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Frederick E Palenschat

from Lemon Grove, CA
Age ~86
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Also known as:
Frederick A Palenschat, Fred Palenschat, Frederick T
Phone and address:
8177 Alton Dr, Lemon Grove, CA 91945
(619) 465-7274
Related to:
Tae Kook Kim, 54Young Kim, 70Julie Crispin, 46Gwen Parker, 45Richard Kim, 62
Connected to:
Aaron C Palenske, 31Caitlin A Palensky, 37Garner A Palenske, 97Jill Palenstijn, 52Albert G Palentchar, 72Maria Palenzuela, 50Mary A Palenzuela, 54Ryan J Palenzuela, 31Xiomara Palenzuela, 76Alex Paleo, 37

Frederick Palenschat Phones & Addresses

  • 8177 Alton Dr, Lemon Grove, CA 91945 (619) 465-7274
  • 13702 Shoal Summit Dr, San Diego, CA 92128 (858) 673-1185
  • 14966 Avenida Venusto, San Diego, CA 92128
  • Chula Vista, CA
  • 8167 Pasadena Ave, La Mesa, CA 91941
  • 8177 Alton Dr, Lemon Grove, CA 91945

Work

Position: Retired

Education

Degree: Associate degree or higher

Emails

s***[email protected]

Industries

Design

Resumes

Resumes

Frederick Palenschat Photo 1

Frederick Palenschat

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Location:
Greater San Diego Area
Industry:
Design

Publications

Us Patents

Laser Wavelength Control Unit With Piezoelectric Driver

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US Patent:
6650666, Nov 18, 2003
Filed:
Dec 21, 2001
Appl. No.:
10/027210
Inventors:
Ronald L. Spangler - Arlington MA
Robert N. Jacques - Andover MA
John A. Rule - Hingham MA
Frederick A. Palenschat - Lemon Grove CA
Igor V. Fomenkov - San Diego CA
John M. Algots - San Diego CA
Jacob P. Lipcon - Winchester MA
Richard L. Sandstrom - Encinitas CA
Assignee:
Cymer, Inc. - San Diego CA
International Classification:
H01S 310
US Classification:
372 20, 372 57
Abstract:
An electric discharge laser with fast wavelength correction. Fast wavelength correction equipment includes at least one piezoelectric drive and a fast wavelength measurement system and fast feedback response times. In a preferred embodiment, equipment is provided to control wavelength on a slow time frame of several milliseconds, on a intermediate time from of about one to five milliseconds and on a very fast time frame of a few microseconds. Preferred techniques include a combination of a relatively slow stepper motor and a very fast piezoelectric driver for tuning the laser wavelength using a tuning mirror. A preferred control technique is described (utilizing a very fast wavelength monitor) to provide the slow and intermediate wavelength control with the combination of a stepper motor and a piezoelectric driver. Very fast wavelength control is provided with a piezoelectric load cell in combination with the piezoelectric driver. Preferred embodiments provide (1) fast feedback control based on wavelength measurements, (2) fast vibration control, (3) active damping using the load cell and an active damping module, (4) transient inversion using feed forward algorithms based on historical burst data.

Six To Ten Khz, Or Greater Gas Discharge Laser System

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US Patent:
6914919, Jul 5, 2005
Filed:
Jun 28, 2002
Appl. No.:
10/187336
Inventors:
Tom A. Watson - Carlsbad CA, US
Richard C. Ujazdowski - San Diego CA, US
Alex P. Ivaschenko - San Diego CA, US
Richard L. Sandstrom - Encinitas CA, US
Robert A. Shannon - Ramona CA, US
R. Kyle Webb - Escondido CA, US
Frederick A. Palenschat - Lemon Grove CA, US
Thomas Hofmann - San Diego CA, US
Curtis L. Rettig - Vista CA, US
Richard M. Ness - San Diego CA, US
Paul C. Melcher - El Cajon CA, US
Alexander I. Ershov - San Diego CA, US
Assignee:
Cymer, Inc. - San Diego CA
International Classification:
H01S003/10
H01S003/22
US Classification:
372 25, 372 55, 372 57, 372 58
Abstract:
The present invention provides gas discharge laser systems capable of reliable long-term operation in a production line capacity at repetition rates in the range of 6,000 to 10,0000 pulses power second. Preferred embodiments are configured as KrF, ArF and Flasers used for light sources for integrated circuit lithography. Improvements include a modified high voltage power supply capable for charging an initial capacitor of a magnetic compression pulse power system to precise target voltages 6,000 to 10,0000 times per second and a feedback control for monitoring pulse energy and determining the target voltages on a pulse-by-pulse basis. Several techniques are disclosed for removing discharge created debris from the discharge region between the laser electrodes during the intervals between discharges. In one embodiment the width of the discharge region is reduced from about 3 mm to about 1 mm so that a gas circulation system designed for 4,000 Hz operation could be utilized for 10,000 Hz operation. In other embodiments the gas flow between the electrodes is increased sufficiently to permit 10,000 Hz operation with a discharge region width of 3 mm.

