Analysis and optimization of a resistive‐feedback inverter LNA

Park, Jun Yong; Lee, Jun-Young; Yeo, Cheong Ki; Yun, Tae Yeoul

doi:10.1002/mop.31120

Cited by 10 publications

(3 citation statements)

References 10 publications

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“…The proposed LNA is a two-stage inverter-based amplifier with resistive feedback. Inverter-type LNA achieves wideband input-and output-impedance matching using feedback resistors, according to the size of the n-and p-type metal-oxide semiconductor transistors [29]. However, impedance mismatching may be generated to obtain the desired voltage gain in the inverter-based LNA, because the transconductances and output resistances of the transistors affect the wideband input and output matching characteristics and the voltage gain.…”

Section: Two-stage Lnamentioning

confidence: 99%

915-MHz Continuous-Wave Doppler Radar Sensor for Detection of Vital Signs

et al. 2019

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A miniaturized continuous-wave Doppler radar sensor operating at 915 MHz to remotely detect both respiration and heart rate (beats per minute) is presented. The proposed radar sensor comprises a front-end module including an implemented complementary metal-oxide semiconductor low-noise amplifier (LNA) and fractal-slot patch antennas, whose area was reduced by 15.2%. The two-stage inverter-based LNA was designed with an interstage capacitor and a feedback resistor to acquire ultrawide bandwidth. Two operating frequencies, 915 MHz and 2.45 GHz, were analyzed with regard to path loss for efficient operation because frequency affects detection sensitivity, reflected signal power from the human body, and measurement distance in a far-field condition. Path-loss calculation based on the simplified layer model indicates that the reflected power of the 915 MHz radar could be higher than that of the 2.45 GHz radar. The implemented radar front-end module excluding the LNA occupies 35 × 55 mm2. Vital signs were obtained via a fast Fourier transform and digital filtering using raw signals. In an experiment with six subjects, the respiration and heart rate obtained at 0.8 m using the proposed radar sensor exhibited mean accuracies of 99.4% and 97.6% with respect to commercialized reference sensors, respectively.

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Section: Two-stage Lnamentioning

confidence: 99%

915-MHz Continuous-Wave Doppler Radar Sensor for Detection of Vital Signs

et al. 2019

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“…However, in short channel devices, by increasing the size of transistors to obtain high G m at the same DC current, the corresponding output resistances decrease and, hence, the intrinsic gain of the RFI stays relatively constant. The NF of the RFI is given by [13]:…”

Section: Low Noise Amplifier (Lna)mentioning

confidence: 99%

A Ku-Band RF Front-End Employing Broadband Impedance Matching with 3.5 dB NF and 21 dB Conversion Gain in 45-nm CMOS Technology

et al. 2020

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This paper presents a K u -band RF receiver front-end with broadband impedance matching and amplification. The major building blocks of the proposed receiver front-end include a wideband low-noise amplifier (LNA) employing a cascade of resistive feedback inverter (RFI) and transformer-loaded common source amplifier, a down-conversion mixer with push–pull transconductor and complementary LO switching stage, and an output buffer. Push–pull architecture is employed extensively to maximize the power efficiency, bandwidth, and linearity. The proposed two-stage LNA employs the stagger-tuned frequency response in order to extend the RF bandwidth coverage. The input impedance of RFI is carefully analyzed, and a wideband input matching circuit incorporating only a single inductor is presented along with useful equivalent impedance matching models and detailed design analysis. The prototype chip was fabricated in 45-nm CMOS technology and dissipates 78 mW from a 1.2-V supply while occupying chip area of 0.29 mm 2 . The proposed receiver front-end provides 21 dB conversion gain with 7 GHz IF bandwidth, 3.5 dB NF, −15.7 dBm IIP 3 while satisfying <−10 dB input matching over the whole input band.

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“…In wideband communications systems, multi-decade gigahertz bandwidth allows higher data throughput than narrowband counterpart, and a low-noise amplifier (LNA) with wideband input match, flat gain, and low noise figure (NF) is required. [1][2][3] Various techniques are utilized to achieve flat gain and wideband input match: distributed amplifier (DA) topology is a good choice for wideband match and high gain, only at a cost of large die area and high power consumption. 4 Bandpass filter match is another method, but multi passive components ahead of amplifying stages will degrade the noise performance, raising the NF headroom.…”

Section: Introductionmentioning

confidence: 99%

An S‐ to Ku‐wideband low‐noise amplifier using asymmetric π filter and shunt‐peaking technique with simultaneous input match and noise flatness

Jing

Qian³

2019

Micro & Optical Tech Letters

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A single-stage S to Ku band (2-18 GHz) low noise amplifier (LNA) employing asymmetric π input match network and inductive shunt-peaking technique in 0.18 μm SiGe BiCMOS is presented. Shunt-shunt feedback is utilized to ensure wide operating as well as form a noise suppression topology. With the process of SiGe heterojunction bipolar transistor (HBT) featuring f T /f max of 240/280 GHz, the measurement of the proposed LNA results in S 11 below −10 dB, S 21 of 19.6 AE 0.8 dB and 2.2-3.2 dB noise figure (NF) from 2 to 18 GHz, drawing 9 mA DC current from a 3.3 V supply. K E Y W O R D SBiCMOS, feedback, low noise amplifier (LNA), SiGe, wideband

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Analysis and optimization of a resistive‐feedback inverter LNA

Cited by 10 publications

References 10 publications

915-MHz Continuous-Wave Doppler Radar Sensor for Detection of Vital Signs

915-MHz Continuous-Wave Doppler Radar Sensor for Detection of Vital Signs

A Ku-Band RF Front-End Employing Broadband Impedance Matching with 3.5 dB NF and 21 dB Conversion Gain in 45-nm CMOS Technology

An S‐ to Ku‐wideband low‐noise amplifier using asymmetric π filter and shunt‐peaking technique with simultaneous input match and noise flatness

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