HEMT Millimeter-wave Monolithic IC
Technology for 76-GHz Automotive Radar
This paper describes monolithic IC technologies for developing practical automotive radar systems, covering the HEMT device structure, IC fabrication process, flip-chip assembling, and circuit design. InGaP/InGaAs HEMTs with a 0.15-μm gate were used in millimeter-wave monolithic ICs for the W-band, providing a maximum stable gain of 9 dB at 76 GHz. Height-controlled flip-chip bonding with pillar interconnection was demonstrated as a low-cost assembly method. A de-embedding technique to model a face-down co-planar waveguide was proposed. A chip set was designed with this technique, consisting of a 76-GHz amplifier, 76-GHz mixer, 76-GHz SPDT switches, 38/76- GHz doubler, 38-GHz voltage-controlled oscillator, and 38-GHz buffer amplifier. The fabricated chip set showed high performance for automotive radar systems.
1. Introduction
In line with recent advances in millimeterwave systems based on semiconductor technology development, the application of these systems is being extended to commercial fields.1),2) One of the most promising areas is automotive radar to provide active safety for driving. Research on automotive radar started in the early 1970s in the United States. In 1981, Fujitsu developed a 50- GHz radar sensor. These efforts, however, did not meet the demands of the market due to cost and size. In the late 1980s, several national programs promoted research on millimeter-wave systems, while during the same period GaAs semiconductor manufacturing grew strongly due to the rapid spread of wireless communications. These circumstances stimulated commercial interest in millimeter- wave systems, including automotive radar. Frequency allocation is a key to the market of any system utilizing electromagnetic waves. The Japanese Ministry of Posts and Telecommunications (MPT) assigned the 60-GHz band for low-power millimeter radar systems in 1995. Following the allocation of the 76-GHz band for radar in the U.S. and Europe, the MPT decided in 1997 to assign the same band to automotive radar systems in addition to the 60-GHz band. Although this action promoted a global standard for commercial use, it gave a rise to challenging technical issues. To realize practical, reasonably priced radar systems for passenger cars, the frequency performance of the devices must be improved and costs reduced. Monolithic integration is the usual approach to cost reduction and is still important for the W-band.3) Much effort has recently been devoted to the development of monolithic integrated circuits, and it has been shown that peripheral elements play a more important role in this frequency region. Die positioning and wiring in a package seriously affect the circuit performance and yield, resulting in higher costs. Flip-chips can be used to avoid these difficulties, as well as digital circuits.4) Using flip-chip bonding, chip positioning can be automated with greater accuracy. The wafer process for flip-chips will be simpler than that for conventional microwave devices. To make use of these advantages in millimeter-wave applications, problems associated with the short wavelength must be overcome.5),6) This paper describes a millimeter-wave monolithic IC (MMIC) technology for the development of 76-GHz automotive radar, including a 0.15-μm HEMT IC process, flip-chip with pillar interconnection, and W-band face-down circuit design. Using an InGaP/InGaAs/GaAs heterostructure with electron beam lithography, the HEMT exhibited good improvement compared to the conventional structure. The pillar interconnection technique was employed in the millimeter-wave monolithic IC for flip-chips. We have demonstrated the good electrical properties of the flip-chip and showed the difficulty of design due to the facedown structure. Several MMICs were successfully designed and fabricated for the 76-GHz automotive radar sensor. These face-down circuits exhibited good performance in the W-band.
