Abstract: Connection settings used by a mobile device to connect to a packet data network, e.g. the internet, are stored in a subscriber identity module (SIM) card. This enables connection settings to be pre-loaded on a SIM card, allowing a mobile device to immediately connect to the internet without manual configuration. The mobile device's connection settings may also be updated by a mobile network operator via an over the air profile update. For example, the operator may supply a device with connection settings the first time it connects to the network. Connection settings may be stored in one or more files within the SIM profile, and may be updated via a remote file management operation. Embedded-SIM (eSIM) profiles may also store connection settings in profile metadata, which may be updated via a metadata update operation.

Abstract: A temporary EID (TEID) is generated based on an indicator of a hash algorithm, a nonce, and a hash generated using the hash algorithm. The hash is generated based on the indicator, nonce, and EID of a mobile device. The TEID is sent to the mobile network operator to identify the mobile device in lieu of using the device's EID. The TEID is stored in a data store and an eSIM profile for the mobile device is associated the TEID. The mobile device sends to an eSIM server the device's EID over a secure communications channel. The eSIM server generates a hash using the indicator and nonce contained in the stored TEID and the EID of the mobile device. The eSIM server verifies that the generated hash matches the hash contained in the TEID stored in the data store. If the hash matches, the eSIM server sends, to the mobile device, subscription credentials for accessing the mobile network in accordance with the data plan.

Abstract: Mobile devices are provisioned that do not have a direct communications path to a data network. A proximate device is discovered that is available for connecting to the mobile device via a peer-to-peer connection. The proximate device is determined to be trusted by the mobile device and usable to communicate to the data network A peer-to-peer connection is established with the proximate device. Identification data is provided to the proximate device, and an activation code is received. The mobile device communicates to the mobile network operator indicated by the activation code. Subscription credentials are received for accessing a mobile network operated by the mobile network operator.

Abstract: Connection settings used by a mobile device to connect to a packet data network, e.g. the internet, are stored in a subscriber identity module (SIM) card. This enables connection settings to be pre-loaded on a SIM card, allowing a mobile device to immediately connect to the internet without manual configuration. The mobile device's connection settings may also be updated by a mobile network operator via an over the air profile update. For example, the operator may supply a device with connection settings the first time it connects to the network. Connection settings may be stored in one or more files within the SIM profile, and may be updated via a remote file management operation. Embedded-SIM (eSIM) profiles may also store connection settings in profile metadata, which may be updated via a metadata update operation.

Abstract: Connection settings used by a mobile device to connect to a packet data network, e.g. the internet, are stored in a subscriber identity module (SIM) card. This enables connection settings to be pre-loaded on a SIM card, allowing a mobile device to immediately connect to the internet without manual configuration. The mobile device's connection settings may also be updated by a mobile network operator via an over the air profile update. For example, the operator may supply a device with connection settings the first time it connects to the network. Connection settings may be stored in one or more files within the SIM profile, and may be updated via a remote file management operation. Embedded-SIM (eSIM) profiles may also store connection settings in profile metadata, which may be updated via a metadata update operation.

Abstract: Connection settings used by a mobile device to connect to a packet data network, e.g. the internet, are stored in a subscriber identity module (SIM) card. This enables connection settings to be pre-loaded on a SIM card, allowing a mobile device to immediately connect to the internet without manual configuration. The mobile device's connection settings may also be updated by a mobile network operator via an over the air profile update. For example, the operator may supply a device with connection settings the first time it connects to the network. Connection settings may be stored in one or more files within the SIM profile, and may be updated via a remote file management operation. Embedded-SIM (eSIM) profiles may also store connection settings in profile metadata, which may be updated via a metadata update operation.

Abstract: An internet of things (“IoT”) device is disclosed that can be authenticated on a wireless local area network (“WLAN”) without human intervention. The IoT device can also authenticate itself with a network service without human intervention. In order to enable this functionality, data identifying a service set identifier (“SSID”) used by the WLAN, a digital certificate for use in authenticating on the WLAN, and a digital certificate for use in authenticating with a network service are stored in the IoT device at the time it is manufactured. The digital certificate for authenticating on the WLAN is stored at an authentication server and information about the digital certificate for use in authenticating with the network service is stored at the network service. The IoT device can use the SSID to connect to the WLAN and use the digital certificates to authenticate with the authentication server and the network service, respectively.

