Patent application number | Description | Published |
20110225128 | CLEAN STORE FOR OPERATING SYSTEM AND SOFTWARE RECOVERY - Systems, methods and apparatus for automatically identifying a version of a file that is expected to be present on a computer system and for automatically replacing a potentially corrupted copy of the file with a clean (or undamaged) copy of the expected version. Upon identifying a file on the computer system as being potentially corrupted, a clean file agent may perform an analysis based on the identity of the file and one or more other properties of the system to determine the version of the file that is expected to be present on the system. Once the expected version is identified, a clean replacement copy of the file may be obtained from a clean file repository by submitting a version identifier of the expected version. The version identifier may be a hash value, which may additionally be used to verify integrity of the clean copy. | 09-15-2011 |
20120151582 | Offline Scan, Clean and Telemetry Using Installed Antimalware Protection Components - The subject disclosure relates to antimalware scanning, and more particularly to offline antimalware scanning of a host environment via an alternate, known safe operating system. An offline scanning product obtains data previously written by the host environment online antimalware scanning tool, e.g., configuration data and antimalware signatures in shared data stores accessible to the offline and online products, and uses that data to perform the offline antimalware scan. The offline scanning product writes results information and any quarantined files to other shared data stores, whereby the online environment, when rebooted, has access to the information, such as for review and to upload telemetry information to an online service for analysis. Also described is offline replacement of operating system files that cannot be cleaned or removed when online. | 06-14-2012 |
Patent application number | Description | Published |
20100034122 | Voice over internet protocol (VoIP) location based conferencing - A Voice Over Internet Protocol (VoIP) device uses its location to narrow down known and unknown potential VoIP third parties meeting the user's criteria, based on their physical proximity to the initial caller and other pre-determined characteristics, to join in a phone conference. A VoIP soft switch includes conference bridges that eliminate the conventional requirement that they dial digits for a direct link with another specific VoIP communications device. Instead, location information relating to the initial VoIP user is passed to the VoIP conference bridge, either from the user's VoIP communication device or from their respective location server. The location information is then compared by the VoIP soft switch against other VoIP devices to find potential VoIP users within a defined geographic region surrounding the initial VoIP user. Those VoIP users matching the criteria are sent an Invite message to join the conference, which they may or may not accept. | 02-11-2010 |
20100272242 | Voice over internet protocol (VolP) location based 911 conferencing - Voice Over Internet Protocol (VoIP) emergency calls to an Emergency Response Center (ERC) are handled through a VoIP conference bridge on a VoIP service provider's soft switch. The soft switch works with a VoIP positioning center (VPC) to obtain location information, which is compared against a PSAP database to find an initial best-appropriate PSAP for the location of the emergency caller. The PSAP is issued an Invite message to join the conference, establishing an emergency call. Third parties such as police, ambulance may be issued Invite messages to join the conference. Cold transfers are avoided by Inviting participants to join a single emergency conference rather than passing an emergency call from party to party (e.g., from PSAP to police to ambulance, etc.) The PSAP, other emergency responders, and even the initial VoIP emergency caller may leave and rejoin the VoIP conference without dropping the conference between the others. | 10-28-2010 |
20110013541 | Voice over internet protocol (VoIP) location based 911 conferencing - Voice Over Internet Protocol (VoIP) emergency calls to an Emergency Response Center (ERC) are handled through a VoIP conference bridge on a VoIP service provider's soft switch. The soft switch works with a VoIP positioning center (VPC) to obtain location information, which is compared against a PSAP database to find an initial best-appropriate PSAP for the location of the emergency caller. The PSAP is issued an Invite message to join the conference, establishing an emergency call. Third parties such as police, ambulance may be issued Invite messages to join the conference. Cold transfers are avoided by Inviting participants to join a single emergency conference rather than passing an emergency call from party to party (e.g., from PSAP to police to ambulance, etc.) The PSAP, other emergency responders, and even the initial VoIP emergency caller may leave and rejoin the VoIP conference without dropping the conference between the others. | 01-20-2011 |
