Other topics about Calibration
It is important to understand the factors contributing to measurement errors in order to determine the appropriate measures that should be taken to improve accuracy. Measurement errors are classified into three categories:
Drift errors are caused by deviations in the performance of the measuring instrument (measurement system) that occur after calibration. Major causes are the thermal expansion of connecting cables and thermal drift of the frequency converter within the measuring instrument. These errors may be reduced by carrying out frequent calibrations as the ambient temperature changes or by maintaining a stable ambient temperature during the course of a measurement.
Random errors occur irregularly in the course of using the instrument. Since random errors are unpredictable, they cannot be eliminated by calibration. These errors are further classified into the following sub-categories depending on their causes:
Instrument noise errors
Switch repeatability errors
Connector repeatability errors
Instrument noise errors are caused by electric fluctuations within components used in the measuring instrument. These errors may be reduced by increasing the power of the signal supplied to the DUT, narrowing the IF bandwidth, or enabling sweep averaging.
Switch repeatability errors occur due to the fact that the electrical characteristics of the mechanical RF switch used in the measuring instrument change every time it is switched on. These errors may be reduced by carrying out measurements under conditions in which no switching operation takes place.
Connector repeatability errors are caused by fluctuations in the electrical characteristics of connectors due to wear. These errors may be reduced by handling connectors with care.
Systematic errors are caused by imperfections in the measuring instrument and the test setup (cables, connectors, fixtures, etc.). Assuming that these errors are repeatable (i.e., predictable) and their characteristics do not change over time, it is possible to eliminate them mathematically at the time of measurement by determining the characteristics of these errors through calibration. There are six types of systematic errors, as follows.
Errors caused by signal leaks in the measuring system:
Directivity
Isolation (cross-talk)
Errors caused by reflections in the measuring system:
Source match
Load match
Errors caused by the frequency response of the receiver within the measuring instrument:
Reflection tracking
Transmission tracking
The E5061B has two receivers for each S-parameter test port: the reference receiver and the test receiver (transmission measurement or reflection measurement). You can perform measurements with both of these receivers at the same time.
E5061B port architecture and systematic errors in S-parameter Measurement
The ports T and R are receivers and LF out supplies the source signal.
E5061B port architecture and systematic errors in Gain-Phase Measurement
Directivity errors are caused by the fact that, in a reflection measurement, signals other than the reflection signal from the DUT are received by the receiver through the directivity coupler. When a certain port is a stimulus port, this error can be defined as a constant value for each stimulus port because the state of the termination at the other ports does not change. The number of directivity errors of the E5061B is the number of stimulus ports you use.
An isolation error (crosstalk error) is caused by signals other than the transmission signal of the DUT leaking to the test receiver of the transmission measurement port in transmission measurements. When a certain port is a stimulus port, an isolation error is defined for each of the ports. Therefore, the number of isolation errors for the E5061B is the total number of combinations of stimulus ports and response ports.
A source match error is caused when the reflection signal of the DUT reflects at the signal source and enters the DUT again. When a certain port is a stimulus port, this error can be defined as a constant value for each stimulus port because the state of the signal source switch does not change. The number of source match errors in the E5061B is equivalent to the number of stimulus ports you use.
A load match error is caused when part, but not all, of the signal transmitted in the DUT reflects at a response port is measured by the receiver of the response port. When a certain port is a stimulus port, a load match error is defined for each of the ports. Therefore, the number of load match errors for the E5061B is the total number of combinations of stimulus ports and response ports.
A reflection tracking error is caused by the differences in frequency response between the test receiver and the reference receiver of a stimulus port in reflection measurements. This error can be defined as a constant value for each stimulus port because the combination of the test receiver and the reference receiver of a stimulus port is always the same. The number of reflection tracking errors for the E5061B is simply the number of stimulus ports you use.
A transmission tracking error is caused by the differences in frequency response between the test receiver of a response port and the reference receiver of a stimulus port in transmission measurements. When a certain port is a stimulus port, a transmission tracking error is defined for each of the ports. Therefore, the number of transmission tracking errors for the E5061B is the total number of combinations of stimulus ports and response ports.