Example implementations described herein are directed to systems and methods for managing internet protocol (IP) address assignment to servers on rack(s) based on their physical locations within the rack(s). Through the example implementations, the physical location of a server within a data center rack can be determined based on the IP address. Example implementations can involve issuing a ping local to determine a plurality of servers; retrieving power on time, current system time, and operating system (OS) uptime for each of the plurality of servers; determining a power on order for the plurality of servers; determining physical locations of the plurality of servers within one or more racks based on installation instructions and power on order; and assigning IP addresses to the plurality of servers based on the physical locations.

The present invention is directed to methods and systems for requesting information from a mobile device with a fencing agent. The fencing agent determines a position with a DNS resolver, queries geofences with an IP address, receives an anchor point with an IP address from the DNS resolver. The device with the fencing agent is able to receive multiple anchor points within multiple geofences within an ROI and translate fence points into fence geometries. Geofence information is stored and registered in a database of geofences, and each geofence is associated with a plurality of geographic designators, wherein each of the plurality of geographic designators is associated with an IP address.

Apparatus and methods are disclosed for bridging communications between a private network and a public network. A mapping that associates a first set of IP addresses of endpoints in the private network with a second set of IP addresses of endpoints in the public network is provided which enables communications between the private network and public network for network-address-translation (NAT). In response to a data packet having a first IP address of the first set of IP addresses, the data packet is used to determine whether the local line should be accessed. In response to an indication that the local line should be accessed, the identifier among the second set of IP addresses may be used to activate bridging (e.g., ATB) circuit and redirect a call associated with the data packet by passing the data packet through the ATB circuit.

Generating an improved/more accurate geolocation database is provided. Given a dataset of reverse DNS hostnames for IP addresses, ground truth information, and a hierarchical geographical database, a machine learning classifier can be trained to extract and disambiguate location information from the reverse DNS hostnames of IP addresses and to apply machine learning algorithms to determine location candidates and to select a most probable candidate for a reverse DNS hostname based on a confidence score. The classifier can be used to generate an accurate geolocation database, or to provide accurate geolocation information as a service.

Aspects of the present disclosure involve a CDN utilizing a Direct Server Return (DSR) request command to create a tunnel from one content server to another content server of the CDN. Through the DSR tunnel, a request for content may be served from a content server that is more advantageous for the CDN for any number of reasons, such as from a content server that is logically closer to the content server. In determining when a DSR tunnel is created to provide the content, the CDN may access a database storing various information concerning the CDN, such as the location of egress gateways of the CDN in relation to one or more content servers, connecting network location information, the capabilities of one or more content servers, and/or load information of available content servers.

Methods and apparatus related to determining and/or utilizing one or more attributes for an Internet Protocol (IP) address. In some of those implementations, the attributes may include a physical address associated with the IP address. Some implementations are directed to determining physical addresses for inclusion in a postal campaign based on computing devices having IP addresses associated with those physical addresses having retrieved content of one or more electronic resources (e.g., webpages) assigned to the campaign.

Various example implementations are directed to circuits, apparatuses, and methods for providing virtual computing services. According to an example embodiment, an apparatus includes a computing server configured to provide a respective group of virtual servers for each of a plurality of accounts. Each of the accounts has a respective set of domain names and a respective settings file. The apparatus also includes a domain name server (DNS). The DNS is to dynamically map a respective set of domain names for each account to network addresses of the respective group of virtual servers, provided for the account. The DNS performs the mapping according to a mapping function indicated in the respective settings file of the account. The respective settings file of a first account accounts includes a mapping function that is different from a mapping function included in the respective settings file of a second account.

Systems and methods for resolving names in a data network. A data network includes an information-centric network layer, ICN-layer, with multiple routers, and a name resolution layer with multiple name resolvers. Each router receives an interest packet announcement describing data objects provided by a data producer. Each router determines a first name resolver of the name resolution layer closest to the data producer and sends a name of the provided data object and geo-location of the data producer to the first name resolver. The first name resolver transmits the name of the data object and geo-location of the data producer to other name resolvers. Each router receives an interest packet request describing a data object requested by a data consumer. Each router transmits the interest packet request to a second name resolver spatially closest to the data consumer. Each name resolver provides the geo-location of the requested data object to the data consumer.

Systems and methods are disclosed for enforcing at least one rule associated with a geofence. At least one device is constructed and configured in network communication with a server platform and a database. The server platform defines at least one geofence for a region of interest and specifies at least one rule associated with the at least one geofence, thereby creating a rule-space model for the region of interest. The at least one geofence comprises a multiplicity of geographic designators with each geographic designator assigned with a unique IPv6 address. The at least one device receives at least one notification signal regarding the at least one rule from the at least one server platform and implements the at least one rule when the at least one device is within a predetermined distance from the at least one geofence for the region of interest.

Embodiments of the present application describe techniques of facilitating directing operations. The techniques comprise obtaining guest information of a target studio, where the guest information includes a room identification number of a guest room, the guest room associated with producing content scenes; generating a directing configuration file based on the guest information of the target studio; and sending the directing configuration file to a director terminal associated with content directing, so that the director terminal performs a directing operation based on the directing configuration file.