2. Device technology
The operation frequency of 76 GHz in MMICs is challenging for transistor technology. The transistors in the circuit must provide sufficient gain at 76 GHz, which conventional semiconductor circuits have not reached. Heterojunction devices such as HEMTs have fundamental advantages over other types of transistors in terms of highfrequency performance, because of the bandgap difference in their structure. Fujitsu has already developed a 0.25-μm gate HEMT technology using photolithography and sidewall techniques, which is commercially available for several millimeter- wave systems. However, even with quarter- micron HEMTs, the frequency performance is not sufficient for 76-GHz automotive radar systems; high-performance transistors with an fmax exceeding 150 GHz are required. The reduction of gate capacitance and increase in transconductance are important to improve transistor characteristics. Scaling is the traditional approach for FET technology and is effective for improving performance even in the sub-micron region, but parasitic factors cannot be neglected for high-performance devices. Such phenomena as the short channel effect, increase in gate resistance and fringing capacitance degrade the transistor performance. Figure 1 shows the new structure employed for the 0.15-μm HEMT. The T-shaped gate was patterned by electron beam lithography. This makes the gate electrode free from the sidewall, thus reducing the fringing capacitance. The i- GaAs/i-InGaAs/n-InGaP/n-GaAs epitaxial layers were grown by MOCVD, where n-InGaP is the electron supply layer instead of the AlGaAs layer in the conventional structure. Thanks to high doping in the InGaP layer, the distance between the channel and gate can be reduced compared with the conventional AlGaAs/GaAs HEMT. This structure thus suppresses the short channel effect for fine gate lengths. In the fabrication process, the recess region was etched after ohmic electrode formation. The Al gate electrode was aligned in the recess region with electron beam lithography and lifted off. Using Al for the T-shaped gate electrode, the gate resistance is low even for a gate length of 0.15 μm. We optimized the structure taking account of the high frequency and process stability. Figure 2 shows the small-signal frequency characteristics of a 0.15-μm HEMT with a bias condition of Vds = 3 V and Vgs = -0.4 V, indicating a cut-off frequency (fT) of 90 GHz, a maximum oscillation frequency (fmax) of 170 GHz, and a maxi
pillars, HEMTs, and an air-bridge on the circuit. This technique provides flexibility, allowing the pillars to be placed anywhere on the chip and thus reduces the source inductance of each transistor by placing a grounded connection just beside the devices. In the fabrication process, pillar plating is also needed, instead of wafer thinning, backside alignment, via hole etching, and back-side plating, which are conventionally used in MMICs. The entire process is thus simplified with this pillar technique.
3. Flip-chip technology for millimeterwave devices
The importance of assembling is much larger for high-frequency applications than for digital or low-frequency ones. The physical length of packages seriously affects the performance of MMICs because the wavelength is comparable to the dimensions of the package and leads. Flipchip bonding causes little loss in performance or size reduction, and its assembly precision enables low-cost fabrication.7)-9) However, two problems remain. Firstly the transmission line on the chip to the substrate exerts a proximity effect on the highfrequency characteristics of the device. Secondly, the reliability of the lines may be compromised when subjected to thermal and mechanical stresses inherent in the inflexible structure of flip-chip bonding. We investigated the high-frequency characteristics and reliability of the flip-chip bonding portion between a GaAs chip and alumina substrate. The gold-tin eutectic reaction method was employed for flip-chip bonding, in which the chip and substrate were heated after connecting the gold pillars on the chip to the tin of the substrate. This process potentially causes less damage to the fragile GaAs chips than conventional gold-to-gold thermocompression bonding7),8) because of its lower temperature and lower load. In addition, the gold-tin method avoids solder contamination of the gold transmission line on the chip, which can be a problem in the solder-bump bonding method.9) The test piece consisted of a 2-mm-square GaAs chip with gold CPW lines and gold pillars on one surface, and a 10-mm-square 0.65-mmthick alumina substrate with a patterned thin film metallization on its surface. Figure 4 shows a schematic diagram of our flip-chip. The substrate metallization consists of 100 nm of Ti, 3,000 nm of Cu, and 500 nm of Sn. The chip was mounted on the substrate with a pulse-heat tool at 350°C for 10 seconds under a 20 g/pillar load.
