Wideband balun‐LNA exploiting noise cancellation and  compensation technique

Liu, Lanqi; Lu, Zhaojing; Zhang, Kefeng; Ren, Zhuoxiang; Hu, Ang; Zou, Xuecheng

doi:10.1049/el.2015.3887

Cited by 17 publications

(6 citation statements)

References 6 publications

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“…The π‐match network is applied for impedance‐matching, the limiter realizes noise/distortion cancelation topology, and the onchip transformer (TF) is used as an inverting‐gain unit to realize g m ‐boosting topology. The limiter decreases amplitude of all RF‐waves sharply at the LNA's input‐port to provide a linear LNA, while other works tried to enhance their LNAs’ linearity by increasing IIP [77–141]. Based on Equation (), the LNA and its next circuits will never get saturated if the input of LNA remains under 50 mV by the limiter.…”

Section: Discussionmentioning

confidence: 99%

“…Several ideas have been proposed since 1960 [2] to design WB/UWB LNAs that the most remarkable ones were

g_{m}

‐boosting [45–108] and noise/distortion cancellation [77–141] topologies.

G_{m}

‐boosting can render a low noise figure (NF), low power consumption (

P_{dc}

) and flat gain, that its general idea is based on a common‐gate (CG) amplifier which its

P_{dc}

and NF were reduced simultaneously by an inverting gain unit (‐A) applied between the source and gate terminals of CG [51].…”

Section: Introductionmentioning

confidence: 99%

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Noise figure and input intercept point's errors in an AGC‐less microwatt ultrawideband system (limiter and low noise amplifier)

Shahrabadi

2021

IET Communications

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The goal is to illustrate new errors about using the figures-of-merit NF and IIP, by investigating an AGC-less microwatt ultrawideband g m -boosted CMOS RF system with noise/distortion cancellation. The system composed of limiter and LNA is designed for 0.3-10.7 GHz at 1.8 V. Thanks to the limiter, the impact of noises and distortions is cancelled and the LNA acts linear without any saturation or block, as well as, it becomes AGC-less. Additionally, achievements prove that NF and IIP sometimes can be accompanied by error, hence engineers must always consider all aspects of a system together during their evaluations. Although this work is not experimental, it applies different methods such as "Regenerating", "Comparing Calculations with Simulations" and "Monte Carlo" to demonstrate the reliability of achievements for applying in a SAW-less RFIC.

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Section: Discussionmentioning

confidence: 99%

“…Several ideas have been proposed since 1960 [2] to design WB/UWB LNAs that the most remarkable ones were

g_{m}

‐boosting [45–108] and noise/distortion cancellation [77–141] topologies.

G_{m}

‐boosting can render a low noise figure (NF), low power consumption (

P_{dc}

) and flat gain, that its general idea is based on a common‐gate (CG) amplifier which its

P_{dc}

and NF were reduced simultaneously by an inverting gain unit (‐A) applied between the source and gate terminals of CG [51].…”

Section: Introductionmentioning

confidence: 99%

Noise figure and input intercept point's errors in an AGC‐less microwatt ultrawideband system (limiter and low noise amplifier)

Shahrabadi

2021

IET Communications

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“…In [12] an ESD-protected Balun LNA with an inductorless broadband input matching is offered, the amplification stage exploited double current reuse and a single-stage thermal noise cancellation to enhance the gain, NF and power consumption. In [13] a Balun LNA using g m compensation technique at the output to improve the limited gain of the CG stage. The Balun LNA is working in parallel with two g m compensation transistors; one for every output stage; improving the gain by 5.4-5.8 dB, this technique also improved the linearity performance.…”

Section: Litreture Reviewmentioning

confidence: 99%

Balun LNA Thermal Noise Analysis and Balancing With Common-Source Degeneration Resistor

Abubaker

Albasha

2020

IEEE Access

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The Balun low noise amplifier (LNA) is an LNA that exploits a combination of a commonsource (CS) and a common-gate (CG) transistors, which cancels the noise and distortion of the CG stage. And since the CG is known to be linear, only the CS needs to be carefully designed and optimized. The Balun LNA also cancels the distortion and noise of the CG. In this paper, the CS section will be fully analyzed, and shown how the condition set in the literature review still satisfy the balancing output and cancel the CS stage thermal noise as well as the CG thermal noise. Also, forward body biasing (FBB) is used to reduce the threshold voltage and an addition of CS degeneration resistor to balance the output while still canceling the thermal noise of the transistors is tested using UMC180nm on Cadence. The LNA achieves a gain of 19-16dB, NF < 3.6 over the bandwidth 200M-1.9GHz without a CS degeneration. A 17.8-14.8dB gain, a NF < 3.8 over the bandwidth 200MHz-2.1GHz and power consumption of 12mW in both cases. Although outside the bandwidth, at ISM 2.4GHz a gain of 14.5dB and a NF of 3.8 is achieved, making it suitable for wireless sensor node (WSN) applications. According to the author's knowledge, this is the first time the degeneration resistor noise analysis on a Balun LNA is derived and analyzed.

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“…[12][13][14] Although these LNAs achieve high gain and good input impedance matching, they suffer from poor noise performance. To counter the noise issue, noise cancellation techniques are used in Guo et al 15 and Liu et al, 16 which result in good noise performance and high gain, but power consumption is noticeably increased.…”

Section: Introductionmentioning

confidence: 99%

Analysis and design of ultra‐wideband low noise amplifier using complementary structure with series inductive peaking technique and shunt feedback

Kazemi

Hayati

2021

Circuit Theory & Apps

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In this paper, an ultra-wideband low noise amplifier (LNA) is presented using 0.18-μm RF CMOS technology. A complementary structure with series inductive peaking technique is introduced by using two inductor-loops to achieve flat gain. In the first and third stages, two complementary structures are utilized to achieve a high and flat gain, a wideband input impedance matching and a low noise figure. In addition, a shunt feedback is utilized to increase input impedance matching and stability. In the second stage, a common source structure is used as interstage, which increases the À3 dB bandwidth. The designed LNA presents a high and flat gain of 15.6-16.5 dB, an excellent input return loss better than À11 dB and a good NF of 2.2-3 dB in the frequency range of 3.1-10.6 GHz. Also, the proposed structure consumes 6.8 mW from a 0.8-V supply voltage and has an IIP3 of À4 dBm at 6.5 GHz. The proposed structure only occupies 0.59 mm 2 .

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Wideband balun‐LNA exploiting noise cancellation and compensation technique

Cited by 17 publications

References 6 publications

Noise figure and input intercept point's errors in an AGC‐less microwatt ultrawideband system (limiter and low noise amplifier)

Noise figure and input intercept point's errors in an AGC‐less microwatt ultrawideband system (limiter and low noise amplifier)

Balun LNA Thermal Noise Analysis and Balancing With Common-Source Degeneration Resistor

Analysis and design of ultra‐wideband low noise amplifier using complementary structure with series inductive peaking technique and shunt feedback

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