Transient Co-Simulation of a Hybrid Ring Mixer with Matching Network
The integration of active components and system level simulation is an outstanding feature for users of CST STUDIO SUITE™ 2006. In this article, a 180° Hybrid junction is employed in the popular mixer topology. The Hybrid itself is simulated in CST MICROWAVE STUDIO® (CST MWS) and the diodes and matching circuits are incorporated in CST DESIGN STUDIO™ (CST DS). Simulation results compare well with measurements and optimization of the matching networks within CST DS is used to improve the overall performance.
Figure 1: Full 3D CST MWS Model of the hybrid Mixer with CST DS Diodes
The 3D model simulated in CST MWS is shown in Fig. 1. As a postprocessing step, the diodes were added to the model using CST DS and simulations were perfomed to obtain S-Parameter, time domain waveforms, and frequency domain spectral content.
Figure 2: 3D Simulation S-Parameter results
Figure 2 shows the simulated S-parameters of the 180° Hybrid junction.
Figure 3: Animated 3D Surface Current Plot
An animation of the surface current at 2.8 GHz is shown in figure 3. This animation can be created effortlessly with the aid of the video animation macro in CST MWS.
Figure 4: Schematic View of the CST MWS / CST DS Co-Simulation
The diodes for mixing and the package parasitic components were included in CST DS as shown in Fig. 4.
Figure 5: Simulated (Green) and Measured (Red) S-parameter results from CST DS Cosimulation
Figure 6: Simulated (Green) and Measured (Red) S-parameter results from CST DS Cosimulation
The aforementioned results are shown in Figs. 5 - 8. Figures 5 and 6 show good correlation between measured and simulated results.
Figure 7: Time Domain Voltage Waveform at IF Port
As a confirmation of proper operation, the time domain voltage waveform is shown in Fig. 7. The IF frequency was chosen to be very low relative to the RF and LO to facilitate its identification in the time domain waveforms. It should be noted that the design frequency of the 180° Hybrid is 2.8 GHz and the LO frequency should match. The proper operating conditions are shown in Fig. 8 along with the simulated spectral content at the IF port.
Figure 8: Frequency Domain Spectral Content
As shown in Fig. 8, the output spectrum is cluttered with harmonics of, and dominated by, the RF and LO inputs.
Figure 9: CST DS Circuit with Matching Network
The performance can be improved by including impedance matching networks at all three ports as shown in Fig. 9. By inspecting the S-parameters of Figs. 5 and 6, one can obtain a decent starting point for the values of the matching elements, however, all three ports must be matched simultaneously at three different frequencies. Such a task would prove difficult and time consuming. Instead, the built in optimizer of CST DS was used to generate the optimal solution. The optimized values are also shown in Fig. 9 and the optimized S-parameters are in Fig. 10.
Figure 10: S-Parameters after DS Matching
It is apparent from Fig. 10 that the optimization worked quite well, providing over 60 dB return loss at all ports. Re-simulating the spectral content at the IF port generated the plot shown in Fig. 11.
Figure 11: Simulated spectral content at IF port after matching in DS
Inspecting Fig. 11 shows that the matching network dramatically improved the performance of the mixer. The output spectrum is now dominated by the IF and the RF/LO and their harmonics are supressed.
In this article, it was shown how CST MWS and CST DS can be combined to analyze and optimize the design of a 180° Hybrid mixer. Comparisons with measured results were made and found to correlate well. Optimized impedance matching networks at the input and output ports provided a simultaneous solution and improved mixer performance.
CST Article "Transient Co-Simulation of a Hybrid Ring Mixer with Matching Network"
last modified 16. May 2006 8:54
printed 4. Jul 2008 3:36, Article ID 268
URL:
All rights reserved.
Without prior written permission of CST, no part of this publication may be
reproduced by any method, be stored or transferred into an electronic data processing system, neither mechanical or by any other method.
Article ID: 268
Last modified: 16. May 2006 8:54
Other Articles
The actual trend in the silicon industry toward higher levels of integration generates chips with densities of tens of millions of transistors. As a consequence, the signal switching frequency in modem digital equipment is beyond the gigahertz range. When the bandwidth requirement increases, the electrical properties of the interconnections affect and limit the integrity of the traveling digital signals.
These phenomena also have an impact on the electromagnetic compatibility (EMC) performance of the system since corrupted signals can easily increase the unwanted electromagnetic interference (EMI).
This article summaries the simulations and measurement carried out using CST MICROWAVE STUDIO® on a multilayered PCB.
Read full article..
The paper demonstrates the possibilitiy to model photonic cyrystals using CST MICROWAVE STUDIO®. A one dimensional periodic band-gap structure is simulated using the Transient Solver.
Read full article..
Radio Frequency Identification Systems (RF-ID) are widely used and are thus one of the fastest growing sectors of todays radio industry, allowing advanced solutions for a variety of applications in the area of authentication, ticketing, access control, supply management, etc. One of the most common band allocated to RFID systems is 13.56 MHz. For this application example operating at this particular frequency band we have chosen a transponder inlay which was created using the ACIS based solid modeler of CST MICROWAVE STUDIO® The frequency domain solver of CST MICROWAVE STUDIO® has been applied to accurately predict the input impedance, followed by a lumped element based equivelent circuit derivation to describe the impedance versus frequency.
Read full article..
This paper describes how Double Negative Materials (DNG) material can be simulated in CST MICROWAVE STUDIO® (CST MWS) by using dispersive materials.
Read full article..
The behaviour of a ferrite loaded waveguide antenna is predicted first by a 2D-analytical model and second by CST MICROWAVE STUDIO®. The results of the predictions are compared with measurements. (Courtesy and permission of KAIST Korea.)
Read full article..