A system for over-the-air testing of a device under test includes a measurement antenna, a reference antenna, a device under test capable of wirelessly transmitting and/or receiving complex radio frequency signals, and an analyzer. The analyzer has at least two ports, wherein the reference antenna is connected with a first port of the analyzer. The measurement antenna is connected with a second port of the analyzer. The analyzer is capable of determining a phase difference and a power ratio of radio frequency signals received via the measurement antenna and the reference antenna. The analyzer is capable of performing an IQ analysis on complex radio frequency signals. Further, a method of over-the-air testing of a device under test is disclosed.

A system may include a printed circuit board with a microstrip and a conductive structure surrounding the microstrip. The system may include a probe lead in communication with the conductive structure. The system may include a first contact pad electrically connected to the conductive structure and a second contact pad electrically connected to the conductive structure.

The present disclosure relates to a system for aligning a measurement system suitable for radio frequency measurement of a device under test. The system includes an alignment device, a measurement module and an indication module. The alignment device includes at least two alignment antennas configured to receive a signal over-the-air from a measurement antenna of the measurement system. The measurement module is configured to measure a phase difference between the at least two alignment antennas receiving the signal. The indication module is configured to indicate the measured phase difference between the at least two alignment antennas or a reference quantity associated with the measured phase difference. Further, a method of aligning a measurement system used for radio frequency measurement of a device under test is described.

The present disclosure relates to a system for aligning a measurement system suitable for radio frequency measurement of a device under test. The system includes an alignment device, a measurement module and an indication module. The alignment device includes at least two alignment antennas configured to receive a signal over-the-air from a measurement antenna of the measurement system. The measurement module is configured to measure a phase difference between the at least two alignment antennas receiving the signal. The indication module is configured to indicate the measured phase difference between the at least two alignment antennas or a reference quantity associated with the measured phase difference. Further, a method of aligning a measurement system used for radio frequency measurement of a device under test is described.

An over-the-air measurement system for performing over-the-air measurements on a device under test is described. The measurement system comprises a measurement device having several measurement antennas, several waveguides, wherein at least one waveguide is assigned to each measurement antenna, several waveguide-to-cable adapters, and a positioning unit assigned to the measurement antennas. The number of the waveguide-to-cable adapters is at least identical to the number of the measurement antennas. The positioning unit is configured to move the measurement antennas with respect to the waveguide-to-cable adapters.

Embodiments of the present disclosure provide an antenna assembly for a test system. The antenna assembly includes a feedthrough part, two waveguide inputs, a single waveguide output as well as a multiplexing part that is interconnected between the two waveguide inputs and the single waveguide output. The multiplexing part is integrated within the feedthrough part at least partially. Moreover, embodiments of the present disclosure provide a test system and a method of establishing a test system for testing a device under test.

A test assembly for testing an antenna-in-package (AiP) device includes a socket over a circuit board, where the socket includes an opening for receiving the AiP device; a plunger configured to move along sidewalls of the opening, where during testing of the AiP device, the plunger is configured to cause the AiP device to be pressed towards the circuit board such that the AiP device is operatively coupled to the circuit board via input/output connections of the AiP device and of the circuit board; and a loadboard disposed within the socket and between the plunger and the AiP device, where the loadboard includes a coupling structure configured to be electromagnetically coupled to a transmit antenna and to a receive antenna of the AiP device, so that testing signals transmitted by the transmit antenna are conveyed to the receive antenna externally relative to the AiP device through the coupling structure.

An inspection device (10) includes a fixing portion (200) fixing a semiconductor device (500) being a DUT and an antenna portion (30) inspecting the semiconductor device (500). The fixing portion (200) defines a hole (210) exposing at least a portion of the semiconductor device (500). At least a portion of the inside surface of the hole (210) in the fixing portion (200) includes a step portion.

The present disclosure provides an over-the-air measurement system for testing a device under test. The over-the-air measurement system includes a single measurement antenna and a rotary antenna positioner for the measurement antenna. The over-the-air measurement system further comprises a hardware trigger that is capable of triggering a measurement. The hardware trigger is associated with the rotary antenna positioner. The over-the-air measurement system comprises at least one rotary joint attached to the antenna positioner.

The present disclosure provides an over-the-air measurement system for testing a device under test. The over-the-air measurement system includes a single measurement antenna and a rotary antenna positioner for the measurement antenna. The over-the-air measurement system further comprises a hardware trigger that is capable of triggering a measurement. The hardware trigger is associated with the rotary antenna positioner. The over-the-air measurement system comprises at least one rotary joint attached to the antenna positioner.