news digest ♦ Telecoms


SMC is utilizing Skyworks’ wireless networking and ZigBee front-end solutions for security sensors, smoke alarms, motion detectors and touch pads.


“SMC is joining forces with Skyworks to deliver innovative solutions for the connected home,” says Max Brogi, vice president of product management at SMC Networks. “With MSOs in the United States and Canada making full-scale deployments this year, SMC sought to collaborate with the industry leader in analog solutions to deliver best-in-class, energy efficient products. Together with Skyworks’ front-end modules, SMC is creating platforms that integrate effortlessly with existing security systems and devices, operate and back up wirelessly, are easy to install, and give MSOs a great opportunity to present revenue-generating services to their customers.”


“Skyworks is pleased to be partnering with SMC, an industry leader in customer premise equipment for both residential and commercial applications,” comments Liam K. Griffin, executive vice president and corporate general manager at Skyworks. “As more and more devices within the home become connected, we look forward to a long and successful partnership with SMC to supply a wide range of wireless solutions and next- generation technologies addressing this enormous market opportunity.”


As cited in GSMA’s Vision of Smart Home: The Role of Mobile in the Home of the Future report, the combined revenue from the smart metering, home automation and home energy management segment is forecasted to generate more than $44 billion in 2016, according to market analyst companies ABI and Berg Insight. The overall revenue potential of the smart home is expected to be even higher as devices from the entertainment, health and home security sectors also become connected.


Skyworks’ Front-end Solutions


The SE2432L is a 2.4 gigahertz (GHz), high performance, fully integrated RF front-end module (FEM) designed for ZigBee® and smart-energy applications. Designed for ease-of-use and maximum flexibility, the FEM contains integrated, fully matched input baluns, integrated inter-stage matching and harmonic filter, and digital controls compatible with 1.6 – 3.6 volt (V) CMOS levels.


The RF blocks operate over a wide supply voltage range from 2.0 to 3.6 V, allowing the device to be used in battery-powered applications over a wide spectrum of the battery-discharge curve.


The SE5003L is a 5 GHz power amplifier (PA) offering high linear power for wireless local area network (WLAN) applications. Incorporating a power detector for closed-


98 www.compoundsemiconductor.net July 2013


loop monitoring and control of the output power, the PA contains high integration for a simplified design, providing quicker time-to-market and higher application board production yield.


The PA also integrates the input, inter-stage and output match and power detector with 15 dB of dynamic range and a 3.8 GHz notch filter. Only six external decoupling capacitors are required to complete the design. For WLAN applications, the device meets the requirements of IEEE 802.11a/n, and delivers approximately 23 dBm of linear power at 5 V. In addition, the PA integrates the reference voltage generator.


Pricing and Availability


Skyworks’ front-end solutions are currently available for both sampling and production. For volume pricing, please contact sales@skyworksinc.com.


Infinera to improve the Terabit era


The company is launching an intelligent based transport network to aid its indium phosphide (InP) based PIC customers


Infinera is launching an Intelligent Transport Network.


This is an architecture for carriers to exploit the increasing demand for cloud-based services and data centre connectivity as they advance into the Terabit Era.


The Terabit Era envisions a highly connected global community sharing experiences and doing business at light speed, delivered by an infinite pool of intelligent bandwidth.


The Intelligent Transport Network will help carriers use time as a weapon to increase revenues with reliable, differentiated services while reducing operating costs through scale, multi-layer convergence and automation.


In 2005, Infinera introduced the Digital Optical Network, an architecture based on the company’s 100 Gigabit per second (Gb/s) InP based Photonic Integrated Circuits (PICs). By integrating PICs into the DTN platform Infinera says it was the first firm to converge Optical Transport Network (OTN) switching and wavelength division multiplexing (WDM) in the same chassis.


Within 18 months of the DTN’s initial deployment Infinera led the highly competitive long-haul optical transport market in North America. The Intelligent Transport Network builds on the foundation of the Digital Optical


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