Show
Sort by
-
Reconfigurable nonlinear nonreciprocal transmission in a silicon photonic integrated circuit
-
- Journal Article
- A1
- open access
Using backscattering and backcoupling in silicon ring resonators as a new degree of design freedom
-
- Journal Article
- A1
- open access
Backcoupling manipulation in silicon ring resonators
-
- PhD Thesis
- open access
Novel degrees of freedom for design of silicon microring resonators
(2018) -
Experimental demonstration of a single silicon ring resonator with an ultra-wide FSR and tuning range
-
- Journal Article
- A1
- open access
Tunable electromagnetically induced transparency in integrated silicon photonics circuit
-
- Conference Paper
- C1
- open access
Engineered reflections in silicon ring resonator : a new degree of freedom for design
-
- Journal Article
- A1
- open access
An actively controlled silicon ring resonator with a fully tunable Fano resonance
-
- Conference Paper
- P1
- open access
A novel approach to create a tunable fano resonance with an extinction ratio over 40 dB
-
- Conference Paper
- P1
- open access
Fundamentally cancel backscattering in silicon microrings
-
- Conference Paper
- C3
- open access
An integrated tunable reflector
-
- Journal Article
- A1
- open access
Fundamental suppression of backscattering in silicon microrings
-
- Conference Paper
- P1
- open access
Variability analysis of device-level photonics using stochastic collocation (Conference Presentation)
-
- Conference Paper
- P1
- open access
A simple and novel method to obtain an FSR free silicon ring resonator
-
Backscatter model for nanoscale silicon waveguides
-
Extreme spectral transmission fluctuations in silicon nanowires induced by backscattering
-
- Journal Article
- A1
- open access
Backscattering in silicon microring resonators: a quantitative analysis
-
- Journal Article
- A1
- open access
Stochastic collocation for device-level variability analysis in integrated photonics
-
Design of a single all-silicon ring resonator with a 150 nm free spectral range and a 100 nm tuning range around 1550 nm
-
A novel sensing scheme based on resonance splitting in silicon microrings