A request to separate a transfer into a plurality of parts may be received, the request defining a total amount and a total time period. A plurality of request for transfer links may be prepared. Each of the links may be associated with a different transfer time period, each transfer time period being less than or equal to the total time period. Each of the links may be associated with a separate transfer part amount, and a summation of the separate transfer part amounts may be equal to the total amount. A plurality of request for transfer links may be provided to a transferor device, each link allowing a transfer to fulfill the separate transfer part amount to be performed without requiring input of the separate transfer part amount or recipient information.

An apparatus for performing an over-the-air (OTA) update for a vehicle includes an estimated-time calculating device that calculates estimated time required for the OTA update of one or more controllers included in the vehicle, an update performing device that starts the OTA update based on the calculated estimated time, and a rollback performing device that performs an initial rollback on a failed OTA update once and to calculate a first value indicating whether a rollback is able to be performed on the failed OTA update in a case where the OTA update of at least one of the controllers fails when the OTA update is started.

A computer system receives user data from a computing device of a user and determines that the user will utilize a transport service to arrive at a destination location at a specified time. The computer system automatically triggers, without user input, a service request for the user by monitoring transport provider availability within a proximity of a current location of the user prior to the specified time, and determines a service request time for the user based on the transport provider availability. The computer system then generates the service request for the scheduled user event based on the service request time.

A computer system receives user data from a computing device of a user and determines that the user will utilize a transport service to arrive at a destination location at a specified time. The computer system automatically triggers, without user input, a service request for the user by monitoring transport provider availability within a proximity of a current location of the user prior to the specified time, and determines a service request time for the user based on the transport provider availability. The computer system then generates the service request for the scheduled user event based on the service request time.

The present disclosure discusses system and methods for improving the efficiency of a remote computing device. The system and methods include generate a profile and delivery schedule for the remote computing device. The system can dynamically update the delivery schedule of future requests the system transmits to the remote computing device based on responses to current request.

The present disclosure discusses system and methods for improving the efficiency of a remote computing device. The system and methods include generate a profile and delivery schedule for the remote computing device. The system can dynamically update the delivery schedule of future requests the system transmits to the remote computing device based on responses to current request.

A method, computer program, and computer system is provided for asynchronous Network-Based Media Processing (NBMP) request processing. A first function call corresponding to a CreateWorkflow request to an NBMP workflow manager is received. A hypertext transfer protocol (HTTP) status code and a delay value retrieved from a database are returned based on receiving the first function call, and the CreateWorkflow request is performed at a later time after the delay has elapsed, whereby a response to the request is performed asynchronously according to the retrieved delay value. A second function call corresponding to an UpdateWorkflow request to the NBMP workflow manager is received after performing the CreateWorkflow request, and results of performing the CreateWorkflow request are returned based on receiving the second function call, wherein a response to the CreateWorkflow request is provided asynchronously according to the retrieved delay value.

A method, computer program, and computer system is provided for asynchronous Network-Based Media Processing (NBMP) request processing. A first function call corresponding to a CreateWorkflow request to an NBMP workflow manager is received. A hypertext transfer protocol (HTTP) status code and a delay value retrieved from a database are returned based on receiving the first function call, and the CreateWorkflow request is performed at a later time after the delay has elapsed, whereby a response to the request is performed asynchronously according to the retrieved delay value. A second function call corresponding to an UpdateWorkflow request to the NBMP workflow manager is received after performing the CreateWorkflow request, and results of performing the CreateWorkflow request are returned based on receiving the second function call, wherein a response to the CreateWorkflow request is provided asynchronously according to the retrieved delay value.

Techniques for committing back end computing resources to an online stream of requests for data from client devices are described herein. A polling schedule server (e.g., a reservation management system), may receive polling reservation requests from a plurality of client devices, may evaluate each client device's need for “fresh” data based on a number of input signals, and may assign the client device a polling slot (e.g., a reservation for a future polling time). The polling scheduler server may subsequently receive a polling request from a client device and, upon validating a token received from the client device as well as a difference between an assigned polling time and the polling request timestamp, may grant the polling request by transmitting a request to one or more communication system servers, receiving data from the communication system servers, and providing the data to the client device.

Techniques for committing back end computing resources to an online stream of requests for data from client devices are described herein. A polling schedule server (e.g., a reservation management system), may receive polling reservation requests from a plurality of client devices, may evaluate each client device's need for “fresh” data based on a number of input signals, and may assign the client device a polling slot (e.g., a reservation for a future polling time). The polling scheduler server may subsequently receive a polling request from a client device and, upon validating a token received from the client device as well as a difference between an assigned polling time and the polling request timestamp, may grant the polling request by transmitting a request to one or more communication system servers, receiving data from the communication system servers, and providing the data to the client device.