Towards a BIST technique for noise figure evaluation

This paper presents a variable-gain amplifier (VGA) in the 68–78 GHz range. To reduce DC power consumption, the drain voltage was set to 0.5 V with competitive performance in the gain and the noise figure. High-Q shunt capacitors were employed at the gate terminal of the core transistors to move input matching points for easy matching with a compact transformer. The four stages amplifier fabricated in 40-nm bulk complementary metal oxide semiconductor (CMOS) showed a peak gain of 24.5 dB at 71.3 GHz and 3‑dB bandwidth of more than 10 GHz in 68–78 GHz range with approximately 4.8-mW power consumption per stage. Gate-bias control of the second stage in which feedback capacitances were neutralized with cross-coupled capacitors allowed us to vary the gain by around 21 dB in the operating frequency band. The noise figure was estimated to be better than 5.9 dB in the operating frequency band from the full electromagnetic (EM) simulation.

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A 90 nm-CMOS broadband receiver with 10 dB conversion gain and 15 dB noise figure in 80–110 GHz suitable for multi-pixel imaging arrays

Review of Scientific Instruments ◽

10.1063/5.0059812 ◽

2021 ◽

Vol 92 (8) ◽

pp. 084703

Author(s):

Hsuan Chu-Chen ◽

Kuan-Han Hsieh ◽

Robert Hu

Keyword(s):

Noise Figure ◽

Conversion Gain ◽

Imaging Arrays

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A Process Scalable Architecture for Low Noise Figure Sub-sampling Mixer-First RF Front-End

2021 IEEE International Symposium on Circuits and Systems (ISCAS) ◽

10.1109/iscas51556.2021.9401387 ◽

2021 ◽

Author(s):

Rakesh Rena ◽

Suraj Kumar Verma ◽

Vijaya Sankara Rao Pasupureddi

Keyword(s):

Noise Figure ◽

Low Noise ◽

Scalable Architecture ◽

Front End ◽

Rf Front End

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RF Transceiver for the Multi-Mode Radar Applications

Sensors ◽

10.3390/s21051563 ◽

2021 ◽

Vol 21 (5) ◽

pp. 1563

Author(s):

Jae Kwon Ha ◽

Chang Kyun Noh ◽

Jin Seop Lee ◽

Ho Jin Kang ◽

Yu Min Kim ◽

...

Keyword(s):

Long Range ◽

Integrated Circuit ◽

Flicker Noise ◽

Noise Figure ◽

Supply Voltage ◽

Doppler Frequency ◽

Cmos Process ◽

Rf Transceiver ◽

Dc Offset ◽

Multi Mode

In this work, a multi-mode radar transceiver supporting pulse, FMCW and CW modes was designed as an integrated circuit. The radars mainly detect the targets move by using the Doppler frequency which is significantly affected by flicker noise of the receiver from several Hz to several kHz. Due to this flicker noise, the long-range detection performance of the radars is greatly reduced, and the accuracy of range to the target and velocity is also deteriorated. Therefore, we propose a transmitter that suppresses LO leakage in consideration of long-range detection, target distance, velocity, and noise figure. We also propose a receiver structure that suppresses DC offset due to image signal and LO leakage. The design was conducted with TSMC 65 nm CMOS process, and the designed and fabricated circuit consumes a current of 265 mA at 1.2 V supply voltage. The proposed transmitter confirms the LO leakage suppression of 37 dB at 24 GHz. The proposed receiver improves the noise figure by about 20 dB at 100 Hz by applying a double conversion architecture and an image rejection, and it illustrates a DC rejection of 30 dB. Afterwards, the operation of the pulse, FMCW, and CW modes of the designed radar in integrated circuit was confirmed through experiment using a test PCB.

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A 4.4-mA ESD-Safe 900-MHz LNA With 0.9-dB Noise Figure

IEEE Transactions on Very Large Scale Integration (VLSI) Systems ◽

10.1109/tvlsi.2020.3038766 ◽

2020 ◽

pp. 1-10

Author(s):

Atul Thakur ◽

Shouri Chatterjee

Keyword(s):

Noise Figure

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60 GHz-Band Low-Noise Amplifier

Journal of Circuits System and Computers ◽

10.1142/s021812661750075x ◽

2017 ◽

Vol 26 (05) ◽

pp. 1750075 ◽

Cited By ~ 1

Author(s):

Najam Muhammad Amin ◽

Lianfeng Shen ◽

Zhi-Gong Wang ◽

Muhammad Ovais Akhter ◽

Muhammad Tariq Afridi

Keyword(s):

Transmission Line ◽

Quality Factor ◽

Noise Figure ◽

Cmos Technology ◽

Low Noise ◽

Constant Current ◽

60 Ghz ◽

Frequency Range ◽

Constant Current Density ◽

Chip Area

This paper presents the design of a 60[Formula: see text]GHz-band LNA intended for the 63.72–65.88[Formula: see text]GHz frequency range (channel-4 of the 60[Formula: see text]GHz band). The LNA is designed in a 65-nm CMOS technology and the design methodology is based on a constant-current-density biasing scheme. Prior to designing the LNA, a detailed investigation into the transistor and passives performances at millimeter-wave (MMW) frequencies is carried out. It is shown that biasing the transistors for an optimum noise figure performance does not degrade their power gain significantly. Furthermore, three potential inductive transmission line candidates, based on coplanar waveguide (CPW) and microstrip line (MSL) structures, have been considered to realize the MMW interconnects. Electromagnetic (EM) simulations have been performed to design and compare the performances of these inductive lines. It is shown that the inductive quality factor of a CPW-based inductive transmission line ([Formula: see text] is more than 3.4 times higher than its MSL counterpart @ 65[Formula: see text]GHz. A CPW structure, with an optimized ground-equalizing metal strip density to achieve the highest inductive quality factor, is therefore a preferred choice for the design of MMW interconnects, compared to an MSL. The LNA achieves a measured forward gain of [Formula: see text][Formula: see text]dB with good input and output impedance matching of better than [Formula: see text][Formula: see text]dB in the desired frequency range. Covering a chip area of 1256[Formula: see text][Formula: see text]m[Formula: see text]m including the pads, the LNA dissipates a power of only 16.2[Formula: see text]mW.

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