Replicas are selected in a large distributed network, and the roles for these replicas are identified. In one example, a leader is selected from among candidate computing dusters. To make this selection, an activity monitor predicts or monitors the workload of one or more clients. Different activities of the workload are given corresponding weights. The delay in performing requested activities, modified by these weights is found, and the candidate leader with the lowest weighted delay is selected as the leader.

The present disclosure relates to techniques for collection and processing of data over a network, and in particular to in providing generalized analysis for preserving privacy of data sources. In some embodiments, a system receives a request for analytical data made by a requester, wherein the request includes: information for identifying one or more data source devices to be queried for input data, a type of data processing to be performed on the input data for generating the analytical data, and a data type for the analytical data. In response to receiving the request, the system causes the one or more data source devices to be queried for the input data. The system causes a response that includes the analytical data to be sent to the requester. Other embodiments are described throughout the present disclosure.

Embodiments of the present invention provide a system for determining real-time resource capacity of entity devices based on performing predictive analysis. In particular, the system may be configured to identify one or more users at a location of an entity device waiting to perform one or more interactions via the entity device, establish a communication link with the entity device, determine identity of the one or more users based on communicating with the entity device, calculate an estimated interaction amount associated with the one or more interactions of the one or more users, determine capacity of the entity device in real-time, identify that the capacity of the entity device does not meet the calculated estimated interaction amount, and transmit a notification to at least one user of the one or more users via the entity application present on a user device of the at least one user.

Embodiments of the present invention provide a system for determining real-time resource capacity of entity devices based on performing predictive analysis. In particular, the system may be configured to identify one or more users at a location of an entity device waiting to perform one or more interactions via the entity device, establish a communication link with the entity device, determine identity of the one or more users based on communicating with the entity device, calculate an estimated interaction amount associated with the one or more interactions of the one or more users, determine capacity of the entity device in real-time, identify that the capacity of the entity device does not meet the calculated estimated interaction amount, and transmit a notification to at least one user of the one or more users via the entity application present on a user device of the at least one user.

A method for perception-sharing between similarly-situated vehicles that are traveling on a portion of a roadway that is equipped with an intelligent vehicle highway system is described, and includes executing, in a multi-access edge computing cluster in communication with a roadside unit disposed to monitor a roadway, an application-layer routine. The application-layer routine includes collecting real-time data associated with a plurality of objects from each of the similarly-situated vehicles, predicting motion of each of the plurality of objects based upon the real-time data, object-matching the motion of each of the plurality of objects, and executing fusion of the plurality of objects based upon the object-matching of the motion of each of the plurality of objects. Locations of the similarly-situated vehicles traveling on the roadway are identified based upon the fusion of the plurality of objects. The locations are communicated to one of the similarly-situated vehicles.

Methods and systems are presented for providing a scalable communication framework for facilitating computing services to computer nodes across multiple availability zones. One or more communication servers act as a communication proxy for a processing server configured to perform the computing services. Upon receiving a service request from a computer node, the communication server establishes a synchronous communication session with the computer node. The communication server generates a request message and inserts the request message in a downstream queue accessible by the processing server. The processing server retrieves the request message from the downstream queue and performs the computing services based on the request message. Outputs from the computing services are encapsulated within a response message and then inserted in an upstream queue. The communication server extracts output data from the response message, and transmits the output data to the computer node via the synchronous communication session.

An information processing apparatus includes a processor configured to: acquire a document; determine a route on which the document is to be processed in a workflow; determine a first process that is a final process for processing the document on the route among processes in which information is allowed to be input for a first item included in the document; and display the first item in a manner in accordance with the first process.

An information processing apparatus includes a processor configured to: acquire a document; determine a route on which the document is to be processed in a workflow; determine a first process that is a final process for processing the document on the route among processes in which information is allowed to be input for a first item included in the document; and display the first item in a manner in accordance with the first process.

A computer-implemented method for establishing and controlling a mobile perimeter and for determining a geographic location of an RF emitting source at or within the mobile perimeter includes receiving from RF sensors in a network, processed RF emissions from the source collected at RF sensors. The RF emissions follow a wireless protocol and include frames encoding RF emitting source identification information. The method further includes extracting RF emitting source identification information from the frames, processing the source identification information to identify the RF emitting source, and classifying the RF emitting source by one or more of UAS type, UAS capabilities, and UAS model. The method also includes receiving from the RF sensors, a geographic location of each RF sensor and a time of arrival (TOA) of the RF emissions at the RF sensor; and executing a multilateration process to estimate a geographic location of the RF emitting source.

A computer-implemented method for establishing and controlling a mobile perimeter and for determining a geographic location of an RF emitting source at or within the mobile perimeter includes receiving from RF sensors in a network, processed RF emissions from the source collected at RF sensors. The RF emissions follow a wireless protocol and include frames encoding RF emitting source identification information. The method further includes extracting RF emitting source identification information from the frames, processing the source identification information to identify the RF emitting source, and classifying the RF emitting source by one or more of UAS type, UAS capabilities, and UAS model. The method also includes receiving from the RF sensors, a geographic location of each RF sensor and a time of arrival (TOA) of the RF emissions at the RF sensor; and executing a multilateration process to estimate a geographic location of the RF emitting source.