Patent application number | Description | Published |
20080225903 | UNSTABLE MONOBLOCK LASER CAVITY WITH INTEGRATED BEAM EXPANDER - A monoblock laser cavity includes a plurality of discrete optical components disposed serially on a substrate and sharing a common optical axis. The optical components include a laser rod of gain material, a Q-switch, an OPO crystal, an output coupler, and a positive lens. The output coupler has a convex input end face and a concave output end face, and acts as the expanding lens element of a beam expander, and the positive lens completes the beam expander to improve the beam quality. | 09-18-2008 |
20080225923 | UNSTABLE MONOBLOCK LASER CAVITY - A monoblock laser cavity includes a plurality of discrete optical components disposed serially on a substrate and sharing a common optical axis. The optical components include a laser rod of gain material, a Q-switch, an OPO crystal, and an output coupler. The output coupler has at least one convex end face to improve the beam quality. | 09-18-2008 |
20090059993 | MONO-SLAB LASER CAVITY - A YAG/Nd:YAG block where an Nd:YAG block ends in a peak integrated inside a YAG block. The YAG block has reflective surfaces positioned at 45° to one another. The angled reflective surfaces serve as a “mirror” within the laser cavity to effectively increase the length of the cavity by a factor greater than 2. Fused to the output end of the laser cavity are a polarizer, an active/passive Q-switch, a one quarter waveplate and an output coupler. In operation, the laser cavity is pumped either from the side or the end of the cavity. The optical components of the present invention are bonded to form one optical ‘block’. All the components are prealigned during the crystal manufacturing process to form the optical laser cavity. The width of the cavity should be selected such that nearly all of the laser diode pump output is absorbed by the cavity. | 03-05-2009 |
20090122818 | ELECTRONIC SELECTABLE TWO-COLOR SOLID STATE LASER - An electronic selectable, two color solid state laser comprising a laser diode pump and a plurality of discrete optical elements disposed serially and sharing a common optical axis. The optical components include a laser rod of gain material having a laser emission wavelength, a polarizer cube, a means for compensating for OPO crystal polarization, an electro-optic active Q-switch having input terminals for applying a voltage across the Q-switch, and an OPO crystal. The laser rod has an input end face coated with an anti-reflector at the laser diode pump wavelength and a high reflector at the laser emission wavelength. The OPO crystal has an input end face coated with an anti-reflector at the laser emission wavelength and a high reflector at the OPO wavelength, and an output end face coated with a partial reflector at the laser emission wavelength and a partial reflector at the OPO wavelength. | 05-14-2009 |
20100189140 | Laser Diode End Pumped Monoblock Laser - A monoblock laser that has a laser cavity having a laser gain material, a Q switch optically coupled to the laser gain material, and an OPO material optically coupled to the Q switch. A laser pump is spaced from an end of the laser cavity. The laser pump has an output that is absorbed along an entire length of the laser cavity providing athermal operation without temperature control of the laser pump over the operating range of the monoblock laser. | 07-29-2010 |
20110051138 | PROCESS TO OPTICALLY ALIGN A PHOTORECEIVER WITH A LASER TRANSMITTER SOURCE IN A LASER RANGEFINDER SYSTEM - A process for optically aligning a laser rangefinder that includes the steps of providing a laser rangefinder having a laser source, a photodetector lens and a photodetector, providing a fiber optic travel path, aligning the laser source to the fiber optic travel path, illuminating the photodetector with a light source, focusing the photodetector lens, coupling the fiber optic travel path to an optical light source, and aligning the fiber optic light relative to the photodetector. | 03-03-2011 |
20110188522 | REDUCTION OF TIMING JITTER IN A PASSIVE Q-SWITCHED SOLID STATE LASER - A method and device for reducing the timing jitter in a passive Q-switched Nd:YAG solid state laser by spatially selective bleaching a thin sheet of a saturable absorber of Cr | 08-04-2011 |
20110286476 | Suppression of Parasitic Lasing - A laser gain medium crystal comprising a square rod of laser gain medium material having top and bottom surfaces that are finely ground to introduce scattering surfaces to cancel parasitic lasing. The square rod of laser gain material has input and output faces and side surfaces, and portions of the side surfaces near the output face of the square rod are finely ground to introduce scattering surfaces to cancel parasitic lasing. The rest of the side surfaces of the square rod are polished. | 11-24-2011 |
20120027034 | Beam Quality of the Monoblock Laser Through Use of a 1.5 Micron External Cavity Partial Reflector - A monoblock laser cavity incorporates optical components for a short-pulse laser. These optical components are ‘locked’ into alignment forming an optical laser cavity for flash lamp or diode laser pumping. The optical laser cavity does not need optical alignment after it is fabricated, increasing the brightness of the monoblock laser. | 02-02-2012 |
20130044769 | MEMS Q-Switched Monoblock Laser - A monoblock laser cavity incorporates optical components required for a short-pulse laser. These optical components are ‘locked’ into alignment forming an optical laser cavity for flash lamp or diode laser pumping. Optical alignment is not necessary after the optical laser cavity is fabricated. An exemplary Q-switched monoblock laser replaces the Cr:YAG Q-switch functionality with a MEMS scanner. | 02-21-2013 |
20130094525 | MEMS Q-Switched Er:Yb:Glass Laser - The compact Er:Yb:Glass Laser Cavity incorporates all optical components required for a short-pulse laser. These optical components are ‘locked’ into alignment forming an optical laser cavity for diode laser or flash lamp pumping. The optical laser cavity does not need optical alignment after it is fabricated. The improvement upon the original Er:Yb:Glass design replaces the Cobalt Spinel passive Q-switch component with a MEMS active Q-Switch component. | 04-18-2013 |
20130094526 | MEMS Q-Switched Nd:YLF Monoblock Laser - A monoblock laser cavity incorporates optical components for a short-pulse laser. These optical components are ‘locked’ into alignment forming an optical laser cavity for flash lamp or diode laser pumping. The optical laser cavity does not need further optical alignment upon fabrication. The improvements upon the original Monoblock design replaces the Cr:YAG Q-switch component with a MEMS scanner and replaces the Nd:YAG with Nd:YLF laser material. | 04-18-2013 |
20140150326 | Process to Optically Align Optical Systems on a Weapon - A process to optically align optical systems on a weapon is disclosed. Several different embodiments of the system and method are disclosed. The use of this process/system will ensure a well aligned weapon with mounted optical systems. It can find applications in aligning rifle scopes, aiming lasers, laser range finders, tactical engagement simulation lasers, e.g., MILES, etc. | 06-05-2014 |