Apparatuses, methods, and systems are disclosed for selecting a network slice. One apparatus includes a processor and a transceiver that communicates with a mobile communication network supporting a plurality of network slices. The processor detects an application of the apparatus that requests to send a data packet and selects a network slice selection indicator associated with the detected application of the apparatus. The processor controls the transceiver to transmit the data packet via a network connection to a network slice in the mobile communication network, the network connection being associated with the selected network slice selection indicator.

Apparatuses, methods, and systems are disclosed for selecting a network slice. One apparatus includes a processor and a transceiver that communicates with a mobile communication network supporting a plurality of network slices. The processor detects an application of the apparatus that requests to send a data packet and selects a network slice selection indicator associated with the detected application of the apparatus. The processor controls the transceiver to transmit the data packet via a network connection to a network slice in the mobile communication network, the network connection being associated with the selected network slice selection indicator.

A system for training animals includes a hand-held device and a remote device, where the remote device applies a stimulus when a user presses a button or trigger on the hand-held device. The amount of pressure applied is measured by a pressure sensitive transducer and transformed into proportional transducer signals. These transducer signals are transmitted to the remote device, which then applies a stimulus to an animal being trained. The amplitude of the applied stimulus corresponds to the amplitude of the transducer signals; a trainer can thus precisely control the intensity of the stimulus by applying and relieving pressure on the button. The type of stimulus applied is controlled based on the position of a rotary switch on the hand-held device. Sensor data generated by specialized sensors in the remote device may be transmitted to the hand-held device to provide the user with sensory feedback.

A system for training animals includes a hand-held device and a remote device, where the remote device applies a stimulus when a user presses a button or trigger on the hand-held device. The amount of pressure applied is measured by a pressure sensitive transducer and transformed into proportional transducer signals. These transducer signals are transmitted to the remote device, which then applies a stimulus to an animal being trained. The amplitude of the applied stimulus corresponds to the amplitude of the transducer signals; a trainer can thus precisely control the intensity of the stimulus by applying and relieving pressure on the button. The type of stimulus applied is controlled based on the position of a rotary switch on the hand-held device. Sensor data generated by specialized sensors in the remote device may be transmitted to the hand-held device to provide the user with sensory feedback.

The disclosure relates to an electronic device for wireless communication, a wireless communication method and a computer readable medium. According to an embodiment, an electronic device for wireless communication includes a processing circuitry. The processing circuitry is configured to acquire a parameter related to a behavior characteristic of a mobile access point. The processing circuitry is further configure to determine a spectrum allocation manner for the mobile access point based on the parameter.

A wireless battery management system includes a plurality of slave BMSs coupled to a plurality of battery modules in one-to-one correspondence. Each slave BMS is configured to operate in active mode and sleep mode. Each slave BMS is configured to wirelessly transmit a detection signal indicating a state of the battery module. The wireless battery management system further includes a master BMS configured to wirelessly receive the detection signal from each of the plurality of slave BMSs. The master BMS is configured to set a scan cycle and a scan duration for each of the plurality of slave BMSs based on the detection signal, and wirelessly transmit a control signal to the plurality of slave BMSs. The control signal includes a wireless balancing command indicating the scan cycle and the scan duration set for each of the plurality of slave BMSs.

Tools and techniques are described to automate line testing when wiring devices (such as equipment and sensors) to controllers. Controllers have access to databases of the devices that are controlled by them, including wiring diagrams and protocols, such that the controller can automatically check that each wire responds correctly to stimulus from the controller. After testing, a reporting device rapidly shows the results of the line testing.

Tools and techniques are described to automate line testing when wiring devices (such as equipment and sensors) to controllers. Controllers have access to databases of the devices that are controlled by them, including wiring diagrams and protocols, such that the controller can automatically check that each wire responds correctly to stimulus from the controller. After testing, a reporting device rapidly shows the results of the line testing.

The method of managing processing resources in a telecommunications network, the telecommunications network having a plurality of network slices and a User Equipment (UE), wherein the UE is allocated to a first network slice to process a network communication from the UE, the method comprising the steps of: monitoring a suitability of the first network slice to process the network communication; identifying a second network slice that is suitable for processing the network communication; and in response to identifying a lack of suitability of the first network slice to process the network communication, reallocating processing resources from the second network slice to the first network slice whilst the UE remains allocated to the first network slice.

A first terminal of a radio communications network. The first terminal includes at least one processor, at least one memory with computer program code, and at least one communication module and at least one antenna. The computer program code is configured in such a way that, using the processor, the communication module, and the antenna, it causes the first terminal to send first messages on a first radio resource to a group of further terminals, to receive at least one response, after sending the particular first message, from at least one of the further terminals of the group, to ascertain a resource change decision as a function of the at least one response, and to send second messages as a function of the resource change decision on a second radio resource to the group of further terminals, the second radio resource being different from the first radio resource.