The present invention relates to an interface device for connecting a vector network analyser to a device under test (DUT), and in a further aspect to a system for executing measurements on a device under test comprising a vector network analyser, and at least one DUT interface device according to an embodiment of the present invention. Furthermore, the present invention relates to a method for using such a system.
In the article by G. Vlachogiannakis et al., “An I/Q-Mixer-Steering Interferometric Technique for High-Sensitivity Measurement of Extreme Impedances”, International Microwave Symposium, May 2015, a vectorial signal cancellation technique based on IQ phase steering is disclosed for measurements on a device under test using a vector network analyser (VNA). The disclosed system uses a splitter on the path of the a1 signal, internally to the VNA. This implementation results in the fact that the signal driving the LO of the IQ mixer and the signal driving the DUT, propagate on different transmission lines, i.e., cables. This makes this setup very sensitive to relative phase fluctuation between the two signals, hampering the cancellation condition. Moreover, to feed back the signal inside the VNA after the splitter, allows to realize signal cancellation only for a subset of VNA's, namely the ones providing front jumpers. In the implementation disclosed in this article no synchronization between the VNA source and the DAC controlling the injection vector was realized, making frequency sweep slow since it is performed one frequency point at the time. Also, this prior art implementation used a resistive divider to create the injection signal, this solution provides no isolation between the main line and injection path, making the cancellation condition susceptible to mismatches along the lines causing reflected signals coupling on the other signal path (i.e., from main to injection path and vice versa). Furthermore, in this prior art implementation there is no capability of decoupling the power level of the main path from the one driving the IQ mixers (of passive type in the mentioned implementation) requiring a specific LO power level. This makes this prior art solution capable to operate only at fixed power level, modifying the power requires changes on the setup by means of mechanical attenuators. Finally, this prior art implementation does not consider active amplification after the IQ mixer, thus often using the mixer in the non-optimal (linear) region, since the amplitude of the injected vector is only defined by the IQ signals.
The present invention seeks to provide improved test set-up arrangements for high frequency measurements of (active) devices (device under test, DUT), which is less susceptible to distortions and more robust during operation, especially suited for devices having a high reflection coefficient (Γ). In present measurement systems and methods, such a high Γ DUT will usually result in problems for performing accurate and repeatable measurements.
According to the present invention, a device under test (DUT) interface device is provided as described above, wherein the DUT interface device comprises an analyser terminal, a DUT terminal and a control input terminal, a divider/coupler component having a main terminal connected to the analyser terminal, a variable gain amplifier connected to a first branch terminal of the divider/coupler component, an I/Q mixer having an input terminal connected to an output terminal of the variable gain amplifier, a bridge/coupler component, of which first branch terminals are connected between a second branch terminal of the divider/coupler component and the DUT terminal for providing a test signal a to the DUT terminal, and second branch terminals are connected between an output of the I/Q mixer and a grounding impedance. This set-up allows the DUT interface device to be positioned directly adjacent the DUT, and as a result the components of the DUT interface device as well. This results in a much lower susceptibility to external distortions and hence better performance of actually testing a DUT, especially when the DUT has a high Γ coefficient.
In a further aspect, the present invention relates to a system as defined above, wherein the DUT interface device is connected to an associated measuring port of the vector network analyser. The system further comprises a control unit connected to the vector network analyser and to control input terminals of associated ones of the at least one DUT interface device, wherein the control unit is arranged to provide quadrature control signals for the associated at least one DUT interface device. The at least one DUT interface device is connected directly to the device under test DUT. In a further aspect the (DC) quadrature control signals are generated by a digital to analogue converter and can vary synchronously to the frequency of the vector network analyser through a hardware trigger loop, allowing quasi real time frequency sweeps with signal cancellation.
In an even further aspect, the present invention relates to a method for using a system according to an embodiment of the present invention, wherein the system comprises a DUT interface device connected to a first measuring port of the vector network analyser. The method comprises calibrating the system by obtaining injection signal parameters and vector calibration coefficients to allow measurements of a device under test connected to the DUT interface device. The method comprises a calibration part wherein the proper injection signals for the DUT interface devices are determined, and optionally an actual measurement step, in which the proper injection signals are used, and which make the method especially suitable for a DUT having a high Γ coefficient.
