Abstract: A measurement instrument identification system is described for identifying one measurement instrument, wherein the identification system includes a sensor unit, a receiving unit for receiving a signal assigned to the measurement instrument, a processing unit, and an augmented reality unit for displaying at least a representative and/or a symbol assigned to the measurement instrument. The processing unit is further configured to select the one measurement instrument out of the plurality of measurement instruments based on the received signal assigned to the at least one measurement instrument and the signal received from the sensor unit. The processing unit is further configured to control the augmented reality unit to display a representative and/or a symbol assigned to the measurement instrument. Further, a method for finding a particular measurement instrument is described.

Abstract: A measurement system comprising a measurement device and at least a first probe unit and a second probe unit is disclosed. The first probe unit and the second probe unit are each connected to the measurement device in a signal transmitting manner. At least one of the measurement device and the first probe unit comprises a control unit. The first probe unit comprises an interface module being configured to generate an input data signal and to provide the input data signal to the control unit. The control unit is configured to generate and provide a control signal at least to the second probe unit based on the input data signal. Moreover, a method for operating a measurement system is disclosed.

Abstract: A system for calibrating a multi-channel radio frequency signal generation system is described. At least two signal sources and a calibration unit are provided. A calibration data module is provided that is assigned to at least one of the signal sources. The at least two signal sources are assigned to at least two signal channels. In a first operation mode, the calibration unit is connected with the at least two signal channels simultaneously. The calibration unit is configured to gather calibration data assigned to the at least two signal channels. The system is configured to transfer the calibration data gathered from the calibration unit to the calibration data module. In a second operation mode, the system is configured to disconnect the at least two signal channels from the calibration unit and to connect the at least two signal channels with a device under test. Further, a method of calibrating a multi-channel radio signal generation frequency system is described.

Abstract: A method for performing a Bode measurement on a device under test having a specified working input range and a specified working output range using a measurement system comprising: receiving at least one input boundary parameter of the working input range and at least one output boundary parameter of the output working range; generating a first stimulus signal using a stimulus signal generator of the measurement system based on the at least one input boundary parameter; feeding the first stimulus signal to an input of the device under test; and measuring an output signal of the device under test using a measurement unit of the measurement system in a measurement range based on the at least one output boundary parameter obtaining a measurement result. Further, a measurement setup is shown.

Abstract: A transmitter module for a broadband data transmission system for radio communications, comprising at least one polyphase FFT filter bank is described. The at least one polyphase FFT filter bank is established as a synthesis polyphase FFT filter bank, wherein the at least one polyphase FFT filter bank comprises several filter units, wherein the transmitter module is configured to receive an input signal comprising a symbol sequence, and wherein the transmitter module is configured to transmit a signal based on the received input signal. Moreover, a receiver module for a broadband data transmission system and a data transmission system are described.

Abstract: A performance testing method for determining a performance of a device under test having non-linear characteristics is disclosed. The performance testing method comprises the following steps: generating a hard clipper model of said device under test; generating a test signal having predefined properties; forwarding said test signal to the device under test, wherein the device under test generates an output signal based on said test signal; feeding said hard clipper model with said test signal, thereby generating a model output signal; and comparing said output signal to said model output signal in order to determine the performance of the device under test. Moreover, a measurement system for determining a performance of a device under test having non-linear characteristics is disclosed.

Abstract: A jitter determination method for determining at least one jitter component of an input signal is described. The input signal is generated by a signal source, including: receiving the input signal; determining a step response based on the decoded input signal, the step response being associated with at least the signal source; and determining the at least one jitter component of the input signal based on at least one of the input signal and the determined step response. Further, a measurement instrument is described.

Abstract: A method for at least one of identifying and compensating for system errors in a measurement system is disclosed, wherein the measurement system comprises a signal generator and a signal analyzer. The method comprises: generating a test signal via the signal generator, the test signal having predetermined properties; forwarding the test signal to a device under test; processing the test signal via the device under test, thereby generating a transmission signal; receiving the transmission signal via the signal analyzer; determining a response function of the device under test based on the test signal and based on the transmission signal; and determining at least one periodic component of the response function. Further, a measurement system as well as a calibration system are disclosed.

Abstract: A signal analysis method is described. The signal analysis method comprises: receiving an N-ary input signal, the input signal comprising a symbol sequence; determining at least two threshold transition times of the input signal within a predetermined time period, wherein the input signal respectively crosses an amplitude threshold of several predetermined amplitude thresholds at each of the threshold transition times; determining time intervals between the threshold transition times; evaluating the time intervals based on a set of predefined conditions; and assigning the threshold transition times to at least one symbol transition based on the evaluation. Further, a signal analysis module is described.

Abstract: The present disclosure relates to a method of analyzing a pulse modulated signal, wherein the method comprises: receiving a pulse modulated signal; determining a dynamic threshold level based on a period of the pulse modulated signal and the pulse modulated signal; and demodulating the pulse modulated signal by the dynamic threshold level. Moreover, a signal analysis instrument for analyzing a pulse modulated signal is described.

