Design Architectures of the CMOS Power Amplifier for 2.4 GHz ISM Band Applications: An Overview

Bhuiyan, Mohammad Arif Sobhan; Badal, Torikul Islam; Reaz, Mamun Bin Ibne; Crespo, M.L.; Cicuttin, A.

doi:10.3390/electronics8050477

Cited by 16 publications

(13 citation statements)

References 47 publications

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“…Frequency domain analysis was performed from 1Hz to 10 GHz. The bias current is adjusted by changing the value of the external resistor allowing changing the transconductance as represented in equation (7). The gain (absolute value) varied from 40.6 dB to 53.8 dB.…”

Section: Resultsmentioning

confidence: 99%

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A 0.35μm Low-Noise Stable Charge Sensitive Amplifier for Silicon Detectors Applications

Bhuiyan¹

2020

Informacije MIDEM

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The Charge Sensitive Amplifier (CSA) is the key module of the front-end electronics of various types of Silicon detectors and most radiation detection systems. High gain, stability, and low input noise are the major concerns of a typical CSA circuit in order to achieve amplified susceptible input charge (current) for further processing. To design such a low-noise, stable, and low power dissipation solution, a CSA is required to be realized in a complementary metal-oxide-semiconductor (CMOS) technology with a compact design. This research reports a low-noise highly stabile CSA design for Silicon detectors applications, which has been designed and validated in TSMC 0.35 um CMOS process. In a typical CSA design, the detector capacitance and the input transistor's width are the dominant parameters for achieving low noise performance. Therefore, the Equivalent Noise Charge (ENC) with respect to those parameters has been optimized, for a range of detector capacitance from 0.2 pF-2 pF. However, the parallel noise of the feedback was removed by adopting a voltage-controlled NMOS resistor, which in turn helped to achieve high stability of the circuit. The simulation results provided a baseline gain of 9.92 mV/fC and show that ENC was found to be 42.5 e-with 3.72 e-/pF noise slope. The Corner frequency exhibited by the CSA is 1.023 GHz and the output magnitude was controlled at-56.8 dB; it dissipates 0.23 mW with a single voltage supply of 3.3 V with an active die area of 0.0049 mm 2 .

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Section: Resultsmentioning

confidence: 99%

“…A VLSI preamplifier costs much less than a hybrid one or a preamplifier unit [5]. CMOS exhibits several advantages over other concurrent technologies and and is preferred in VLSI circuit design [6][7]. A very popular approach in designing the VLSI CSA is the usage of an operational amplifier (Op-amp), with the R-C feedback network.…”

Section: Introductionmentioning

confidence: 99%

A 0.35μm Low-Noise Stable Charge Sensitive Amplifier for Silicon Detectors Applications

Bhuiyan¹

2020

Informacije MIDEM

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“…CMOS exhibits several advantages over other concurrent technologies (such as Bipolar, BiCMOS, etc.) and therefore, usually preferred to design application-specific integrated circuits (ASICs) [ 6 , 14 , 18 , 19 ]. A widely accepted front-end electronics (FEE) design approach is the use of an operational amplifier (Op-amp), with the R-C feedback network.…”

Section: Introductionmentioning

confidence: 99%

“…A. Baschirotto et al [ 20 ], designed a front-end using a single-ended amplifier as CSA. The circuit works at high frequency and very low voltage; however, the disadvantages of that circuit are high power consumption and high equivalent noise charge (ENC) which worsen the radiation-hardened behavior of the circuit [ 9 , 19 , 25 , 28 , 29 ]; furthermore, the circuit was prone to more parallel noise generated by the passive feedback resistor. The main problem in designing nuclear spectroscopy very large scale integration (VLSI) readout front ends is the execution of low-noise and low-power CSA, which guarantees high particles flux with the lowest pulse pile-up.…”

Section: Introductionmentioning

confidence: 99%

An 8.72 µW Low-Noise and Wide Bandwidth FEE Design for High-Throughput Pixel-Strip (PS) Sensors

