SAN JOSE, Calif. – Small cell base stations are quietly moving from trials to real world deployments, thanks in part to a new class of SoCs. Small cells represent a new class of base stations that help carriers cost effectively handle the flood of mobile data.
Carriers are “moving beyond trials to deployments with public access use cases--we see examples from around the world,” said Gordon Mansfield, chairman of the Small Cell Forum, citing work in Korea with LTE and in Europe with Vodafone and partnerships with retailers.
In the U.S., AT&T has moved beyond trials and early projects—the “crawl and walk phases…to the run phase where we are opening up to use cases and I expect a pretty significant growth in numbers month over month,” said Mansfield who also serves as executive director of small cell solutions and radio access network delivery at AT&T Mobility.
“I can’t be specific yet about some of the types of areas” for AT&T deployments of small cells, but “hopefully we’ll talk about that in the near future,” he said. “Generally all of our use cases have been vetted in various trials and pilots, we have a couple outdoor [deployments] up and running and are evolving the use cases,” he added.
Sprint and Verizon are “starting their early test activities based on public statements they have made,” he said. The Forum is working to develop realistic worldwide shipment figures for small cells amid a wide variety of numbers from analyst reports.
Offering free small cell base stations to users in areas with poor cell phone coverage in exchange for allowing access by outsiders would seem to be a win-win program. We've all experienced the countless dead spaces that we'd love to see filled in.
Rick, have you heard any more about the Alcatel-Lucent (SOI-based) solution (w/Freescale) they showed at Barcelona a couple years ago? (see http://www.advancedsubstratenews.com/2011/02/topple-the-towers-freescales-soi-soc-in-alcatel-lucents-lightradio/)
Millimeter Waves are the highest band of radio waves and operate at a frequency range of 20-300 GHz. The radio waves in this band have wavelengths that are in order of millimeters (mm), which is why the waves in this band are called millimeter waves, abbreviated as MM Waves. In wireless communications, frequency is one of the major factors that ascertain the feasibility of the technology.
The global millimeter wave market is expected to reach $116 million by end of 2013 and is expected to grow to cross $1.1 billion in 2018 at a CAGR of 59.1%. Similarly volumes are estimated to grow from 11.8 thousand units to more than 360 thousand units in 2018. This growth is heralded by the expected by the growing telecom application market for millimeter wave especially in the small cell back haul field. The millimeter wave scanner market is also expected to grow rapidly in the coming five years. For further details, may write at - firstname.lastname@example.org
David Patterson, known for his pioneering research that led to RAID, clusters and more, is part of a team at UC Berkeley that recently made its RISC-V processor architecture an open source hardware offering. We talk with Patterson and one of his colleagues behind the effort about the opportunities they see, what new kinds of designs they hope to enable and what it means for today’s commercial processor giants such as Intel, ARM and Imagination Technologies.