Abstract: A method of calibrating a setup comprises: performing at least one calibration of the setup, thereby obtaining calibration data; setting a quantity representing forward tracking to be equal with a quantity representing reverse tracking; solving a system of equations having at least an unknown quantity representing the forward tracking or the reverse tracking, thereby obtaining at least one equation having the unknown quantity squared; creating based on the calibration data obtained two phase over frequency relationships for the respective quantity; determining two lines having a linear change in phase over frequency for the phase over frequency relationships created; extrapolating the lines determined to a frequency of 0 Hz; and determining the respective quantity by selecting one line of the lines extrapolated that is closer to a phase of zero, 2? or a multiple thereof at the frequency of 0 Hz.

Abstract: A method of absolute phase calibration of at least a first port of a test and measurement equipment, comprising: providing the test and measurement equipment having the first port to be calibrated; providing a calibration mixer having a first port, a second port and a local oscillator port; providing at least one phase reproducible source that outputs a local oscillator signal; and performing at least two UOSM measurements at the first port of the test and measurement equipment, wherein at least one of the at least two UOSM measurements is performed with a frequency shift from a first frequency to a second frequency by using the calibration mixer. Furthermore, a calibration system is described.

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 calibrating a setup comprises: performing at least one calibration of the setup, thereby obtaining calibration data; setting a quantity representing forward tracking to be equal with a quantity representing reverse tracking; solving a system of equations having at least an unknown quantity representing the forward tracking or the reverse tracking, thereby obtaining at least one equation having the unknown quantity squared; creating based on the calibration data obtained two phase over frequency relationships for the respective quantity; determining two lines having a linear change in phase over frequency for the phase over frequency relationships created; extrapolating the lines determined to a frequency of 0 Hz; and determining the respective quantity by selecting one line of the lines extrapolated that is closer to a phase of zero, 2? or a multiple thereof at the frequency of 0 Hz.

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 calibrating a measurement and analyzing device for measuring a frequency-converting device under test, comprises the steps of connecting a first port of the measurement and analyzing device with a radio frequency port assigned to the frequency-converting device under test as well as connecting a second port of the measurement and analyzing device with an intermediate frequency port assigned to the frequency-converting device under test. Further, a scalar-mixer calibration is performed at the radio frequency port and the intermediate frequency port, thus providing a precise calibration conversion amplitude. A relative calibration is performed between the radio frequency port and the intermediate frequency port by using a calibration mixer. At least one correction coefficient is determined by the difference between the results obtained from the scalar-mixer calibration and the relative calibration. The at least one correction coefficient is used to correct an error term applied.

Abstract: A method of absolute phase calibration of at least a first port of a test and measurement equipment, comprising: providing the test and measurement equipment having the first port to be calibrated; providing a calibration mixer having a first port, a second port and a local oscillator port; providing at least one phase reproducible source that outputs a local oscillator signal; and performing at least two UOSM measurements at the first port of the test and measurement equipment, wherein at least one of the at least two UOSM measurements is performed with a frequency shift from a first frequency to a second frequency by using the calibration mixer. Furthermore, a calibration system is described.

Abstract: A measurement method and a measurement device for performing a measurement with respect to a frequency-converting device under test and compensating for a shifting frequency are provided. The measurement method comprises the steps of applying an input signal to an input of the device under test, receiving an output signal from an output of the device under test, converting the output signal into a digitized signal comprising digital samples, estimating a received frequency with respect to the output signal on the basis of the digital samples, and comparing the received frequency to an expected frequency.

Abstract: A method of calibrating a measurement and analyzing device for measuring a frequency-converting device under test, comprises the steps of connecting a first port of the measurement and analyzing device with a radio frequency port assigned to the frequency-converting device under test as well as connecting a second port of the measurement and analyzing device with an intermediate frequency port assigned to the frequency-converting device under test. Further, a scalar-mixer calibration is performed at the radio frequency port and the intermediate frequency port, thus providing a precise calibration conversion amplitude. A relative calibration is performed between the radio frequency port and the intermediate frequency port by using a calibration mixer. At least one correction coefficient is determined by the difference between the results obtained from the scalar-mixer calibration and the relative calibration. The at least one correction coefficient is used to correct an error term applied.

Abstract: A signal source is described. The signal source comprises a signal generator, a first frequency divider and a second frequency divider. The first and the second frequency divider are each connected to the signal generator. The signal generator is configured to generate a source signal having a source frequency and to selectively forward the source signal to at least one of the first frequency divider and the second frequency divider. The first frequency divider is established as an integer frequency divider and is configured to generate a first output signal from the source signal. The second frequency divider is different from the first frequency divider and is configured to generate a second output signal from the source signal, wherein a phase noise of the second output signal is considerably lower than a phase noise of the first output signal. Moreover, a test system and a method for testing a device under test are described.

Abstract: A method of measuring the AM/PM conversion of a device under test having a local oscillator is described. A device under test with an embedded local oscillator is provided. A signal source is connected to an input of the device under test. A receiver is connected to an output of the device under test. An input signal is provided by the signal source. The input signal has an initial power level. The input signal is input to the device under test. The power level of the input signal is changed. An output signal of the device under test is measured at different power levels of the input signal.

Abstract: A measurement method and a measurement device for performing a measurement with respect to a frequency-converting device under test and compensating for a shifting frequency are provided. The measurement method comprises the steps of applying an input signal to an input of the device under test, receiving an output signal from an output of the device under test, converting the output signal into a digitized signal comprising digital samples, estimating a received frequency with respect to the output signal on the basis of the digital samples, and comparing the received frequency to an expected frequency.

Abstract: A signal source is described. The signal source comprises a signal generator, a first frequency divider and a second frequency divider. The first and the second frequency divider are each connected to the signal generator. The signal generator is configured to generate a source signal having a source frequency and to selectively forward the source signal to at least one of the first frequency divider and the second frequency divider. The first frequency divider is established as an integer frequency divider and is configured to generate a first output signal from the source signal. The second frequency divider is different from the first frequency divider and is configured to generate a second output signal from the source signal, wherein a phase noise of the second output signal is considerably lower than a phase noise of the first output signal. Moreover, a test system and a method for testing a device under test are described.

Abstract: A method of measuring the AM/PM conversion of a device under test having a local oscillator is described. A device under test with an embedded local oscillator is provided. A signal source is connected to an input of the device under test. A receiver is connected to an output of the device under test. An input signal is provided by the signal source. The input signal has an initial power level. The input signal is input to the device under test. The power level of the input signal is changed. An output signal of the device under test is measured at different power levels of the input signal.