Jérôme

Evariste

Bernard

et al. 2021

Sensors

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The front-end electronics (FEE) of the Compact Muon Solenoid (CMS) is needed very low power consumption and higher readout bandwidth to match the low power requirement of its Short Strip application-specific integrated circuits (ASIC) (SSA) and to handle a large number of pileup events in the High-Luminosity Large Hadron Collider (LHC). A low-noise, wide bandwidth, and ultra-low power FEE for the pixel-strip sensor of the CMS has been designed and simulated in a 0.35 µm Complementary Metal Oxide Semiconductor (CMOS) process. The design comprises a Charge Sensitive Amplifier (CSA) and a fast Capacitor-Resistor-Resistor-Capacitor (CR-RC) pulse shaper (PS). A compact structure of the CSA circuit has been analyzed and designed for high throughput purposes. Analytical calculations were performed to achieve at least 998 MHz gain bandwidth, and then overcome pileup issue in the High-Luminosity LHC. The spice simulations prove that the circuit can achieve 88 dB dc-gain while exhibiting up to 1 GHz gain-bandwidth product (GBP). The stability of the design was guaranteed with an 82-degree phase margin while 214 ns optimal shaping time was extracted for low-power purposes. The robustness of the design against radiations was performed and the amplitude resolution of the proposed front-end was controlled at 1.87% FWHM (full width half maximum). The circuit has been designed to handle up to 280 fC input charge pulses with 2 pF maximum sensor capacitance. In good agreement with the analytical calculations, simulations outcomes were validated by post-layout simulations results, which provided a baseline gain of 546.56 mV/MeV and 920.66 mV/MeV, respectively, for the CSA and the shaping module while the ENC (Equivalent Noise Charge) of the device was controlled at 37.6 e− at 0 pF with a noise slope of 16.32 e−/pF. Moreover, the proposed circuit dissipates very low power which is only 8.72 µW from a 3.3 V supply and the compact layout occupied just 0.0205 mm2 die area.

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“…Several methods have been proposed to improve the traditional transceiver structure by integrating multiple functions in one module or reusing bias current in multiple modules [3][4][5][6][7]. For each module in the transceiver, the traditional design optimization theory is mainly aimed at the improvement of circuit performance while less consideration is given to power saving [8][9][10][11][12]. In order to minimize the power consumption of the WSN system fundamentally, attention should be paid both to the system architecture and to the circuit modules.…”

Section: Introductionmentioning

confidence: 99%

A Low-Voltage Multi-Band ZigBee Transceiver

Yao

Wang

et al. 2019

Electronics

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This paper presents a low-voltage ZigBee transceiver covering a unique frequency band of 780/868/915/2400 MHz in 180 nm CMOS technology. The design consists of a receiver with a wideband variable-gain front end and a complex band-pass filter (CBPF) based on poles construction, a transmitter employing the two-point direct-modulation structure, a Ʃ-Δ fractional-N frequency synthesizer with two VCOs and some auxiliary circuits. The measured results show that under 1 V supply voltage, the receiver reaches −93.8 dBm and −102 dBm sensitivity for 2.4 GHz and sub-GHz band, respectively, and dissipates only 1.42 mW power. The frequency synthesizer achieves −106.8 dBc/Hz and −116.7 dBc/Hz phase noise at 1 MHz frequency offset along with 4.2 mW and 3.5 mW power consumption for 2.4 GHz and sub-GHz band, respectively. The transmitter features 2.67 dBm and 12.65 dBm maximum output power at the expense of 21.2 mW and 69.5 mW power for 2.4 GHz and sub-GHz band, respectively.

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Design Architectures of the CMOS Power Amplifier for 2.4 GHz ISM Band Applications: An Overview

Cited by 16 publications

References 47 publications

A 0.35μm Low-Noise Stable Charge Sensitive Amplifier for Silicon Detectors Applications

A 0.35μm Low-Noise Stable Charge Sensitive Amplifier for Silicon Detectors Applications

An 8.72 µW Low-Noise and Wide Bandwidth FEE Design for High-Throughput Pixel-Strip (PS) Sensors

A Low-Voltage Multi-Band ZigBee Transceiver

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