A Cost‐Effective 40‐Gb/s ROSA Module Employing Compact TO‐CAN Package

In this paper, we present an implemented serial 40‐Gb/s receiver optical subassembly (ROSA) module by employing a proposed TO‐CAN package and flexible printed circuit board (FPCB). The TO‐CAN package employs an L‐shaped metal support to provide a straight line signal path between the TO‐CAN package and the FPCB. In addition, the FPCB incorporates a signal line with an open stub to alleviate signal distortion owing to an impedance mismatch generated from the soldering pad attached to the main circuit board. The receiver sensitivity of the ROSA module measures below –9 dBm for 40 Gb/s at an extinction ratio of 7 dB and a bit error rate of 10^?12.     

Design and Implementation of Open‐Loop Clock Recovery Circuit for 39.8 Gb/s and 42.8 Gb/s Dual‐Mode Operation

This paper proposes an open‐loop clock recovery circuit (CRC) using two high‐Q dielectric resonator (DR) filters for 39.8 Gb/s and 42.8 Gb/s dual‐mode operation. The DR filters are fabricated to obtain high Q‐values of approximately 950 at the 40 GHz band and to suppress spurious resonant modes up to 45 GHz. The CRC is implemented in a compact module by integrating the DR filters with other circuits in the CRC. The peak‐to‐peak and RMS jitter values of the clock signals recovered from 39.8 Gb/s and 42.8 Gb/s pseudo‐random binary sequence (PRBS) data with a word length of 2³¹?1 are less than 2.0 ps and 0.3 ps, respectively. The peak‐to‐peak amplitudes of the recovered clocks are quite stable and within the range of 2.5 V to 2.7 V, even when the input data signals vary from 150 mV to 500 mV. Error‐free operation of the 40 Gb/s‐class optical receiver with the dual‐mode CRC is confirmed at both 39.8 Gb/s and 42.8 Gb/s data rates.     

A 40 Gb/s Clock and Data Recovery Module with Improved Phase‐Locked Loop Circuits

A 40 Gb/s clock and data recovery (CDR) module for a fiber‐optic receiver with improved phase‐locked loop (PLL) circuits has been successfully implemented. The PLL of the CDR module employs an improved D‐type flip‐flop frequency acquisition circuit, which helps to stabilize the CDR performance, to obtain faster frequency acquisition, and to reduce the time of recovering the lock state in the event of losing the lock state. The measured RMS jitter of the clock signal recovered from 40 Gb/s pseudo‐random binary sequence (2³¹‐1) data by the improved PLL clock recovery module is 210 fs. The CDR module also integrates a 40 Gb/s D‐FF decision circuit, demonstrating that it can produce clean retimed data using the recovered clock.