The present invention will be discussed in more detail below, with reference to the attached drawings, in which
High frequency devices are characterized by their reflection (Γ) and transmission coefficients when driven from input and/or output, often represented in the S-parameter formalism when a vector correction is applied to the measurement instrument. Characterization of the device under test (DUT exhibiting a large voltage standing wave ratio (VSWR) condition, i.e.
(1+|Γ|)/(1−|Γ|)>9,
(representing a |Γ|=0.8 and real impedances smaller than 5.5Ω and larger than 450 Ω),
result in an increased uncertainty of the measured impedance (i.e., Z), i.e., higher than two order of magnitude compared to the zero VSWR case. Thus, extreme impedances (i.e., falling under the VSWR>9 category), in respect to the system impedance (generally 50Ω), present a big challenge for high frequency characterization.
The reason for this can be easily found observing the relation between the device impedance and the instrument measured parameter, i.e., Γ vs. Z. For impedance levels between a few Ω's and a few hundredths Ω's the derivative of the reflection coefficient versus impedance (δ Γ/δZ) is high, resulting in a compression of the measured noise. When the impedance levels are shifted to the ones providing a VSWR larger than 9 the δ Γ/δZ derivate approaches zero, resulting in an expansion of the measured noise providing large uncertainty in DUT impedance value. E.g. the relative uncertainty of the measured impedance may increase more than two orders of magnitudes for impedance levels lower than 5.5Ω and higher than 450Ω. In order to provide low uncertainty measurements under high VSWR conditions, various techniques have been proposed to cancel the large reflecting wave scattered by the DUT during testing, i.e., transforming the device back to a low VSWR case. These techniques can be grouped based on the implemented method:
1) matching approaches (i.e., transforming the impedance using passive elements),
2) interferometric techniques, i.e., cancelling the reflected signal with a signal with similar amplitude and opposite phase.
Several interferometric techniques to achieve impedance renormalization of a one-port VNA are known in the art. An exemplary test set-up using a network analyser 21 is shown in the schematic view of
The large electrical distance between the injection point of the cancellation signal (at the upper directional coupler 26b) and the DUT 29 (i.e., due to cables 27 and two directional couplers 26a, 26b) makes the cancellation condition extremely sensitive to system variations (i.e., phase and amplitude due to cable 27 movements and temperature fluctuations). Moreover the use of only a variable attenuator 25 makes the cancellation condition possible only at specific frequencies i.e., frequencies at which the phase of the injected signal is opposite to the phase of the reflected signal at the plane of a3.
As mentioned above, in the article G. Vlachogiannakis, H. T. Shivamurthy, et al., “An I/Q-Mixer-Steering Interferometric Technique for High-Sensitivity Measurement of Extreme Impedances”, International Microwave Symposium, May 2015, an interferometric (cancellation) technique based on IQ phase steering is disclosed.
This implementation of the test set-up 40 results in the fact that the signal driving the LO of the IQ mixer 44 and the signal driving the DUT 49, propagate on different transmission lines, i.e., cables. This makes this setup very sensitive to relative phase fluctuation between the two signals, hampering the cancellation condition, since small variations on large vectors cause a large residual vector difference which corresponds to the b′ wave in
The present invention embodiments provide solutions to the disadvantages associated with prior art set-ups as discussed above.
