Efficient Microwave and Millimeter-Wave Frequency Multipliers Using Nonlinear Transmission Lines in CMOS Technology

Adnan, Muhammad; Afshari, Ehsan

doi:10.1109/tmtt.2015.2459688

Cited by 27 publications

(7 citation statements)

References 43 publications

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“…Naturally, it is common to find GaAs diode-based harmonic generators operating from hundreds of GHz to few THz [ 50 , 51 ]. In recent days, with significant process miniaturization down to 65 nm and beyond, it has become possible to realize frequency multipliers even beyond 100 GHz using silicon substrate [ 52 , 53 ].…”

Section: Harmonic Generationmentioning

confidence: 99%

“…One such structure is called the nonlinear transmission line (NLTL). The NLTL can be a continuous co-planar waveguide (CPW) line on a semiconductor substrate with discrete metal-semiconductor junction diodes [ 52 , 54 ], or distributed configuration using a metal-semiconductor junction on GaAs substrate [ 55 ], or discrete inductor and varactor diode structure fabricated monolithically [ 38 ], or discrete inductor and varactor diode structure fabricated on a PCB using discrete packaged components [ 56 ]. As the maximum bandwidth is dictated by the NLTL cut-off frequency, a monolithic fabrication would provide the most operational bandwidth as high as 20–30 GHz [ 54 ].…”

Section: Enhanced Harmonic Generation: Nltlmentioning

confidence: 99%

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Recent Advances and Applications of Passive Harmonic RFID Systems: A Review

2021

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Harmonic Radio Frequency Identification (RFID) systems have attracted significant interest over the last decade as it provides many benefits over the conventional RFID systems. Harmonic RFID is desired over conventional RFID systems due to reduced self-jamming, location accuracy from dual frequency, and higher phase noise immunity. In a harmonic RFID system, the tag receives instructions from the reader at an RF carrier frequency and replies back at the harmonic of the RF frequency. A nonlinear element consuming very low power at the tag is required to generate the harmonic carrier for the battery-less system. In this review article, a detailed contrast between conventional and harmonic RFID systems is presented. This is followed by different circuit design techniques to generate harmonics and integration techniques to form a fully operable passive harmonic RFID tag. Also, a wide range of applications, especially sensor integration with harmonic RFID’s, along with the future trends are presented.

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Section: Harmonic Generationmentioning

confidence: 99%

Section: Enhanced Harmonic Generation: Nltlmentioning

confidence: 99%

Recent Advances and Applications of Passive Harmonic RFID Systems: A Review

2021

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“…A frequency doubler and tripler were fabricated using CMOS processing to generate 20 GHz and 100 GHz, respectively. The 100 GHz tripler produced 0.7 W and a 12.2 dB bandwidth [43]. Table 1 summarizes the studies that evaluate lumped element NLTLs.…”

Section: B Experimental Contributionsmentioning

confidence: 99%

A Review of Nonlinear Transmission Line System Design

2020

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Nonlinear transmission lines (NLTLs) have been increasingly studied to produce high power microwaves (HPM) at higher repetition rates than conventional HPM devices without requiring the same auxiliary systems. The ability to array NLTLs to produce higher power and achieve beam steering provides an additional capability. This review summarizes the various NLTL topologies designed to achieve these design objectives. Specifically, we summarize modeling and experimental studies for three primary topologies: the lumped element NLTL, the split ring resonator, and the traditional transmission line geometry using nonlinear materials. The lumped element NLTL and the traditional transmission line constructed with nonlinear materials lend themselves to higher power applications, while the split ring resonator is better suited for applications involving antennas. We provide a detailed summary of past studies for these topologies and conclude by exploring ongoing work and future opportunities for technological development.

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“…The non-uniform Transmission lines are widely used in numerous applications such as electrical resonators 1 , hybrid amplifiers 2 , frequency synthesizers 3 , pulse shaping circuits 4 , antenna array beamforming networks 5 , and coupled microstrip lines 6 . Transmission lines made of the non-uniform profile are classified into two groups.…”

Section: Introductionmentioning

confidence: 99%

A new method for analyzing non-uniform guiding structures

Yasi

Boozari

Alijani

et al. 2023

Sci Rep

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This paper presents a new technique for analyzing a non-uniform transmission line (NUTL). This method expands the differential equations of voltage and current as the slope functions. Then, differential equations are solved using the explicit Runge–Kutta technique with the fourth-order method with four stages. It is shown that the proposed method can be used not only for analyzing the NUTL but also for analyzing the no-uniform waveguides (NUWG). Additionally, it is shown that the sensitivity of the proposed method concerning the discretization error is suitable. Several theoretical and practical NUTLs and NUWG are investigated to verify the proposed method’s accuracy and advantages. The performance of the proposed method is compared with those obtained by the other popular techniques, such as uniform cascaded sections (UCS).

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Efficient Microwave and Millimeter-Wave Frequency Multipliers Using Nonlinear Transmission Lines in CMOS Technology

Cited by 27 publications

References 43 publications

Recent Advances and Applications of Passive Harmonic RFID Systems: A Review

Recent Advances and Applications of Passive Harmonic RFID Systems: A Review

A Review of Nonlinear Transmission Line System Design

A new method for analyzing non-uniform guiding structures

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