A Low-Voltage 35-GHz Silicon Photonic Modulator-Enabled 112-Gb/s Transmission System

Samani, Alireza; Chagnon, Mathieu; Patel, David; Veerasubramanian, Venkat; Ghosh, Samir; Osman, Mohamed; Zhong, Qiuhang; Plant, David V.

doi:10.1109/jphot.2015.2426875

Cited by 87 publications

(47 citation statements)

References 27 publications

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“…10a. This discrepancy was also observed in others' works [12,14]. In the subsection of large-signal analysis, effects of this error on the extinction ratio of the modulator are investigated.…”

Section: B DC Performancesupporting

confidence: 66%

“…Coplanar waveguide (CPW) and coplanar strip (CPS) transmission line (TML) are commonly used as traveling-wave electrodes for high-speed modulators [11][12][13][14][15]. The CPS is considered in this case as our traveling wave electrode because of its compact geometry in comparison to CPW.…”

Section: Tw Electrodementioning

confidence: 99%

“…The CPS is considered in this case as our traveling wave electrode because of its compact geometry in comparison to CPW. To maximize the bandwidth of a TW modulator, the following should be respected: (1) mismatch between the optical group velocity and RF group velocity should be minimized; (2) characteristic impedance of the electrode loaded by p-n-junction should match the input and output impedance of RF ports, typically 50 Ω; and (3) modulator RF losses should be minimized [12,14].…”

Section: Tw Electrodementioning

confidence: 99%

“…The maximum unloaded microwave effective index, nRF,u achievable in a CPS transmission line on SOI, without slowing down RF, is around 2.4, much lower than no,g [12]. Because of the very low dispersion in a transmission line, the difference between RF phase velocity and RF group velocity is negligible [12,14]. Hence we focus on slowing the RF phase velocity to force nRF,L to approach no,g.…”

Section: A Group Velocity Match Between Rf and Opticmentioning

confidence: 99%

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Time-Domain Large-Signal Modeling of Traveling-Wave Modulators on SOI

Bahrami

Sepehrian

Park

et al. 2016

J. Lightwave Technol.

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Abstract-Silicon photonic modulators have strong nonlinear behavior in phase modulation and frequency response, which needs to be carefully addressed when they are used in high-capacity transmission systems. We demonstrate a comprehensive model for depletion-mode Mach-Zehnder modulators (MZMs) on silicon-on-insulator, which provides a bridge between device design and system performance optimization. Our methodology involves physical models of p-n-junction phase-shifters and traveling-wave electrodes, as well as circuit models for the dynamic microwave-light interactions and time-domain analysis. Critical aspects in the transmission line design for high-frequency operation are numerically studied for a case of p-n-junction loaded coplanar-strip electrode. The dynamic interaction between light and microwave is simulated using a distributed circuit model solved by the finite-difference time-domain method, allowing for accurate prediction of both small-signal and large-signal responses. The validity of the model is confirmed by the comparison with experimental results for a series push-pull MZM with a 6 mm phase shifter. The simulation shows excellent agreement with experiment for high-speed operation up to 46 Gbps. We show that this time-domain model can well predict the impact of the nonlinear behavior on the large-signal response, in contrast to the poor prediction from linear models in the frequency domain.

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Section: B DC Performancesupporting

confidence: 66%

Section: Tw Electrodementioning

confidence: 99%

Section: Tw Electrodementioning

confidence: 99%

Section: A Group Velocity Match Between Rf and Opticmentioning

confidence: 99%

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Time-Domain Large-Signal Modeling of Traveling-Wave Modulators on SOI

Bahrami

Sepehrian

Park

et al. 2016

J. Lightwave Technol.

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“…Different doping profiles and concentrations are used. The pn-diode in the optical waveguide can be designed in vertical direction (Liao et al, 2007;Azadeh et al, 2015b), lateral direction (Samani et al, 2015;Tu et al, 2014;Wang et al, 2013) or with interdigitated doping patterns (Xu et al, 2012;Hao Xu et al, 2014;Giesecke et al, 2016). Some important figures of merit of the modulator and geometry dimensions of the published devices are presented in Table 1 and compared with the results of this work.…”

Section: Comparison With Other Technologiesmentioning

confidence: 99%

Design of a carrier-depletion Mach-Zehnder modulator in 250 nm silicon-on-insulator technology

Rosa¹,

Rathgeber

Elster

et al. 2017

Adv. Radio Sci.