In general, the present invention relates to a device under test (DUT) interface device 1 (or high gamma (HΓ)-pod) for connecting a vector network analyser 11 to a device under test 9. The DUT interface device 1 comprises an analyser terminal 2, a DUT terminal 3, and a control input terminal 8. A divider/coupler component 4 is present having a main terminal connected to the analyser terminal 2, a variable gain amplifier 5 is connected to a first branch terminal of the divider/coupler component 4, and an I/Q mixer 6 is present having an input terminal connected to an output terminal of the variable gain amplifier 5. Furthermore, a bridge/coupler component 7 is present, of which first branch terminals are connected between a second branch terminal of the divider/coupler component 4 and the DUT terminal 3 for providing a test signal a to the DUT terminal 3, and second branch terminals are connected between an output of the I/Q mixer 6 and a grounding impedance 7a. Such a DUT interface device 1 having all relevant elements for the intended purpose, allows a connection close to the DUT 9, and hence a better performance for measurements, as the relevant leads and connections are close to the DUT 9.
In a further embodiment, an additional power amplifier may be added receiving an output from the I/Q mixer 6, and providing an amplified signal to the bridge/coupler component 7. This allows to further optimize the I/Q linearity.
In an embodiment, the I/Q mixer 6 is arranged to generate an injection signal binj which is coherently combined with a reflected signal b received on the DUT terminal 3. Again, as this takes place in the DUT interface device 1 close to the DUT, it will be less likely that errors or interference occurs. More in particular, the cancellation is close to the DUT 9 thus the sensitivity of the cancellation condition, due to vibration or changes in the setup is less pronounced. In an even further embodiment, the I/Q mixer 6 (and optionally the variable gain amplifier 5) is connected to the control input terminal 8. This allows to use proper wiring to run to the DUT interface device 1, which as a result will be less susceptible to distortion or other error introducing effects. Since all the loops are incorporated near the DUT 9, the LO and RF path are coupled, thus creating phase fluctuation (which in effect are the ones leading to the errors in the interferences) coherent which do ratio out in the cancellation condition.
In an even further embodiment, the variable gain amplifier 5 comprises a plurality of variable attenuators. The presence of the variable gain amplifier 5, possibly in the form of variable or switchable attenuators, allows to independently control power between the RF signal to the DUT 9 and the local oscillator signal in the I/Q mixer 6, which allows to optimize the drive level of the I/Q mixer 6 and at the same time providing independent power control towards the DUT 9 (via the signal generated from the analyser terminal 2). In an even further embodiment this is implemented using an integrated circuit digitally controlled variable attenuator, obviating any switching parts.
A simplified schematic view of the DUT interface device 1 (HF pod) according to a present invention embodiment is shown in
In the specific embodiment shown in
As mentioned above, in a further embodiment, an additional (variable gain) amplifier is added at the output of the IQ mixer. This allows to optimize the linearity of the I/Q mixer 6, e.g. by not having the output of the I/Q mixer 6 go higher than the optimal linear range of the mixer (and using the additional amplifier to get a sufficiently high signal level. Also, it is then possible to keep the output of the I/Q mixer 6 at a sufficiently high level (not at levels comparable to DC signal noise levels (quantization noise), even if a lower level is desired at the bridge/coupler component 7 (then using an attenuation by the additional amplifier).
As shown in the system view of
Therefore, the present invention in a further aspect relates to a system for executing measurements on a device under test (DUT) 9, comprising a vector network analyser 11, at least one DUT interface device 1 (HΓ-pod) according to any one of the present invention embodiments connected to an associated measuring port of the vector network analyser 11, and a control unit 12 connected to the vector network analyser 11 and to control input terminals 8 of associated ones of the at least one DUT interface device 1 (HΓ-pod). The control unit 12 is arranged to provide quadrature control signals VI, VQ (i.e. synchronized I/Q mixer signals) for the associated at least one DUT interface device 1, wherein the at least one DUT interface device 1 is connected directly to the device under test 9. Thus, as compared to prior art systems, the loops in the measurement system are set-up differently, which improves performance. No longer is it necessary to provide a split of signals inside the vector network analyser 11. In the prior art solution the split is very far from the actual DUT loop creating several problems for the cancellation stability. Additionally, such an approach is making it very difficult to achieve two port configuration in conventional vector network analysers.
In a further embodiment, the control unit 12 comprises (high bit count) digital-to-analogue converters to provide quadrature control signals VI, VQ for each of the at least one DUT interface device 1. The vector network analyser 11 is connected to the control unit 12 using a synchronization interface for executing frequency sweeps. E.g. the synchronization interface comprises a control signal (TTL) and an acknowledgment return signal (ACK), as discussed above.
