Mark Alan Osterkamp, 573601 Red Bud Dr, Weatherford, TX 76087

7370532, May 13, 2008

Jan 11, 2002

10/044408

Mark Alan Osterkamp - Weatherford TX, US

Lockheed Martin Corporation - Bethesda MD

G01P 3/04
H04B 7/00

73510, 73 179, 73584, 73488, 455 412, 455 413

A system including a processor, a high-energy density system linked to the processor, and a communicator linked to the processor. The communicator comprehensively integrates a plurality of hardware and software functions associated with operating the high-energy density system into a single, convenient interface. In one exemplary embodiment, the communicator comprises a wireless communicator. In operation, the communicator generates a command signal whereby the command signal is received by the processor. Accordingly, the processor controls the high-energy density system based on the command signal. In one aspect, the communicator interfaces with a security system for selectively limiting user access through a restricted system. In another aspect, the communicator is used for object information storage and retrieval associated with operating a high-energy density system, such as an ultrasonic laser system. In another aspect, the communicator is used to control a robotic device.

7463363, Dec 9, 2008

Aug 5, 2003

10/634342

Mark A. Osterkamp - Fort Worth TX, US

Lockheed Martin Corporation - Bethesda MD

G01B 9/02

356502, 356432

The present invention for detecting ultasonic displacements includes a detection laser to generate a first pulsed laser beam to generate the ultrasonic surface displacements on a surface of the target. A seocond pulsed laser beam to detect the ultrasonic surface displacements on a surface of the target. Collection optics to collect phase modulated light from the first pulsed laser beam either reflected or scattered by the target. An interferometer which processes the phase modulated light and generate at least one output signal. A processor that processes the at least one output signal to obtain data representative of the ultrasonic surface displacements at the target.

7734133, Jun 8, 2010

May 15, 2008

12/121559

Marc Dubois - Keller TX, US
Mark A. Osterkamp - Weatherford TX, US

Lockheed Martin Corporation - Bethesda MD

G02B 6/26
G02B 6/42
G02B 6/32
G01N 9/24
G01N 29/00
G01H 11/00
G01N 24/00
G01N 29/04

385 38, 385 31, 385 33, 73643, 73649, 73570, 73618, 73620

A laser transmission system is used for inspecting workpieces. The system has a source of laser beams that is coupled to a first lens assembly. A first hollow core waveguide is operably coupled to the first lens assembly. An end of an optical fiber coupled to the first hollow core waveguide. A second hollow core waveguide is coupled to the other end of the optical fiber. A second lens assembly operably coupled to the second hollow core waveguide. The length of the hollow core waveguides range from about 5 to 100 times the focal lengths of the lens assemblies. A motion control system is operably coupled to the second hollow core waveguide and the second lens assembly for controllably displacing the second hollow core waveguide and the second lens assembly with respect to a workpiece.

7784348, Aug 31, 2010

Feb 21, 2007

11/709342

Marc Dubois - Keller TX, US
Kenneth Yawn - Weatherford TX, US
Mark Osterkamp - Weatherford TX, US

Lockheed Martin Corporation - Bethesda MD

G01N 29/06
G01N 29/26

73621, 73620, 73643

An ultrasonic non-destructive evaluation (NDE) system operable to inspect target materials is provided. This ultrasonic NDE system includes an articulated robot, an ultrasound inspection head, a processing module, and a control module. The ultrasound inspection head couples to or mounts on the articulated robot. The ultrasound inspection head is operable to deliver a generation laser beam, a detection laser beam, and collect phase modulated light scattered by the target materials. The processing module processes the phase modulated light and produces information about the internal structure of the target materials. The control module directs the articulated robot to position the ultrasound inspection head according to a pre-determined scan plan.

8220335, Jul 17, 2012

May 16, 2008

12/122034

Marc Dubois - Fort Worth TX, US
Mark A. Osterkamp - Weatherford TX, US
David L. Kaiser - Fort Worth TX, US
Tho X. Do - Fort Worth TX, US

Lockheed Martin Corporation - Bethesda MD

G01N 29/04
G01S 5/02

73618, 345419, 348135

A system and method for the analysis of composite materials. Improved techniques for the measurement of the shape and position of the composite article are provided, which include improved scanning rates using structured light.

2009028, Nov 19, 2009

May 16, 2008

12/122119

Marc Dubois - Fort Worth TX, US
David L. Kaiser - Fort Worth TX, US
Mark A. Osterkamp - Weatherford TX, US

LOCKHEED MARTIN CORPORATION - Bethesda MD

G01B 11/30
G01B 17/00

702 39, 702152

A system and method for the analysis of composite materials. Laser ultrasound measurements of composite materials are correlated to the shape and position of the composite article.

2009028, Nov 19, 2009

May 16, 2008

12/122158

Marc Dubois - Fort Worth TX, US
Mark A. Osterkamp - Weatherford TX, US
David L. Kaiser - Fort Worth TX, US
Tho X. Do - Fort Worth TX, US
Kenneth R. Yawn - Weatherford TX, US

LOCKHEED MARTIN CORPORATION - Bethesda MD

G01B 11/00

702152

A system and method for the analysis of composite materials. Structured light measurements are used to determine the 3-dimensional shape of an object, which is then analyzed to minimize the number of scans when performing laser ultrasound measurements.

2012003, Feb 9, 2012

Aug 8, 2011

13/205325

Mark A. Osterkamp - Weatherford TX, US
Kenneth R. Yawn - Weatherford TX, US
Alan J. Norris - Southlake TX, US

PaR Systems, Inc. - Shoreview MN

G01N 21/01

356244

Containerized systems are provided. In one embodiment, a containerized system includes a moveable three-dimensional container, a first generator, a second generator, and a scanner. The first generator is located within the container, and the second generator is located outside of the container. The scanner is mechanically supported by the container and transmits waves received from the first and the second generators. The containerized system optionally includes one or more rails connected to the outside of the container, and the scanner moves along the one or more rails. The containerized system may also include a multi-axes arm that positions the scanner and that is mechanically supported by the container. Furthermore, the containerized system may include an interferometer, an electronics rack, and/or an air conditioning unit.