A fixture and a measurement system are provided. The fixture is adapted for electrically connecting a measurement device with a device under test, DUT, in particular a wireless DUT, and for mechanically holding the DUT. The fixture comprises a clamp for clamping the DUT; a male plug for engaging a mating socket of the DUT; and an electrical cable connected to the plug on one end and connectable with the measurement device at its other end. The fixture is arranged to mechanically hold the DUT such that the DUT can be rotated relative to the measurement device. The fixture reduces a shielding effect in respect of antenna modules of the DUT.

An electronic device may include a shaft insertable into a target area, and an electronic component configured to generate a signal. The electronic component may be on or within the shaft. The electronic device may also include at least one antenna on or within the shaft. The electronic device may also include a receiver operatively coupled to the antenna. The receiver may monitor an electrical characteristic of the antenna to identify an effect of an electromagnetic field on the electrical characteristic of the antenna. The electronic device may also include a processor communicatively coupled to the receiver. At least one of the receiver and the processor may predict an effect of the electromagnetic field on the signal generated by the electronic component, based at least in part on the effect of the electromagnetic field on the electrical characteristic of the antenna.

Disclosed is an apparatus for testing a device, comprising: a switch (100) arranged to replace a circuit breaker (30) associated with an individual system in the device under test, wherein the switch (100) is operable to be controlled remotely from the device under test such that the switch (100) either activates or deactivates the individual system.

The present disclosure relates to a shield box for testing a mobile telecommunication terminal in which an increase in temperature in a shield box is prevented in performing various tests on a mobile telecommunication terminal having multiple antennas in an Over The Air (OTA) method to perform a stable test.

The shield box for testing a communication terminal of the present disclosure includes a shield box main body made of metal, having a jig entrance formed on the front side, and equipped with a vent which a plurality of vent holes of 1 to 10 mm in size are formed on the upper and rear sides, respectively; a test jig assembly installed to be able to enter and exit through the jig entrance while mounting a PCB for non-contact wireless connection in which a plurality of non-contact wireless connection parts that are wirelessly connected to a mobile telecommunication terminal and transmit and receive signals are arranged; and a ventilation fan mounted on the upper vent or the rear vent.

A measurement system for testing a device under test is described, with at least two antennas, at least two reflectors, a signal generation and/or analysis equipment and a test location. Each of the antennas is assigned to a corresponding reflector. Each of the antennas is configured to transmit/receive an electromagnetic signal so that a beam path is provided between the respective antenna and the test location. The electromagnetic signal is reflected by the respective reflector so that the electromagnetic signal corresponds to a planar wave. The beam paths have different angular orientations that are adjustable. At least one antenna and the corresponding reflector are coupled with each other so that an integrated beam path adjustment unit is established including at least one antenna and the corresponding reflector. Further, a testing method is described.

A system for calibrating radio frequency test chambers is provided. The system comprises an antenna array with a plurality of antenna elements arranged in a three dimensional configuration, a plurality of power measuring units downstream to the plurality of antenna elements and a processing unit. In this context, the plurality of power measuring units output a power from each antenna elements corresponds to a radiation pattern generated by an incident test signal. The processing unit is configured to analyze the power distribution of the test signal in order to calculate a calibration.

A measurement system utilizing metasurfaces and compressive sensing is provided that measures specular and diffuse RF reflection properties of a sample omnidirectionally across a broad frequency regime in a monostatic, bistatic, or BRDF sense. The measurement system may be used to measure the full hemispherical (or spherical) reflection from a target that has been illuminated in a monostatic or bistatic case. The measurement system may also be used to measure the full BRDF of a sample or spatially complex bistatic reflections from a sample.

A measuring device 1 includes a DUT scanning mechanism 56 that is provided in the OTA chamber 50, includes a biaxial positioner which can be rotationally driven by drive motors 56f and 56g, and rotates a DUT 100 to sequentially face all preset directions of a spherical coordinate system; an integrated control device 10 that measures the DUT 100 at each measurement position corresponding to each of the all directions; and a rotation speed management control unit 18b that controls a rotation speed of the drive motors 56f and 56g at a rotation speed which shortens a time required for the movement in a case where the biaxial positioner is moved at a unit step angle from a measurement position where the measurement is completed to a measurement position where next measurement is performed during the DUT 100 is measured.

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.

A system for characterizing a quiet zone of an over-the-air testing space includes at least one measurement antenna and at least one scattering member. The measurement antenna is configured to at least transmit electromagnetic signals. The scattering member includes predefined scattering properties. The scattering member is enabled to scatter the electromagnetic signals so as to generate scattered electromagnetic signals that are transmitted in a defined manner. Further, a method of characterizing a quiet zone of an over-the-air testing space is described.