A wireless device includes a radio transceiver, and a digital transmitter configured to transmit, via the radio transceiver, a first data symbol, and to transmit, via the radio transceiver, a repetition of the first data symbol immediately after the first data symbol, where the first data symbol forms a cyclic prefix for the repetition of the first data symbol.

The invention discloses a method for fast detection scan of NB-IoT signals in networks. The object of the invention to provide a scanning procedure which is reliable and very fast in order to reduce the search time and hence the power consumption will be solved by a method for fast detection scan of NB-IoT signals in a network by applying a higher sampling rate than 240 kHz and observing a received signal at a receive bandwidth around a magnitude wider than the NB-IoT signal bandwidth of 180 kHz, wherein a set of 2M+1 NB-IoT signals each having a different E-UTRA absolute radio frequency channel number (EARFCN) can be observed simultaneously, whereas M is a natural number and 2M+1 indicates the number of concurrently observed channels.

The invention discloses a method for fast detection scan of NB-IoT signals in networks. The object of the invention to provide a scanning procedure which is reliable and very fast in order to reduce the search time and hence the power consumption will be solved by a method for fast detection scan of NB-IoT signals in a network by applying a higher sampling rate than 240 kHz and observing a received signal at a receive bandwidth around a magnitude wider than the NB-IoT signal bandwidth of 180 kHz, wherein a set of 2M+1 NB-IoT signals each having a different E-UTRA absolute radio frequency channel number (EARFCN) can be observed simultaneously, whereas M is a natural number and 2M+1 indicates the number of concurrently observed channels.

A wireless device includes a radio transceiver, and a digital transmitter configured to transmit, via the radio transceiver, a first data symbol, and to transmit, via the radio transceiver, a repetition of the first data symbol immediately after the first data symbol, where the first data symbol forms a cyclic prefix for the repetition of the first data symbol.

A method for achieving synchronization between a transmit unit and at least one receive unit of a communications system with multi-carrier signal transmission via a transmit channel includes generating a synchronization symbol using predefined carrier frequencies, modulating the generated synchronization symbol with a predefined synchronization sequence via a transmitter to generate a synchronization signal, emitting the generated synchronization signal by the transmitter with a predefinable repetition period, the synchronization signal being utilized for transmission of an item of transmit-specific status information, receiving a signal by a receiver following transmission via the transmit channel, the received signal being formed by the emitted generated synchronization signal and transmitted repeatedly with the predefinable repetition period, and detecting and evaluating, by the receiver, the received signal via a detection algorithm, the detection algorithm determining a period of the received signal as the synchronization instant at which the synchronization signal is almost certainly present.

A method for achieving synchronization between a transmit unit and at least one receive unit of a communications system with multi-carrier signal transmission via a transmit channel includes generating a synchronization symbol using predefined carrier frequencies, modulating the generated synchronization symbol with a predefined synchronization sequence via a transmitter to generate a synchronization signal, emitting the generated synchronization signal by the transmitter with a predefinable repetition period, the synchronization signal being utilized for transmission of an item of transmit-specific status information, receiving a signal by a receiver following transmission via the transmit channel, the received signal being formed by the emitted generated synchronization signal and transmitted repeatedly with the predefinable repetition period, and detecting and evaluating, by the receiver, the received signal via a detection algorithm, the detection algorithm determining a period of the received signal as the synchronization instant at which the synchronization signal is almost certainly present.

The present invention relates to a non-coherent neighbor cell search method for primary synchronization signal (PSS) and secondary synchronization signal (SSS). In order to eliminate the channel response of the home cell, the present invention utilizes the similarity of channel responses at adjacent subcarriers, components at the k.sup.th subcarrier and the (k+1).sup.th subcarrier of the received signal are respectively multiplied by the conjugation of the corresponding local synchronization signal to respectively obtain the k.sup.th product and the (k+1).sup.th product. Afterward, a combination signal is obtained by examining the difference of the k.sup.th product and the (k+1).sup.th product. By mathematical simplification and analysis, the main unknown component of the combination signal is the synchronization signal of neighbor cell, also in a compound form. Thus, the neighbor cell ID can be obtained by performing the correlation operation of the combination signal to the compound reference sequence.

Various aspects of the present disclosure generally relate to wireless communication. In some aspects, an apparatus for wireless communication may receive a communication indicating a set of deactivated measurement gaps based at least in part on the set of measurement gaps occurring during a time associated with a communication of extended reality (XR) traffic. The apparatus may extend a set of radio resource management (RRM) delays by a number of measurement gap repetition periods (MGRPs), wherein the number of MGRPs is determined based at least in part on a quantity of deactivated measurement gaps, of the set of deactivated measurement gaps, occurring during a corresponding RRM period. Numerous other aspects are described.