Disclosed are a method and an apparatus for selecting a transmission path, and a storage medium. The method for selecting the transmission path includes: determining performance parameters of each of a plurality of transmission paths in a terminal; selecting a transmission path or a transmission path combination according to the performance parameters of the plurality of transmission paths, a service requirement and a usage scenario; switching to the selected transmission path or the selected transmission path combination.

Disclosed are a method and an apparatus for selecting a transmission path, and a storage medium. The method for selecting the transmission path includes: determining performance parameters of each of a plurality of transmission paths in a terminal; selecting a transmission path or a transmission path combination according to the performance parameters of the plurality of transmission paths, a service requirement and a usage scenario; switching to the selected transmission path or the selected transmission path combination.

A testing method for determining radiation performance of a device under test (DUT) is disclosed. The testing method comprises the following steps. The DUT is arranged at a first orientation. A first effective isotropic radiated power (EIRP) and a first effective isotropic sensitivity (EIS) of the DUT are measured at the first orientation. The DUT is arranged at a second orientation different from the first orientation, and a second EIRP of the DUT is measured at the second orientation. A second EIS of the DUT is measured at the second orientation according to a correlation between the first EIRP, the first EIS and the second EIRP.

A testing method for determining radiation performance of a device under test (DUT) is disclosed. The testing method comprises the following steps. The DUT is arranged at a first orientation. A first effective isotropic radiated power (EIRP) and a first effective isotropic sensitivity (EIS) of the DUT are measured at the first orientation. The DUT is arranged at a second orientation different from the first orientation, and a second EIRP of the DUT is measured at the second orientation. A second EIS of the DUT is measured at the second orientation according to a correlation between the first EIRP, the first EIS and the second EIRP.

A test control unit controls a mobile terminal such that a first period T1, T3, T5, and T7 in which power of a transmission signal is maintained constant, and a second period T2, T4, T6, and T8 in which the power of the transmission signal is changed stepwise are alternately and continuously repeated, and changes a maximum value of signal power that is receivable by a pseudo base station unit in each first period T1, T3, T5, and T7, according to a power range of the transmission signal to be changed in each second period T2, T4, T6, and T8. A minimum value of the signal power that is receivable by the pseudo base station unit is determined, according to a maximum value of the signal power that is receivable by the pseudo base station unit and a reception dynamic range of a mobile terminal testing apparatus.

A test control unit controls a mobile terminal such that a first period T1, T3, T5, and T7 in which power of a transmission signal is maintained constant, and a second period T2, T4, T6, and T8 in which the power of the transmission signal is changed stepwise are alternately and continuously repeated, and changes a maximum value of signal power that is receivable by a pseudo base station unit in each first period T1, T3, T5, and T7, according to a power range of the transmission signal to be changed in each second period T2, T4, T6, and T8. A minimum value of the signal power that is receivable by the pseudo base station unit is determined, according to a maximum value of the signal power that is receivable by the pseudo base station unit and a reception dynamic range of a mobile terminal testing apparatus.

A method for determining a beam correspondence parameter of a device under test includes arranging the device under test within a measurement environment to allow an exchange of a wireless signal with the device under test. The method generating a first beam with the measurement environment for the exchange of the wireless signaland causing causing the DUT to generate, by using an antenna arrangement of the DUT, a second beam, to form a beam pair with the first beam, the beam pair including a TX beam and an RX beam and to generate a third beam corresponding to the second beam. The method includes determining the beam correspondence parameter for the beam pair using characterizing the second beam and a measurement characterizing the third beam.

Disclosed is a method (310) for providing operational feedback during power transfer in a wireless power transfer system. The wireless power transfer system comprises a power transmit device arranged to transfer power over an inductive wireless power transfer interface operating at a transmit frequency to a power receive device. The wireless power transfer system is adapted to transfer information at half duplex using Frequency Shift Keying, FSK, in one direction and Amplitude Shift Keying, ASK, in the other direction. The method comprises transferring (308), at the transmit frequency by the power transmit device, power to the power receive device. During the transferring (308), the method further comprises transmitting (311), at the transmit frequency by one of the power transmit device or the power receive device, a first data packet to the other of the power transmit device or the power receive device using one of two modulation types being FSK or ASK. The method (310) further comprises receiving (311), by the other of the devices, the first data packet and, during the receiving (312) and if a signaling condition is determined (313) to be fulfilled, transmitting (314), at the transmit frequency, by the other of the devices to said one of the devices, operational information using the other of said modulation types. In addition to this, a power receive device, a power transmit device and a test system are introduced.

A test apparatus includes a test antenna that is provided in an OTA chamber 50 and transmits or receives a radio signal to or from an antenna 110 of a DUT 100, and a measurement device that measures transmission characteristics or reception characteristics of the DUT 100 disposed in a quiet zone QZ, by using the test antenna. The test antenna includes a reflector reflection type test antenna 6a that transmits or receives a radio signal to or from the antenna 110 of the DUT via a reflector 7, and mirror reflection type test antennae 6b, 6c, 6d, 6e, and 6f that transmits or receives a radio signal to or from the antenna 110 of the DUT via mirrors 9b to 9f.

The present disclosure relates to an un-manned aerial vehicle (200) for aligning a first directive antenna (101) in a direction D1 towards a second antenna (102), comprising a docking interface (210) arranged to attach the aerial vehicle (200) to a first alignment device (110) of the first directive antenna (101) and an alignment actuator (220) arranged to mechanically interface with the alignment device (110) and to actuate alignment of the first directive antenna (101) based on an alignment control signal. The aerial vehicle further comprises a control unit (230) configured to generate an alignment control signal.