Patent application number | Description | Published |
20100046489 | Enhanced E911 network access for a call center using session initiation protocol (SIP) messaging - A switched emergency call (e.g., a 911 call, an alarm company call) forwarded by a telematics call center is converted into a session initiation protocol (SIP) packetized phone call at the call center, and routed over an IP network, for presentation to an emergency services gateway, which connects to a selective router via dedicated circuits, gaining full access to the Enhanced 911 network. This provides a PSAP receiving a call from a telematics call center or other call center with all features available in an Enhanced 911 network, e.g., callback number of the 911 caller, and location of the 911 caller. Location of the caller is provided using a VoIP positioning center (VPC), queried from the call center. In this way, the switched emergency call is converted into a SIP packetized phone call and routed without further passage through the public switched telephone network (PSTN). | 02-25-2010 |
20110019664 | Emergency alert for voice over internet protocol (VoIP) - A voice over Internet Protocol (VoIP) positioning center (VPC) is implemented in configuration with support from a text-to-voice module, emergency routing database, and VoIP switching points (VSPs) to allow a public safety access point (PSAP) or other emergency center to effectively communicate the nature of an emergency alert notification and the area of notification to the VoIP positioning center (VPC). The inventive VPC in turn determines which phones (including wireless and/or VoIP phones) are currently in the area for notification, and reliably and quickly issues the required warning to all affected wireless and VoIP phones. | 01-27-2011 |
20120189107 | Enhanced E911 Network Access for a Call Center Using Session Initiation Protocol (SIP) Messaging - A switched emergency call (e.g., a 911 call, an alarm company call) forwarded by a telematics call center is converted into a session initiation protocol (SIP) packetized phone call at the call center, and routed over an IP network, for presentation to an emergency services gateway, which connects to a selective router via dedicated circuits, gaining full access to the Enhanced 911 network. This provides a PSAP receiving a call from a telematics call center or other call center with all features available in an Enhanced 911 network, e.g., callback number of the 911 caller, and location of the 911 caller. Location of the caller is provided using a VoIP positioning center (VPC), queried from the call center. In this way, the switched emergency call is converted into a SIP packetized phone call and routed without further passage through the public switched telephone network (PSTN). | 07-26-2012 |
20120287826 | Enhanced E911 Network Access for Call Centers - An emergency call (e.g., a 911 call, an alarm company call) forwarded by a telematics call center is routed over the switched PSTN to a Voice Over Internet Protocol (VoIP) call server, where the switched call is converted to a session initiating protocol (SIP) packetized IP call for presentation to an emergency services gateway, which reconverts the call to TDM and connects to a selective router via dedicated circuits, gaining full access to the Enhanced 911 network. This provides a PSAP receiving a call from a telematics call center or other call center with all features available in an Enhanced 911 network, e.g., callback number of the 911 caller, and location of the 911 caller. Location of the caller is provided using a VoIP positioning center (VPC). | 11-15-2012 |
20130149988 | Enhanced E911 Network Access for a Call Center Using Session Initiation Protocol (SIP) Messaging - A switched emergency call (e.g., a 911 call, an alarm company call) forwarded by a telematics call center is converted into a session initiation protocol (SIP) packetized phone call at the call center, and routed over an IP network, for presentation to an emergency services gateway, which connects to a selective router via dedicated circuits, gaining full access to the Enhanced 911 network. This provides a PSAP receiving a call from a telematics call center or other call center with all features available in an Enhanced 911 network, e.g., callback number of the 911 caller, and location of the 911 caller. Location of the caller is provided using a VoIP positioning center (VPC), queried from the call center. In this way, the switched emergency call is converted into a SIP packetized phone call and routed without further passage through the public switched telephone network (PSTN). | 06-13-2013 |