High Repetition Rate Laser Produced Plasma Euv Light Source

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US Patent:
7087914, Aug 8, 2006
Filed:
Mar 17, 2004
Appl. No.:
10/803526
Inventors:
Robert P. Akins - Escondido CA, US
Richard L. Sandstrom - Encinitas CA, US
William N. Partlo - Poway CA, US
Igor V. Fomenkov - San Diego CA, US
John Martin Algots - San Diego CA, US
Robert N. Jacques - La Jolla CA, US
Frederick Palenschat - Lemon Grove CA, US
Jun Song - San Diego CA, US
Assignee:
Cymer, INC - San Diego CA
International Classification:
H01J 35/20
US Classification:
250504R, 2504931, 378119
Abstract:
An EUV light source apparatus and method are disclosed, which may comprise a pulsed laser providing laser pulses at a selected pulse repetition rate focused at a desired target ignition site; a target formation system providing discrete targets at a selected interval coordinated with the laser pulse repetition rate; a target steering system intermediate the target formation system and the desired target ignition site; and a target tracking system providing information about the movement of target between the target formation system and the target steering system, enabling the target steering system to direct the target to the desired target ignition site. The target tracking system may provide information enabling the creation of a laser firing control signal, and may comprise a droplet detector comprising a collimated light source directed to intersect a point on a projected delivery path of the target, having a respective oppositely disposed light detector detecting the passage of the target through the respective point, or a detector comprising a linear array of a plurality of photo-sensitive elements aligned to a coordinate axis, the light from the light source intersecting a projected delivery path of the target, at least one of the which may comprise a plane-intercept detection device. The droplet detectors may comprise a plurality of droplet detectors each operating at a different light frequency, or a camera having a field of view and a two dimensional array of pixels imaging the field of view. The apparatus and method may comprise an electrostatic plasma containment apparatus providing an electric plasma confinement field at or near a target ignition site at the time of ignition, with the target tracking system providing a signal enabling control of the electrostatic plasma containment apparatus.

Laser Wavelength Control Unit With Piezoelectric Driver

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US Patent:
20020006149, Jan 17, 2002
Filed:
Feb 27, 2001
Appl. No.:
09/794782
Inventors:
Ronald Spangler - Arlington MA, US
Robert Jacques - Andover MA, US
George Everage - Escondido CA, US
Stuart Anderson - San Diego CA, US
Frederick Palenschat - Lemon Grove CA, US
Igor Fomenkov - San Diego CA, US
Richard Sandstrom - Encinitas CA, US
William Partlo - Poway CA, US
John Algots - San Diego CA, US
Daniel Brown - San Diego CA, US
International Classification:
H01S003/03
H01S003/22
US Classification:
372/061000, 372/055000
Abstract:
An electric discharge laser with fast wavelength correction. Fast wavelength correction equipment includes at least one piezoelectric drive and a fast wavelength measurement system and fast feedback response times. In a preferred embodiment, equipment is provided to control wavelength on a slow time frame of several milliseconds, on a intermediate time from of about one to three millisecond and on a very fast time frame of a few microseconds. Techniques include a combination of a relatively slow stepper motor and a very fast piezoelectric driver for tuning the laser wavelength using a tuning mirror. A preferred control technique is described (utilizing a very fast wavelength monitor) to provide the slow and intermediate wavelength control and a piezoelectric load cell in combination with the piezoelectric driver to provide the very fast (few microseconds) wavelength control.

