Qianqian Lei scite author profile

A wide tuning range, low power CMOS automatic gain control (AGC) with a simple architecture is proposed. The proposed AGC is composed of a variable gain amplifier (VGA), a comparator and a charge pump, and the dB-linear gain is controlled by the charge pump. The AGC was implemented in a 0.18 m CMOS technology. The dynamic range of the VGA is more than 55 dB, the bandwidth is 30 MHz, and the gain error is lower than ˙1.5 dB over the full temperature and gain ranges. It is designed for GPS application and is fed from a single 1.8 V power supply. The AGC power consumption is less than 5 mW, and the area of the AGC is 700 450 m 2 .

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A 3~10GHz High Gain Low Noise Amplifier With Transformer Feedback Technique

Liu

Lei

Zhao

et al. 2022

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A CMOS low power, process/temperature variation tolerant RSSI with an integrated AGC loop

Lei¹,

Lin²,

Yin³

2013

J. Semicond.

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A low voltage low power CMOS limiter and received signal strength indicator (RSSI) with an integrated automatic gain control (AGC) loop for a short-distance receiver are implemented in SMIC 0.13 m CMOS technology. The RSSI has a dynamic range of more than 60 dB and the RSSI linearity error is within ˙0.5 dB for an input power from -65 to -8 dBm. The RSSI output voltage is from 0.15 to 1 V and the slope of the curve is 14.17 mV/dB while consuming 1.5 mA (I and Q paths) from a 1.2 V supply. Auto LNA gain mode selection with a combined RSSI function is also presented. Furthermore, with the compensation circuit, the proposed RSSI shows good temperature-independent and good robustness against process variation characteristics.

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A programmable gain amplifier with a DC offset calibration loop for a direct-conversion WLAN transceiver

Lei

Lin²,

Chen

et al. 2011

J. Semicond.

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A high-linearity PGA (programmable gain amplifier) with a DC offset calibration loop is proposed. The PGA adopts a differential degeneration structure to vary voltage gain and uses the closed-loop structure including the input op-amps to enhance the linearity. A continuous time feedback based DC offset calibration loop is also designed to solve the DC offset problem. This PGA is fabricated by TSMC 0.13 m CMOS technology. The measurements show that the receiver PGA (RXPGA) provides a 64 dB gain range with a step of 1 dB, and the transmitter PGA (TXPGA) covers a 16 dB gain. The RXPGA consumes 18 mA and the TXPGA consumes 7 mA (I and Q path) under a 3.3 V supply. The bandwidth of the multi-stage PGA is higher than 20 MHz. In addition, the DCOC (DC offset cancellation) circuit shows 10 kHz of HPCF (high pass cutoff frequency) and the DCOC settling time is less than 0.45 s.

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Qianqian Lei

Fabrication and photoelectric properties of a graphene-silicon nanowire heterojunction on a flexible polytetrafluoroethylene substrate

A high-performance low-power CMOS AGC for GPS application

A 3~10GHz High Gain Low Noise Amplifier With Transformer Feedback Technique

A CMOS low power, process/temperature variation tolerant RSSI with an integrated AGC loop

A programmable gain amplifier with a DC offset calibration loop for a direct-conversion WLAN transceiver

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