Single-mode glass waveguide platform for DWDM chip-to-chip interconnects

Brusberg, Lars; Schröder, Henning; Queisser, Marco; Lang, Klaus‐Dieter

doi:10.1109/ectc.2012.6249039

Cited by 15 publications

(3 citation statements)

References 8 publications

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“…Thus, cutting these wavelengths from the available spectrum to be used for control, would not degrade the system bandwidth. These five wavelengths will be negligible especially when Dense Wavelength Division Multiplexing (DWDM) is used providing up to 128 wavelengths per waveguide [52]. The wavelength assignment for each port is shown in Table 2.…”

Section: Non-blocking Photonic Switchmentioning

confidence: 99%

Hybrid silicon-photonic network-on-chip for future generations of high-performance many-core systems

Ahmed

Abdallah

2015

J Supercomput

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Photonic Networks-on-Chip (PNoCs) promise significant advantages over their electronic counterparts. In particular, they offer a potentially disruptive technology solution with fundamentally low power dissipation that remains independent of capacity while providing ultra-high throughput and minimal access latency.In conventional hybrid PNoC systems, several electrical control functions, such as path setup, acknowledgment and tear-down are necessary for the end-to-end optical transfer. However, the circuit-switched nature of photonic interconnect directly affects the performance and power characteristics of on-chip communication.In this paper, we propose an energy-efficient and high-throughput hybrid Silicon-Photonic Network-on-Chip, named PHENIC 1 , targeted for future generations of high-performance many-core systems. PHENIC is based on a smart contention-aware path configuration algorithm and an energy-efficient non-blocking optical switch to further exploit the low energy proprieties of the PNoC systems. Through detailed simulation, we demonstrate that the proposed system has a better performance and low energy dissipation compared to conventional hybrid PNoCs.

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Section: Non-blocking Photonic Switchmentioning

confidence: 99%

Hybrid silicon-photonic network-on-chip for future generations of high-performance many-core systems

Ahmed

Abdallah

2015

J Supercomput

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“…To fully exploit their potential however, efficient light coupling solutions are required, especially with Silicon photonics integrated components, which are favored by the industry for commercial exploitation due to their unparalleled small foot-print attributes and their compatibility with Complementary Metal Oxide Semiconductor (CMOS) technology that allows for cost-effective large-scale production. In order to overcome this prominent technological barrier, a variety of out of plane coupling schemes have already been proposed, including integrated mirrors and diffraction gratings, suffering however from fabrication-assembly difficulties, bandwidth limitations and high coupling losses [3] [4].…”

Section: Introductionmentioning

confidence: 99%

SiN-assisted flip-chip adiabatic coupler between SiPh and Glass OPCBs

et al. 2016

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We demonstrate, for the first time to our knowledge, a SiN-assisted in-plane adiabatic coupler between SiPh and onboard glass waveguides. Our numerical study is founded on an actual graded index glass waveguide developed by Fraunhofer-IZM. The Silicon taper profile and the optimal length are extracted employing the supermode theory and the adiabatic theorem. Fabrication and assembly issues are investigated, resulting to an optimized coupler design that exhibits a theoretical Si-to-glass loss below 0.1dB over the entire C-band. The proposed solution can be realized utilizing standard passive flip-chip assembly equipment and is, therefore, cost-effective, easy to be fabricated, and well-suited for compact packaging

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“…Nevertheless, cost-efficient production of meso-scale waveguides is inevitable to enable optical interconnects on the printed circuit board (PCB) level [1]. Predominant waveguide manufacturing technologies on PCB level are lithographically implemented in polymers [2][3][4] or glass-based by changing the refractive index with ion exchange [5][6][7][8]. These technologies can achieve low optical transmission losses; however, such technologies struggle with application challenges such as optical coupling, electro-optical alignment, packaging, thermal stability and mechanical requirements of PCBs [9][10][11].…”

Section: Introductionmentioning

confidence: 99%

Rotative printing processes for polymer waveguide manufacturing

Evertz,

Fütterer,

Fritze

et al. 2023

Optifab 2023

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Single-mode glass waveguide platform for DWDM chip-to-chip interconnects

Cited by 15 publications

References 8 publications

Hybrid silicon-photonic network-on-chip for future generations of high-performance many-core systems

Hybrid silicon-photonic network-on-chip for future generations of high-performance many-core systems

SiN-assisted flip-chip adiabatic coupler between SiPh and Glass OPCBs

Rotative printing processes for polymer waveguide manufacturing

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