Active inductor based fully integrated CMOS transmit/ receive switch for 2.4 GHz RF transceiver

Bhuiyan, Mohammad Arif Sobhan; Zijie, Yeoh; Yu, Jong Min; Reaz, Mamun Bin Ibne; Kamal, Noorfazila; Chang, Tae‐Gyu

doi:10.1590/0001-3765201620150123

Cited by 14 publications

(6 citation statements)

References 20 publications

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“…The active inductors are preferred because of their large inductance values, high quality factor, low chip area and tenability. But the usage of active inductors in RF bandpass filter encounters a few difficulties like poor noise performance, inadequate dynamic range and relatively higher power consumption [19]. Fig.…”

Section: Methodsmentioning

confidence: 99%

Design of a band-pass filter in 0,18 μm CMOS for 2,4 GHz reader-less RFID transponder

et al. 2017

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Original scientific paper Radio Frequency Identification (RFID) based systems are ubiquitous nowadays. Band pass filters always play an important role in overall performance of an RFID transponder. In this paper, a band pass filter with a transistor only active inductor is presented for compact high performance reader-less RFID transponder. Post layout simulation result reveals that the centre frequency of the filter can be set to 2,42 GHz frequency with a bandwidth of 38 MHz. The filter core occupies an area of 0,004 mm 2 and dissipates only 1,3 mW at 1,5 V supply voltage. CEDEC 0,18 µm CMOS technology in Mentor Graphics environment has been used for the design of the proposed filter. Keywords: active inductor; band-pass filter; CMOS (Complementary Metal-Oxide Semiconductor); RFID (Radio Frequency Identification)Dizajn pojasnog filtra u 0,18 μm CMOS za 2,4 GHz RFID transponder bez čitača Izvorni znanstveni članak Sustavi temeljeni na Radio Frequency Identification (RFID) sada su široko rasprostranjeni. Pojasno fazni filtri igraju važnu ulogu u funkcioniranju RFID transpondera. U ovom radu, pojasno fazni filtar s induktorom aktivnim samo s tranzistorom prikazan je za kompaktni RFID transponder bez čitača visokih performansi. Rezultat simulacije rasporeda otkriva da središnja frekvencija filtra može biti postavljena na frekvenciju od 2,42 GHz sa širinom pojasa od 38 MHz. Jezgra filtra zauzima površinu od 0,004 mm 2 i gubi samo 1,3 mW kod napona napajanja od 1,5 V. Predloženi filtar dizajniran je pomoću CEDEC 0,18 μm CMOS tehnologije u Mentor Graphics okruženju. Ključne riječi: aktivni induktor; pojasno fazni filtar; CMOS (dopunski metalno oksidni poluvodič); RFID (radio frekvencijska identifikacija)

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Section: Methodsmentioning

confidence: 99%

Design of a band-pass filter in 0,18 μm CMOS for 2,4 GHz reader-less RFID transponder

et al. 2017

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“…The insertion loss is inversely proportional to the S21 parameter of the switch core, as follows: (1) According to Fig. 4, the value of S21 is derived by the following equation: (2) where Z0 is the characteristic impedance of the system, and Z1 is the total impedance at port 1; therefore, the following equations have been achieved: (6) According to Eq. (6), the insertion loss of a transistor is primarily dependent on its on-state resistance (Ron), and this is given by Eq.…”

Section: Transistor W/l Optimizationmentioning

confidence: 99%

“…1). During the transmission phase, the switch connects the antenna to the power amplifier of the transmitter so that the large signal is radiated to the surroundings, and the low-power receiver circuit is simultaneously protected from being damaged [2]; alternatively, during the reception phase, it ensures that the low-noise amplifier receives the intended signal with a minimum loss. The key requisites for a T/R switch are an enhanced isolation, the minimal insertion loss, the maximum power-handling capacity, a high linearity, and an acceptable reliability for a large range of signal amplitudes [2,3].…”

Section: Introductionmentioning

confidence: 99%

Design of an Active Inductor-Based T/R Switch in 0.13 μm CMOS Technology for 2.4 GHz RF Transceivers

Bhuiyan

Reaz²,

Badal

et al. 2016

Transactions on Electrical and Electronic Materials

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A high-performance transmit/receive (T/R) switch is essential for every radio-frequency (RF) device. This paper proposes a T/R switch that is designed in the CEDEC 0.13 μm complementary metal-oxide-semiconductor (CMOS) technology for 2.4 GHz ISM-band RF applications. The switch exhibits a 1 dB insertion loss, a 28.6 dB isolation, and a 35.8 dBm power-handling capacity in the transmit mode; meanwhile, for the 1.8 V/0 V control voltages, a 1.1 dB insertion loss and a 19.4 dB isolation were exhibited with an extremely-low power dissipation of 377.14 μW in the receive mode. Besides, the variations of the insertion loss and the isolation of the switch for a temperature change from -25℃ to 125℃ are 0.019 dB and 0.095 dB, respectively. To obtain a lucrative performance, an active inductor-based resonant circuit, body floating, a transistor W/L optimization, and an isolated CMOS structure were adopted for the switch design. Further, due to the avoidance of bulky inductors and capacitors, a very small chip size of 0.0207 mm 2 that is the lowest-ever reported chip area for this frequency band was achieved.

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“…CMOS technology enables operation at a lower power supply, resulting in a reduced power dissipation in the circuit [3,4] and a minimized fabrication cost because of the compact chip size. CMOS offers the prospect of integrating radiofrequency (RF)/digital/analog functions on a single chip in a low-cost manner [5][6][7]. The CMOS power amplifier (PA) is a promising solution for modern wireless devices to satisfy the demand of a low-power and low-cost design.…”

Section: Introductionmentioning

confidence: 99%

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

et al. 2019

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Power amplifiers (PAs) are among the most crucial functional blocks in the radio frequency (RF) frontend for reliable wireless communication. PAs amplify and boost the input signal to the required output power. The signal is amplified to make it sufficiently high for the transmitter to propagate the required distance to the receiver. Attempted advancements of PA have focused on attaining high-performance RF signals for transmitters. Such PAs are expected to require low power consumption while producing a relatively high output power with a high efficiency. However, current PA designs in nanometer and micrometer complementary metal–oxide semiconductor (CMOS) technology present inevitable drawbacks, such as oxide breakdown and hot electron effect. A well-defined architecture, including a linear and simple functional block synthesis, is critical in designing CMOS PA for various applications. This article describes the different state-of-the art design architectures of CMOS PA, including their circuit operations, and analyzes the performance of PAs for 2.4 GHz ISM (industrial, scientific, and medical) band applications.

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Active inductor based fully integrated CMOS transmit/ receive switch for 2.4 GHz RF transceiver

Cited by 14 publications

References 20 publications

Design of a band-pass filter in 0,18 μm CMOS for 2,4 GHz reader-less RFID transponder

Design of a band-pass filter in 0,18 μm CMOS for 2,4 GHz reader-less RFID transponder

Design of an Active Inductor-Based T/R Switch in 0.13 μm CMOS Technology for 2.4 GHz RF Transceivers

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

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