A method for determining a nonlinearity characteristic of a receiver path includes generating a set of NM digital samples by repeating N times selecting an scaling factor from a set of N scaling factors, generating a version of a test signal, the version of the test signal corresponding to a test signal scaled by the respective scaling factor, processing the respective version of the test signal in at least a part of the receiver path to generate a respective processed signal, and storing M digital samples corresponding to the respective processed signal. Fourier-transformed data are generated using at least a portion of the set of NM digital samples and a nonlinearity characteristic of the receiver path is determined based on the Fourier-transformed data.

A measurement device is provided. Said measurement device comprises a plurality of ports for receiving and/or transmitting radio frequency signals, a plurality of measurement units with one measurement unit for each of the plurality of ports, each measurement unit being configured to measure the corresponding forward and/or reverse radio frequency signal, and a subset of additional measurement units, preferably one additional measurement unit, configured to be connected to a subset, preferably one, of the ports in addition to or instead of the respective at least one of the plurality of measurement units.

Systems, methods, apparatuses, and computer program products for enhanced beam switching. A method may include informing a network element about a user equipment type and capability in beam switching from a source beam to a target beam. The method may further include receiving a request from the network element to switch from the source beam to the target beam. The method may also include based on the user equipment type and capability, receiving a reference signal for timing adjustment with the target beam. In addition, the method may include switching from the source beam to the target beam. Further, the method may include adjusting the time or frequency tracking of the target beam after the switching based the reference signal.

The invention relates to a measurement system, including a signal analyzer or monitoring receiver, for measuring and analyzing modulated signals. The system includes a signal acquisition device having input port(s), wherein the signal acquisition device is configured to capture modulated signal(s) applied to the input ports, wherein each captured modulated signal can be represented as an I/Q signal; wherein the signal acquisition device generates at least two digital I/Q data streams based on the one or more modulated signals, wherein the at least two digital I/Q data streams are generated in parallel. The measurement system includes a selection device to select at least one target frequency bandwidth in each of the at least two digital I/Q data streams; and a signal processing device configured to analyze the at least two digital I/Q data streams in the selected target frequency bandwidths.

Apparatus and methods are provided for determining AR filter coefficient and numbers of synchronization. In one novel aspect, the AR filter coefficient and times of synchronization are determined based on the temperatures of the oscillator. In one embodiment, the UE determines a temperature drift rate by collecting sets of temperatures before and after the UE in the sleep mode of the CDRX, generates one or more threshold look-up tables and performs an optimization selection based on the temperature drift rate and the one or more threshold of look-up tables, wherein the optimization selection comprising selecting an alpha coefficient and a number of subframes for synchronization. In another embodiment, the optimization selection is further determined based on a subcarrier spacing, and a channel type of being a static channel type and a fading channel type. The UE further performs an on-the-fly oscillator S-curve calibration based on the set of temperatures.

Aspects of the disclosure are directed to a user equipment (UE) configured for detecting phase coherence failure in coherent joint transmissions (CJTs) from multiple wireless nodes (e.g., transmission/reception points (TRPs) and/or base stations). In some examples, the UE is configured to obtain signaling from a plurality of wireless nodes, the signaling including a first signal from a first wireless node of the plurality of wireless nodes and a second signal from a second wireless node of the plurality of wireless nodes. The UE is also configured to estimate a phase difference between the first signal and the second signal. In some examples, the UE is configured to output, for transmission to at least one of the first wireless node or the second wireless node, an indication of the estimated phase difference.

A satellite orbit calculation unit that calculates a satellite orbit based on position information and a movement speed of a satellite at a start of measurement, a Doppler shift calculation unit that calculates a Doppler shift amount and displays, on the display unit, a difference between a carrier frequency of a downlink signal and a carrier frequency at the start of the measurement and a difference between a carrier frequency of an uplink signal and the carrier frequency at the start of the measurement, a Doppler shift removal unit that removes a Doppler shift added to the uplink signal based on the calculated Doppler shift amount, and a frequency error measurement unit that calculates a difference between the carrier frequency after the Doppler shift is removed and the carrier frequency at the start of the measurement and displays the difference on the display unit are provided.