Design and Implementation of a Farrow-Interpolator-Based Digital Front-End in LTE Receivers for Carrier Aggregation

Chester Sungchung Park,Sunwoo Kim,Sungkyung Park,Jooho Wang

doi:10.3390/electronics10030231

Chester Sungchung Park, Sunwoo Kim + Show 2 more

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https://doi.org/10.3390/electronics10030231

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Journal: Electronics	Publication Date: Jan 20, 2021
Citations: 3	License type: CC BY 4.0

Affiliation: Konkuk University, Pusan National University

Abstract

A digital front-end decimation chain based on both Farrow interpolator for fractional sample-rate conversion and a digital mixer is proposed in order to comply with the long-term evolution standards in radio receivers with ten frequency modes. Design requirement specifications with adjacent channel selectivity, inband blockers, and narrowband blockers are all satisfied so that the proposed digital front-end is 3GPP-compliant. Furthermore, the proposed digital front-end addresses carrier aggregation in the standards via appropriate frequency translations. The digital front-end has a cascaded integrator comb filter prior to Farrow interpolator and also has a per-carrier carrier aggregation filter and channel selection filter following the digital mixer. A Farrow interpolator with an integrate-and-dump circuitry controlled by a condition signal is proposed and also a digital mixer with periodic reset to prevent phase error accumulation is proposed. From the standpoint of design methodology, three models are all developed for the overall digital front-end, namely, functional models, cycle-accurate models, and bit-accurate models. Performance is verified by means of the cycle-accurate model and subsequently, by means of a special C++ class, the bitwidths are minimized in a methodic manner for area minimization. For system-level performance verification, the orthogonal frequency division multiplexing receiver is also modeled. The critical path delay of each building block is analyzed and the spectral-domain view is obtained for each building block of the digital front-end circuitry. The proposed digital front-end circuitry is simulated, designed, and both synthesized in a 180 nm CMOS application-specific integrated circuit technology and implemented in the Xilinx XC6VLX550T field-programmable gate array (Xilinx, San Jose, CA, USA).

Highlights

The digital front-end (DFE) of a radio receiver is used to convert the sample rate of the analog-to-digital converter (ADC) and filter out the remaining interference after the radio frequency (RF) front-end filters serve the role of initial band and channel selection
Fractional sample-rate conversion (FSRC) can filter the desired signal more sharply than the cascaded integrator comb (CIC) filter or FIR1, which is plotted in Figure 15 [23]
Signal (c) that is the FSRC output is fed to the DM, which translates or relocates the carrier instead of suppressing interference

Summary

Introduction

The digital front-end (DFE) of a radio receiver is used to convert the sample rate of the analog-to-digital converter (ADC) and filter out the remaining interference after the radio frequency (RF) front-end filters serve the role of initial band and channel selection. The filtered signal channel from the DFE in the radio chip is typically passed over to the digital baseband processor or modem chip and at the same time the sample rate is reduced from the high ADC sample rate to acceptable rates for the baseband processor by means of downsampling in the DFE circuitry. This is in contrast to what is accomplished in the radio transmitter where upsampling or sample rate multiplication is carried out in the interpolation chain. A multirate subsampling front-end incorporates programmable digital decimation stages to accommodate variable bit rates in a software radio receiver in [2]

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Discussion

Conclusion