- Device family is first to enable digital ODUs that deliver 24-channel satellite video services to the home over a single coax cable
CARLSBAD, Calif. — (BUSINESS WIRE) — December 29, 2014 — MaxLinear Inc. (NYSE: MXL), a leading provider of integrated radio frequency (RF) and mixed-signal integrated circuits for broadband communications applications, today announced that it has started volume production shipments of its innovative MxL86x family of 24-channel, Full-Spectrum Capture™ (FSC™) band translation and channel stacking system on chip (SoC) devices.
The performance-leading devices, which have been adopted by key satellite outdoor unit (ODU) manufacturers, enable satellite operators to accelerate the transition from analog ODUs to higher-density digital channel-stacking ODUs. Digital channel stacking is a technology required for delivering the most advanced satellite multi-channel services to the home over a single coax cable. The devices are also suitable for multi-dwelling unit (MDU) switches.
The MxL86x SoCs feature a very high level of integration, ultra small size (10mm x 10mm) and the industry’s lowest power consumption. The parts replace complex, power-inefficient, multi-chip analog solutions that require expensive discrete radio-frequency filters, a separate microcontroller and additional FSK or DiSEqC ICs for communication between the set-top box (STB) and the ODU.
In contrast, the ultra-low power MxL86x single-chip solutions enable OEMs to introduce a new generation of compact, cost-effective and software-configurable digital ODU products to the market.
“Digital ODUs help satellite providers expand their multi-channel service offerings and simplify home installation via a single-cable solution from ODU to set-top box, which makes them a critical component of next-generation satellite infrastructure,” said Yves Rasse, MaxLinear’s Senior Product Line Director for Satellite and Terrestrial TV. “We’re shipping this product ahead of our internal schedule and before anyone in the industry, which cements MaxLinear’s leadership position in the high-density digital channel stacking market.”
The MxL86x family of digital channel stacking SoCs includes the MxL868, MxL865 and MxL862 each of which supports up to 10 GHz of RF capture bandwidth. These devices are based on MaxLinear’s ultra-low power Full-Spectrum Capture technology, and integrate a complete 24-channel digital stacking switch platform including DiSEqC and FSK communication modems and a microcontroller.
The MxL868 and MxL865 support multi-feed, low-noise block down-converter (LNB) applications. The MxL868 can be configured for either dual-band/triple-band translation or channel-stacking applications. The MxL862 is optimized for single-feed LNB applications and, combined with the wide-band MxL80x Ku-band down-converter, delivers a turnkey channel-stacking system solution that includes the protocol application software supporting the EN50494 and EN50607 single-cable standards.
The parts are packaged in a 10mm x 10mm QFN. Due to the MxL86x family’s high levels of system integration, the bill of material (BOM) is reduced to a minimal number of low-cost, passive components, which enables ultra-compact, low-cost system solutions when compared to existing analog implementations.
All MxL86x products are now available in production quantity. Product sales information is available from MaxLinear’s worldwide sales force or by emailing firstname.lastname@example.org.
About MaxLinear, Inc.
MaxLinear, Inc. is a leading provider of radio-frequency and mixed-signal semiconductor solutions for broadband communications applications. MaxLinear is headquartered in Carlsbad, California. For more information, please visit www.maxlinear.com.
MxL, Full-Spectrum Capture, FSC and the MaxLinear logo are trademarks of MaxLinear, Inc. Other trademarks appearing herein are the property of their respective owners.
Cautionary Note About Forward-Looking Statements
This press release contains forward-looking statements within the
meaning of the Private Securities Litigation Reform Act of 1995.
Forward-looking statements include, among others, statements concerning
or implying future financial performance or trends and growth
opportunities affecting MaxLinear and its products, in particular
statements relating to or implying continued volume shipments of the
MxL86x family of integrated circuits, continued adoption by satellite
ODU manufacturers of these products and their use in next-generation
satellite infrastructure, and MaxLinear’s continued leadership position
in the high-density digital channel stacking market. These
forward-looking statements involve known and unknown risks,
uncertainties, and other factors that may cause actual results to differ
materially from any future results expressed or implied by these
forward-looking statements. Forward-looking statements are based on
management’s current, preliminary expectations and are subject to
various risks and uncertainties, including (among others) intense
competition in our industry; the ability of our customers to cancel or
reduce orders; uncertainties concerning how end user markets for our
products will develop; our lack of long-term supply contracts and
dependence on limited sources of supply; potential decreases in average
selling prices for our products; currently pending intellectual property
litigation; and the potential for additional intellectual property
litigation, which is prevalent in our industry. In addition to these
risks and uncertainties, investors should review the risks and
uncertainties contained in MaxLinear’s filings with the United States
Securities and Exchange Commission, including risks and uncertainties
identified in our Quarterly Report on Form 10-Q for the quarter ended
September 30, 2014. All forward-looking statements are qualified in
their entirety by this cautionary statement. MaxLinear is providing this
information as of the date of this release and does not undertake any
obligation to update any forward-looking statements contained in this
release as a result of new information, future events, or otherwise.