A holiday telephone system comprising: a smartphone; a holiday telephone in wireless communication with the smartphone; a holiday telephone app installed on the smartphone, where the app is configured to perform a method, the method comprising: creating a new message by inputting a message into the app via the smartphone; selecting an elf character to speak the message; scheduling the app to cause the holiday telephone to ring at predetermined date, and time; and playing the message as recited by the elf character when the telephone is answered. A non-transitory computer-readable medium includes a set of instructions stored thereon that when accessed by a processor enable the processor to perform a method of creating and scheduling a message to be delivered via a telephone, the method comprising: opening a messages page by default; determining whether the user selects to continue with messages; creating a new message if the user selects to continue with messages; determining whether the user selects to use most recently messaged child; choosing select elf, edit elf, or add new elf, if the user selects to use most recently messaged child; selecting an elf character, if the user chose select elf option; choosing enter message or quick message; entering message, if the user chose enter message option; choosing call now or schedule time for message; entering date and time for telephone message to be delivered to a telephone, if the user chose schedule time for message; displaying scheduled message; changing elf name, changing ringtone associated with elf, changing voice associated with elf, changing gender of elf, if the edit elf option was selected in the choosing select elf, edit elf, or add new elf query; returning to the selecting an elf character query; entering name of new elf; entering gender of new elf, selecting ringtone associated with new elf, selecting voice associated with new elf, if add new elf is selected at the choosing select elf, edit elf, or add new elf query.

Methods, systems, and devices for wireless communication are described. A transmitting device may select an orthogonal metric based at least in part on at least one of each direction of a plurality of directions to transmit millimeter wave discovery signals or a location parameter associated with the transmitting device. The transmitting device may transmit, in the each direction of the plurality of directions, the millimeter wave discovery signals, where the each transmitted millimeter wave discovery signal has a different orthogonal metric applied that was selected based at least in part on the at least one of the each direction or the location parameter.

An electronic device may advertise a first BSSID and a second BSSID having a common SSID, separate wireless connection interfaces, and different capabilities, where the first BSSID may support a first IEEE 802.11 standard, and the second BSSID may support one or more previous IEEE 802.11 standards, but may not support the first IEEE 802.11 standard. Then, the electronic device may receive a probe request associated with a second electronic device. Moreover, the electronic device may determine whether the second electronic device supports the first IEEE 802.11 standard based at least in part on one or more fields in the probe request. Next, the electronic device may selectively provide a probe response to the second electronic device with one of the first BSSID and the second BSSID based at least in part on the determination.

Various techniques are described herein for autonomously registering and/or activating Internet-of-Things (IoT) devices, provisioning wireless network access of those devices, and connecting the IoT device to an NB-IoT network with agreed-to terms for network usage. In various embodiments, IoT devices may be configured to negotiate for NB-IoT network access by (i) sharing their data with the NB-IoT network provider, (ii) security storing and using cryptocurrency to obtain NB-IoT network access, and/or (iii) automatically providing the NB-IoT network provider with access to data from other associated IoT devices and/or with payment from a separate payment provider. Individual IoT devices may be preconfigured with negotiation terms for NB-IoT network access, pre-associated with other devices/users, and/or pre-loaded with cryptocurrency in a secure storage.

A device (110) arranged for wireless communication (130) according to a communication protocol has a processor (112) to execute a connection sequence according to a discovery protocol. The connection sequence comprises determining a current cluster identity and a current discovery window timing used by the device. Next, at least one other device (120,120′) within wireless range is detected, while further determining a detected cluster identity and a detected discovery window timing of the detected other device. Then it is detected whether the detected device is operating in a different cluster than the device by comparing the current cluster identity with the detected cluster identity or comparing the current discovery window timing with the detected discovery window timing. Finally, upon detecting said different cluster, a security process is executed, which may warn the user or abort the connection sequence. Thereby, a malicious device trying to manipulate the connection sequence is detected.

Methods, devices, systems, and means for selection of a coordinating user equipment, UE, in a user equipment-coordination set, UECS, that facilitates selection of the coordinating UE by the UEs in the UECS are described herein. Sharing of the role of coordinating UE by UEs in the UECS can be scheduled in a round-robin manner. Selection criteria can be used to determine which one or more UEs in the UECS will offer better performance in the role of coordinating UE.

A method and system for allocating receiving and processing resources for scanning communication channels over a scanning time are provided herein. The method may include the following steps: dividing the scanning time into time slots, wherein at each time slot, allocating an RF receiver to receive signals in a channel selected from a first number of communication channels, and allocating the processor to process signals received in an earlier time slot; assigning a scanning priority to each of the first number of communication channels; scanning, in accordance with the assigned scanning priority, at least one of a second number of communication channels, to detect and process RF signals; processing the received signals and assigning an updated scanning priority to at least one of the first number of communication channels, wherein the assigned scanning priority is dynamically modifiable; and repeating the scanning and the processing with the updated scanning priority.

A first wireless device receives, from a second wireless device, one or more messages indicating one or more location areas where the first wireless device continuously monitors for one or more sidelink signals. The first wireless device determines that the first wireless device is located in the one or more location areas. Based on the determining, the first wireless device starts continuous monitoring of a control channel for the one or more sidelink signals from a third wireless device. The first wireless device receives, from the third wireless device and based on the starting continuous monitor, the one or more sidelink signals.

A method for secure pairing between a sensor and a concentrator using a mobile terminal includes generating and emitting a confirmation code by the concentrator; converting by the sensor of the confirmation code into a sequence of light signals executed by at least one light-emitting diode; converting by the mobile terminal of the sequence of light signals into a sequence code; sending the sequence code to the concentrator; comparing, by the concentrator, the sequence code and the generated confirmation code: if the sequence code does not match the generated confirmation code, generating a warning; if the sequence code matches the generated confirmation code, pairing and exchanging information between the sensor and the concentrator.

Disclosed are a method and apparatus for transmitting system parameters of a soft access device, a device and a medium. A method for acquiring system parameters of a soft access device includes: receiving a broadcast message sent by the soft access device on a main link, a reduced neighbor report information element in the broadcast message including a multi-link device identifier, an identifier of a non-main link and a system parameter change count; sending a first message for requesting system parameters on the non-main link to the soft access device on the main link in a case that the received broadcast message indicates that a value of a system parameter change count corresponding to the non-main link is different from that of a system parameter change count received last time; and receiving a second message in response to the first message and sent by the soft access device on the main link.