Proximity of a user/device to a designated location or other user/device can be determined and used to trigger automatic reconfiguration of a telephone ring list associated with the user/device. Accordingly, there is no need for manual reconfiguration to accommodate changes in the user's location or schedule. Specific phone numbers may be added or removed from a user's ring list based on the user's location, and the ring list may be reconfigured as the user enters or leaves a location. The user's desired phones will automatically ring for incoming calls based on the ring list and/or an identification of the incoming call.

Proximity of a user/device to a designated location or other user/device can be determined and used to trigger automatic reconfiguration of a telephone ring list associated with the user/device. Accordingly, there is no need for manual reconfiguration to accommodate changes in the user's location or schedule. Specific phone numbers may be added or removed from a user's ring list based on the user's location, and the ring list may be reconfigured as the user enters or leaves a location. The user's desired phones will automatically ring for incoming calls based on the ring list and/or an identification of the incoming call.

A feedback system is provided. The feedback system includes a main body, a vibration module, a sensing module, and a control module. The vibration module includes a first vibration mechanism. The first vibration mechanism is used for providing a first vibration force to the main body at a first vibration position. The sensing module is used for detecting the status of the main body and providing a sensing signal. The control module is used for receiving the sensing signal and providing a driving signal to the first vibration mechanism to generate the first vibration force.

A system and method for processing a plurality of channels, for example audio channels, in parallel is provided. For example, a plurality of telephony channels are processed in order to detect and respond to call progress tones. The channels may be processed according to a common transform algorithm. Advantageously, a massively parallel architecture is employed, in which operations on many channels are synchronized, to achieve a high efficiency parallel processing environment. The parallel processor may be situated on a data bus, separate from a main general purpose processor, or integrated with the processor in a common board or integrated device. All, or a portion of a speech processing algorithm may also be performed in a massively parallel manner.

A system and method for processing a plurality of channels, for example audio channels, in parallel is provided. For example, a plurality of telephony channels are processed in order to detect and respond to call progress tones. The channels may be processed according to a common transform algorithm. Advantageously, a massively parallel architecture is employed, in which operations on many channels are synchronized, to achieve a high efficiency parallel processing environment. The parallel processor may be situated on a data bus, separate from a main general purpose processor, or integrated with the processor in a common board or integrated device. All, or a portion of a speech processing algorithm may also be performed in a massively parallel manner.

The present disclosure generally relates to the field of telecommunication systems. The disclosure more particularly relates to a system and method for effectuating real time shaped data transfer during call setup procedure in a telecommunication network, where selection is made to shape the data transfer during call setup by called party, providing a dynamic tone service operation, where dynamic tone consists of dynamic ring back tone and dynamic busy tone.

A ringing suppression circuit applicable to a transmitter module in a controller area network is provided, which includes a CANH driver circuit, a CANL driver circuit, a first operable circuit transmitting a CAN high signal, a second operable circuit transmitting a CAN low signal, and a termination component connected between the first operable circuit and the second operable circuit. By sequentially turning on a first, second, and third transistor of the CANH driver circuit and sequentially turning on a fourth, fifth, and sixth transistor of the CANL driver circuit, conventional ringing phenomenon is effectively suppressed. A plurality of transistors may also be configured for implementing the CANH driver circuit or the CANL driver circuit for further reducing a glitch. The transmitter module employing the proposed ringing suppression circuit is able to pull the bus to a recessive state and meanwhile suppress the ringing and improve the maximum data rate.

Proximity of a user/device to a designated location or other user/device can be determined and used to trigger automatic reconfiguration of a telephone ring list associated with the user/device. Accordingly, there is no need for manual reconfiguration to accommodate changes in the user's location or schedule. Specific phone numbers may be added or removed from a user's ring list based on proximity information, and the ring list may be reconfigured as the user and a second user enter or leave a common location. The user and the second user's desired phones will automatically ring for incoming calls based on the ring list and/or an identification of the incoming call.

Proximity of a user/device to a designated location or other user/device can be determined and used to trigger automatic reconfiguration of a telephone ring list associated with the user/device. Accordingly, there is no need for manual reconfiguration to accommodate changes in the user's location or schedule. Specific phone numbers may be added or removed from a user's ring list based on proximity information, and the ring list may be reconfigured as the user and a second user enter or leave a common location. The user and the second user's desired phones will automatically ring for incoming calls based on the ring list and/or an identification of the incoming call.

We provide a computer-implemented method for automatic transfer of an upcoming event, which is stored in an event-processing entity (20) of a client (30) assigned to a user, through an interface to an endpoint (60, 80) assigned to the user, comprising the following steps: the client (30) sends first additional information concerning the upcoming event to a conversion unit (40), the conversion unit (40) generates an appointment reminder for the upcoming event and sends the appointment reminder to a telecommunication platform (50), the telecommunication platform (50) processes the appointment reminder, generates a signal, and sends the signal to the endpoint (60, 80), wherein the signal is adapted to the endpoint (60, 80) and is preferably an audible and/or visual signal, and the endpoint (60, 80) processes the signal and the first additional information, in order to accept or reject the first appointment reminder as a result, and sends that result back to the client (30).

We also provide a conversion unit and a machine-readable data carrier (90) with a computer program product stored on it.