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We demonstrate a single-chip, monolithically integrated, dual-polarization QPSK transmitter which combines over 1700 functions and is capable of delivering 2.25 Tb/s of bandwidth.
A dual-polarization QPSK transmitter is demonstrated with a record 40 tunable distributed feedback lasers, 80 nested Mach-Zehnder-modulators, and other elements totaling over 1700 functions monolithically integrated on a single InP-based chip that is capable of delivering 2.25 Tb/s.
A monolithic dual-polarisation quadrature phase shift keying transmitter is demonstrated for operation at 2.25 Tbit/s over 40 wavelengths and 1 THz of spectral bandwidth. The single-chip InP-based transmitter employs 40 tunable distributed feedback lasers, 80 nested Mach-Zehnder modulators and other elements to provide more than 1700 integrated photonic functions.
We will present state of the art performance of monolithically integrated 500 Gb/sec and 1 Tb/s coherent transmitter and receiver PICs with integrated multi-channel tunable laser arrays optimized for coherent transmission.
In this talk, we report on a pair of monolithically integrated multi-wavelength transmitter and receiver PICs employing polarization multiplexing and quadrature phase-shift keying modulation to provide an aggregate bandwidth greater than 1Tbps on a single chip.
We present an overview of Infinera's current generation of 100 Gb/s transmitter and receiver PICs as well as results from the next-generation 500 Gb/s PM-QPSK PICs.
A 10-wavelength, polarization-multiplexed, monolithically integrated InP transmitter PIC is demonstrated for the first time to operate at 112 Gb/s per wavelength with a coherent receiver PIC.
We report on the current state of large-scale and high functionality photonic integrated circuits on the InP platform for transmitters, receivers, and other device applications.
We report on the current state of large-scale and high functionality photonic integrated circuits on the InP platform for transmitters, receivers, and other device applications.
We report on development of large-scale and high functionality photonic integrated circuits on InP and Si platforms for transmitter, receiver, filtering and routing applications and discuss the merits of both platform.
We report the first demonstration of a large-scale InP-based transmitter photonic integrated circuit (PIC) capable of 10-channel times 40 Gb/s per wavelength polarization-multiplexed RZ-DQPSK modulation.
We will review the latest performance metrics for components enabling communication networks based on phase modulation formats. For spectral efficiency, reduced complexity, reliability, and power consumption; monolithic integration on InP is clearly the superior path.
We review progress in the area of InP large scale photonic integrated circuits (LS-PICs). We will review transmitter and receiver PICs for digital optical networking.
We review our work on high density, monolithically integrated, dense wavelength division multiplexed, monolithic, InP transmitter and receiver photonic integrated circuits (DWDM PIC) capable of operating at aggregate data rates of up to 1.6 Tbit/s per chip.
We demonstrate 100-Gbps tunable transmitter (Tx) and receiver (Rx) photonic integrated circuits (PICs) with minimal performance penalties over a 150 GHz tuning range.
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