Bastidas
Carlos Bastidas, Tucson, AZ US
Patent application number | Description | Published |
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20150257156 | DYNAMIC RADIO FREQUENCY MAPPING - An intelligent cognitive radio system is disclosed that acquires information about its environment to make operational decisions. Dynamic radio frequency mapping provides estimates of RF power levels over an area where spectrum activity or changes in the environment may be transient. These power levels can be used for a variety of applications such as interference management, spectrum policing, and facilitating spectrum auctions. The RF mapping can be accomplished by a network of sensors that are distributed in a geographical area and used to spatially sample signal levels. The present invention can quantify the effect of aliasing on the estimation of an RF map as a function of the sampling density and the number of antennas used at the sensing node. | 09-10-2015 |
Lenin W. Bastidas, Tinley Park, IL US
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20110048264 | ELEVEN-COLOR PRINTING INK SET AND METHOD OF USE - An eleven-color printing ink set and method of use including an eleven-color ink set including a cyan ink with coordinates of L*=55, a*=−28, and b*=−43; a magenta ink with coordinates of L*=48, a*=61, and b*=1; a yellow ink with coordinates of L*=88, a*=−5, and b*=91; a black ink with coordinates of L*=27, a*=0.3, b*=0.7; an XG Purple 1 ink with coordinates of L*=41, a*=10, and b*=−53; an XG Purple 2 ink with coordinates of L*=33, a*=34, and b*=−48; an XG Orange 1 ink with coordinates of L*=67, a*=53, and b*=57; an XG Orange 2 ink with coordinates of L*=56, a*=61, and b*=35; an XG Green 1 ink with coordinates of L*=64, a*=−57, and b*=37; an XG Green 2 ink with coordinates of L*=63, a*=−65, and b*=6; and an XG Quinacridone ink with coordinates of L*=62, a*=49, and b*=−19. | 03-03-2011 |
Monica Bastidas, Pacifica, CA US
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20140314980 | SAFETY DROP CLOTH - A safety drop cloth is provided having a first face, and a reverse second face; the second face substantially contacts with a subordinate surface in use; and the first face includes a body and periphery. The cloth is arranged with demarcation to distinguish the periphery from the body by light transmission characteristics where in various light levels, the cloth acts to demarcate an area for safety purposes. | 10-23-2014 |
Santiago Xavier Bastidas, San Francisco, CA US
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20140101644 | USING A DATA DICTIONARY TO DETERMINE AN UPGRADE EDITION OF A RELATIONAL DATABASE TABLE - A method, system, and computer program product using a data dictionary to automatically determine an upgrade edition of relational database table in a database installation. The editioning method commences upon receiving a data dictionary of the database comprising at least entries corresponding to a first edition of the relational database table, then reading entries of the data dictionary to identify at least one relational database table column of the relational database table that has a revision identifier. The revision identifiers are used to determine a first edition (e.g., a run edition) and a second edition (e.g., an upgrade edition). Then, the method proceeds by creating at least a first relational database table view corresponding to the first edition of the relational database table; and creating at least a second relational database table view corresponding to the upgrade edition of the relational database table using the identified relational database table column. | 04-10-2014 |
20140101645 | ONLINE UPGRADING OF A DATABASE ENVIRONMENT USING TRANSPARENTLY-PATCHED SEED DATA TABLES - A method, system, and computer program product for managing upgrades of database systems using a transparently-patched seed data table. The method commences on a running system by copying (while software applications are running) portions of data comprising a seed data table to database table rows that are temporarily inaccessible by the software applications. The copy operation creates new rows (a seed data table copy) in a database table. The method continues while software applications are running by modifying the seed data table copy (e.g., by applying a patch). For a brief time, the method stops the software applications, then changes the database table rows that were temporarily inaccessible by the software applications to become accessible by the software applications and restarts the software application to point to the patched seed data table copy. The patch can add or change a column of the seed data table copy or its schema. | 04-10-2014 |
20140101646 | REDUCING DOWNTIME DURING UPGRADES OF INTERRELATED COMPONENTS IN A DATABASE SYSTEM - A method, system, and computer program product for reducing downtime during upgrades of interrelated components in a computing environment. The method commences while at least one running software application is executing within the computing environment by loading a plurality of database objects from an initial run edition into a patch edition. The database objects comprise at least one software application code module, at least one relational database table, and at least one file system. The method continues by applying at least one patch to the software application code module(s) corresponding to the running software application(s) to create patched software application(s), then applying patches to the relational database table to create a patched relational database table, and further applying a patch to the file system to create a patched file system. When the subject patches have been applied, the method stops the running software application(s) and starts the patched software application(s). | 04-10-2014 |
20140101650 | TRANSPARENTLY UPGRADING DERIVED DATABASE OBJECTS - A method for transparently upgrading derived database objects commences upon analysis of the data dictionary definition for an initial derived database object as compared to the data dictionary definition for a patched derived database object, then determining if a regenerated instance of the derived database object would be logically different from the initial derived database object. The determination is based on comparisons of the definitions of the initial derived database objects and patched definitions of respective database objects. The method produces a regenerated instance of the derived database object when a regenerated instance of the patched derived database object would be logically different from the initial derived database object. The method will suppress the production of a regenerated instance when a regenerated instance of the derived database object would not be logically different from the initial derived database object. Once regenerated or suppressed, a post-upgrade software application accesses the regenerated derived database object instance (if regenerated) or the initial derived database object if the regenerated instance was suppressed. | 04-10-2014 |