According to a further aspect of the present invention, a method is provided for using a system according to any one of the embodiments described above, wherein the system comprises a DUT interface device 1 according to any one of the embodiments described herein connected to a first measuring port of the vector network analyser 11. The method comprises calibrating the system by obtaining injection signal parameters to allow measurements of a device under test 9 connected to the DUT interface device 1. Actual measurements of a device under test (DUT) 9 can then be executed by using the obtained injection signal parameters to control the DUT interface device 1 (i.e. with injection signal on).
In accordance with further embodiments, one of three different calibration methods are provided to obtain various effects. In a first group of embodiments (labelled as method M1 in the following), measurement sensitivity at high gamma loads is improved (i.e. reduced trace noise), as shown in the flow schedule of
The three groups of calibration procedures (methods M1, M2, M3) can be applied to a one port or a two port measurement system, following the description presented below.
Calibration method embodiments are provided for the test set-up arrangement of
Both the method groups M1 and M2 may be applied for a two port DUT 9. To that end the system comprises a further DUT interface device connected to a second measuring port of the vector network analyser 11. The steps as described above are then repeated for the second measuring port of the vector network analyser (11).
connecting the further DUT interface device 1 (block 52) and then determining the second injection signal (block 60).
As shown in the flow charts of
In more generic terms, a method embodiment is provided for calibrating a system according to any one of the system embodiments described herein, wherein the system comprises two DUT interface devices 1 connected to two measuring ports of the vector network analyser 11. The method comprises:
In a further embodiment, in step (b) the required quadrature signals VI, VQ are determined for a range of frequencies of interest, i.e. a number of discrete frequencies in a frequency range. The method may further comprise computing two-port scattering parameters of the high gamma load as device under test 9 by using a thru connection between the first and second measuring port of the vector network analyser 11, with the injection signal (binj) off. These method embodiments are specifically advantageous in that both measurement ports are being calibrated, taking into account specific issues in relation to the use of two measurement ports of the vector network analyser 11.
The above mentioned generic calibration method embodiments are clarified and further detailed in the following description.
The widely used short-open-load (SOL) method for calibration of one-port vector network analysers relies on three pre-characterized calibration devices used as device under test 9. The transfer function between uncorrected Γraw and corrected Γ reflection coefficient is determined through three error terms e00, e11, and e10e01, and Γ at the calibration reference plane can be calculated using the following expression:
Here, the error terms e00, e11, and e10e01 respectively represent directivity, source match, and reflection tracking of the calibrated VNA 11. The SOL method relies on the use of three calibration devices with known electrical properties Γi, resulting in three independent measurements Γraw(i) with three unknown error-terms, which are calculated using the following equation:
The calibration procedure is as follows (see also flow charts of
The impedance standard of interest HighGammaload (HΓ) is connected to the system test-port (block 55). The measurement software uses an iteration algorithm (e.g. the Newton-Raphson algorithm. as such known to the person skilled in the art) to minimize Γraw to zero (e.g. at every desired frequency, block 56) and stores the corresponding VI(f) and VQ(f) values (this step does not apply to calibration method M1, see
A first SOL calibration with injection signal binj turned off is performed (applies to all method groups M1-M2-M3).
A conventional SOL calibration method is used (block 59) for calculation of system error terms, see equation (2), with injection off (eterm_50).
The second SOL calibration is performed with the measurement of three calibration devices with suitable electrical properties to improve accuracy over the impedance measurement range of interest, the HΓ, and two other known device typically the short (S) and the open (O). This applies to method groups M2 and M3 only. Again, a conventional SOL calibration method is used for calculation of system error terms, see equation (2), with injection on (eterm_HG).