Figure 5 shows the scattering parameters of the sample: S21 at 76 GHz measures -1.8 dB. By removing the return loss (-0.3 dB), the loss from the substrate coplanar lines (-0.5 dB) and the transmission line on the chip (-0.6 dB), the insertion loss of the pillar portion is estimated to be -0.2 dB/pillar. S11 is below -15 dB at 76 GHz. Using simulation, typical values for conventional wire bonding were estimated at -0.6 dB for S21, and -10 dB for S11.3) These results show that flipchip bonding has both a lower insertion loss and a return loss than conventional wire bonding. Next, we estimated the proximity effect on the high-frequency characteristics of the device by simulating the electromagnetic field using the moment method. Figure 6 shows the simulated characteristic impedance of the transmission line on the chip as a function of the pillar height. The transmission line on the chip has a coplanar structure for a 20-μm gap and 20-μm line width. The characteristic impedance gradually decreases with a decrease in pillar height. A ± 5-μm change in the height of a 20-μm-high pillar results in a ± 2- ohm change in the 52-ohm characteristic impedance. The slope of the curve becomes remarkable below a 15-μm pillar height. This is possibly explained by the change in the transmission mode. The result indicates that the flip-chip needs bonding technology with a controlled air gap, especially at a low pillar height such as 10 μm. The controllability closely depends on the load in the bonding process. Gold-tin eutectic bonding is suitable because of its low load. The pillar adherence strength was determined by measuring the die shear strength of the flip-chipped GaAs chips. The pillar adherence strength was equivalent to or larger than the TAB bump adherence strength.7) In general, the major problem in flip-chip bonding is the thermal expansion mismatch between the chip and substrate, because both are inflexible and thermal stress concentrates at the bonding portion. GaAs has a thermal expansion coefficient (6.0 ppm/°C) similar to that of alumina (6.5 ppm/°C), which is a typical substrate material. The flip-chip bonding of GaAs devices on an alumina substrate is expected to have a relatively small thermal expansion mismatch. The bonding reliability was estimated by thermal cycle tests (-55 to 150°C; 1,000 cycles), thermal shock tests
(0 to 100°C; 1,000 cycles) and vibration tests (10 to 200 Hz; 10 G, 6 hours). All samples passed these tests, indicating that the bonding technology has a high reliability. Figure 7 shows a cross-section of the flip-chip bonding after the thermal cycle test.
4. Circuit Design
4.1 Face-down chip design
Designing the W-band millimeter-wave circuit with face-down chips is another challenge. A precise model of the transmission line is one of the key issues for MMICs. In spite of much research on CPW design,10),11) there remain several difficulties in using CPW for flip-chip circuits, such as the proximity effect and signal transition to the chip. An actual flip-chip CPW line contains signal transition parts such as pillars or bumps to transmit a signal from the external feed line to the CPW line. When characterizing the actual CPW lines, however, the signal transition part hinders the de-embedding of the external feed lines since the transverse electromagnetic field extends toward each line. Figures 8(a) and (b) show a portion of an actual flip-chip structure, which includes a signal transition pillar. A simulated result of a magnitude contour map shows the electric field distribution at a distance of 10 μm from the alumina substrate at 76 GHz. The simulation was performed using a 3-dimensional full-wave electromagnetic field simulator. As shown in Figure 8(b), the electric field expands under the CPW line on the GaAs chip. This leads to interaction between the signal transition pillar and CPW line, thus making it difficult to determine the reference plane when de-embedding each line. When designing the circuits, the pillar transitions and CPW lines must be characterized independently. Therefore, we propose an experimental technique to model flip-chip CPW lines without signal transition pillars. This experiment is based on the reversed-structure flip-chip, which consists of a CPW line chip and lid ground. The CPW lines are measured with the lid ground attached to the pillar. By using this technique, the characteristics of the transmission line can be evaluated without affecting signal transition through the pillars. We obtained that Z0 = 49.0 ohms, Eeff = 5.41, and Attn= 0.300 dB/mm from measured data for a line width of 20 μm, a ground-to-ground spacing of 60 μm, and a pillar height of 20 μm. We also obtained that Z0 = 55.9 ohms, Eeff = 6.33, and Attn= 0.241 dB/ mm for the same line width and ground-to-ground spacing for a line without the lid ground. As mentioned in the previous section, the CPW line and ground on the substrate interact. These results closely agree with the simulation results and indicate that W-band flip-chip MMICs with CPW lines can be designed using the quasi-TEM mode approximation. Thus, we identified the parameters for the transmission line model in the circuit simulator by using this method.
