Abstract: A system for measuring residual phase noise of a device under test (DUT) includes first and second signal sources, first and second receivers, and a processor. The first signal source generates a first signal to be input to the DUT as a stimulus signal and provides a second signal that is phase coherent with the first signal. The second signal source receives the second signal and generates a reference signal based on the second signal, which is phase coherent with the stimulus signal. The first receiver measures an output signal from the DUT responsive to the stimulus signal, and the second receiver measures the reference signal from the second signal source. The processor mathematically suppresses a carrier of the output signal by determining a difference between the measured output signal and the measured reference signal, and determines the residual phase noise of the DUT based on the difference.

Abstract: A network analyzer comprises: a signal source configured to supply an input signal to a device, wherein the device is configured to generate a phase reference signal; a receiver configured to receive the phase reference signal from the device and to measure a phase response of the device according to the phase reference signal; and a calibration component configured to compare the measured phase response of the device with an actual phase response of the device to identify a tracking parameter for the receiver.

Abstract: A system and method for determining the linearity of a device-under-test combine a first periodic signal and a second periodic signal to produce a combined signal, wherein the second periodic signal has at least one of a phase difference and a frequency difference with respect to the first periodic signal, and applying the combined signal to an input of the device-under-test. The linearity of the device-under-test is determined from an output signal of the device-under-test based on the at least one of the phase difference and frequency difference between the first periodic signal and the second periodic signal.

Abstract: A method is presented where the phase trace is offset for each sweep such that the first point is always at zero degrees. The resulting traces are then averaged. The average reduces the noise in the phase trace and results in a less noisy group delay trace.

Abstract: A measurement and correction method provides for a complete full correction of a true-mode system using only the single ended error matrix developed for 4 port correction of single ended measurements. The degree of misalignment of the balanced sources may be determined from these measurements.

Abstract: A test system and methods using the test system correlate measurements of a device under test (DUT) regardless of which test fixture is used for in-fixture testing of the DUT. The test system includes test equipment, a test fixture that interfaces the DUT to the test equipment, a computer and a computer program executed by the computer. The computer program includes instructions that implement determining a port-specific difference array for test fixtures used with the test system. The difference array describes a difference between the test fixtures at a corresponding test port thereof. The method includes determining the difference array, measuring a performance of the DUT in a second test fixture, and applying the difference array such that the measured performance approximates a hypothetical DUT performance for the DUT as if mounted in a first test fixture.

Abstract: A method is presented where the phase trace is offset for each sweep such that the first point is always at zero degrees. The resulting traces are then averaged. The average reduces the noise in the phase trace and results in a less noisy group delay trace.

Abstract: A measurement and correction method provides for a complete full correction of a true-mode system using only the single ended error matrix developed for 4 port correction of single ended measurements. The degree of misalignment of the balanced sources may be determined from these measurements.

Abstract: A method for extending dynamic range and a test system with extended dynamic range compensate for a compression effect on measured data caused by a receiver channel of the test system being compressed. The measured data is magnitude and phase data for one of a device under test and a signal under test that is measured using the test system. The method comprises characterizing a first channel of the test system for first channel compression responses to magnitude and phase, characterizing a second channel of the test system for second channel compression response to magnitude and phase, and compensating to correct for the effect of compression on the measured data. The test system comprises a receiver channel, and a computer program stored in memory that implements the method. Test systems with a plurality of receiver channels may be characterized in pairs.

Abstract: A method and a measurement system determine a transmission response of a device under test (DUT). The method includes measuring a reflection response from a first port of the DUT while a known reflective termination is on a second port of the DUT, and time gating the measured reflection response to produce a gated reflection response that is the transmission response of the DUT. The measurement system includes a vector network analyzer, a controller, a memory and a computer program. The computer program includes instructions that implement measuring the reflection response from the first port of the DUT, and further implement time gating the measured reflection response. The time gating isolates reflection data associated with the known reflective termination from the measured reflection response.

Abstract: In one embodiment, a vector network analyzer (VNA) comprises a plurality of ports for coupling to a device under test (DUT), at least one reference receiver for measuring signals associated with the DUT, and logic for processing measurement data from the at least one reference receiver to compensate for transmission line effects, wherein the logic for processing evaluates a function, of several controllable variables, that is a sum of multiple transmission line models, wherein each of the controllable variables is related to a respective transmission line length associated with a corresponding transmission line model.