Discharge Produced Plasma Euv Light Source

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US Patent:
20040160155, Aug 19, 2004
Filed:
Dec 18, 2003
Appl. No.:
10/742233
Inventors:
William Partlo - Poway CA, US
Gerry Blumenstock - San Diego CA, US
Norbert Bowering - San Diego CA, US
Kent Bruzzone - Cardiff by the Sea CA, US
Dennis Cobb - Lake Arrowhead CA, US
Timothy Dyer - Oceanside CA, US
John Dunlop - San Diego CA, US
Igor Fomenkov - San Diego CA, US
James Hysham - Oceanside CA, US
I. Oliver - San Diego CA, US
Frederick Palenschat - Lemon Grove CA, US
Xiaojiang Pan - San Diego CA, US
Curtis Rettig - Vista CA, US
Rodney Simmons - San Diego CA, US
John Walker - Escondido CA, US
R. Webb - Escondido CA, US
Thomas Hofmann - San Diego CA, US
International Classification:
H01J017/26
H01J061/28
US Classification:
313/231310
Abstract:
An DPP EUV source is disclosed which may comprise a debris mitigation apparatus employing a metal halogen gas producing a metal halide from debris exiting the plasma. The EUV source may have a debris shield that may comprise a plurality of curvilinear shield members having inner and outer surfaces connected by light passages aligned to a focal point, which shield members may be alternated with open spaces between them and may have surfaces that form a circle in one axis of rotation and an ellipse in another. The electrodes may be supplied with a discharge pulse shaped to produce a modest current during the axial run out phase of the discharge and a peak occurring during the radial compression phase of the discharge. The light source may comprise a turbomolecular pump having an inlet connected to the generation chamber and operable to preferentially pump more of the source gas than the buffer gas from the chamber. The source may comprise a tuned electrically conductive electrode comprising: a differentially doped ceramic material doped in a first region to at least select electrical conductivity and in a second region at least to select thermal conductivity. The first region may be at or near the outer surface of the electrode structure and the ceramic material may be SiC or alumina and the dopant is BN or a metal oxide, including SiO or TiO. The source may comprise a moveable electrode assembly mount operative to move the electrode assembly mount from a replacement position to an operating position, with the moveable mount on a bellows. The source may have a temperature control mechanism operatively connected to the collector and operative to regulate the temperature of the respective shell members to maintain a temperature related geometry optimizing the glancing angle of incidence reflections from the respective shell members, or a mechanical positioner to position the shell members. The shells may be biased with a voltage. The debris shield may be fabricated using off focus laser radiation. The anode may be cooled with a hollow interior defining two coolant passages or porous metal defining the passages. The debris shield may be formed of pluralities of large, intermediate and small fins attached either to a mounting ring or hub or to each other with interlocking tabs that provide uniform separation and strengthening and do not block any significant amount of light.

6 Khz And Above Gas Discharge Laser System

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US Patent:
20060222034, Oct 5, 2006
Filed:
Mar 31, 2005
Appl. No.:
11/095976
Inventors:
Richard Ujazdowski - Poway CA, US
Richard Ness - San Diego CA, US
J. Algots - San Diego CA, US
Vladimir Fleurov - Escondido CA, US
Frederick Palenschat - San Diego CA, US
Walter Gillespie - Poway CA, US
Bryan Moosman - San Marcos CA, US
Thomas Steiger - San Diego CA, US
Brett Smith - Murrieta CA, US
Thomas McKelvey - Ramona CA, US
Assignee:
Cymer, Inc. - San Diego CA
International Classification:
H01S 3/22
H01S 3/223
US Classification:
372057000, 372055000
Abstract:
A high pulse repetition rate gas discharge laser system pulse power system magnetic reactor may comprise a housing comprising a core containing compartment between an inner wall of the housing, an outer wall and a bottom wall of the housing; a cooling mechanism operative to withdraw heat from the at least one of the inner wall, outer wall and bottom of the housing; at least one two magnetic cores contained within the core containing compartment; a cooling fin disposed between each of the at least two magnetic cores; and a thermal conductivity enhancement mechanism intermediate at least one of each respective cooling fin and each respective core and a respective one of the inner wall, the outer wall or the bottom wall, the thermal conductivity enhancement mechanism comprising a band comprising a plurality of torsion spring or leaf spring elements.

