MultiPhy is a fast growing semiconductor company providing next generation ICs at 100G speeds for Metro and Data Center connections. Our patented technology enables large amounts of data to pass through optical networks fast and efficiently setting new benchmarks for cost and performance.
Todays’ era of big data needs are causing bandwidth demands to boom and traffic congestion across networks. Social networks, video streaming operators, search engine providers and telecom companies alike are investing massively in infrastructure to carry these complex types of traffic, undergoing a rapid transformation from traditional 10G networks to 100G and 400G. This transition is enabled by a paradigm shift in disruptive technologies of digital signal processing (DSP) for optical communication achieving the required speeds while benefiting from the semiconductors economies of scale.
MultiPhy’s talented team of multidisciplinary experts in DSP optical communications, high speed digital design and analog design, have created differentiated technology that redefines cost effective, high-performance solutions at 100G, 400G and beyond for next-generation networks.
DSP-based Integrated Circuits for Optical Communications
This product profile describes the properties and applications of the ProMetric® I-SC Solution Imaging Colorimeter.
The Filmetrics F20 benchtop film thickness measurement tool is a general purpose instrument for measuring thickness and refractive index.
Dynamic characterization of MEMs devices is achieved by Micro System Analyzer MSA-650 IRIS.
Dr. Keith Paulsen
AZoOptics speaks to Dr. Keith Paulsen about the importance of breast cancer detection and the introduction of his team's deep-learning algorithm that associates spatial images of tissue optical properties with optical signal patterns measured during an imaging experiment or patient exam.
Prof. Simon Scheuring & Dr. Alma P. Perrino
AZoOptics speaks to Prof. Simon Scheuring & Dr. Alma P. Perrino about their recent research using a new line-scanning high-speed atomic force microscopy technique. The method helps characterize the single-molecule kinetics of wild-type bR (bR-WT) exposed to continuous light and short light pulses.
R. Bruce Weisman
AZoOptics interviews R. Bruce Weisman from Rice University in Texas, US, who has discovered fluorescence from silicon nanoparticles in cement and how it can be used to reveal early signs of damage in concrete structures.