Abstract: The power differential between balanced signals is measured and the resultant level is used to control the phase between the signals. In one embodiment, I and Q inputs to vector modulator is adjusted to control the phase.

Abstract: The occurrence of spurs when analyzing signals is reduced. A first signal is mixed with a local oscillator signal to produce an intermediate signal. When a spur is predicted to occur when high side mixing is performed, low side mixing is performed. When a spur is predicted to occur when low side mixing is performed, high side mixing is performed.

Abstract: The power differential between balanced signals is measured and the resultant level is used to control the phase between the signals. In one embodiment, I and Q inputs to vector modulator is adjusted to control the phase.

Abstract: Differential (balanced) drive signals are created where at least one of the drive signals can be controlled in phase relative to the other, and both of which could be controlled in amplitude. In one embodiment, a coherent signal is generated in a first electronic signal generator (ESG) and applied to a second ESG. The coherent signal replaces the normal input signal of the second ESG and the I and Q inputs of the second ESG controls the amplitude and phase of the output signal. This output signal, when combined with the output signal of the first ESG is a differentially balanced signal having both amplitude and phase control.

Abstract: Modulated differential (balanced) drive signals are created where, at least one of the signals can be controlled in phase relative to the other, and both of which could be controlled in amplitude and both of which have the same modulation envelope. In one embodiment, a coherent signal is generated in a first electronic signal generator (ESG) and applied to a second ESG. The coherent signal replaces the normal input signal of the second ESG and the I and Q inputs of the second ESG control the amplitude and phase of the output signal. This output signal is applied to a third ESG replacing the normal input signal to the vector modulator.

Abstract: The present invention tunes a coupled resonator filter to a given tuning specification using a reference filter that was previously tuned to the specification. A method of tuning a subject filter comprises determining a frequency change for each resonator of the subject filter and applying each determined change to the respective resonator, such that the subject filter is tuned to the specification. The frequency changes are determined from frequency-pushing interactions between combinations of resonators in either the reference or subject filter. A system for tuning the subject filter comprises a measurement system, a tuning program stored in a system memory, and a controller that controls the measurement system and executes the tuning program. The tuning program comprises instructions that preferably implement the tuning method. A tuned coupled resonator filter comprises a plurality of resonators that are adjusted in accordance with the method or using the tuning system.

Abstract: In a method for characterizing frequency translation devices (FTDs), a stimulus signal is applied to a first port of a frequency translation device and a drive signal is applied to a second port of the frequency translation device. A third port of the frequency translation device is coupled to an input of a filter. The frequency translation device, at the third port, provides a translated signal having a sum signal component and a difference signal component. A first, second and third reflection response to the applied stimulus signal are obtained with alternative terminations coupled to an output of the filter. The reflection responses include variations in either the sum signal component or the difference signal component as designated by the filter, where the variations depend on which of the alternative terminations is coupled to the output of the filter.

Abstract: A method for extending dynamic range and a test system with extended dynamic range compensate for a compression effect on measured data caused by a receiver channel of the test system being compressed. The measured data is magnitude and phase data for one of a device under test and a signal under test that is measured using the test system. The method comprises characterizing a first channel of the test system for first channel compression responses to magnitude and phase, characterizing a second channel of the test system for second channel compression response to magnitude and phase, and compensating to correct for the effect of compression on the measured data. The test system comprises a receiver channel, and a computer program stored in memory that implements the method. Test systems with a plurality of receiver channels may be characterized in pairs.

Abstract: A vector stimulus/response system enables the vector responses of frequency translation devices (FTDs) to be accurately characterized. The system includes a source, having a predetermined source match, reflection tracking and directivity, that generates a stimulus signal. A receiver having a predetermined load match is also included in the system. The receiver measures a first series of responses of a reference translator to the stimulus signal, when the reference translator is coupled between the source and receiver. The reference translator has predetermined transmission characteristics, input match and output match. The receiver measures a second series of responses of a FTD to the stimulus signal. A processor generates a correction array from the first series of responses, the predetermined transmission characteristics, input match output match, source match, and the directivity, reflection tracking and load match.