20130215797 | Enhanced E911 Network Access for Call Centers - An emergency call (e.g., a 911 call, an alarm company call) forwarded by a telematics call center is routed over the switched PSTN to a Voice Over Internet Protocol (VoIP) call server, where the switched call is converted to a session initiating protocol (SIP) packetized IP call for presentation to an emergency services gateway, which reconverts the call to TDM and connects to a selective router via dedicated circuits, gaining full access to the Enhanced 911 network. This provides a PSAP receiving a call from a telematics call center or other call center with all features available in an Enhanced 911 network, e.g., callback number of the 911 caller, and location of the 911 caller. Location of the caller is provided using a VoIP positioning center (VPC). | 08-22-2013 |
20150029941 | Public Services Access Point (PSAP) Designation of Preferred Emergency Call Routing Method Via Internet or Public Switched Telephone Network (PSTN) - The use of the VoIP emergency network for routing wireless E911 calls to a designated PSAP. In this embodiment, a mobile positioning center (MPC) assigns an ESRK per existing prior art, but uses the invention to route the call to the PSAP via the VoIP server and an ESGW. This relieves wireless carriers of the obligation to install and maintain expensive dedicated SS7 or CAMA trunks from each MSC to each selective router in the areas served by that MSC. Instead, wireless 911 calls can be consolidated by ESGW vendors, maximizing the efficiency of the dedicated trunks to the selective router by sharing those trunks with multiple MSCs. | 01-29-2015 |
Patent application number | Description | Published |
20080249796 | Voice over internet protocol (VoIP) location based commercial prospect conferencing - An automated system for matching a calling potential buyer on a VoIP phone with a prospective commercial business within their current area. The buyer may accept or reject connection with a best available prospective business to be automatically presented with the next prospective business as ranked by the presenting business locating service. The location of the potential buyer is provided or obtained, and the best available business selected from the database based on proximity to the buyers current location. A secondary prioritization may be applied to highest bidding businesses. The business finding module establishes a VoIP conference bridge, and invites the buyer and best available business. A pre-recorded message may be played into the conference bridge or directly to the buyer or business. The businesses may be ranked based on how much they pay or bid to be presented first to potential buyers. | 10-09-2008 |
20080259908 | Location object proxy - The function of determination of location is separated from the function of gathering information based on determined location by use of a Location Object (LO) proxy between an initiating VoIP capable device and a positioning center. The LOProxy queries an appropriate location database using a location key, and injects a PIDF-LO into a routing SIP message otherwise without location. A SIP request without location is received from a VoIP capable device. The SIP request contains messages indicating the type of location generator or service needed. A location key (like a telephone number or SIP URI), in addition to the type of location generator or service needed, is included in a SIP request. A location object (LO) broker may be used between a routing SIP message and a positioning center to direct a routing SIP message to an appropriate one of a plurality of location object (LO) proxies. | 10-23-2008 |
20080261619 | Injection of location object into routing SIP message - The function of determination of location is separated from the function of gathering information based on determined location by use of a Location Object (LO) proxy between an initiating VoIP capable device and a positioning center. The LOProxy queries an appropriate location database using a location key, and injects a PIDF-LO into a routing SIP message otherwise without location. A SIP request without location is received from a VoIP capable device. The SIP request contains messages indicating the type of location generator or service needed. A location key (like a telephone number or SIP URI), in addition to the type of location generator or service needed, is included in a SIP request. A location object (LO) broker may be used between a routing SIP message and a positioning center to direct a routing SIP message to an appropriate one of a plurality of location object (LO) proxies. | 10-23-2008 |
20080267172 | Location object proxy broker - The function of determination of location is separated from the function of gathering information based on determined location by use of a Location Object (LO) proxy between an initiating VoIP capable device and a positioning center. The LOProxy queries an appropriate location database using a location key, and injects a PIDF-LO into a routing SIP message otherwise without location. A SIP request without location is received from a VoIP capable device. The SIP request contains messages indicating the type of location generator or service needed. A location key (like a telephone number or SIP URI), in addition to the type of location generator or service needed, is included in a SIP request. A location object (LO) broker may be used between a routing SIP message and a positioning center to direct a routing SIP message to an appropriate one of a plurality of location object (LO) proxies. | 10-30-2008 |
