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Date Announced: 27 Dec 2016
Mach-Zehnder Design Enables Data Rates Approaching 10 Gigabits/sec and Provides Initial Demonstration of Polymer Photonics Integrated Circuits (P2ICs™) for Telecom and Datacom Applications.
LONGMONT, CO--(Marketwired - December 27, 2016) - Lightwave Logic, Inc. (OTCQB: LWLG), a technology company focused on the development of Next Generation Photonic Devices and Non-Linear Optical Polymer Materials Systems for applications in high-speed fiber-optic data communications and telecommunications, announced today it has achieved high-speed modulation in its first all-organic polymer ridge waveguide intensity modulator prototype.
A modulator converts electronic/digital information into pulses of light that can traverse fiber optic cables. Modulation is the central information-encoding technology for the Telecom, Datacom and Datacenter industries.
A Polymer Photonics Integrated Circuit is analogous to an electronic integrated circuit, but incorporates two or more optical functions integrated onto a single substrate platform. P2ICs™ are expected to experience a similar density trajectory as Moore's Law described for ICs where numerous photonic functions are integrated using polymer materials, which are scalable in low cost as well as high performance.
Tom Zelibor, Chairman and CEO of Lightwave Logic commented, "This is one of the most significant moments in the history of our great company. Our initial "alpha" prototype has exceeded our expectations. This device, enabled by our P2IC™ polymer system, has demonstrated bandwidth suitable for data rates up to about 10 Gbps, and we believe it can be extended to operate up to 25 Gbps, which is important to the optical networking industry because this data rate is a major node to achieve 100 Gbps (using 4 channels of 25 Gbps).
"Our development plan didn't anticipate attaining a 10 Gbps data rate until the first quarter of 2017, but due to exceptional engineering work, we were able to exceed this goal, and demonstrate true amplitude (intensity) modulation in a Mach-Zehnder modulator structure incorporating our polymer waveguides.
"I want to commend both our material and device development teams that worked tirelessly to successfully synthesize a commercially viable organic polymer system and then implement it in a high-speed working modulator prototype of our own proprietary design -- importantly, ahead of schedule.
"There is a lot more to do so we will now turn our efforts to push the data rate in subsequent iterations and optimize performance characteristics to meet or exceed industry benchmarks. The road to commercialization is necessarily paved with data and we now begin to collect device hard performance parameters that substantiate the power, reliability, and ultimately the value proposition of our P2IC™ technology to provide our growing list of interested parties.
"We anticipate that both a 10 Gbps device and ultimately a 25 Gbps device will generate industry attention as they squarely address a compact efficient solution for both today's 40 Gbps (4x10), and 100 Gbps (4x25) markets, and future higher performance markets."
Source: Lightwave Logic
E-mail: steve@lightwavelogic.com
Web Site: www.lightwavelogic.com
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