4.2 MMIC chip set for automotive radar
Based on the CPW model, we developed a 76- GHz chip set for automotive radar. The chip set consists of a 76-GHz amplifier, 76-GHz mixer, 76- GHz SPDT switches, 38/76-GHz doubler, 38-GHz voltage-controlled oscillator, and 38-GHz buffer amplifier. Figure 9 shows photographs of the chip set. The amplifier has a two-stage configuration
with 80-μm HEMTs. Short-circuited stubs are used in the inter-stage and output matching circuits to reduce the chip size. Each short-circuited stub is composed of a transmission line and a grounded MIM capacitor. Figure 10 shows the measured S-parameters of the amplifier. The amplifier has a small-signal gain of 10.6 dB at 76.5 GHz
The mixer has a singly balanced configuration. The RF and LO signals are fed into the gate of each HEMT through the 0-p hybrid circuit. The 0-p hybrid circuit consists of a quarter-wavelength transmission line and a branch line hybrid circuit. The mixer using the 0-p hybrid circuit exhibits good isolation between the RF and LO ports even if the unit mixers have large reflection coefficients. Also, the mixer reduces AM noise from the LO in cooperation with an external IF 180- degree hybrid circuit. The mixer has a conversion gain of -4 dB at a 76-GHz LO frequency for an LO power of -1 dBm. The 76-GHz SPDT switch consists of two parallel- resonated 160-μm HEMTs. The transmission line connected to the drain and source terminals of the HEMT is employed as a resonant inductor in parallel with the fringing capacitance. The obtained insertion loss and isolation at 76.5 GHz were 3.4 dB and -17 dB, respectively. The 38/76-GHz doubler chip consists of two single-ended 80-μm HEMT frequency doublers and a branch line hybrid circuit. This circuit con- figuration leads to a low input return and high isolation between the two output ports. Figure 11 shows the measured frequency response of the doubler. The doubler has a conversion gain of -3.7 dB for a 38.25-GHz input signal power of 3 dBm. In the 38-GHz voltage controlled oscillator, we adopted the reverse channel HEMT configuration to generate sufficient negative resistance and reduce the size of the source feedback circuit. The oscillator uses the transmission line resonator terminated by a 160-μm Schottky-barrier diode as a varactor. The 38-GHz buffer amplifier provides impedance isolation between the oscillator and the external load. The chip has an output power of -0.7 dBm at 39.6 GHz. Figure 12 shows an SEM photo of the flipchip MMIC, indicating the amplifier chip on the evaluation board.
5. Conclusion
We have successfully developed an HEMT MMIC technology for 76-GHz automotive radar. The wafer process is based on a 0.15-μm InGaP/ InGaAs HEMT and interconnecting pillars for flipchip bonding. The maximum stable gain of the HEMT is 9 dB at 76 GHz. The flip-chip bonding technology uses gold micro pillars and tin metallization on an alumina substrate. Results of reliability tests indicated that the flip-chip bonding is very resistant to thermal and mechanical stresses, and thus is suitable for practical use. For designing flip-chip mounted MMICs for the W-band, we propose an experimental method to model facedown CPW transmission lines. By using this model, the chip set was designed and fabricated, and achieved sufficient performance for 76-GHz automotive radar systems. The results indicated that our MMIC technology is promising for achieving low-cost 76-GHz automotive radar systems.
Luiggi Marquez C.I 17677911 CRF
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