The present invention provides a method of selecting an optimal communication routing between a UE and a core network wherein a plurality of differing communication paths are establishable between the UE and the network. Duplicate packets are transmitted over two communication paths and a latency difference determined between the two paths. This latency difference is used to select a communication path for subsequent communication.

Systems and methods of performing automated testing using a process flow of messages are provided. In one exemplary embodiment, a method includes receiving an indication that represents a time stamped message that is sent or received by a second electronic node and that is associated with a certain function. The method also includes generating a process flow of messages between the set of electronic nodes for the certain function based on the time stamped message of the second electronic node that is associated with the certain function and time stamped messages of the other electronic nodes associated with the same function so that the first electronic node is operable to simulate the certain function specific to that node based on the process flow of messages so as to test that at least one electronic node is operable to perform the certain function in conformance with the process flow of messages.

Systems and methods of performing automated testing using a process flow of messages are provided. In one exemplary embodiment, a method includes receiving an indication that represents a time stamped message that is sent or received by a second electronic node and that is associated with a certain function. The method also includes generating a process flow of messages between the set of electronic nodes for the certain function based on the time stamped message of the second electronic node that is associated with the certain function and time stamped messages of the other electronic nodes associated with the same function so that the first electronic node is operable to simulate the certain function specific to that node based on the process flow of messages so as to test that at least one electronic node is operable to perform the certain function in conformance with the process flow of messages.

Methods and systems described herein are directed resolving object dependencies in a data center. A trie data structure that represents network paths of objects utilized by a selected source object is constructed. The trie data structure comprises nodes linked by edges. Each node represents an edge identification (“ID”) of source objects and destination objects of one or more network paths of objects utilized by the selected source object in a user-defined time interval. The trie data structure is traversed to resolve the different versions of source objects and destination objects utilized by the selected source object in subintervals of the time interval. A graph of the objects and destination objects utilized by the selected source object in the subintervals is generated and used to identify source objects and destination objects utilized by the selected source object during a performance problem of the selected source object.

The present invention relates to methods, processes, and systems for monitoring security policy violations in a computer network. Details of such monitoring include creating a rule according to a security policy, determining if the rule is violated by a value of a variable, and recording security events and comparing the number of events to a threshold.

The present invention relates to methods, processes, and systems for monitoring security policy violations in a computer network. Details of such monitoring include creating a rule according to a security policy, determining if the rule is violated by a value of a variable, and recording security events and comparing the number of events to a threshold.

Methods, systems, and devices for wireless communication are described. A network node may determine a first time location associated with a peak in data traffic for multiple devices in communication with a communications network including the network node. The network node may determine a second time location for the peak in the data traffic for a subset of the devices based on a threshold for an overall peak in data traffic for the multiple devices. The network node may transmit a signal that indicates the second time location for the peak in the data traffic for the subset of devices. The network node may communicate the data with the subset of devices based on the signal indicating the second time location.

Methods, systems, and devices for wireless communication are described. A network node may determine a first time location associated with a peak in data traffic for multiple devices in communication with a communications network including the network node. The network node may determine a second time location for the peak in the data traffic for a subset of the devices based on a threshold for an overall peak in data traffic for the multiple devices. The network node may transmit a signal that indicates the second time location for the peak in the data traffic for the subset of devices. The network node may communicate the data with the subset of devices based on the signal indicating the second time location.

A device may receive a simulation start command and status data indicating that network elements are ready to process data for multiple simulations. The device may align a time slot to zero, and may define a simulation start time, for the multiple simulations, based on the simulation start command and the status data. The device may define a verification start time, for the multiple simulations, based on the simulation start command, the status data, the time slot, and a system frame number being zero, and may define a network frame number that increments when the verification start time changes from zero to one. The device may cause the multiple simulations to be executed by the network elements, based on the time slot, the system frame number, and the network frame number, and may receive synchronized simulation results based on causing the multiple simulations to be executed by the network elements.

A device may receive a simulation start command and status data indicating that network elements are ready to process data for multiple simulations. The device may align a time slot to zero, and may define a simulation start time, for the multiple simulations, based on the simulation start command and the status data. The device may define a verification start time, for the multiple simulations, based on the simulation start command, the status data, the time slot, and a system frame number being zero, and may define a network frame number that increments when the verification start time changes from zero to one. The device may cause the multiple simulations to be executed by the network elements, based on the time slot, the system frame number, and the network frame number, and may receive synchronized simulation results based on causing the multiple simulations to be executed by the network elements.