Abstract: Disclosed are various embodiments for managing computing capacity in radio-based networks and associated core networks. In one embodiment, it is determined that a set of computing hardware implementing a radio-based network for a customer has an excess capacity. At least one action is implemented to reallocate the excess capacity of the computing hardware.

Abstract: Disclosed are various embodiments relating to an intersection of on-demand network slicing and content delivery. In one embodiment, in response to an application programming interface (API) request, a network slice is provisioned with a quality-of-service requirement in a radio-based network having a radio access network and an associated core network. Also in response to the API request, a transfer of content to a content delivery service at an edge location in the radio-based network is initiated in order to meet the quality-of-service requirement for the network slice.

Abstract: Disclosed are various embodiments for managing radio-based private networks. In one embodiment, a cellular network comprises at least one cell that provides a radio-based private network coverage of a site of an organization. The system further comprises at least one computing device in a cloud provider network that implements one or more network functions for an associated core network of the radio-based private network.

Abstract: Disclosed are various embodiments for on-demand application-driven network slicing. In one embodiment, it is determined that an application executed in a particular computing device has a quality-of-service requirement. The particular computing device is connected to a communications network. A request is sent that causes a network slice allocation service to reserve a network slice having the quality-of-service requirement in the communications network. Data to or from the application is transmitted using the network slice.

Abstract: Disclosed are various embodiments for managing assignments of network slices. In one embodiment, a request is received to allocate a network slice in a radio-based network having a radio access network and an associated core network to an application connected to the radio-based network. The request specifies a set of quality-of-service constraints required for the network slice. A set of network functions in the radio-based network is configured to implement the network slice.

Abstract: Network hardware devices organized in a wireless mesh network (WMN). The mesh network device receives, from a first device that is not part of the WMN, a first request to receive information about radar events in an area. The first request includes an identifier of a Dynamic Frequency (DFS) channel and first proximity data for at least one mesh network device in the vicinity of the first device. The mesh network device determines that i) the first device is located within the area; and ii) the first device is communicatively coupled with the at least one mesh network device and sends authorization to receive information about the radar events and coverage map data that identifies the area. The mesh network device sends, to the first device, first data about a first radar event in response to the radar event.

Abstract: Technologies directed to determining a role of a network device, configuring the network device according to the role, and provisioning the network device to a network are described. In one method, the hardware configuration information and external connection information are stored by the network device. The network device determines a role using the hardware configuration information and the external connection information without any manual intervention or manual configuration. The role can be any one of a Router Node, a Storage Node, a Base Station Node, a Relay Node, a Gateway Node, or a Customer Premises Equipment (CPE) Node. After recognizing the role, the network device can be configured and provisioned to the network without any manual intervention or manual configuration.

Abstract: Technology for content distribution in wireless mesh network is described. In one embodiment, the wireless mesh network includes a plurality of mesh nodes, wherein each of the mesh nodes includes a content agent configured to receive a content command from a cloud computing content management service communicatively coupled to the wireless mesh network, the content command identifying one or more segments of a media content file corresponding to a media title to be stored on the mesh node. Each mesh node includes a storage system configured to store the one or more segments of the media content file specified in the content command. Each mesh node further includes a content server configured to service requests for playback of the media title from one or more mesh clients. The mesh nodes also include a mesh communication component configured to communicate with other mesh nodes in the wireless mesh network to retrieve segments of the media content file stored on the other nodes.

Abstract: Technology for content distribution in wireless mesh network is described. In one embodiment, a cloud computing system includes one or more computing devices running a media provider service and a content management service. The media provider service is configured to select a subset of a plurality of media titles having a highest relative popularity available from one or more media content providers for distribution to one or more mesh nodes in a wireless mesh network. The content management service is configured to retrieve media content files corresponding to the subset of the plurality of media titles, divide each of the media content files into a plurality of smaller segments, send at least a portion of the plurality of smaller segments to the one or more mesh nodes in the wireless mesh network.

Abstract: Network hardware devices organized in a wireless mesh network (WMN). A first mesh network device performs a three-stage discovery protocol; in a first stage, a discovery scan uses a first radio to find a set of neighbor devices in proximity; in a second stage, a discovery locate probe process is performed on a secondary discovery channel that is from a same frequency band group as a first DFS channel; in a third stage, a CAC is performed via the first DFS channel and, after the CAC, a neighbor peering request is sent and a neighbor peering response is received from a second mesh network device via a second radio. The neighbor peering response confirms establishment of a first communication channel between the second radio of the first mesh network device and a radio of the second mesh network device over the first DFS channel.

Abstract: Technology for event propagation and action coordination in a mesh network is described. In one embodiment, a master mesh node for a first communication channel in a mesh network receives a first event notification message from a first dependent mesh node associated with the master mesh node. The first event notification message pertains to a first event detected by the first dependent mesh node. In response, the master mesh node generates a first action message specifying a first action associated with the first event and sends the first action message to the first dependent mesh node and to a second dependent mesh node associated with the master mesh node. The master mesh node, the first dependent mesh node, and the second dependent mesh node all exchange communications with each other using the first communication channel in the mesh network.

Abstract: A method includes determining, by a cloud computing system, a number of radar events detected by wireless access point (WAP) devices of a wireless mesh network and by channels associated with respective ones of the WAP devices. The method includes determining a first WAP device has detected a fewest number of radar events and that a first DFS channel, of the first WAP device, has detected a fewest number of radar events as compared with a number of radar events detected via each of the other DFS channels of the first WAP device. The method includes assigning the first WAP device to be a master on the first DFS channel and transmitting, to the first WAP device, a message containing first assignment information regarding the first WAP device being assigned as the master on the first DFS channel.

Abstract: A wireless device includes a radio, a first directional antenna, a second directional antenna, an omnidirectional antenna, and a switch selectively coupled between the radio and the first directional antenna, the second directional antenna, and the omnidirectional antenna. A processor is coupled to the switch and to, for a frame: determine, based on an arbitration table, a destination medium access control address of a client wireless device and identifiers of antennas for transmitting the frame and receiving acknowledgement data; cause the switch to couple the radio to the first directional antenna; transmit the frame to the client wireless device via the first directional antenna, wherein the first client wireless device is located along a first direction with respect to the wireless device; cause the switch to couple the radio to the omnidirectional antenna; and receive an acknowledgment, corresponding to the frame, from the client wireless device via the omnidirectional antenna.

Abstract: A mesh network device includes a content repository including a first section to store original data and a second section to store cached data, and an application processor including a user space, kernel space, and an on-path data caching engine. The on-path data caching engine is to receive, from a second mesh network device, data frames via a data link layer of a TCP/IP mesh network. The data frames include audio or video content. The on-path data caching engine is further to store the data frames in a socket kernel buffer, determine that a third mesh network device is a destination for the data frames, and forward the data frames to the third mesh network device. The on-path data caching engine is to determine that the audio or video content is to be cached and asynchronously copy the audio or video content to the second section of the content repository.

Abstract: Network hardware devices organized in a wireless mesh network (WMN) in which one mesh network device includes a first radio and one or more additional radios coupled to an application processor. The application processor receives a request to stream content data to a client consumption device, via the first radio, and receives portions of the content data from multiple devices at different retrieval rates via the one or more additional radios. The application processor calculates an average retrieval rate for retrieving the first segments and the second segments, determines a desired streaming bitrate value, and determines an end time to complete transmission of a first portion to the client consumption device. The application processor transmits, via the first radio, the first portion such that at least one byte of the first portion is transmitted at the end time to complete transmission of the first portion.

Abstract: A mesh network device includes a radio and an application processor including a hop-aware multicast engine to: determine a mesh header time to live (TTL) value for a broadcast frame in a data link layer. The mesh header TTL value is the lessor of an internet protocol (IP) header TTL value of the first broadcast frame in an IP layer and a predefined value. The broadcast frame includes a request for a service or a resource to be sent. The hop-aware multicast engine sends the broadcast frame to a first set of mesh network devices being defined by the mesh header TTL value. The hop-aware multi-case engine determines that a response was not received within a time period; increases the mesh header TTL value; and sends a broadcast frame to a second set of one or more additional mesh network devices being defined by the increased mesh header TTL value.

Abstract: Systems and approaches arc provided to enable multiple user devices to share data between devices. In one scenario, a user may click on or touch a telephone hyperlink from a browser of a desktop computer to initiate a telephone call from the user's mobile phone. In another situation, a user may begin various computing tasks from a tablet in the evening, share data associated relating to her work with a business computer, and complete her tasks the next day in the office with little to no minimal disruption to her work flow. In effect, the user may “cut” or “copy” data from a first personal computing device and paste that “data” onto a second computing device.

Abstract: Approaches are described which enable a user equipment (UE) device (e.g., mobile phone, tablet computer) to measure signal strength of neighboring cells in a cellular network based at least in part on direction and/or location information of the UE device. The computing device may determine, based on location and/or direction information, that the device is moving away from a neighboring cell and either stop measuring the signal strength or reduce the rate of measuring the signal strength of that neighboring cell. This selective measuring can enable computing devices to conserve battery power and reduce processing overhead when moving between cells of a cellular network.

Abstract: Sending short message service (SMS) messages and receiving a response report based at least in part on the sent SMS message, even if a communicative connection with the mobile communications network had been severed, so that duplication of the SMS message is avoided is disclosed. In this case, a communicative connection may be re-established and used to receive an acknowledgment from the mobile communications network and subsequently send another acknowledgement to the mobile communications network. The UE may also be configured to send an information element to the one or more elements of the mobile communications network to indicate that a communicative connection with the network is to remain established so that acknowledgements may be reconciled between the UE and the network. Additionally, the mobile communications network may be configured to transmit the SMS message only after receiving the acknowledgement from the UE, to avoid sending duplicate SMS messages.

Abstract: Sending short message service (SMS) messages and receiving a response report based at least in part on the sent SMS message, even if a communicative connection with the mobile communications network had been severed, so that duplication of the SMS message is avoided is disclosed. In this case, a communicative connection may be re-established and used to receive an acknowledgment from the mobile communications network and subsequently send another acknowledgement to the mobile communications network. The UE may also be configured to send an information element to the one or more elements of the mobile communications network to indicate that a communicative connection with the network is to remain established so that acknowledgements may be reconciled between the UE and the network. Additionally, the mobile communications network may be configured to transmit the SMS message only after receiving the acknowledgement from the UE, to avoid sending duplicate SMS messages.