Techniques herein facilitate a device address rotation management protocol that may be implemented for a wireless local area network (WLAN), which can be used to influence when wireless client devices or stations may rotate their Media Access Control (MAC) addresses, how to perform such rotations, and/or the like. In one example, a method may include providing, by an access point (AP), a first communication indicating that the AP supports a MAC address rotation management protocol; obtaining, by the AP, a second communication from a wireless station (STA) indicating that the STA intends to perform a MAC address rotation; and transmitting, by the AP, a third communication to influence the MAC address rotation of the STA, the third communication comprising a rotation status indicator and timing information.

Techniques herein facilitate a device address rotation management protocol that may be implemented for a wireless local area network (WLAN), which can be used to influence when wireless client devices or stations may rotate their Media Access Control (MAC) addresses, how to perform such rotations, and/or the like. In one example, a method may include providing, by an access point (AP), a first communication indicating that the AP supports a MAC address rotation management protocol; obtaining, by the AP, a second communication from a wireless station (STA) indicating that the STA intends to perform a MAC address rotation; and transmitting, by the AP, a third communication to influence the MAC address rotation of the STA, the third communication comprising a rotation status indicator and timing information.

A server and an updating method for a MAC address are provided in the present application. The server includes: a network chipset having a preset first MAC address; a first non-volatile memory storing the first MAC address of the network chipset; a second non-volatile memory storing a first BIOS code data; a central processing unit coupled to the network chipset and the second non-volatile memory; and a baseboard management controller coupled to the central processing unit, the first non-volatile memory, and the second non-volatile memory. The baseboard management controller reads the first non-volatile memory to obtain the first MAC address and stores a second BIOS code data including the first MAC address to the second non-volatile memory, causing the first BIOS code data to be overwritten by the second BIOS code data

A communication apparatus includes a processor and a memory. The processor executes computer-readable instructions stored in the memory. The instructions instruct the communication apparatus to establish a first network including the communication apparatus and a first device. The instructions instruct the communication apparatus to establish a second network including the communication apparatus and a second device. The instructions instruct the communication apparatus to determine a target IP address. Determining the target IP address includes identifying a particular IP address, which is an IP address of the communication apparatus used in the second type network. Determining the target IP address includes generating the target IP address to be within a particular range using the particular IP address. The particular range is a range of IP addresses that are not available in the second type network. The instructions instruct the communication apparatus to assign the target IP address to the first device.

A local area network tracking system and method of use is described herein. An exemplary embodiment of the system comprises a central tracker server that registers and tracks third-party vendor kiosks when the kiosks connect to a retail store local area network. The unique tracker server system is configured to efficiently route web application traffic on the same retail store local area network. The tracker server stores a local IP address and a unique identifier for each vendor kiosk connected to a particular retail store network. Customers connected to the network are routed to the tracker server to obtain the IP address for a suitable vendor kiosk, with which the customer can establish a direct wireless connection to that kiosk over the retail store network. The system described herein can be implemented without modifying any aspect of the retail store LAN infrastructure.

A local area network tracking system and method of use is described herein. An exemplary embodiment of the system comprises a central tracker server that registers and tracks third-party vendor kiosks when the kiosks connect to a retail store local area network. The unique tracker server system is configured to efficiently route web application traffic on the same retail store local area network. The tracker server stores a local IP address and a unique identifier for each vendor kiosk connected to a particular retail store network. Customers connected to the network are routed to the tracker server to obtain the IP address for a suitable vendor kiosk, with which the customer can establish a direct wireless connection to that kiosk over the retail store network. The system described herein can be implemented without modifying any aspect of the retail store LAN infrastructure.

Disclosed are an electronic device for wireless communication and a method thereof. The electronic device may include an interface module and a processor. The processor may be configured to establish a first Ethernet tethering connection with an external electronic device by using an Ethernet driver, provide an Internet service to the external electronic device using a first IP address allocated to the external electronic device, deactivate the Ethernet driver in response to identifying that the IP address of the electronic device is changed and the first Ethernet tethering connection is in the bridge mode, reactivate the deactivated Ethernet driver, establish a second Ethernet tethering connection with the external electronic device by using the reactivated Ethernet driver, and provide the Internet service to the external electronic device using a second IP address allocated to the external electronic device.

Systems and methods are provided for reducing communications between servers and a mobile device and providing enhanced security and privacy to wireless beacon services. This can involve a broadcast device transmitting a beacon transmission using a short range wireless radio, such a Bluetooth or WiFi, and including a MAC address, a first unique identifier, and a beacon service identifier. The mobile device then selects one or more unique identifiers from received beacon transmissions, by filtering (that is, selecting) those beacon transmissions which include the beacon service identifier. The wireless device then takes further action, if the first unique identifier is present among the selected one or more unique identifiers, using stored information from the server. The stored information may be delivered to the wireless device in response to the wireless device sending the first unique identifier to a server, or the stored information may have been previously downloaded.

A method is provided in one example embodiment and includes, for each of a plurality of individual storage units collectively comprising a virtual storage unit, mapping an internal address of the storage unit to a unique IP address, wherein each of the storage units comprises a block of storage on one of a plurality of physical storage devices and wherein the IP address includes a virtual storage unit number identifying the virtual storage unit; receiving from a client a request to perform an operation on at least one of the data storage units, wherein the request identifies the internal address of the at least one of the data storage units; translating the internal address of the at least one of the data storage unit to the unique IP address of the at least one of the data storage units; and performing the requested operation on the at least one of the data storage units.

A method is provided in one example embodiment and includes, for each of a plurality of individual storage units collectively comprising a virtual storage unit, mapping an internal address of the storage unit to a unique IP address, wherein each of the storage units comprises a block of storage on one of a plurality of physical storage devices and wherein the IP address includes a virtual storage unit number identifying the virtual storage unit; receiving from a client a request to perform an operation on at least one of the data storage units, wherein the request identifies the internal address of the at least one of the data storage units; translating the internal address of the at least one of the data storage unit to the unique IP address of the at least one of the data storage units; and performing the requested operation on the at least one of the data storage units.