Power Amplifier for 77-GHz Automotive Radar in 90-nm LP CMOS Technology

Lin, Jing-Fung; To, Kun-Hin; Hammock, D.; Knappenberger, B.; Majerus, Michael; Huang, Weicheng

doi:10.1109/lmwc.2010.2045598

Cited by 22 publications

(5 citation statements)

References 8 publications

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“…Performance variation with temperature and V DD is non-negligible, and the P out variation is directly related to the length of the VCO chain. Finally, our 77GHz VCO with its high P out readily enables integration with CMOS PAs [10]- [11] to realize viable 77GHz-TX capable of operation across wide temperature range. …”

Section: Discussionmentioning

confidence: 99%

“…The limited TR~10% is then insufficient for manufacturable, i.e., with room for process-voltage-temperature (PVT) variations, VCO for wideband applications such as WPAN at 60GHz and automotive radar at 77GHz. Furthermore, typical CMOS PAs [10]- [12] with output power (P out ) >10dBm (as needed for 60GHz/77GHz applications) require input power ≥0dBm, while majority of the demonstrated VCOs have P out <-10dBm; and high P out tends to trade off TR per loading from stronger buffer. Finally, VCO performance over wide temperature (-40 o C to +125 o C) and typical supply voltage (V DD ) variations (±10%), which can be detrimental particularly with long chain of functional blocks, has not been considered.…”

Section: Introductionmentioning

confidence: 99%

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A 77GHz CMOS VCO with 11.3GHz tuning range, 6dBm output power, and competitive phase noise in 65nm bulk CMOS

Trivedi¹,

To²,

Huang³

2011

2011 IEEE Radio Frequency Integrated Circuits Symposium

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We demonstrate, using a foundry-based 65nm bulk technology, mmWave CMOS VCOs in the range of 38GHz and 77GHz with highest reported continuous tuning range (14%-25%), competitive phase noise (-88dBc/Hz at 1MHz offset at 77GHz), and high P out (6dBm at 77GHz) needed to readily integrate with CMOS PA and to tolerate PVT variations. The DC power consumption of the 77GHz VCO is ~190mW and that of the 38GHz VCOs is ~60mW (~16mW without buffer) from 1V supply (V DD ). Device and design optimizations responsible for the high performance are presented. The impact of temperature and V DD variation (e.g., ~2.6GHz shift in frequency and >5.3dB variation in P out at 77GHz) is reported for the first time.

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Section: Discussionmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

A 77GHz CMOS VCO with 11.3GHz tuning range, 6dBm output power, and competitive phase noise in 65nm bulk CMOS

Trivedi¹,

To²,

Huang³

2011

2011 IEEE Radio Frequency Integrated Circuits Symposium

Self Cite

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show abstract

“…This situation is exacerbated by additional loss due to rain, fog, and atmospheric particles such as oxygen and water vapor. Deployment of effective power amplifiers (PAs) with high output power capability is, therefore, necessary to overcome these high path losses .…”

Section: Introductionmentioning

confidence: 99%

E-band transformer-based differential 4-way power-combining amplifier

Thian

2014

Microw. Opt. Technol. Lett.

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This paper presents the design and implementation of a differential 4-way powercombining amplifier operating at E-band. The proposed 4-way power combiner (4WPC) facilitates short interconnects to the PA cells, thereby resulting in reduced loss. Simple C-L-C and L-C networks are deployed in order to compensate inductive loading due to the routing lines that would otherwise introduce mismatch and subsequently increase overall loss. Realized in SiGe technology, the PA prototype delivered 13.2 dBm output-referred 1-dB compression point and 14.3 dBm saturated output power when operated from a single 3.3 V DC supply at 75 GHz.

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“…Several V-band CMOS power amplifiers have been published [4][5][6][7][8][9][10][11], those power amplifiers are realized in typical circuit topology such as common-source or cascade configuration. However, the output power has been relatively low under the low supply voltage requirement of CMOS technology.…”

Section: Introductionmentioning

confidence: 99%

Implementation of V-band power amplifier with high linearity in 90nm CMOS technology

Hsu

Chen

Weng

2014

2014 IEEE Wireless Power Transfer Conference

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This study used 90-nm CMOS technology to design a power amplifier (PA) applicable to the V-band operation. The on-chip transformers play the power combination roles that were used to design the input, interstage and output impedance matching networks. To alleviate the power loss, the ground shielding technique is employed in proposed transformer. The measurement results indicated that the output power and OP 1dB achieve 13.2dBm and 11.6dBm, respectively. The gain was 10dB, the bandwidth is 20GHz, ranging from 55GHz to 75GHz, the power added efficiency was 4.1% at 60GHz, and the power dissipation was 430mW.Index Terms -90nm CMOS, on-chip transformer, power amplifier, power combination, V-band.

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Power Amplifier for 77-GHz Automotive Radar in 90-nm LP CMOS Technology

Cited by 22 publications

References 8 publications

A 77GHz CMOS VCO with 11.3GHz tuning range, 6dBm output power, and competitive phase noise in 65nm bulk CMOS

A 77GHz CMOS VCO with 11.3GHz tuning range, 6dBm output power, and competitive phase noise in 65nm bulk CMOS

E-band transformer-based differential 4-way power-combining amplifier

Implementation of V-band power amplifier with high linearity in 90nm CMOS technology

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