Value-based data transmission in an autonomous vehicle, comprising: acquiring sensor data from a plurality of sensors of the autonomous vehicle, the sensor data comprising a plurality of portions; determining, for each portion of the sensor data, a value based on one or more objects identified in the sensor data; determining, based on the values for the sensor data, an upload policy; and transmitting, based on the upload policy, one or more portions of the sensor data to a server.

Value-based data transmission in an autonomous vehicle, comprising: acquiring sensor data from a plurality of sensors of the autonomous vehicle, the sensor data comprising a plurality of portions; determining, for each portion of the sensor data, a value based on one or more objects identified in the sensor data; determining, based on the values for the sensor data, an upload policy; and transmitting, based on the upload policy, one or more portions of the sensor data to a server.

Some embodiments provide a method for providing access in a scalable manner to resources in a first datacenter to clients operating in one or more public clouds. The method of some embodiments implements with multiple machines a public-cloud proxy to connect clients in the public cloud(s) to a reverse proxy in the first datacenter. For instance, in response to a request to access a first resource in the first datacenter from a first client executing outside of the first datacenter, the method: (1) assigns a first proxy-implementing machine operating outside of the first datacenter to establish a first connection with the first client, (2) assigns a second proxy-implementing machine operating outside of the first datacenter to establish a second connection with the reverse proxy that operates in the first datacenter and that provides access to the first resource, and (3) establishes a third connection between the first and second proxy-implementing machines to forward messages between the first client and the reverse proxy through the first, second, and third connections.

Some embodiments provide a method for providing access in a scalable manner to resources in a first datacenter to clients operating in one or more public clouds. The method of some embodiments implements with multiple machines a public-cloud proxy to connect clients in the public cloud(s) to a reverse proxy in the first datacenter. For instance, in response to a request to access a first resource in the first datacenter from a first client executing outside of the first datacenter, the method: (1) assigns a first proxy-implementing machine operating outside of the first datacenter to establish a first connection with the first client, (2) assigns a second proxy-implementing machine operating outside of the first datacenter to establish a second connection with the reverse proxy that operates in the first datacenter and that provides access to the first resource, and (3) establishes a third connection between the first and second proxy-implementing machines to forward messages between the first client and the reverse proxy through the first, second, and third connections.

Examples relate to maintaining consistent cluster data across a cluster in a network. A computing system may receive a first signature of a first state of the cluster data present at a leader gateway and a plurality of signatures of a plurality of states of the cluster data present at a plurality of member network devices of the cluster. The cluster may include a plurality of gateways including the leader gateway and a plurality of member gateways. The member network devices may include the plurality of member gateways and a plurality of interconnecting network devices. In response to determining that a signature of the plurality of signatures received from one of the member network devices is different from the first signature, the computing system may send a message to one of the plurality of gateways to update the cluster data at the member network device to represent the first state.

A server system for managing electronic content receives the electronic content at a data flow adapter. The electronic content is to be stored at a data storage system. The server system attempts to transmit the electronic content from the data flow adapter to the data storage system but receives a notification indicating that the data storage system will not store the electronic content. In response to the notification, the server system temporarily stores the electronic content at a data staging memory. A staging data adapter polls the data staging memory for electronic content awaiting to be stored at the data storage system. The server system detects the electronic content stored at the data staging memory and, in response, causes the staging data adapter to move the electronic content from the data staging memory to the data storage system when the data storage system will store the electronic content.

A server system for managing electronic content receives the electronic content at a data flow adapter. The electronic content is to be stored at a data storage system. The server system attempts to transmit the electronic content from the data flow adapter to the data storage system but receives a notification indicating that the data storage system will not store the electronic content. In response to the notification, the server system temporarily stores the electronic content at a data staging memory. A staging data adapter polls the data staging memory for electronic content awaiting to be stored at the data storage system. The server system detects the electronic content stored at the data staging memory and, in response, causes the staging data adapter to move the electronic content from the data staging memory to the data storage system when the data storage system will store the electronic content.

A communication system for transmitting data packets includes: at least one Access Node (AN) connectable to a user equipment (UE); a User Plane Function (UPF) component; and a data network (DN). The UPF component is a distributed component and comprises: at least one User Plane Function Edge (UPF-E) component and a User Plane Function Core (UPF-C) component, the UPF-E component being connected between the at least one AN and the UPF-C component, and the UPF-C component being connected between the UPF-E component and the data network (DN) or another UPF-C; and a UPF Management (UPF-M) component configured to terminate an N4 interface.

A communication system for transmitting data packets includes: at least one Access Node (AN) connectable to a user equipment (UE); a User Plane Function (UPF) component; and a data network (DN). The UPF component is a distributed component and comprises: at least one User Plane Function Edge (UPF-E) component and a User Plane Function Core (UPF-C) component, the UPF-E component being connected between the at least one AN and the UPF-C component, and the UPF-C component being connected between the UPF-E component and the data network (DN) or another UPF-C; and a UPF Management (UPF-M) component configured to terminate an N4 interface.

Examples described herein include systems and methods for performing email synchronization in situations where mobile-device connectivity is lacking. The mobile device can send an SMS message to an email notification server requesting email synchronization and the email notification server can request synchronization with the email server associated with the user's email account. After receiving an email from the email server, the email notification server can encrypt the email and break it into various chunks, with each chunk including a header having identifying information. The chunks can be transmitted as SMS messages to the mobile device. The email application can retrieve the SMS messages, decrypt them, and reconstruct the email. The email application can then display the email for the user.