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Abstract. We present the design of a single-drive MachZehnder modulator for amplitude modulation in silicon-oninsulator technology with 250 nm active layer thickness. The applied RF signal modulates the carrier density in a reverse biased lateral pn-junction. The free carrier plasma dispersion effect in silicon leads to a change in the refractive index. The modulation efficiency and the optical loss due to free carriers are analyzed for different doping configurations. The intrinsic electrical parameters of the pn-junction of the phase shifter like resistance and capacitance and the corresponding RC-limit are studied. A first prototype in this technology fabricated at the IMS CHIPS Stuttgart is successfully measured. The structure has a modulation efficiency of V π L = 3.1 V·cm at 2 V reverse bias. The on-chip insertion loss is 4.2 dB. The structure exhibits an extinction ratio of around 32 dB. The length of the phase shifter is 0.5 mm. The cutoff frequency of the entire modulator is 30 GHz at 2 V. Finally, an optimization of the doping structure is presented to reduce the optical loss and to improve the modulation efficiency. The optimized silicon optical modulator shows a theoretical modulation efficiency of V π L = 1.8 V·cm at 6 V bias and a maximum optical loss due to the free carrier absorption of around 3.1 dB cm −1 . An ultra-low fiber-to-fiber loss of approximately 4.8 dB is expected using the state of the art optical components in the used technology.

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Radio‐Frequency Linear Analysis and Optimization of Silicon Photonic Neural Networks

Blow,

Bilodeau,

Zhang

et al. 2024

Advanced Photonics Research

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Broadband analog signal processors utilizing silicon photonics have demonstrated a significant impact in numerous application spaces, offering unprecedented bandwidths, dynamic range, and tunability. In the past decade, microwave photonic techniques have been applied to neuromorphic processing, resulting in the development of novel photonic neural network architectures. Neuromorphic photonic systems can enable machine learning capabilities at extreme bandwidths and speeds. Herein, low‐quality factor microring resonators are implemented to demonstrate broadband optical weighting. In addition, silicon photonic neural network architectures are critically evaluated, simulated, and optimized from a radio‐frequency performance perspective. This analysis highlights the linear front‐end of the photonic neural network, the effects of linear and nonlinear loss within silicon waveguides, and the impact of electrical preamplification.

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A Low-Voltage 35-GHz Silicon Photonic Modulator-Enabled 112-Gb/s Transmission System

Cited by 87 publications

References 27 publications

Time-Domain Large-Signal Modeling of Traveling-Wave Modulators on SOI

Time-Domain Large-Signal Modeling of Traveling-Wave Modulators on SOI

Design of a carrier-depletion Mach-Zehnder modulator in 250 nm silicon-on-insulator technology

Radio‐Frequency Linear Analysis and Optimization of Silicon Photonic Neural Networks

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A Low-Voltage 35-GHz Silicon Photonic Modulator-Enabled 112-Gb/s Transmission System

Cited by 87 publications

References 27 publications

Time-Domain Large-Signal Modeling of Traveling-Wave Modulators on SOI

Time-Domain Large-Signal Modeling of Traveling-Wave Modulators on SOI

Design of a carrier-depletion Mach-Zehnder modulator in 250 nm silicon-on-insulator technology

Radio‐Frequency Linear Analysis and Optimization of Silicon Photonic Neural Networks

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Design of a carrier-depletion Mach-Zehnder modulator in 250 nm silicon-on-insulator technology