While calibrations are covered in detail in another section of the measurement guide, there are some peculiarities relative to broadband and mmWave operation that require some comment.

In classical broadband mode (3738-based), a hybrid coupler combining the bands into a single W1 coaxial connector is typically used with a default breakpoint of 67 GHz (i.e., at 67 GHz and below, the base VNA is used for both source and receiver; at 67.000000001 GHz and above, the external modules are used for source and receiver). This structure is key to allowing the combined sweep. To calibrate this connector type, typically two calibrations are recommended: SOLT from the low frequency limit to 67 GHz and SSST from 67 GHz to 110 GHz. The two calibrations are performed separately and then combined using calibration merge (see calibration section for details). The only constraints are the two calibrations must be of the same type (e.g., both 1-Port S11 or both full 2-Port) and the total point count must not exceed the current maximum for the instrument (25000 or 100000). Note that other calibration types (e.g., LRL) can be successfully combined with this connector type.

In the 3739-based systems, a similar protocol is used with a 67 GHz breakpoint also typically used for ME7838A/AX and ME7838E/EX (and related) systems (W1 connector-based). For the ME7838D and related systems (using the MA25300A modules) which are 0.8 mm-connector based, a breakpoint for the calibrations of 80 GHz is typically used. In all cases, it is generally a SOLT calibration at the lower frequencies and an SSST calibration at higher frequencies. For the ME7838G and related systems, a coaxial-mode flange-based interface is used for direct connection to wafer probes so the same merged calibrations are used less often (and an on-wafer LRM calibration, for example, is broadband inherently). Adapters from the MA25400A module’s native interface to a 0.8 connector are available and calibrations as discussed above using the 0.8 calibration kit are possible. Adapters to WR-5 waveguide are also available and traditional waveguide calibrations covering, for example, 140-220 GHz are possible in that case.

The 1mm (W1) and 0.8 mm calibration kits both contain 3 shorts, an open, and a load for both connector genders (along with many adapters, tools and verification components). For the SOLT calibration, the coefficients are setup assuming that SHORT 1 is used for that calibration.

In some software versions (including and after V2017.06.01), a calibration method termed ‘broadband cal’ is available for ME7838X systems that allows one to perform the SOLT/R and SSST/R calibrations in one session without using the merge. This broadband calibration saves some connections and a number of keystrokes. Also, since the thru/reciprocal is only connected once, some steps in error coefficients at the breakpoint frequency due to connector repeatability can be reduced. Note that since different algorithms are used above and below the breakpoint, some small steps in data are to be expected (within the uncertainties of each calibration).

As shown in the modify setup dialog below, the concept of the breakpoint frequency is still relevant and one can use the 67 GHz or the 80 GHz (for the 0.8 mm calibration kit and ME7838D) default values or one can enter different numbers. If the current frequency range is either entirely above or below the entered breakpoint, only one of the calibration types will be used but all standards will still need to be connected. Note that the published uncertainty curves only apply if the default breakpoint frequencies are used. Note that options are available on the 3656B/C calibration kits to have .s1p definitions of the standards (in addition to the traditional .ccf files which define the components by means of frequency-dependent circuit models). These .s1p-based calibrations can offer improved uncertainties, particularly for reflection measurements (and all measurements for reciprocal-based calibrations). Lower frequency cal kits (e.g., 3652 and 3654 series) also offer this option.

Note that this calibration method choice will only be available if the system is in an appropriate 3739 mode. The reciprocal choice is available as it is for the base open-short-load and triple-offset-short calibrations but the same reciprocal (or thru) will be used for the entire sweep. If it is desired to use different thrus/reciprocal elements, then the traditional merge method described above should be employed. During the calibration, the open, the load, three shorts and the thru/reciprocal must be measured. Short 1 and the thru/reciprocal data will be used for both upper and lower calibrations. As with the regular versions of these calibrations, losses in the opens and shorts can be defined. See SOLT/SOLR Calibration for more information on these entries, but the loss is entered in terms of dB/mm at a specific reference frequency (fref). Losses at other frequencies are found by scaling as the square root (sqrt(f/fref)). If 0 is entered for the reference frequency, the loss is assumed to be constant with frequency.

As discussed above, the ME7838G and related systems (using the MA25400A module) do not general use this same type of broadband calibration since those systems are almost exclusively used on-wafer with inherently broadband calibrations. Adapters to 0.8 mm can be used with the MA25400A modules and a broadband calibration in 0.8 mm can be performed to 145 GHz.

In the modular BB approach, the multiplexing is instead done behind the high frequency reflectometers and happens at two disjoint frequencies instead of at a common breakpoint. This typically does not affect the calibration break frequency as the latter is more determined by the characteristics of the calibration kit. Thus when using Anritsu’s 3656x W1 calibration kit, the same 67 GHz breakpoint is commonly used for both the classical and modular broadband systems.

Some additional comments related to use of the modular BB system: