Abstract

The data link from the detectors to the back-end stage must keep up with the requirements from the upcoming generation of High Energy Physics experiments. Last year, we presented at TWEPP the investigation on the feasibility and limitation of high data-rate links based on the 4-Level Pulse-Amplitude Modulation (PAM4) technology. Commercial PAM4 technology poses strict constraints on the data rate of links which translates into a highly complex rad-hard SerDes design. Alternatively, pushing the limit of the Non-Return to Zero (NRZ) modulated signals, a line rate of up to 28 Gbps can be realized. This is less constraining thanks to the possibility of bypassing retimers of NRZ modules. As a part of the Work Package 6 of the CERN EP Research and Development programme, the feasibility as well as the availability in the telecom and datacom market of such NRZ links have been investigated. The rate of 25.65 Gbps per lane (an integer multiplication of the 40.0798 MHz Bunch Clock) with NRZ modulation have been identified as the target for the next generation of detector-to-backend links. The Demonstrator ASIC for Radiation-Tolerant Transmitter in 28 nm (DART28) chip, designed at 28 nm and targeting high-radiation hardness, is currently being designed at this data rate with a custom protocol and a Reed-Solomon Forward Error Correction (FEC). A proof-of-concept on FPGA emulating the DART28 protocol has been built for early evaluation. The system uses commercially available optoelectronics transceivers and FPGA platforms to implement the DART28 data path containing a scrambler, interleaver and FEC. The VCU129 Xilinx Virtex Ultrascale+ and Intel Stratix 10 evaluation boards were used for this work. In this paper, the implementation of the demonstrator systems will be presented. The performance characteristic of these links will be discussed and the FEC performance will be compared to that of an ideal model.

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