High Repetition Rate Laser Produced Plasma Euv Light Source

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US Patent:
20080197297, Aug 21, 2008
Filed:
Jun 20, 2006
Appl. No.:
11/471434
Inventors:
Robert P. Akins - Escondido CA, US
Richard L. Sandstrom - Encinitas CA, US
William N. Partlo - Poway CA, US
Igor V. Fomenkov - San Diego CA, US
Thomas D. Steiger - San Diego CA, US
John Martin Algots - San Diego CA, US
Norbert Bowering - San Diego CA, US
Robert N. Jacques - San Diego CA, US
Frederick Palenschat - San Diego CA, US
Jun Song - San Diego CA, US
International Classification:
G01J 3/10
US Classification:
250504 R
Abstract:
An EUV light source apparatus and method are disclosed, which may comprise a pulsed laser providing laser pulses at a selected pulse repetition rate focused at a desired target ignition site; a target formation system providing discrete targets at a selected interval coordinated with the laser pulse repetition rate; a target steering system intermediate the target formation system and the desired target ignition site; and a target tracking system providing information about the movement of target between the target formation system and the target steering system, enabling the target steering system to direct the target to the desired target ignition site. The target tracking system may provide information enabling the creation of a laser firing control signal, and may comprise a droplet detector comprising a collimated light source directed to intersect a point on a projected delivery path of the target, having a respective oppositely disposed light detector detecting the passage of the target through the respective point, or a detector comprising a linear array of a plurality of photo-sensitive elements aligned to a coordinate axis, the light from the light source intersecting a projected delivery path of the target, at least one of the which may comprise a plane-intercept detection device. The droplet detectors may comprise a plurality of droplet detectors each operating at a different light frequency, or a camera having a field of view and a two dimensional array of pixels imaging the field of view. The apparatus and method may comprise an electrostatic plasma containment apparatus providing an electric plasma confinement field at or near a target ignition site at the time of ignition, with the target tracking system providing a signal enabling control of the electrostatic plasma containment apparatus. The apparatus and method may comprise a vessel having and intermediate wall with a low pressure trap allowing passage of EUV light and maintaining a differential pressure across the low pressure trap. The apparatus and method may comprise a magnetic plasma confinement mechanism creating a magnetic field in the vicinity of the target ignition site to confine the plasma to the target ignition site, which may be pulsed and may be controlled using outputs from the target tracking system.

6 Khz And Above Gas Discharge Laser System

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US Patent:
20120120974, May 17, 2012
Filed:
Jan 17, 2012
Appl. No.:
13/352127
Inventors:
Richard C. Ujazdowski - Poway CA, US
Richard M. Ness - San Diego CA, US
J. Martin Algots - San Diego CA, US
Vladimir B. Fleurov - Escondido CA, US
Frederick A. Palenschat - San Diego CA, US
Walter D. Gillespie - Poway CA, US
Bryan G. Moosman - San Marcos CA, US
Thomas D. Steiger - San Diego CA, US
Brett D. Smith - Murrieta CA, US
Thomas E. McKelvey - Ramona CA, US
International Classification:
H01S 3/041
H01S 3/03
US Classification:
372 34, 372 65, 372 61
Abstract:
A system and method of operating a high repetition rate gas discharge laser system. The system includes a gas discharge chamber having a hot chamber output window heated by the operation of the gas discharge laser chamber, an output laser light pulse beam path enclosure downstream of the hot chamber window and comprising an ambient temperature window, a cooling mechanism cooling the beam path enclosure intermediate the output window and the ambient window. The gas discharge chamber can include a longitudinally and axially compliant ground rod, including a first end connected to a first chamber wall, a second end connected to a second chamber wall, the second chamber wall opposite the first chamber wall and a first portion formed into a helical spring, the ground rod providing mechanical support for a preionizer tube.
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Frederick E Palenschat from Lemon Grove, CA, age ~86 Get Report