Novel microwave photonic fractional Hilbert transformer using a ring resonator-based optical all-pass filter

Zhuang, Leimeng; Khan, M. R. H.; Beeker, Willem P.; Leinse, Arne; Heideman, René; Roeloffzen, C.G.H.

doi:10.1364/oe.20.026499

Cited by 71 publications

(52 citation statements)

References 21 publications

(21 reference statements)

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“…Examples range from tunable microwave filters, phase shifters, frequency converters, ultra-wideband microwave signal generators to tunable true time delay (TTD) elements for optical beamforming networks (OBFN) [69][70][71][72][73]. A detailed discussion of the basic building blocks applied in integrated OBFNs can be found in [33].…”

Section: Communicationsmentioning

confidence: 99%

TriPleX: a versatile dielectric photonic platform

Wörhoff

Heideman

Leinse

et al. 2015

Advanced Optical Technologies

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Photonic applications based on planar waveguide technology impose stringent requirements on properties such as optical propagation losses, light coupling to optical fibers, integration density, as well as on reliability and reproducibility. The latter is correlated to a high level of control of the refractive index and waveguide geometry. In this paper, we review a versatile dielectric waveguide platform, called TriPleX, which is based on alternating silicon nitride and silicon dioxide films. Fabrication with CMOS-compatible equipment based on low-pressure chemical vapor deposition enables the realization of stable material compositions being a prerequisite to the control of waveguide properties and modal shape. The transparency window of both materials allows for the realization of low-loss waveguides over a wide wavelength range (400 nm-2.35 μm). Propagation losses as low as 5 × 10 -4 dB/cm are reported. Three basic geometries (box shell, double stripe, and filled box) can be distinguished. A specific tapering technology is developed for on-chip, low-loss ( < 0.1 dB) spotsize convertors, allowing for combining efficient fiber to chip coupling with high-contrast waveguides required for increased functional complexity as well as for hybrid integration with other photonic platforms such as InP and SOI. The functionality of the TriPleX platform is captured by verified basic building blocks. The corresponding library and associated design kit is available for multi-project wafer (MPW) runs. Several applications of this platform technology in communications, biomedicine, sensing, as well as a few special fields of photonics are treated in more detail.

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Section: Communicationsmentioning

confidence: 99%

TriPleX: a versatile dielectric photonic platform

Wörhoff

Heideman

Leinse

et al. 2015

Advanced Optical Technologies

Self Cite

207

175

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“…Toward this goal, we proposed a particular processor design that comprises a serial cascade of three RRs of different FSRs [63], as illustrated in Figure 8. In this design, again, a pair of RRs with identical FSRs are used for filter shape synthesis and a third RR with a smaller FSR is used to perform the function as a modulation translator [64,65] that enables a separate manipulation of the optical carrier phase. This processor works with DSB modulation and allows for the use of a simple phase modulator.…”

Section: Reconfigurable Filtersmentioning

confidence: 99%

Programmable optical processor chips: toward photonic RF filters with DSP-level flexibility and MHz-band selectivity

et al. 2017

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Integrated optical signal processors have been identified as a powerful engine for optical processing of microwave signals. They enable wideband and stable signal processing operations on miniaturized chips with ultimate control precision. As a promising application, such processors enables photonic implementations of reconfigurable radio frequency (RF) filters with wide design flexibility, large bandwidth, and high-frequency selectivity. This is a key technology for photonic-assisted RF front ends that opens a path to overcoming the bandwidth limitation of current digital electronics. Here, the recent progress of integrated optical signal processors for implementing such RF filters is reviewed. We highlight the use of a low-loss, high-index-contrast stoichiometric silicon nitride waveguide which promises to serve as a practical material platform for realizing high-performance optical signal processors and points toward photonic RF filters with digital signal processing (DSP)-level flexibility, hundreds-GHz bandwidth, MHz-band frequency selectivity, and full system integration on a chip scale.

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“…PHTs have been practically realized via various methods, e.g. using fiber Bragg gratings (FBGs) [5][6][7], optical ring resonators [8] and planar Bragg gratings [9].…”

Section: Bragg Grating Based Integrated Photonic Hilbert Transformersmentioning

confidence: 99%