User equipment (UE) that includes a processor and that executes a random access procedure with a base station (E-UTRAN Node B (eNodeB), also known as Evolved Node B) is provided. The UE can at least temporarily be embodied by the processor. The UE may comprise: a determination unit for determining a message size that can be transmitted and that corresponds to a physical random access channel according to an assigned communication method with the base station; a calculation unit for configuring a message to correspond to the message size and for respectively calculating a preamble index and at least one message index from the message; and an encoder for providing respective encoding of the preamble index and the at least one message index, and transmitting the same to the base station.

The present invention relates to a surge protection device for multi-protection mode communications, comprising: an input line into which a voltage is introduced; an output line connected to an external line; a surge discharge part provided with a ground terminal; a surge protection circuit part provided between the input line and the output line and having at least two or more surge protection circuits provided in parallel and discharging the introduced voltage to the ground terminal if the introduced voltage is a surge voltage; circuit conversion parts for selectively connecting the input line and the output line to any one of the surge protection circuits; a condition measuring part for measuring an input voltage introduced into an input terminal of the input line and a second discharge voltage from the surge protection circuit to the ground terminal and comparing each of the input voltage and the second discharge voltage with preset reference voltages; and a control circuit part for detecting abnormality of the connected surge protection circuit by using the comparison result of the input voltage and the comparison result of the second discharge voltage and converting the connected surge protection circuit into another one of the connected surge protection circuits through the circuit conversion parts if the abnormality of the connected surge protection circuit is detected. By the surge protection device for multi-protection mode communications, the damage to the surge protection circuits can be detected using the input surge voltage and no voltage is required to be additionally applied for detecting the damage to the surge protection circuits.

The present invention relates to a surge protection device for multi-protection mode communications, comprising: an input line into which a voltage is introduced; an output line connected to an external line; a surge discharge part provided with a ground terminal; a surge protection circuit part provided between the input line and the output line and having at least two or more surge protection circuits provided in parallel and discharging the introduced voltage to the ground terminal if the introduced voltage is a surge voltage; circuit conversion parts for selectively connecting the input line and the output line to any one of the surge protection circuits; a condition measuring part for measuring an input voltage introduced into an input terminal of the input line and a second discharge voltage from the surge protection circuit to the ground terminal and comparing each of the input voltage and the second discharge voltage with preset reference voltages; and a control circuit part for detecting abnormality of the connected surge protection circuit by using the comparison result of the input voltage and the comparison result of the second discharge voltage and converting the connected surge protection circuit into another one of the connected surge protection circuits through the circuit conversion parts if the abnormality of the connected surge protection circuit is detected. By the surge protection device for multi-protection mode communications, the damage to the surge protection circuits can be detected using the input surge voltage and no voltage is required to be additionally applied for detecting the damage to the surge protection circuits.

The present disclosure provides a method and a device in a User Equipment (UE) and a base station used for paging. The UE first monitors a first signaling in X time intervals respectively, and then receives a first radio signal. The first signaling is used for determining scheduling information for the first radio signal. The scheduling information includes at least one of {occupied time-frequency resource, adopted MCS, subcarrier spacing of subcarriers in occupied frequency domain resource}. The first radio signal carries a paging message. The frequency domain resource is used for transmitting the first signaling belongs to a first subband. The first subband includes a positive integer number of consecutive subcarriers in frequency domain. At least one of {location of the first subband in frequency domain, subcarrier spacing of subcarriers included in the first subband} is used for determining the X time intervals.

The present disclosure provides a method and a device in a User Equipment (UE) and a base station used for paging. The UE first monitors a first signaling in X time intervals respectively, and then receives a first radio signal. The first signaling is used for determining scheduling information for the first radio signal. The scheduling information includes at least one of {occupied time-frequency resource, adopted MCS, subcarrier spacing of subcarriers in occupied frequency domain resource}. The first radio signal carries a paging message. The frequency domain resource is used for transmitting the first signaling belongs to a first subband. The first subband includes a positive integer number of consecutive subcarriers in frequency domain. At least one of {location of the first subband in frequency domain, subcarrier spacing of subcarriers included in the first subband} is used for determining the X time intervals.

A system and method for compensating for detected phase errors during communications between synchronized devices. In an embodiment, the two devices may be a touch screen device and a synchronized stylus device. To this end, the touch screen device includes a controller configured to receive data signals from the stylus at specific time intervals. The touch screen device generates an internal control signal for receiving the incoming data signals at an expected frequency. The touch screen device further includes circuitry for measuring differences in the time a data signal is actually received against when the data signal was expected to be received and determines a time difference (e.g., a phase error). Then, the internal control signal may be adjusted to compensate for the accumulated phase error. Such a measurement and compensation helps ensure that communications remain in synchronization without having to reestablish synchronization through a cumbersome synchronization process.

A communication system 100 is configurable to operate in either a transparent mode or a data streaming mode. In the transparent mode data is transferred to a data requesting component 112 from a data source 102 using a request-response protocol. In the data streaming mode a second data transfer component 106 is configured to obtain 606 data from the data source component via a third data link 104, and to transfer 608 the data to a first data transfer component 110 via a second data link 106, which has a relatively higher latency, without using the request-response protocol. The first data transfer component is configured to store 610 the transferred data and to transfer 614 the stored data to the data requesting component via the first data link upon receiving a request for the stored data from the data requesting component.

A serializer may be provided. The serializer may include a first data output circuit and a second data output circuit. The first data output circuit may provide first data to an output node in synchronization with a first phase clock and a second phase clock. The second data output circuit may provide second data to the output node in synchronization with the second phase clock and a third phase clock. The first data output circuit may perform a precharge operation or an emphasis operation for the second data output circuit, in synchronization with a third phase clock.

Example embodiments may include a method for configuring an interface that includes determining information for a configuration of an interface of a first device including a plurality of SERDES slices having a plurality of connections to a second device over the interface; and configuring a back channel layer associated with the first device to form a back channel path to carry a message between a transmitter and a receiver of the first device based on the configuration of the plurality of connections to the second device. The transmitter can be in a first SERDES slice of the plurality of SERDES slices and the receiver is in a second SERDES slice of the plurality of SERDES slices.

The present disclosure discloses a method for processing data, a network node, and a terminal. The method includes determining a first data block division manner according to first baseband capability information, where the first baseband capability information includes at least one piece of: capability information, space layer information, or time-frequency resource information of a baseband processing unit. The method also includes dividing a to-be-sent data block into first processing blocks according to the first data block division manner and performing first baseband processing on the first processing block based on a granularity of the first processing block.