Abstract: Sets of drones are deployed to create an ad-hoc 5G network in a physical environment to collect sensor data and generate a map of the physical environment in real time. Master drones configured with 5G capabilities are deployed to the physical area to create the 5G ad-hoc network, and swarm drones configured with sensors are deployed to gather environmental data on the physical environment. The gathered data is transmitted to the master drones to generate a map. The deployable 5G network is leveraged to identify precise locations for the swarm drones and each instance of sensor data collected by the swarm drones in order to create an accurate and detailed map of the environment. The map can include information regarding the structural layout of the space and environmental characteristics, such as temperature, the presence of smoke or other gases, etc.

Abstract: A temporary EID (TEID) is generated based on an indicator of a hash algorithm, a nonce, and a hash generated using the hash algorithm. The hash is generated based on the indicator, nonce, and EID of a mobile device. The TEID is sent to the mobile network operator to identify the mobile device in lieu of using the device's EID. The TEID is stored in a data store and an eSIM profile for the mobile device is associated the TEID. The mobile device sends to an eSIM server the device's EID over a secure communications channel. The eSIM server generates a hash using the indicator and nonce contained in the stored TEID and the EID of the mobile device. The eSIM server verifies that the generated hash matches the hash contained in the TEID stored in the data store. If the hash matches, the eSIM server sends, to the mobile device, subscription credentials for accessing the mobile network in accordance with the data plan.

Abstract: A temporary EID (TEID) is generated based on an indicator of a hash algorithm, a nonce, and a hash generated using the hash algorithm. The hash is generated based on the indicator, nonce, and EID of a mobile device. The TEID is sent to the mobile network operator to identify the mobile device in lieu of using the device's EID. The TEID is stored in a data store and an eSIM profile for the mobile device is associated the TEID. The mobile device sends to an eSIM server the device's EID over a secure communications channel. The eSIM server generates a hash using the indicator and nonce contained in the stored TEID and the EID of the mobile device. The eSIM server verifies that the generated hash matches the hash contained in the TEID stored in the data store. If the hash matches, the eSIM server sends, to the mobile device, subscription credentials for accessing the mobile network in accordance with the data plan.

Abstract: A temporary EID (TEID) is generated based on an indicator of a hash algorithm, a nonce, and a hash generated using the hash algorithm. The hash is generated based on the indicator, nonce, and EID of a mobile device. The TEID is sent to the mobile network operator to identify the mobile device in lieu of using the device's EID. The TEID is stored in a data store and an eSIM profile for the mobile device is associated the TEID. The mobile device sends to an eSIM server the device's EID over a secure communications channel. The eSIM server generates a hash using the indicator and nonce contained in the stored TEID and the EID of the mobile device. The eSIM server verifies that the generated hash matches the hash contained in the TEID stored in the data store. If the hash matches, the eSIM server sends, to the mobile device, subscription credentials for accessing the mobile network in accordance with the data plan.

Abstract: Mobile devices are provisioned that do not have a direct communications path to a data network. A proximate device is discovered that is available for connecting to the mobile device via a peer-to-peer connection. The proximate device is determined to be trusted by the mobile device and usable to communicate to the data network A peer-to-peer connection is established with the proximate device. Identification data is provided to the proximate device, and an activation code is received. The mobile device communicates to the mobile network operator indicated by the activation code. Subscription credentials are received for accessing a mobile network operated by the mobile network operator.

Abstract: A mobile local computing device is configured to access memories or storage devices associated with a remote computing device using remote direct memory access (RDMA) over a wireless fifth generation (5G) network link that provides high bandwidth and low latency relative to previous wireless network protocols. The mobile local computing device utilizes a local compute context that is unique to the local environment and which may be facilitated by devices, components, or functionalities that are local to the mobile local computing device, but which are not available with the same context to the remote computing device. The 5G network link supports high bandwidth and low latency so that the mobile local computing device can access and utilize the remote data in large datasets in a similar manner to how it would for locally stored data, while still being able to leverage the local I/O and maintain its unique local compute context.

