MIN Wenchao，SUN Hao，ZHANG Qilian，TONG Rui，QIAN Rong，SUN Xiaowei*

（1.Shanghai Institute of Micro-System and Information Technology，Chinese Academy of Sciences，Shanghai 200050，China；2.University of Chinese Academy of Sciences，Beijing 100049，China）

A High-Performance W-Band Subharmonic Mixer Based on Anti-Parallel Diode Pair*

MIN Wenchao1，2，SUN Hao1，ZHANG Qilian1，TONG Rui1，QIAN Rong1，SUN Xiaowei1*

（1.Shanghai Institute of Micro-System and Information Technology，Chinese Academy of Sciences，Shanghai 200050，China；2.University of Chinese Academy of Sciences，Beijing 100049，China）

A high-performance W-band subharmonic mixer utilizing GaAs anti-parallel diode pair（APDP）is pre?sented.The APDP is fabricated by GaAs process platform of our laboratory，and the model of APDP shows ultrahigh cut-off frequency and low series resistance，which is suitable for W-band mixers.Based on the APDP，a W-band subharmonic mixer on quartz substrate was designed，fabricated and measured.The results show that the con?version loss of the subharmonic mixer is 9.2 dB～12 dB from 80 GHz to 100 GHz，and the required local oscillator（LO）power is just 6 dBm，which can significantly reduce the requirement for LO source.

subharmonic mixer；W-band；schottky diode；low LO power

Recently，radar and communication systems at W-band have been of an increasing importance［1-2］.Mix?ers are widely used in transceiver/receiver（T/R）mod?ules，in which subharmonic mixers are the most popu?lar topology at millimeter-wave applications with its ad?vantages of subharmonically pumping，inherently sup?pressing local oscillator（LO）noise，and reducing the demands on LO source［3］.Subharmonic mixers usually use a nonlinear device with an antisymmetric currentvoltage characteristic，such as anti-parallel diode pair（APDP）.The subharmonic mixers already have been reported by adopting fineline structures［4］，which is dif?ficult to be integrated with other planar circuits.There have also been several reports about subharmonic mix?ers of monolithic integrated circuit［5-7］（MIC）.Com?pared with MIC，hybrid integrated circuit（HIC）main? tains the flexibility of design and fabrication［8］，and it has lower cost.Moreover，by using the thin substrate，subharmonic mixers HIC has been smaller and small?er，which is in favor of small system integrations.

As the key component of mixers，the characteris?tics of APDP determine the performance of mixers，while APDP is significantly affected by its parasitic pa?rameters for millimeter-wave band［9-10］.The model of APDP parasitic parameters［11-12］is adopted to analyze the characteristics of our APDP for its cut-off frequen?cy and series resistance.We designed and fabricated a W-band subharmonic mixer based on the APDP.The measured results show that the lowest conversion loss is 9.2 dB at 91 GHz，and the required LO power is as low as 6 dBm.Our mixer has the characteristics of sub?harmonically pumping and low LO power，which cansimplify LO source designs including oscillator，dou?bler and amplifier circuits.

1 Schottky Diode Model

The GaAs Schottky diode utilized in this paper is designed and fabricated in our laboratory.Fig.1（a）shows the photograph of the APDP with dot Schottky junction of 1μm diameter.By DC measurements，the main parameters of Schottky diode are that reverse saturation current Isis 4.62 fA，series resistance Rsis 12 Ω，and ideality factor n is 1.14.The classic equiva?lent model of APDP［12］is adopted to analyze the parasitic parameters as Fig.1（b）shows.

Fig.1 Photograph of APDF and its equivalent model

The S parameter measurements of APDP are im?plemented and compared with the APDP model above，and then we can get the zero-bias junction capacity Cj0of 2.5 fF and the parasitic parameters at Table 1.The model above reveals that the cut-off frequency of the APDP can be expressed as：

From Eq.（1），the cut-off frequency fTof our AP?DP can reach 1.3 THz，so it is suitable for W-band sub?harmonic mixer.Furthermore，the low serious resis?tance contributes to low conversion loss and LO power of the designed mixer below.

Table 1 Parasitic parameters of APDP model

2 Design of Subharmonic Mixer

The schematic of the subharmonic mixer circuit is shown in Fig.2（a）.It consists of two networks，where RF network is on the left side of APDP，and LO net?work is on the right side.In the Radio Frequency（RF）network，RF port has a parallel-strip coupler to choke Intermediate Frequency（IF）signal，while IF port has a fan stub to choke RF signal，which are components of a duplexer for RF and IF signal.Meanwhile，a λLO/4 opencircuited stub provides the ground of LO signal.In the LO network，the 5nd stepped-impedance microstrip line is designed as a low pass filter（LPF），and its pass band is from DC to 50 GHz，which can feed LO signal to APDP.In addition，as the ground of RF signal，the LPF can reflect the RF signal to the APDP.The ground of IF signal is also designed with a fan stub of LO fre?quency.The schematic includes all of RF，LO and IF loops through APDP，which can achieve the subharmon?ic mixer.Finally，the both RF and LO network is simu?lated and optimized by ADS technology.By combining these networks with the analyzed APDP model，the sim?ulated result of conversion loss with a fixed IF frequen?cy（80 MHz）is shown in Fig.2（b）.

