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Do Ambient Backscatter Communication Receivers Require Low-Noise Amplifiers?

Xinyi Wang, Yuxin Li, Yinghui Ye, Gongpu Wang, Guangyue Lu

Abstract

In ambient backscatter communication (AmBC), strong direct interference from the ambient source poses a major challenge to reliable symbol detection. Although previous studies have shown that employing a low-noise amplifier (LNA) in conventional point-to-point communication improves symbol detection performance at low-to-moderate transmission power, it remains unclear whether this improvement also holds for AmBC. To respond it, in this work, we investigate the symbol detection performance of an AmBC receiver that is equipped with an LNA and adopts the energy detection (ED) to recover tag's information. Particularly, we first propose a new AmBC symbol detection framework that incorporates LNA parameters. On this basis, we derive the bit error rate (BER) of the ED and employ the deflection coefficient (DC) to demonstrate that the detection performance can be enhanced by the LNA at low-to-moderate ambient source transmission power. Then, we derive the near-optimal detection threshold to minimize the BER and propose a method to estimate the required parameters for this threshold by leveraging the tag's pilot symbols.

Do Ambient Backscatter Communication Receivers Require Low-Noise Amplifiers?

Abstract

In ambient backscatter communication (AmBC), strong direct interference from the ambient source poses a major challenge to reliable symbol detection. Although previous studies have shown that employing a low-noise amplifier (LNA) in conventional point-to-point communication improves symbol detection performance at low-to-moderate transmission power, it remains unclear whether this improvement also holds for AmBC. To respond it, in this work, we investigate the symbol detection performance of an AmBC receiver that is equipped with an LNA and adopts the energy detection (ED) to recover tag's information. Particularly, we first propose a new AmBC symbol detection framework that incorporates LNA parameters. On this basis, we derive the bit error rate (BER) of the ED and employ the deflection coefficient (DC) to demonstrate that the detection performance can be enhanced by the LNA at low-to-moderate ambient source transmission power. Then, we derive the near-optimal detection threshold to minimize the BER and propose a method to estimate the required parameters for this threshold by leveraging the tag's pilot symbols.
Paper Structure (10 sections, 16 equations, 5 figures, 1 table)

This paper contains 10 sections, 16 equations, 5 figures, 1 table.

Table of Contents

  1. Introduction
  2. System Model
  3. Signal Model Without LNA
  4. Signal Model with LNA
  5. Performance of an ED with LNA
  6. BER Performance with LNA Integration
  7. Theoretical Analysis of LNA-Induced Performance Gain
  8. Threshold Required Parameters Estimation
  9. Simulation Results
  10. Conclusions

Figures (5)

  • Figure 1: A three-node ambient backscatter system.
  • Figure 2: Architecture of a conventional AmBC receiver.
  • Figure 3: Architecture of the AmBC receiver with an LNA.
  • Figure 4: BER performance under different ambient source power levels and link quality conditions.
  • Figure 5: Relative approximation error versus number of pilot symbols.