Gunturu
Naga Veera Venkata Gunturu, Hyderabad IN
Patent application number | Description | Published |
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20150365845 | WIRELESS COMMUNICATION SYSTEM WITH SIPTO CONTINUITY - A communication system network element includes a Local Gateway co-located with a Home eNodeB. The Local Gateway has an open flow switch and a flow table, and provides service continuity of active SIPTO (selective IP traffic offload) sessions using open flow/software defined networking. An operator-controlled Open flow controller manages sessions at the Local Gateway. A flow modification feature is used to modify an existing flow in the flow table, which provides a means for interception and handover from a source Home eNodeB to a target Home eNodeB. | 12-17-2015 |
Rajasekhar R. Gunturu, Aurora, IL US
Patent application number | Description | Published |
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20130103830 | Time Monitor - A method and system for measuring latency is provided. A monitor node is used to measure latency in a computer network or in a computing device by time stamping signal messages sent from nodes in the computer network and/or tasks in a particular node or device. The time stamps are generated using a system clock of the monitor node to reduce any discrepancies in timing. In addition, the monitor node may compensate for latencies between the monitor node and each of the one or more nodes or devices across which latency is to be measured. Signal messages may include a data message ID and/or a node ID identifying the message that is being tracked and for which latency is being measured. Latency may further be measured across multiple tasks being performed in the same or different nodes or devices by transmitting signal messages for each of the multiple tasks. | 04-25-2013 |
20150156097 | Time Monitor - A method and system for measuring latency is provided. A monitor node is used to measure latency in a computer network or in a computing device by time stamping signal messages sent from nodes in the computer network and/or tasks in a particular node or device. The time stamps are generated using a system clock of the monitor node to reduce any discrepancies in timing. In addition, the monitor node may compensate for latencies between the monitor node and each of the one or more nodes or devices across which latency is to be measured. Signal messages may include a data message ID and/or a node ID identifying the message that is being tracked and for which latency is being measured. Latency may further be measured across multiple tasks being performed in the same or different nodes or devices by transmitting signal messages for each of the multiple tasks. | 06-04-2015 |
Sashi Gunturu, Katy, TX US
Sashi B. Gunturu, Katy, TX US
Patent application number | Description | Published |
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20140075297 | 3D VISUALIZATION AND MANAGEMENT OF RESERVOIR MONITORING DATA - Data collected during reservoir monitoring may include fiber optic measurements utilizing a distributed sensing system. Downhole monitoring with the distributed sensing system may generate large amounts of data. For example, the system may be capable of producing the functional equivalent of tens, hundreds, or even thousands of sensors along a length of a wellbore. Continuous monitoring of various properties, including temperature, pressure, Bragg gradient, acoustic, and strain, may create a large volume of data, possibly spanning into several gigabytes. Embodiments of the present invention provide techniques for analyzing a large volume of measurements taken in a wellbore without compromising on the integrity of data. | 03-13-2014 |
20150241580 | THREE/FOUR DIMENSIONAL IMAGING FOR BIG OILFIELD DATA - Oilfield and wellbore data may include geophone data (seismic) and airborne surveys such as microseep data, as well as fiber optic measurements collected utilizing a distributed sensing system. Continuous monitoring of various oilfield and wellbore properties, such as temperature, pressure, Bragg gradient, acoustic, and strain, and the like, may generate a large volume of data, possibly spanning into several terabytes. Embodiments of the present invention provide techniques for visualizing a large volume of such measurements taken in a oilfield or wellbore without down-sampling measurement data. | 08-27-2015 |
20150241581 | THREE/FOUR DIMENSIONAL DATA MANAGEMENT AND IMAGING FOR BIG OILFIELD DATA - Oilfield and wellbore data may include geophone data (seismic) and airborne surveys such as microseep data, as well as fiber optic measurements collected utilizing a distributed sensing system. Continuous monitoring of various oilfield and wellbore properties, such as temperature, pressure, Bragg gradient, acoustic, and strain, and the like, may generate a large volume of data, possibly spanning into several terabytes. Embodiments of the present invention provide techniques for visualizing a large volume of such measurements taken in an oilfield or wellbore without down-sampling measurement data. | 08-27-2015 |
Vittal Gunturu, Flower Mound, TX US
Patent application number | Description | Published |
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20120060096 | Methods and Systems for Managing Support Cases Based on Support Issues Received by way of Social Media Outlets - Exemplary systems and methods for managing support cases based on support issues received by way of social media outlets are disclosed. An exemplary method includes a social media management subsystem receiving data representative of a support issue by way of a social media outlet, establishing a support case based on the support issue, displaying a portal configured to facilitate management of a plurality of support cases including the support case, receiving a request to assign the support case to one or more backend support subsystems, transmitting data representative of the support case to the one or more backend support subsystems, and monitoring one or more actions performed by the one or more backend support subsystems to address the support issue. Corresponding methods and systems are also disclosed. | 03-08-2012 |
20120137309 | WORKFLOW INTEGRATION AND PORTAL SYSTEMS AND METHODS - An exemplary system includes a workflow integration subsystem communicatively coupled to a backend workflow subsystem maintaining a set of backend workflow tasks native to the backend workflow subsystem, the workflow integration subsystem configured to maintain a set of integrated workflow tasks representative of the set of backend workflow tasks. The system also includes a portal subsystem configured to communicate with the workflow integration subsystem and the backend workflow subsystem. The portal subsystem is further configured to provide a frontend portal for access by a user, receive a request provided by the user through the frontend portal, and provide access to workflow functionality through the frontend portal in response to the request, wherein the portal subsystem is configured to select whether the workflow functionality is subject to control by the backend workflow subsystem or the portal subsystem. Corresponding systems and methods are also disclosed. | 05-31-2012 |