Receiver Front-End Circuits for Future Generations of Wireless Communications

Sanduleanu, Mihai; Vidojkovic, Maja; Vidojkovic, Vojkan; Roermund, Arthur van; Tasic, A.

doi:10.1109/tcsii.2008.919566

Cited by 22 publications

(4 citation statements)

References 9 publications

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“…Overcoming this challenge requires innovations in various areas including novel ways for spectrum sensing and reuse, mechanisms for using higher frequencies such as 60 GHz and the visible light, novel ideas for dealing with interference, multiple-input multiple-output (MIMO), and generally more efficient protocols and systems [1][2][3][4][5][6][7][8][9][10][11][12]. MIMO technology promises a linear gain in capacity with the number of antennas [13], but it is yet to be adopted on a scale commensurate with its true potential [14][15][16].…”

Section: Introductionmentioning

confidence: 99%

Quadrature spatial modulation–performance analysis and impact of imperfect channel knowledge

Mesleh

Ikki

Aggoune

2014

Trans. Emerging Tel. Tech.

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In this paper, a new multiple-input multiple-output transmission technique called quadrature spatial modulation (QSM) is proposed and analyzed in the presence of imperfect channel estimation at the receiver. In QSM, conventional spatial constellation diagram of spatial modulation (SM) system is expanded to include both in-phase and quadrature components. As such, significant enhancement in the overall spectral efficiency is achieved while retaining all inherent advantages of SM technique, such as inter-channel interference avoidance, single radio frequency chain transmitter and low receiver complexity. It is shown that significant performance enhancements can be achieved as compared with SM, Alamouti, and spatial multiplexing systems. Besides, the impact of Gaussian imperfect channel estimation on the performance of QSM system is studied. A closed-form expression for the pairwise error probability of generic QSM system is derived and used to calculate a tight upper bound of the average bit error probability over Rayleigh fading channels with perfect and imperfect channel knowledge. Also, simple asymptotic expression is derived and analyzed. Obtained Monte Carlo simulation results highlight the accuracy of the conducted analysis.

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Section: Introductionmentioning

confidence: 99%

Quadrature spatial modulation–performance analysis and impact of imperfect channel knowledge

Mesleh

Ikki

Aggoune

2014

Trans. Emerging Tel. Tech.

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“…To date, the major hurdle in achieving a completely silicon based heterodyning transceiver is the off-chip resonators, which typically does not have integrated circuit (IC) compatible fabrication methods [15]. A key component in the transceiver system, these resonators are often utilized for frequency selection in the radio-frequency (RF) and intermediate-frequency (IF) stages.…”

Section: Introductionmentioning

confidence: 99%

Mems-Based Oscillators: A Review

Karim

Alam

Nordin

2014

IIUMEJ

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ABSTRACT: This paper presents an overview of microelectromechanical (MEMS) based oscillators. The accuracy and stability of the reference frequency will normally limit the performance of most wireless communication systems. MEMS technology is the technology of choice due to its compatibility to silicon, leading to integration with circuits and lowering power consumption. MEMS based oscillators also provide the potential of a fully integrated transceiver. The most commonly used topology for MEMS based oscillators are pierce oscillator circuit topology and TIA circuit topology. Both topologies result in very competitive output in terms of phase noise and power consumption.Â They can be used for either higher or lower Rx. The major difference between both topologies is the number of transistors used. TIA circuit used more number of transistor compare to pierce circuit. Thus design complexity of the TIA is higher. Pierce circuit is simpler, provide straightforward biasing and easier to design. The highly integratable of MEMS-based oscillators have made them much needed in future multiband wireless system. So that future wireless systems are able to function globally without any problem. ABSTRAK: Kertas kerja ini membentangkan gambaran keseluruhan mikroelektromekanikal (MEMS) berdasarkan pengayun.Â Ketepatan dan kestabilan frekuensi rujukan sering membataskan perlaksanaan kebanyakan sistem komunikasi tanpa wayar. Teknologi MEMS merupakan teknologi pilihan memandangkan ia serasi dengan silikon; membolehkan integrasi dengan litar dan penggunaan tenaga yang rendah.Â Pengayun berdasarkan MEMS jugaÂ berpotensi sebagai integrasi penuh penghantar-terima. Topologi yang sering digunakan untuk pengayun berdasarkan MEMS adalah topologi litar pengayun pencantas dan topologi litar TIA.Â Keputusan bagi kedua-dua topologi adalah amat kompetitif dari segi fasa bunyi dan penggunaan tenaga. Ia boleh digunakan untuk meninggikan atau merendahkan Rx. Perbezaan utama di antara kedua-dua topologi adalah bilangan transistor yang digunakan. Litar TIA menggunakan bilangan transistor yang lebih daripada litar pencantas.Â Maka, rekaan TIA adalah lebih rumit.Â Litar pencantas adalah lebih ringkas, memberikan pincangan yang jelas dan rekabentuk yang mudah. Pengayun berdasarkan MEMS amat bersepadu menjadikan ia sesuai sebagai sistem tanpa wayar berbilang jalur masa depan.Â Jesteru sistem tanpa wayar dapat berfungsi pada peringkat global tanpa sebarang kesulitan.

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“…To date, the major hurdle in achieving a completely silicon based heterodyning transceiver is the off-chip resonators, which typically does not have integrated circuit (IC) compatible fabrication methods [4]. A key component in the heterodyne transceiver system, these resonators are often utilized for frequency selection in the radio-frequency (RF) and intermediate-frequency (IF) stages.…”

Section: Introductionmentioning

confidence: 99%

RF oscillator implementation using integrated CMOS surface acoustic wave resonators

Nordin

Zaghloul

2011

Analog Integr Circ Sig Process

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This work is a proof of concept that a monolithic CMOS surface acoustic wave (SAW) resonator can function as an RF oscillator. The design of the oscillator includes the measurement characteristics of the CMOS SAW resonator, its matching networks, and RF amplifier is described. The integrated SAW resonator, with its operating frequency controlled by the spacing of its transducers was fabricated using a combination of CMOS plus post-CMOS processes. Based on the operation and performance of the SAW resonators, an equivalent circuit model of the CMOS SAW resonator was developed. A series resonant oscillator design was simulated using Microwave Office TM . The designed matching network improves both the insertion losses and the phase slope of the resonator, while the RF amplifier provides sufficient gain to ensure oscillation. Measurements conducted on the RF-CMOS SAW oscillator demonstrated oscillation at 600 MHz.

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Receiver Front-End Circuits for Future Generations of Wireless Communications

Cited by 22 publications

References 9 publications

Quadrature spatial modulation–performance analysis and impact of imperfect channel knowledge

Quadrature spatial modulation–performance analysis and impact of imperfect channel knowledge

Mems-Based Oscillators: A Review

RF oscillator implementation using integrated CMOS surface acoustic wave resonators

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