Abstract: A digital-to-analog conversion device and a digital-to-analog conversion system with multiple digital-to-analog conversion cores is provided. At least some of the multiple digital-to-analog conversion cores may be operated with different clock signals, especially with clock signals of different clock frequencies. For this purpose, each digital-to-analog conversion stage is provided with multiple different clock signals and each stage individually selects one of the multiple clock signals.

Abstract: An apparatus for identifying network devices comprises a data acquisition unit that receives data from a multiplicity of network devices. It also comprises an interpretation unit that extracts identification data from the data and determines which of the multiplicity of network devices has sent the received data. A similarity of measured data of a physical clock to a predefined pattern and/or to previously measured data of the physical clock is analysed as a first criterion of an association of received data. In addition, at least one further criterion of an association of received data can be analysed among the identification data.

Abstract: A device for converting a digital input signal into an analog output signal is provided. The device includes a first digital to analog converter configured to generate a first analog signal, and a second digital to analog converter configured to generate a second analog signal. The device further includes a signal splitter configured to couple out a feedback signal from the second analog signal. The device further includes a first signal combiner configured to subtract the feedback signal from the first analog signal to generate an error signal. The device further includes an amplifier configured to amplify the error signal, resulting in an amplified error signal. The device further includes a second signal combiner configured to combine the amplified error signal and a signal derived from the second analog signal, resulting in the analog output signal.

Abstract: A vehicle black box for implementation in a vehicle is described. The vehicle black box includes a sensor interface for receiving sensor data of a sensor module sensing at least one physical vehicle parameter. Further, the vehicle black box includes a wireless module for receiving a radio frequency signal, wherein the wireless module generates IQ data based on the radio frequency signal received. The vehicle black box also includes a recording module with a first memory for temporarily storing the IQ data generated and a second memory for permanently storing the IQ data generated. Moreover, the vehicle black box has a processing unit configured to receive and evaluate the sensor data, wherein the processing unit is further configured to control a transfer of the IQ data from the first memory to the second memory based upon the evaluation result. A vehicle and a method of gathering data associated with at least one physical vehicle parameter are also described.

Abstract: An error rate test method is disclosed. The error rate test method comprises the following steps. At least one test signal with a predetermined frequency is received from at least one device under test. A symbol sequence comprised in the at least one test signal is determined. At least one error quantity being associated with the at least one device under test and the at least one test signal is determined based on the determined symbol sequence, wherein the at least one error quantity determined is indicative of a rate of erroneous symbols comprised in the symbol sequence. Respective error quantities are determined simultaneously for at least one of multiple devices under test and for multiple different predetermined frequencies. Further, a test system for testing a device under test is disclosed.

Abstract: A method of measuring a total radiated power of a device under test by a test system is described. The test system has a measurement antenna, a positioning system and a control and/or measurement equipment, wherein the device under test is positioned on the positioning system. The method includes: moving the device under test with respect to an azimuth axis and an elevation axis by the positioning system; transmitting a time dependent signal by the device under test; and recording a correlation between the control and/or measurement equipment and a respective spherical position of the positioning system. Furthermore, a test system for measuring a total radiated power of a device under test is described.

Abstract: A broadband transition coupling for transition between a waveguide and a printed circuit board with a substrate integrated waveguide is disclosed. The broadband transition coupling comprises a main body that encompasses an air-filled waveguide section and a transition section. The air-filled waveguide section comprises a first interface for the waveguide. The transition section provides a second interface for the printed circuit board. The transition section continuously tapers along the second interface in order to reduce a height of the transition section for transition coupling with the printed circuit board. Further, the present disclosure relates to a broadband system for processing electromagnetic signals.

Abstract: A method of setting an analyzer, the method comprising: providing an analyzer with a first signal source and a second signal source; connecting the signal sources with a device under test; generating a first signal, transmitting the first signal to the device under test, measuring the first transmitted signal and a first signal reflected from the device under test, thereby obtaining first compensation parameters; generating a second signal, transmitting the second signal to the device under test, measuring the second transmitted signal and a second signal reflected from the device under test, thereby obtaining second compensation parameters; using the first and second compensation parameters to compensate the signal sources; and transmitting the first and second signals simultaneously.

Abstract: A method of measuring a total radiated power of a device under test by a test system with a base station simulator, a measurement antenna assigned to the base station simulator and a control and/or measurement equipment is described. The method includes: establishing a radio resource control connection between the device under test and the base station simulator via the measurement antenna; activating an uplink-beam lock function at the device under test; and performing a total radiated power measurement by the control and/or measurement equipment while continuously sending a downlink signal from the base station simulator via the measurement antenna to the device under test. A test system is further described.

Abstract: A method of timeslot-wise detection of at least one radio signal in a cellular radio network. A radio signal is received via at least one first radio antenna and at least one second radio antenna. The radio signal received by the respective radio antennas is forwarded to at least one first radio receiver assigned to the first radio antenna and to at least one second radio receiver assigned to the second radio antenna. The radio signal forwarded is evaluated. The radio receivers are synchronized with a preconfigured frame structure. At least one identical time slot is selected out of the frame structure Timing information of the selected time slot is provided from the first radio receiver to the second radio receiver, from the second radio receiver to the first radio receiver and/or from the respective radio receiver to a central unit for calculating a time difference of arrival. Further, a device for timeslot-wise detection is described.