Fig.2 Mixer circuit and conversion loss

The mixer was fabricated on 0.127 mm thick quartz substrate and the APDP is flip-chip mounted shown in Fig.3.The ground-signal-ground（GSG）struc?tures with two fan stub capacitances are adopted atboth RF and LO ports in favor of feeding signals during on-chip test.Because of the low frequency of IF signal，it is difficult to design GSG structure for IF port，so that we adopted IF signal at a relatively low frequency，which can be extracted by DC probe during on-chip test.Meanwhile，the ground of IF signal is connected to the common ground by another DC probe.The mixer design can avoid via in the quartz substrate in favor of the simplification of fabrication process.Excluding the GSG pads for measurement，the actually chip area de?fined by the reference planes is 3.4 mm×2 mm.

Fig.3 Photograph of the W-band subharmonic mixer

3 Measurements and Discussions

An on-chip measurement was implemented shown in Fig.4.RF and LO signal were fed by GSG probes. RF signal was supplied by Agilent N5245A network an?alyzer and a 75～110 GHz frequency extender in contin?uous wave mode，and calibrated at-20 dBm by power sensor，while LO signal was supplied by Agilent E8247C signal generator and a quadrupler.The extract?ed IF signal was linked to Agilent N9030A spectrum analyzer.All the loss of signal lines was calibrated and deembedded from the measured data，so the measured conversion loss represented the loss from the RF GSG pad to the IF-port reference plane（see Fig.3）.In the actual application that the RF signal is fed on RF-port reference plane，the conversion loss can be further re?duced without RF GSG pad.

Fig.4 On-chip measurement for the mixer

RF frequency was set from 75 GHz to 105 GHz，while the IF frequency was fixed at 80 MHz.The mea?sured results are shown in Fig.5.The minimum conver?sion loss is 9.2 dB at 91 GHz of RF frequency.Fur?thermore，the mixer is broad-band with a conversion loss of 9.2 dB～12 dB from 80 GHz to 100 GHz.Dur?ing the measurement，we also set different LO power when the RF frequency was fixed at 90 GHz，and found that the optimum LO power is about 6 dBm.Al?though there is some difference of simulations and measurements which mainly results from the flip-chip mounting effect，the similar results and trends reveal that the APDP model is relatively exact for W-band applications.

Fig.5 Measured conversion loss including CL（Coversion Loss）vs RF frequency and CL vs LO power

Compared with other W-band subharmonic mix?ers in Table 2，the mixer in this paper has a relatively good conversion loss，and furthermore the minimum LO power（6 dBm）and the widest band（80 GHz～100 GHz），which result from the high cut-off frequency and low series resistance of the APDP.

Table 2 Performances of the reported W-band subharmonic mixers

4 Conclusion

A W-band subharmonic mixer is designed and fab?ricated on quartz substrate utilizing our APDP，which is of flexible fabrication and low cost.According to ex?act APDP model，the APDP shows superior characteris?tics of high cutoff frequency fT and low series resis?tance Rs，which contribute to the high mixing perfor?mance in terms of the conversion loss and LO power. The results show that the conversion loss is 9.2 dB～12 dB from 80 GHz to100 GHz.Furthermore，the optimum LO power is 6 dBm，and this，to the best of our knowl?edge，is the minimum among the W-band subharmonic mixers of APDP technology.The subharmonic mixer with low LO power can reduce the demand on both the frequency and power of LO source.

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閔文超（1991-），男，江蘇蘇州人，漢族，中科院上海微系統(tǒng)與信息技術研究所，碩士研究生，研究方向為射頻毫米波集成電路設計，minwc@mail.sim.ac.cn；

孫曉瑋（1958-），女，陜西西安人，漢族，中科院上海微系統(tǒng)與信息技術研究所，研究員，博士研究生導師，研究方向為微波毫米波器件單片集成電路及其相關毫米波雷達探測器等，xwsun@mail.sim.ac.cn。

基于反向平行二極管對管的高性能W波段諧波混頻器*

閔文超1，2，孫 浩1，張祁蓮1，佟 瑞1，錢 蓉1，孫曉瑋1*

（1.中國科學院上海微系統(tǒng)與信息技術研究所，上海200050；2.中國科學院大學，北京100049）

采用砷化鎵反向平行二極管對管，提出了一款W波段高性能諧波混頻器。二極管對管是由實驗室砷化鎵工藝線制作而成，并且二極管對管的模型顯示具有極高的截止頻率和低的串聯(lián)電阻特性，所以適用于W波段?；诖硕O管對管，設計、制作并測試了石英襯底上的W波段諧波混頻器。結果顯示在80 GHz～100 GHz的頻率范圍內(nèi)，諧波混頻器的變頻損耗為9.2 dB～12 dB，并且所需要的本振功率僅為6 dBm，能夠很好地減少對本振源的需求。

諧波混頻器；W波段；肖特基二極管；低本振功率

TN454

A

1005-9490（2016）06-1283-04

2015-12-23 修改日期：2016-01-14

1250

10.3969/j.issn.1005-9490.2016.06.001

項目來源：上海市科委基礎研究重大重點項目（14JC1407500）