The standard definition of the short and the open is converted in the gamma plane of the new reference impedance, i.e., where HighGammaload (HΓ) is now zero. Considering Z1 the original reference impedance and Z2 the new reference impedance, the scattering matrix Si associated to either the short or the open standard in Z1 is converted in the new reference plane using the equation:
S′=P
−1(S−γ)(1−γS)−1P
wherein:
and S is the scattering matrix in the old reference system and S′ is the new reference system (i.e., high gamma), I is the identity matrix.
With the system error-terms known, equation (1) is used to correct the input and output reflection coefficient of the high gamma device with injection on.
In order to compute the two-ports scattering parameters of the extreme gamma device the load match (e22) and transmission tracking term (e10e32) are then computed.
In order to obtain improved two port parameters of a high Γ device (i.e., reduced mismatched uncertainty and increased absolute accuracy of the reflection coefficients, using method group M3), after the above described calibration the measurement procedure is as follows, see
0) Connect the two-port high Γ DUT 9 (step 62)
1) Turn on the cancellation signal at port one, and acquire the raw input reflection coefficient ΓINraw (step 63, sparse dot pattern)
2) Turn on the cancellation signal at port two, and acquire the raw output reflection coefficient ΓOUTraw (step 64, dense dot pattern)
3) Turn the injection signals off and acquire S12raw and S21raw (step 65)
4) Correct the input/output reflection coefficients (ΓIN and ΓOUT) using eq. (1) and eterm_HG (step 66)
5) Correct the S21 and S12 using two port calibration equation (see above) and eterm_50 (step 67)
5) Use the following eq. (4) to obtain the normalized scattering parameters of the high Γ DUT 9 (step 68)
Where the error terms in (4) are eterm_50.
If the method M1 is applied for a two port DUT 9 measurement (using a further DUT interface device 1) the following method steps may also describe this method M1:
Also method M2 may be applied for a two-port DUT 9, with the following modifications to the method M2 (with reference to the blocks identified in
The method group M3 can in this respect be seen as a repeat of the procedure of method group M2 and then derive the VI and VQ signals to cancel the corrected input and output reflection coefficient, i.e., identify the cancellation signal binj, followed by renormalizing the S-parameter to a given reference impedance.
When considering a frequency sweep of the DUT 9, due to the reactive parasitic and delays involved, the measured impedance (at any port) will vary versus frequency, in many cases going from a high gamma value at lower frequencies to a lower gamma value at higher frequencies.
In a further embodiment of the present invention, a decision making algorithm is added to the method embodiments, based on the system sensitivity. The decision making algorithm was developed to choose, during the post processing phase of the measurement, which data will provide a lower uncertainty.
The algorithm is based on computing the derivative of the magnitude of the reflection coefficient (normalized to 50Ω) in respect of the magnitude of Z, this quantity will be defined as Δ. The system settings (injection off versus injection on) providing the highest value of Δ for any given impedance will provide the highest sensitivity and thus lowest uncertainty, and will be used to further process the data. Thus, in a further embodiment of the measurement method the measurement of a device under test (DUT) is executed at a predetermined frequency with or without injection signals binj in dependence of a sensitivity parameter Δ, the sensitivity parameter Δ being defined as the derivative of the magnitude of the reflection coefficient Γ in respect of the magnitude of the load impedance Z.
In an example Δ is computed for a (standard) 50Ω system and the system with injection on (i.e., 1 KΩ in the specific case). Depending on the value of Δ the data from the 50Ω system may provide a higher sensitivity, or the data from the 1 KΩ system will provide a higher sensitivity, and a selection is made accordingly.
It is noted that the present invention embodiments are advantageously applicable when the high gamma load, in operation, has a high voltage standing wave ratio (as compared to normal system impedance of 50Ω), e.g. a voltage standing wave ratio is higher than 9.
The present invention has been described above with reference to a number of exemplary embodiments as shown in the drawings. Modifications and alternative implementations of some parts or elements are possible, and are included in the scope of protection as defined in the appended claims.
Number | Date | Country | Kind |
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2018225 | Jan 2017 | NL | national |
Filing Document | Filing Date | Country | Kind |
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PCT/NL2018/050055 | 1/25/2018 | WO | 00 |