Access points can be mounted in a variety of locations or orientations and can support multiple communications protocols. In some embodiments, an access point includes a main housing and a front housing. The main and front housing are connected by a hinge. A Wi-Fi antenna is included in the front housing in some embodiments. The access point is configured for use in either an open or closed position. When mounted in a vertical position, the front housing can be lowered into a horizontal position, which facilitates a preferred orientation of an antenna with respect to the ground. A first set of cooling fins serves to maintain components of the access point offset from a wall to which the access point is mounted. This facilitates airflow. Additional fins act as a spacer between the main housing and the front housing when the access point is used in a closed position. This facilitates air flow around both sides of the main housing.

The present disclosure relates to positioning request processing methods, devices, and systems In one example method, a mobility management network element receives a request message, and sends a first message to a location management network element based on the request message, where the first message is used to trigger the location management network element to obtain location information of a first terminal device through user plane positioning. After receiving the first message, the location management network element sends a second message to the first terminal device based on the first message by using a protocol data unit (PDU) session of the first terminal device, where the second message indicates the first terminal device to report positioning data.

The disclosed technology separates session management function signaling from the AMF. In particular, an SMF key is created for each SMF following the AMF generating an SM context request that contains gNB information and UE subscription information. Each PDU session creates a direct connection between the SMF and a local gNB. The gNB communicates with each SMF directly over a new interface (N3-C) for session management that is independent of the N2 interface used by the gNB to communicate with the AMF for mobility management. In this way, each SMF independently handles NAS signaling with the UE, using the SMF key and gNB related session-management signaling over an independent interface with the gNB. This removes the burden of relaying these communications through the AMF, which is then freed up to solely to handle mobility management signaling, resulting in an improved architecture.

The disclosed technology separates session management function signaling from the AMF. In particular, an SMF key is created for each SMF following the AMF generating an SM context request that contains gNB information and UE subscription information. Each PDU session creates a direct connection between the SMF and a local gNB. The gNB communicates with each SMF directly over a new interface (N3-C) for session management that is independent of the N2 interface used by the gNB to communicate with the AMF for mobility management. In this way, each SMF independently handles NAS signaling with the UE, using the SMF key and gNB related session-management signaling over an independent interface with the gNB. This removes the burden of relaying these communications through the AMF, which is then freed up to solely to handle mobility management signaling, resulting in an improved architecture.

Environmental monitoring systems that include base stations and environmental sensor units (ESUs) that communicate in a wireless sensor network. A base station may include environmental sensors and may communicate with a remote server using a wide-area wireless network. The base station may also communicate with an environmental sensor unit using a wireless personal area network. The ESU may include environmental sensors and may communicate with the remote server via the base station. The base station and ESU may be adapted to automatically pair with one another to enable the ESU to communicate via the base station. An ESU may also be adapted to process data regarding environmental conditions by automatically determining a type of environmental sensor from which the data was received and processing the data based on the type. An ESU may also include physical ports by which new sensors can be connected to the ESU.

Environmental monitoring systems that include base stations and environmental sensor units (ESUs) that communicate in a wireless sensor network. A base station may include environmental sensors and may communicate with a remote server using a wide-area wireless network. The base station may also communicate with an environmental sensor unit using a wireless personal area network. The ESU may include environmental sensors and may communicate with the remote server via the base station. The base station and ESU may be adapted to automatically pair with one another to enable the ESU to communicate via the base station. An ESU may also be adapted to process data regarding environmental conditions by automatically determining a type of environmental sensor from which the data was received and processing the data based on the type. An ESU may also include physical ports by which new sensors can be connected to the ESU.

Access points can be mounted in a variety of locations or orientations and can support multiple communications protocols. In some embodiments, an access point includes a main housing and a front housing. The main and front housing are connected by a hinge. A Wi-Fi antenna is included in the front housing in some embodiments. The access point is configured for use in either an open or closed position. When mounted in a vertical position, the front housing can be lowered into a horizontal position, which facilitates a preferred orientation of an antenna with respect to the ground. A first set of cooling fins serves to maintain components of the access point offset from a wall to which the access point is mounted. This facilitates airflow. Additional fins act as a spacer between the main housing and the front housing when the access point is used in a closed position. This facilitates air flow around both sides of the main housing.

A communication node provides information relating to a location of a user device in a communication system. The communication node associates with a relay node for providing the user device with access to the communication system via a cell operated by the relay node. The communication node obtains an indication of whether or not the cell is configured as a mobile cell and provides, when the cell is configured as a mobile cell, information indicating that the cell is configured as a mobile cell to a further communication node.

A ZigBee management system includes an auto configuration server (ACS) that manages customer premises equipment (CPE) through CWMP messaging and a CPE proxy that is coupled to the ACS to provide a protocol translation between the CWMP messaging and ZigBee device object (ZDO) messaging for a ZigBee device. The ZigBee management system also includes a hybrid ZigBee coordinator that is coupled to the CPE proxy and has a ZigBee protocol stack having a ZigBee MAC layer as an initial layer, a non-ZigBee physical layer that is coupled to the ZigBee protocol stack and communicates the ZDO messaging over a non-standard ZigBee interface with the CPE proxy, and a ZigBee physical layer that is coupled to the ZigBee protocol stack and the non-ZigBee physical layer and transceives the ZDO messaging for the ZigBee device over a standard ZigBee interface. A method of managing a ZigBee network is also provided.

Techniques described herein provide means by which cell information indicative of a location of a UE may be conveyed to a location server over a 5G NR data connection using a SUPL message with an LTE cell ID data field. In some embodiments, for example, the UE may include the Cell ID of a LTE neighbor cell or information regarding a 5G NR serving cell, such as a portion of the 5G NR Cell ID or a reserved value or sequence identifying the 5G NR serving cell. The techniques may be applicable to the Secure User Plane Location (SUPL) solution defined by OMA and may enable a UE and a SUPL Location Platform (SLP) to support location of the UE using a version of SUPL without explicit support of 5G NR wireless access.