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.

An electrical infrastructure system and method of use of the system for a vehicle. There are several electronic control units (ECU) for one or several functional units (30n) for the vehicle. The ECUs are connected through a network (32). The infrastructure system is configured to implement a state map including various operational states Sn that the vehicle can adopt. These operational states are connected by one or several transitions Tn, where the transition from one operational state to another depends on predetermined transition conditions being satisfied. The infrastructure system is configured to receive one or several input signals (34) to at least one ECU, comprising parameter values that represent events. The at least one ECU is configured to analyze the input signals with the aid of the transition conditions, to determine an operational state, and to make the operational state that has been determined available on the network (32).

Aspects of the subject disclosure may include, for example, a method for down-converting a long-range communication signal that is wirelessly received via a first antenna of a communication device to extract a first version of a baseband signal, down-converting a short-range communication signal wirelessly received from a second device via a second antenna of the communication device to extract a second version of the baseband signal from the long-range communication signal that can be received at the second device, which is remote from the communication device, via a second antenna. The first version and second version of the baseband signal can be combined to generate an information signal that can be processed. Other embodiments are disclosed.

A voice-controlled system for allowing a guest of a hospitality establishment to play desired media content on an in-room device includes one or more servers coupled to a network and a plurality of in-room devices. A user device captures audio from a microphone and converts the audio into a text transcript utilizing a voice-to-text conversion service. The user device passes the text transcript to the servers where a particular room of the hospitality establishment with which the user device is currently associated is determined. The servers check a program guide for the particular room in order to determine a channel on which a program name determined according to the text transcript is currently playing, and determine one or more target in-room devices of the particular room. The servers send commands causing the target in-room devices to play the channel on which the program name is currently playing.

The user calls to the mobile device with a predetermined pattern. In one embodiment the predetermined pattern is coded on the duration of the unanswered calls and the duration between successive calls. The predetermined pattern may be time coded on the durations of successive calls. After detecting the predetermined pattern the mobile device answers the incoming call. The user may continue by identifying via the voice line, if that is required. The mobile device responds to commands provided via the voice line, for example by providing contact information as synthesized speech.

A method of using voice commands from a mobile device to remotely access and control a computer. The method includes receiving audio data from the mobile device at the computer. The audio data is decoded into a command. A software program that the command was provided for is determined. At least one process is executed at the computer in response to the command. Output data is generated at the computer in response to executing at least one process at the computer. The output data is transmitted to the mobile device.

There is provided a method for controlling a first device by a control device using BLE (Bluetooth Low Energy) technology in a wireless communication system, the method comprises establishing a BLE connection with the first device; opening a control channel for controlling the first device; determining the first device and a specific control level to the first device, via the control channel, wherein the specific control level indicates a control authority to control the first device by the control device, wherein the specific control level is determined based on a required security level for the first device; and controlling a controllable operation for the first device based on the determined specific control level, wherein the controllable operation is defined based on the determined specific control level.

A method alerts a user of a first device to the presence of a second device which can interact with the first device. The method includes using an ultrasonic signal transmitted by one of the devices to determine whether the first device is within a threshold distance of the second device. If the first device is determined to be within the threshold distance of the second device, a notification is triggered on the first device.

The present invention provides an intelligent security system, where the system includes an in-vehicle information detection apparatus, a telecommunication server, a smartphone, and an unlocking apparatus, where the in-vehicle information detection apparatus sends collected instant vehicle information to the telecommunication server; the network server sends processed instant vehicle information to the smartphone by using a signal; the smartphone sends mobile phone control signal to the telecommunication server; the telecommunication server sends the mobile phone control signal to the in-vehicle information detection apparatus; the unlocking apparatus sends an unlocking signal to the in-vehicle information detection apparatus; and the smartphone and the unlocking apparatus receive a detection signal of an in-vehicle hardware apparatus. The present invention belongs to the technical field of electronic products. An objective of the present invention is to provide an intelligent security system having a real-time anti-theft function and a function of real-time information sharing after a vehicle is stolen.

A flying device that flies by being controlled from an external location, the flying device including a determination unit that determines a communication quality on a first wireless communication channel used for transmitting data to a control device that controls the flying device within a prescribed range from a flight position at which the flying device is flying; and a transmission control unit that controls a type of data to be transmitted to the control device on the basis of the communication quality determined by the determination unit.