20120270573 | POSITIONING SYSTEM AND METHOD FOR SINGLE AND MULTILEVEL STRUCTURES - A system for determining the position of users, stores, products, or brands inside one or more structures, such as a store, shopping center, cruise ship, etc. In some embodiments, the system utilizes an image capture module of a wireless device to capture information relating to an object disposed at a known location. The information regarding the location of the object is used to provide navigation information, product information, advertising information, and the like to the user while inside the structure. In other embodiments, a positioning system capable of determining the locations of RF signal sources within one or more structures and then using the determined locations of the RF signal sources to determine locations of users' wireless devices is provided. | 10-25-2012 |
20130115971 | CORRELATING WIRELESS SIGNALS TO A LOCATION ON AN IMAGE USING MOBILE SENSOR TECHNOLOGIES - Using ground truth events and sensors available on a first mobile device, an algorithm executed at the first mobile device determines the mobile device's position; the first mobile device also obtains wireless signal information; the wireless signal information is associated with the position determined via the sensor data and ground truth events; the associated data is stored and may be sent to or used by a second device; the second device may then, for example, detect then-current wireless signal information and may locate the second device by looking up the then-current wireless signal information in the associated data. | 05-09-2013 |
20130150002 | Identify a Radio Frequency Device by MAC Address System and Method - A computer system reports “logical usage pattern data” and location information in a Device Report; in addition, another computer system reports MAC addresses associated with mobile device in Network Device reports; the Device Reports and Networks Reports are correlated based on various factors; if a set of Device Reports and Network Reports correlate, then a Device Identifier is created and sent to the corresponding mobile device; the Device Identifier may then be used to identify the mobile device, such as when the MAC address is inaccessible. The Device Identifier may be associated with other devices used by the user of the mobile device. Behavioral information associated with all the devices may be obtained and behavioral patterns determined. Content served to the mobile device may then be optimized based on the determined behavioral patterns. | 06-13-2013 |
20130217411 | BATTERY-SAVING IN GEO-FENCE CONTEXT METHOD AND SYSTEM - While traveling to a destination, potentially traversing geo-fences along the way, a routine on a mobile device estimates arrival at the next geo-fence and performs a location check at the estimated arrival time. Between iterations of this process, the routine may correct the “time of next check” based on correction factors. When the mobile device arrives at the destination, it switches to terrestrial location determining services. In addition, the mobile device monitors its sensors to determine whether motion is gross motion which may warrant performing a location probe or whether motion is not gross motion, in which case location probes may be disabled. | 08-22-2013 |
20130281062 | IDENTIFY A RADIO FREQUENCY DEVICE BY MAC ADDRESS SYSTEM AND METHOD - A computer system reports “logical usage pattern data” and location information in a Device Report; in addition, another computer system reports MAC addresses associated with mobile device in Network Device reports; the Device Reports and Networks Reports are correlated based on various factors; if a set of Device Reports and Network Reports correlate, then a Device Identifier is created and sent to the corresponding mobile device; the Device Identifier may then be used to identify the mobile device, such as when the MAC address is inaccessible. The Device Identifier may be associated with other devices used by the user of the mobile device. Behavioral information associated with all the devices may be obtained and behavioral patterns determined. Content served to the mobile device may then be optimized based on the determined behavioral patterns. | 10-24-2013 |
20140045517 | SYSTEM FOR DETERMINATION OF REAL-TIME QUEUE TIMES BY CORRELATING MAP DATA AND MOBILE USERS' LOCATION DATA - A system collects and correlates dynamic mobile user data location with a structure map and determined, for individuals and groups, average queue times for waypoints or average dwell time for areas within the structure. The determined times are made available for use. | 02-13-2014 |