Abstract: Mobile devices are provisioned that do not have a direct communications path to a data network. A proximate device is discovered that is available for connecting to the mobile device via a peer-to-peer connection. The second device is determined to be trusted by the mobile device and usable to communicate to the data network A peer-to-peer connection is established with the proximate device. Identification data is provided to the proximate device, and an activation code is received. The mobile device, via the peer-to-peer connection, communicates to the mobile network operator indicated by the activation code. Subscription credentials are received for accessing a mobile network operated by the mobile network operator.

Abstract: Mobile devices are provisioned that do not have a direct communications path to a data network. A proximate device is discovered that is available for connecting to the mobile device via a peer-to-peer connection. The second device is determined to be trusted by the mobile device and usable to communicate to the data network A peer-to-peer connection is established with the proximate device. Identification data is provided to the proximate device, and an activation code is received. The mobile device, via the peer-to-peer connection, communicates to the mobile network operator indicated by the activation code. Subscription credentials are received for accessing a mobile network operated by the mobile network operator.

Abstract: Sets of drones are deployed to create an ad-hoc 5G network in a physical environment to collect sensor data and generate a map of the physical environment in real time. Master drones configured with 5G capabilities are deployed to the physical area to create the 5G ad-hoc network, and swarm drones configured with sensors are deployed to gather environmental data on the physical environment. The gathered data is transmitted to the master drones to generate a map. The deployable 5G network is leveraged to identify precise locations for the swarm drones and each instance of sensor data collected by the swarm drones in order to create an accurate and detailed map of the environment. The map can include information regarding the structural layout of the space and environmental characteristics, such as temperature, the presence of smoke or other gases, etc.

Abstract: A mobile local computing device is configured to access memories or storage devices associated with a remote computing device using remote direct memory access (RDMA) over a wireless fifth generation (5G) network link that provides high bandwidth and low latency relative to previous wireless network protocols. The mobile local computing device utilizes a local compute context that is unique to the local environment and which may be facilitated by devices, components, or functionalities that are local to the mobile local computing device, but which are not available with the same context to the remote computing device. The 5G network link supports high bandwidth and low latency so that the mobile local computing device can access and utilize the remote data in large datasets in a similar manner to how it would for locally stored data, while still being able to leverage the local I/O and maintain its unique local compute context.

Abstract: Identities of mobile communications devices and subscription credentials are maintained by an enterprise server. The subscription credentials are operative to enable access to subscription services of a mobile network operator. Control of the subscription credentials is delegated from the mobile network operator to the enterprise server. The enterprise server determines which of the mobile communications devices are to be provisioned by the subscription credentials. Policies for use of the subscription credentials by the determined mobile communications devices are identified. The subscription credentials and policies are applied to the mobile communications devices.

Abstract: Techniques for managing a plurality of mobile communications devices by an enterprise server are described. The mobile communications devices may be configured to communicate on a mobile communications network operated by a mobile network operator. A communicative link is established with a proxy interface configured to implement a standardized interface for exchanging information between the enterprise and the mobile network operator. Data is received by the enterprise server via the proxy interface. The data is associated with subscription services for a plurality of mobile communications devices that are operable on the mobile communications network. The subscription services are associated with the mobile network operator. Requests are sent by the enterprise server via the proxy interface. The requests are for updating the subscription services of the mobile network operator.

Abstract: Techniques for managing a plurality of mobile communications devices by an enterprise server are described. The mobile communications devices may be configured to communicate on a mobile communications network operated by a mobile network operator. A communicative link is established with a proxy interface configured to implement a standardized interface for exchanging information between the enterprise and the mobile network operator. Data is received by the enterprise server via the proxy interface. The data is associated with subscription services for a plurality of mobile communications devices that are operable on the mobile communications network. The subscription services are associated with the mobile network operator. Requests are sent by the enterprise server via the proxy interface. The requests are for updating the subscription services of the mobile network operator.