Ner
Haim S. Ner, Fair Lawn, NJ US
Patent application number | Description | Published |
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20120281559 | MAXIMUM TRANSFER UNIT (MTU) OPTIMIZATION FOR ADVANCED WIRELESS NETWORKS - A network device is configured to identify a configured maximum segment size value, for a wireless access network associated with the network device, which is calculated to prevent fragmentation over the wireless access network. The network device is configured to receive, from a first computing device, a synchronization message including an initial maximum segment size value for a Transmission Control Protocol (TCP) socket connection between the first computing device and a second computing device that uses the wireless access network. When the initial maximum segment size value is larger than the configured maximum segment size value, the network device is configured to replace the initial maximum segment size value with the configured maximum segment size value to create a modified synchronization message, and send the modified synchronization message to the second computing device for establishing the TCP socket connection. | 11-08-2012 |
20140185452 | Flow Control Methods and Systems for Use with a Wireless Network - An exemplary method includes an interface device 1) detecting a request provided by a user device for a server to transmit data to the user device by way of a base station and a wireless network that connects the user device to the base station, 2) pre-fetching, in response to the request, the data from the server, 3) transmitting the pre-fetched data to the base station for forwarding by the base station to the user device by way of the wireless network, 4) dynamically receiving, as the interface system transmits the pre-fetched data to the base station, queue occupancy information from the base station, and 5) using the queue occupancy information to perform flow control with respect to the transmission of the pre-fetched data by the interface system to the base station. Corresponding methods and systems are also disclosed. | 07-03-2014 |
20140289383 | PROVISIONING OF NETWORK COMMUNICATION PARAMETERS BASED ON DEVICE TYPE - The device type of a user computing device may be used to optimize network communication sessions. In one implementation, an indication of the device type of the user computing device may be received and a communication profile for the user computing device may be determined. The communication profile may be associated with values for a number of parameters relating to one or more communication protocols used to implement communication sessions with the user computing device. One or more network elements, that are involved in the communication sessions with the user computing device, may be provisioned, to cause the one or more network elements to implement the communication protocols, for the user computing device, using the values for the parameters relating to the one or more communication protocols. | 09-25-2014 |
Yogesh Ner, Mcallen, TX US
Patent application number | Description | Published |
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20130234372 | SINGLE STEP POLYMERIZATION OF COVALENTLY BOUND MULTILAYER MATRICES - A method is provided for forming complex tissue using density gradient multilayer polymerization (DGMP) to form strong hydrogels with smooth transitions between layers. The multicompartment hydrogel is formed by co-dissolving a polymer precurser with a constituent in multiple solvent fractions to a create prepolymer solutions with different densities, layering the prepolymer solutions on top of each other from high to low solvent density, and irradiating the prepolymer solutions to form a polymer. The hydrogels may be used as biomimetic matrices. | 09-12-2013 |
20140035177 | DEVICES AND METHODS FOR THE PRODUCTION OF MICROFIBERS AND NANOFIBERS HAVING ONE OR MORE ADDITIVES - Described herein are apparatuses and methods of creating fibers, such as microfibers and nanofibers, which include additives that modify one or more properties of the produced fibers. The methods discussed herein employ centrifugal forces to transform material into fibers. Apparatuses that may be used to create fibers are also described. | 02-06-2014 |
20140159262 | DEVICES AND METHODS FOR THE PRODUCTION OF MICROFIBERS AND NANOFIBERS IN A CONTROLLED ENVIRONMENT - Described herein are apparatuses and methods of creating fibers, such as microfibers and nanofibers. The methods discussed herein employ centrifugal forces to transform material into fibers. Apparatuses that may be used to create fibers are also described. To improve the formation of fibers, various devices and systems for controlling the micro-environment around the fiber producing device are described. | 06-12-2014 |
Yogesh J. Ner, Willimantic, CT US
Patent application number | Description | Published |
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20090311799 | Nucleic Acid Materials for Nonradiative Energy Transfer and Methods of Production and Use - Nucleic acid materials for FRET-based luminescence and methods of making and using the nucleic acid materials are provided. The nucleic acid materials provide an innovative and synergistic combination of three disparate elements: a nucleic acid material, the processing technique for forming a nucleic acid material into films, fibers, nanofibers, or non-woven meshes, and nonradiative energy transfer. This combination can be formed into electrospun fibers, nanofibers, and non-woven meshes of a nucleic acid material-cationic lipid complex with encapsulated chromophores capable of nonradiative energy transfer such as efficient Förster Resonance Energy Transfer (FRET). | 12-17-2009 |
20100288343 | Nucleic acid-based photovoltaic cell - Photovoltaic cells containing nucleic acid materials and methods of production and use are provided. The nucleic acid materials have photovoltaic donor and acceptor molecules incorporated therein and define a spatial organization and orientation for these molecules that inhibits recombination of excitons and promotes efficiency in the photovoltaic cell. Preferred nucleic acid materials contain nucleic acid molecules complexed with ionic surfactants and are in the form of films, fibers, nanofibers, or non-woven meshes. | 11-18-2010 |