Dogariu
Aristide Dogariu, Winter Springs, FL US
Patent application number | Description | Published |
---|---|---|
20090091741 | Optical coagulation monitor and method of use - An optical coagulation monitor and the method of monitoring blood coagulation status are disclosed. The method includes positioning a sample probe containing an optical fiber within a circulating blood; transmitting a low-coherence light through the optical fiber into the blood; detecting dynamic light scatter signals generated by the blood within a coherence volume and received through the optical fiber; analyzing the dynamic light scatter signals in comparison to a predetermined coagulation criterion; and reporting the coagulation status of the blood. The method can be used for monitoring blood coagulation status in vivo or in vitro in real time. Further disclosed is a method of determining blood clotting time in vitro using the optical coagulation monitor. | 04-09-2009 |
20100301234 | Systems and Methods for Controlling Objects - Systems and methods for controlling an object are disclosed. In one embodiment, a system and method pertain to irradiating the object with polarized electromagnetic radiation for a duration of time sufficient to effect a physical change with the object. | 12-02-2010 |
20130271946 | SYSTEMS AND METHODS FOR CONTROLLING OBJECTS - Systems and methods for controlling an object are disclosed. In one embodiment, a system and method pertain to irradiating the object with polarized electromagnetic radiation for a duration of time sufficient to effect a physical change with the object. | 10-17-2013 |
Arthur Dogariu, Hamilton, NJ US
Patent application number | Description | Published |
---|---|---|
20080245964 | Method and Apparatus for Detecting Surface and Subsurface Properties of Materials - A method and apparatus for remotely monitoring properties of gases and plasmas, and surface and sub-surface properties of materials, is disclosed. A laser beam is focused at a desired region within a gas, plasma, or material (e.g., solid or liquid) to be analyzed, generating an ionized sample region or a localized, enhanced free carrier region. A beam of microwave radiation is directed toward the ionized sample region or the free carrier region, and the microwave radiation is scattered. The scattered microwave radiation is received by a microwave receiver, and is processed by a microwave detection system to determine properties of the gas, plasma, or material, including surface and sub-surface properties. | 10-09-2008 |
20140064316 | SYSTEMS AND METHODS FOR LASING FROM A MOLECULAR GAS - Systems and methods for lasing molecular gases, and systems and methods of detecting molecular species are provided. The systems and methods can include the use of an excitation laser tuned to a wavelength associated with oxygen or nitrogen. The lasing can occur in both the forward and reverse directions relative to the excitation laser beam. Reverse lasing can provide a laser beam that propagates back toward the excitation laser source, and can provide a method for remote sampling of molecular species contained in the air. For example, systems and methods of detecting a molecular species of interest can be achieved by using the properties of the backward or forward propagating air laser to indicate a change in a pulse from the source of laser pulses caused by a modulation laser tuned to interact with the molecular species of interest. | 03-06-2014 |
20140071256 | FEMTOSECOND LASER EXCITATION TAGGING ANEMOMETRY - An apparatus for the imaging of gaseous fluid motion is disclosed. The apparatus includes a sub-nanosecond pulsed laser. The sub-nanosecond pulsed laser is configured to cause a particle species to fragment and for the recombining fragments subsequently to fluoresce. The apparatus also includes a gaseous fluid comprised of particle species. The apparatus also includes a time gated camera. The time gated camera configured to capture at least one image of the fluorescence from the recombining particle fragment species displaced after a specific time lapse following the laser pulse. Additionally, a fluid velocity can be calculated from a comparison of the image of the displaced particle species to an initial reference position and the time lapse. A Femtosecond Laser Electronic Excitation Tagging (FLEET) method of using the disclosed apparatus is also disclosed. | 03-13-2014 |
Markus Dogariu, Regensburg DE
Patent application number | Description | Published |
---|---|---|
20140291119 | DEVICE AND METHOD FOR TRANSFERRING ELECTRONIC COMPONENTS FROM A FIRST CARRIER TO A SECOND CARRIER - A device for transferring electronic components from a first carrier to a second carrier. A first receiving portion positions the first carrier on a support, wherein the electronic components are provided on a side of the first carrier, which faces away from the support. A second receiving portion positions the second carrier. The first receiving portion and the second receiving portion are arranged with respect to each other in such a manner that a gap separates the first carrier from the second carrier. A cap and/or the second receiving portion move from a first position into a second position to make the gap smaller. At least one slide lifts the first carrier, which is applied against the support, away from the support, and to move an electronic component provided on the first carrier, in the direction of the second carrier. | 10-02-2014 |
Michael J. Dogariu, Chesterfield Township, MI US
Patent application number | Description | Published |
---|---|---|
20090317697 | VEHICULAR COMBINATION CHILLER BYPASS SYSTEM AND METHOD - A chiller bypass system is provided for deployment onboard a vehicle that includes a battery pack through which a first coolant is circulated. In one embodiment, the chiller bypass system comprises a chiller, a chiller bypass duct fluidly coupled to the battery pack and configured to supply the first coolant thereto, and a chiller bypass valve. The chiller bypass valve includes: (i) a valve inlet fluidly coupled to the battery pack and configured to receive the first coolant therefrom, (ii) a first valve outlet fluidly coupled to the chiller and configured to supply the first coolant thereto, and (iii) a second valve outlet fluidly coupled to the chiller bypass duct and configured to supply the first coolant thereto. The chiller bypass valve selectively directs coolant flow between the first valve outlet and the second valve outlet to adjust the volume of the first coolant cooled by the chiller. | 12-24-2009 |