A Novel 2-Dimensional Correction Method For Mm-Wave Cartesian I/Q Modulators
2021 IEEE INTERNATIONAL SYMPOSIUM ON CIRCUITS AND SYSTEMS (ISCAS)(2021)
摘要
This paper proposes a self-corrected In-phase/Quadrature-phase (I/Q) digital Cartesian modulator. The modulator is comprised of double balanced Gilbert cells to mitigate code dependent input and output impedances. Transistor-level simulations in 28 nm bulk CMOS demonstrate a static error vector magnitude (EVM) of -35 dB at 79 GHz carrier while providing 9.5 dBm peak output power with similar to 19% drain efficiency. Transistor level analysis shows that the linearity is limited by the transconductance (g(m)) I and Q input code dependency. To address this dependency a self-contained 2-dimensional correction technique is proposed.The proposed correction method improves the EVM from -35 dB to -42.5 dB without compromising the output power, power efficiency and occupied silicon area. The proposed solution enables linear and power efficient transmitters (TXs) for mm-Wave applications.
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关键词
drain efficiency,transistor level analysis,EVM,power efficiency,power efficient transmitters,mm-Wave applications,double balanced Gilbert cells,transistor-level simulations,static error vector magnitude,input code dependency,self-corrected in- phase-quadrature-phase digital cartesian modulator,I-Q digital Cartesian modulator,mm-wave Cartesian I-Q modulators,code dependent input-output impedance mitigation,bulk CMOS,transconductance I-Q input code dependency,self-contained 2-dimensional correction technique,size 28.0 nm,frequency 79.0 GHz,noise figure -42.5 dB to -35.0 dB
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