A method for communication by an electronic device is provided. The method comprises determining establishment of a data channel during an ongoing call with another electronic device; determining at least one application displayed on the electronic device and the another electronic device over the data channel during the ongoing call; determining a disconnection of the ongoing call between the electronic device and the another electronic device; and storing (508) a state of the at least one application in a memory of the electronic device based on determining the disconnection of the ongoing call, wherein the stored state of the at least one application is used for execution of the at least one application during another call.

A mobile-cordless phone system including a mobile-cordless phone assembly; the mobile-cordless phone assembly including an external-phone-body and an internal-circuitry system. The external-phone-body and the internal-circuitry system are structured and arranged to provide the user with a device useful for communications with the internal-circuitry useful for providing a user with a portable telephone with the capabilities to operate on a wireless cellular network and, optionally, a telephone landline. The mobile-cordless phone assembly may be weather-resistant in some embodiments, and may include a multi-color-LED-light-source useful for providing visual indications and notifications to the user. The mobile-cordless phone system includes a solar panel for charging. The mobile-cordless phone assembly may also include a charging-port for connecting a charging-device to the mobile-cordless phone system. Preferred embodiments may also include a fingerprint-reader.

Systems and methods associated with an intercom system for a drive-through, quick service restaurant facility is disclosed. Generally, a plurality of headsets is configured for communication with a base station. A speaker is associated with the drive-through facility is configured to be located near a menu board, and is configured for communication with the base station. A microphone is also configured to be located near the menu board and configured for communication with the base station. A plurality of parameters control the configuration of the intercom system, and the base station is connectable to a wide area communication network to enable remote adjustment of the plurality of parameters.

An intelligent connection station has at least one wireless transceiver operating in a wireless protocol, at least one speaker and one microphone, a connection to a wide area network, and software executing on the connection station from a non-transitory physical medium, the software providing a first function seeking compatible communication appliances within range of the wireless transceiver operating in the wireless protocol, and a second function enabling wireless pairing, providing a wireless link between the intelligent connection station and any communication appliance discovered within range and activated to pair. The pairing enables digital communication between the paired device and a remote communication appliance over the wireless link, through the intelligent connection station and the wide area network.

A method and system for automatically changing the operation of signaling features in a telephone are disclosed. In one embodiment, a method includes: storing, in a first handset of a telephone system, quiet mode settings that specify a start time and an end time for a quiet mode signaling feature; wirelessly transmitting, from the first handset of the telephone system to a second handset of the telephone system, the quiet mode settings that specify the start time and the end time for the quiet mode signaling feature; and updating quiet mode settings for the quiet mode signaling feature in the second handset in response to receiving quiet mode settings from the first handset, and wherein the first handset and the second handset of the telephone system self-check the status of their quiet mode settings.

Technologies are described for a distributed audio system configured to switch operating modes. In some examples, the distributed audio system may include a device configured to execute first instructions from a first memory corresponding to operation in a first mode, receive a signal to switch modes, and, responsive to receiving the signal, switch a select signal corresponding to the first memory to select a second memory. Responsive to selecting the second memory, the device may be configured to execute second instructions from the second memory corresponding to operation in a second mode. The device may enter a registration mode to register portable parts to the device.

Technologies are described for a distributed audio system configured to switch operating modes. In some examples, the distributed audio system may include a device configured to execute first instructions from a first memory corresponding to operation in a first mode, receive a signal to switch modes, and, responsive to receiving the signal, switch a select signal corresponding to the first memory to select a second memory. Responsive to selecting the second memory, the device may be configured to execute second instructions from the second memory corresponding to operation in a second mode. The device may enter a registration mode to register portable parts to the device.

Disclosed is cordless telephone equipment allowing various kinds of data stored in a mobile telephone to be stored in a cordless handset in a state usable therein, without provision of a new device thereto. A handset transfer-data conversion section that executes a predetermined conversion process according to a type of handset transfer-data stored in a storage section. Specifically, the handset transfer-data conversion section converts an audio format of ringtone data according to a use CODEC of a cordless handset. In addition, the handset transfer-data conversion section converts an image size of wallpaper data into a size reproducible in the cordless handset. Further, the handset transfer-data conversion section converts an image size of image data of the other party included in telephone directory data into a size reproducible in the cordless handset.

Slave device information transmitting unit of the present invention transmits slave device information to a mobile phone. Slave device transfer data receiving unit receives slave device transfer data from the mobile phone, and stores the slave device transfer data in storage unit. Destination slave device determining unit extracts destination slave device information from slave device transfer data stored in storage unit, and selects a cordless telephone slave device which is a destination of the slave device transfer data, based on destination slave device identification information which is set in the destination slave device information. Slave device transfer data transmitting unit transmits slave device transfer data to a cordless telephone slave device selected by destination slave device determining unit.

Cordless telephone equipment includes a portable unit and a base unit. The base unit includes: a portable unit control section controlling a communication protocol with the portable unit through a wireless interface wirelessly connecting with the non-IP terminal type portable unit; a wireless LAN interface section transmitting and receiving packet data to and from a wireless IP terminal and wireless LAN access point; a wireless LAN bridge control section forwarding the received packet data to the wireless IP terminal, or the wireless LAN access point, or within the base unit in accordance with a destination address of the packet data received through the wireless LAN interface section; and a base unit control section processing the packet data received from the wireless IP terminal and forwarded within the base unit, as data received from a portable unit under control of the base unit.