Integrated Microwave Photonics for Wideband Signal Processing

Yi, Xiaoke; Chew, Suen Xin; Song, Shijie; Nguyen, Linh; Minasian, R.A.

doi:10.3390/photonics4040046

Cited by 37 publications

(12 citation statements)

References 85 publications

(123 reference statements)

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“…To realize compact photonics-based microwave IRMs with high stability, integrated microwave photonic technology can be applied [47][48][49][50][51][52][53][54][55][56][57][58][59][60]. Integrated components including modulators, 90 • optical hybrids, PDs [47][48][49], optical oscillators and circulators [50], integrated sub-systems (such as lasers) [51], microwave photonic spectrum shapers [52], phase shifters [53], delay lines [54], filters [55] and processors [56][57][58][59] have been widely investigated, and great progress has been made. In addition, incorporation of new materials, such as graphene [60], to the field of integrated microwave photonics, brings new advantages, such as fast tuning speed, high nonlinearity and so on.…”

Section: Discussionmentioning

confidence: 99%

Photonics-Based Microwave Image-Reject Mixer

Zhu

Pan

2018

Photonics

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Recent developments in photonics-based microwave image-reject mixers (IRMs) are reviewed with an emphasis on the pre-filtering method, which applies an optical or electrical filter to remove the undesired image, and the phase cancellation method, which is realized by introducing an additional phase to the converted image and cancelling it through coherent combination without phase shift. Applications of photonics-based microwave IRM in electronic warfare, radar systems and satellite payloads are described. The inherent challenges of implementing photonics-based microwave IRM to meet specific requirements of the radio frequency (RF) system are discussed. Developmental trends of the photonics-based microwave IRM are also discussed.

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Section: Discussionmentioning

confidence: 99%

Photonics-Based Microwave Image-Reject Mixer

Zhu

Pan

2018

Photonics

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“…Following these pioneering results, extensive research has been directed toward MWP [3,4,6,8,9,[13][14][15][16][17][18][19], especially on solutions for the generation, transmission, and processing of microwave signals, because of its enormous potential for new technological applications in telecommunications [7]. In particular, at the present time, MWP provides new ways and possibilities to approach the emerging information technology scenarios, such as 5G mobile communications and Internet of Things (IoT), with capabilities beyond those of conventional electronic systems, in terms of enhanced flexibility, scalability, and capacity [1,[6][7][8]20,21]. The massive bandwidth, electromagnetic interference immunity, and flexible photonic platform are intrinsic remarkable advantages of MWP solutions to efficiently generate, transmit over low-loss optical fibers, and process microwave signals, overcoming inherent electronic limitations [2][3][4]8,20,22].…”

Section: Introductionmentioning

confidence: 99%

“…In particular, at the present time, MWP provides new ways and possibilities to approach the emerging information technology scenarios, such as 5G mobile communications and Internet of Things (IoT), with capabilities beyond those of conventional electronic systems, in terms of enhanced flexibility, scalability, and capacity [1,[6][7][8]20,21]. The massive bandwidth, electromagnetic interference immunity, and flexible photonic platform are intrinsic remarkable advantages of MWP solutions to efficiently generate, transmit over low-loss optical fibers, and process microwave signals, overcoming inherent electronic limitations [2][3][4]8,20,22]. Figure 1 shows the schematic of a generic MWP system consisting of three main blocks: (1) a transmitter, (2) a MWP processor, and (3) a receiver.…”

Section: Introductionmentioning

confidence: 99%

“…Photonics 2018, 4, x FOR PEER REVIEW 2 of 42 immunity, and flexible photonic platform are intrinsic remarkable advantages of MWP solutions to efficiently generate, transmit over low-loss optical fibers, and process microwave signals, overcoming inherent electronic limitations [2][3][4]8,20,22]. Figure 1 shows the schematic of a generic MWP system consisting of three main blocks: (1) a transmitter, (2) a MWP processor, and (3) a receiver.…”

Section: Introductionmentioning

confidence: 99%

“…Therefore, since 2005, there has been a strong drive for miniaturizing MWP systems onto a single chip to handle analog signals with low power, high efficiency, and high reliability metrics, which can be additionally reconfigured via software-defined networking (SDN) techniques [3,7,[36][37][38][39]. As such, integrated photonics technologies have been increasingly adopted by the MWP community to implement MWP functionalities [7,20,[40][41][42][43]. This has led to a second generation of MWP platforms termed 'Integrated Microwave Photonics' (IMWP).…”

Section: Introductionmentioning

confidence: 99%

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Recent Trends and Advances of Silicon-Based Integrated Microwave Photonics

et al. 2019

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Multitude applications of photonic devices and technologies for the generation and manipulation of arbitrary and random microwave waveforms, at unprecedented processing speeds, have been proposed in the literature over the past three decades. This class of photonic applications for microwave engineering is known as microwave photonics (MWP). The vast capabilities of MWP have allowed the realization of key functionalities which are either highly complex or simply not possible in the microwave domain alone. Recently, this growing field has adopted the integrated photonics technologies to develop microwave photonic systems with enhanced robustness as well as with a significant reduction of size, cost, weight, and power consumption. In particular, silicon photonics technology is of great interest for this aim as it offers outstanding possibilities for integration of highly-complex active and passive photonic devices, permitting monolithic integration of MWP with high-speed silicon electronics. In this article, we present a review of recent work on MWP functions developed on the silicon platform. We particularly focus on newly reported designs for signal modulation, arbitrary waveform generation, filtering, true-time delay, phase shifting, beam steering, and frequency measurement.

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Spatial Microwave Field Frequency Measurement through Two‐Level Resonance of Nitrogen‐Vacancy Color Center in Diamond

Gao,

Liu,

Guo

et al. 2023

Physica Status Solidi (b)

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This paper presents a frequency measurement method for spatial microwave signals with solid‐state atom resonance, performing measurements based on the burnt hole in spectrum with two microwave fields acting on nitrogen vacancies (NV) simultaneously. The population on |0> of the NV color center in the ground state affected by the resonance of two microwave fields with similar frequencies responds excellently to external microwave frequencies, and a phenomenon named hole burning occurred. The full width at half maximum (FWHM) of the resonant peak at the hole is 18.9 kHz. When microwaves of different frequencies were applied, the resonant peak precisely followed the signal frequency in the experiment. Subsequently, the resonant peak was processed using the differential method to obtain a frequency measurement error on the order of 100 Hz. The spatial resolution of this method is within the millimeter scale. This study can provide technical support for applications in microwave frequency measurement and spatial mapping with quantum precision measurement.This article is protected by copyright. All rights reserved.

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Integrated Microwave Photonics for Wideband Signal Processing

Cited by 37 publications

References 85 publications

Photonics-Based Microwave Image-Reject Mixer

Photonics-Based Microwave Image-Reject Mixer

Recent Trends and Advances of Silicon-Based Integrated Microwave Photonics

Spatial Microwave Field Frequency Measurement through Two‐Level Resonance of Nitrogen‐Vacancy Color Center in Diamond

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