channel 304a, cooling channel 304b, cooling channel 306a, cooling channel 306b, cooling channel 308a, and cooling channel 308b could be formed in a variety of ways, e.g., by forming a channel in at least one half of a cold plate 300, illustrated by way of example in
It will be understood that the cold plate 300 may be attached to the transformer 56, e.g., by extending the length of at least one side 460′ of the pucks 402 to meet the cold plate and attaching the cold plate 300 to such extended sides of the respective puck 402, e.g., by a thermally conductive adhesive, such as Silver Conductive Grease made by ITW Chemtronics, U.S.A., such as is shown in
According to aspects of an embodiment of the present invention, applicants have found that during high voltage operation of the SSPPM transformer 56, corona or partial discharge can develop in the transformer 56 assembly (particularly in the region between the transformer secondary winding 400 and the individual pucks 402). The pucks 402 may each contain a single winding 404 (as shown for example in
Previously applicants' assignee's lasers systems have employed extruded coaxial cable 430, shown, e.g., in
A solution, as illustrated, e.g., in
As can be seen from
Turning now to
Each of the diodes 58′, 58″, 58′″ and 58″″ may comprise a pair of series connected diodes 58′a and b, 58″a and b, 58′″a and b and 58″″a and b, each with a respective resonance bypass circuit. Each of the charging inductors L0 48′, 48″, 48′″ and 48″″ has in this prior art circuit 120 that may be used to bias respective ones of the inductor pairs 48′, 48″ and 48′″, 48″″, e.g., by being magnetically connected, respective to the cores of saturable inductors 48′ a and b on the one hand and 48″″ a and b on the other.
Turning now to
A single biasing circuit 120′ which may comprise a bias inductor 122, in series with a parallel arrangement of two identical RC circuits 124 which may comprise a 24000 μF capacitor 126 across a 5V dc biasing voltage power supply 128 and series with a 0.1 ohm resistor 129, both in parallel with a 12000 μF capacitor 130.
The bias inductor 122 may also be connected in parallel with the saturable portions 48′ a and b and 48″ a and b of the respective charging inductors 48′ and 48″. such an arrangement, in addition to being less costly can provide for a smoother and more echonomical transition of the energy from Charging Capacitor C0 42 to first stage capacitor C1 52 when the solid state switches 46′ and 46″ are closed.
While the particular aspects of embodiment(s) of the 6K PULSE REPETITION RATE AND ABOVE GAS DISCHARGE LASER SYSTEM SOLID STATE PULSE POWER SYSTEM IMPROVEMENTS described and illustrated in this patent application in the detail required to satisfy 35 U.S.C. §112 is fully capable of attaining any above-described purposes for, problems to be solved by or any other reasons for or objects of the aspects of an embodiment(s) above described, it is to be understood by those skilled in the art that it is the presently described aspects of the described embodiment(s) of the present invention are merely exemplary, illustrative and representative of the subject matter which is broadly contemplated by the present invention. The scope of the presently described and claimed aspects of embodiments fully encompasses other embodiments which may now be or may become obvious to those skilled in the art based on the teachings of the Specification. The scope of the present 6K PULSE REPETITION RATE AND ABOVE GAS DISCHARGE LASER SYSTEM SOLID STATE PULSE POWER SYSTEM IMPROVEMENTS is solely and completely limited by only the appended claims and nothing beyond the recitations of the appended claims. Reference to an element in such claims in the singular is not intended to mean nor shall it mean in interpreting such claim element “one and only one” unless explicitly so stated, but rather “one or more”. All structural and functional equivalents to any of the elements of the above-described aspects of an embodiment(s) that are known or later come to be known to those of ordinary skill in the art are expressly incorporated herein by reference and are intended to be encompassed by the present claims. Any term used in the specification and/or in the claims and expressly given a meaning in the Specification and/or claims in the present application shall have that meaning, regardless of any dictionary or other commonly used meaning for such a term. It is not intended or necessary for a device or method discussed in the Specification as any aspect of an embodiment to address each and every problem sought to be solved by the aspects of embodiments disclosed in this application, for it to be encompassed by the present claims. No element, component, or method step in the present disclosure is intended to be dedicated to the public regardless of whether the element, component, or method step is explicitly recited in the claims. No claim element in the appended claims is to be construed under the provisions of 35 U.S.C. § 112, sixth paragraph, unless the element is expressly recited using the phrase “means for” or, in the case of a method claim, the element is recited as a “step” instead of an “act”.
It will be understood by those skilled in the art that the aspects of embodiments of the present invention disclosed above are intended to be preferred embodiments only and not to limit the disclosure of the present invention(s) in any way and particularly not to a specific preferred embodiment alone. Many changes and modification can be made to the disclosed aspects of embodiments of the disclosed invention(s) that will be understood and appreciated by those skilled in the art. The appended claims are intended in scope and meaning to cover not only the disclosed aspects of embodiments of the present invention(s) but also such equivalents and other modifications and changes that would be apparent to those skilled in the art. In additions to changes and modifications to the disclosed and claimed aspects of embodiments of the present invention(s) noted above others could be implemented.
The present application is a continuation-in-part of U.S. patent application Ser. No. 11/241,850, entitled GAS DISCHARGE LASER SYSTEM ELECTRODES AND POWER SUPPLY FOR DELIVERING ELECTRICAL ENERGY TO SAME, filed on Sep. 29, 2005, Attorney Docket No. 2005-0051-01, and claims priority to U.S. Patent Application No. 60/733,052, filed on Nov. 2, 2005, the disclosures of which is hereby incorporated by reference. The present application is related to U.S. Pat. No. 6,690,706, entitled HIGH REP-RATE LASER WITH IMPROVED ELECTRODES, issued to Morton et al. on Feb. 10, 2004, and U.S. Pat. No. 6,882,674, entitled 4 KHZ GAS DISCHARGE LASER SYSTEM, issued to Wittak et al on Apr. 19, 2005; and U.S. Pat. No. 6,442,181, entitled EXTREME REPETITION RATE GAS DISCHARGE LASER, issued to Oliver, et al. on Aug. 27, 2002; and U.S. Pat. No. 5,448,580, entitled AIR AND WATER COOLED MODULATOR, issued to Birx, et al. on Sep. 5, 1995, and U.S. Pat. No. 5,315,611, entitled HIGH AVERAGE POWER MAGNETIC MODULATORS FOR METAL VAPOR LASERS, issued to Ball et al. on May 24, 1994, and U.S. patent application Ser. No. 10/607,407, entitled METHOD AND APPARATUS FOR COOLING MAGNETIC CIRCUIT ELEMENTS, filed on Jun. 25, 2003, published on Dec. 30, 2004, Attorney Docket No. 2003-0051-01; the disclosures of each of which are hereby incorporated by reference.
Number | Date | Country | |
---|---|---|---|
60733052 | Nov 2005 | US |
Number | Date | Country | |
---|---|---|---|
Parent | 11241850 | Sep 2005 | US |
Child | 11300979 | Dec 2005 | US |