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insight - Wireless Communications - # OTFS Channel Estimation and Detection for Overspread Channels

Efficient Channel Estimation and Detection for Orthogonal Time Frequency Space (OTFS) in Overspread Wireless Channels


Conceitos essenciais
This paper proposes a two-stage channel estimation scheme and a modified low-complexity maximum ratio combining (MRC) detection algorithm for OTFS systems operating in overspread wireless channels with very large delay spread.
Resumo

The paper addresses the challenge of channel estimation and detection for OTFS systems in overspread wireless channels, where the delay spread exceeds the block duration in the transmission frame.

The key highlights are:

  1. Proposed a two-stage channel estimation (CE) scheme:

    • The first stage uses an embedded pilot in the delay-Doppler (DD) domain to estimate the aliased delays and Doppler shifts, and identifies underspread paths not coinciding with overspread ones.
    • The second stage employs time-domain dual chirp correlation to estimate the actual delays and Doppler shifts of the remaining paths, resolving ambiguity in estimating delays and Doppler shifts for paths sharing the same aliased delay.
  2. Presented a modified low-complexity MRC detection algorithm for reduced zero-padded OTFS (RZP-OTFS) in overspread channels.

  3. Analyzed the complexity of the proposed CE and MRC detection schemes.

  4. Evaluated the performance of the proposed CE and MRC detection in terms of normalized mean square error (NMSE) and bit error rate (BER) for different synthetic and practical overspread channel models.

The proposed two-stage CE and modified MRC detection demonstrate reliable performance in overspread channels, outperforming existing methods designed for underspread channels.

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Estatísticas
The delay spread of the channel exceeds the block duration in the OTFS frame. The maximum normalized delay lmax = 2400. The maximum normalized Doppler shift kmax = 16.
Citações
"In low latency applications and in general, for overspread channels, channel delay spread is a large percentage of the transmission frame duration." "Increasing the duration of a block (or decreasing subcarrier spacing) to meet the underspread condition on maximum delay spread of the channel would require to increase the number of subcarriers. As a consequence, the number of blocks must decrease to satisfy the low latency constraint on the fixed frame duration. However, decreasing such a number reduces the maximum allowable channel Doppler spread."

Perguntas Mais Profundas

How can the proposed two-stage channel estimation and modified MRC detection be extended to handle overspread Doppler shifts in addition to overspread delays

To extend the proposed two-stage channel estimation and modified MRC detection to handle overspread Doppler shifts, we can incorporate additional processing steps in the algorithms. For the channel estimation, we can modify the first stage to include a Doppler estimation component along with the delay estimation. This would involve analyzing the frequency components in the received signal to estimate the Doppler shifts associated with each path. By incorporating Doppler estimation techniques such as autocorrelation or frequency domain analysis, we can accurately estimate the Doppler shifts even in overspread scenarios. In the second stage, the chirp correlation method can be enhanced to handle overspread Doppler shifts. By considering the impact of Doppler on the correlation between the received signal and the transmitted chirps, we can refine the estimation of delays and Doppler shifts for each path. This refinement process can help resolve ambiguities and improve the accuracy of the channel parameter estimates. For the modified MRC detection, we can adjust the combining weights based on the estimated Doppler shifts. By weighting the contributions from each diversity branch according to the Doppler shifts, the MRC detector can effectively mitigate the effects of overspread Doppler shifts and enhance the detection performance in such challenging conditions.

What are the potential trade-offs between the complexity and performance of the proposed schemes compared to other detection algorithms like message passing algorithm (MPA) and its variants

The proposed schemes offer a trade-off between complexity and performance compared to other detection algorithms like message passing algorithm (MPA) and its variants. In terms of complexity, the proposed two-stage channel estimation method may introduce additional computational overhead due to the iterative nature of the algorithm and the refinement steps. However, this complexity is justified by the improved accuracy in estimating channel parameters for overspread channels, leading to enhanced detection performance. The modified MRC detection algorithm, although designed for reduced complexity, may require additional processing steps to handle overspread channels effectively. This could slightly increase the computational load compared to traditional MRC detection. However, the trade-off lies in the improved detection performance and robustness in challenging channel conditions. In contrast, MPA and its variants offer excellent performance but come with higher complexity, especially with increasing modulation order. The computational burden of MPA grows significantly with the modulation order, making it less suitable for real-time applications or systems with limited processing capabilities. Overall, the proposed schemes strike a balance between complexity and performance, providing a practical solution for overspread channel estimation and detection.

Can the dual chirp-based channel estimation approach be applied to other modulation schemes beyond OTFS to handle overspread channel conditions

The dual chirp-based channel estimation approach can be adapted to handle overspread channel conditions in other modulation schemes beyond OTFS by leveraging the inherent properties of the modulation scheme. For modulation schemes with similar delay-Doppler characteristics as OTFS, such as generalized frequency division multiplexing (GFDM) or universal filtered multicarrier (UFMC), the dual chirp sequence can be tailored to match the specific properties of the modulation scheme. By designing chirp sequences that align with the modulation's time-frequency characteristics, the channel estimation can be optimized for overspread channels. Additionally, for more traditional modulation schemes like orthogonal frequency-division multiplexing (OFDM) or single-carrier frequency-division multiple access (SC-FDMA), the dual chirp approach can be adapted by considering the specific signal processing requirements of these schemes. By customizing the chirp sequences and correlation methods to suit the modulation scheme's characteristics, overspread channel estimation can be effectively implemented. Overall, the dual chirp-based channel estimation technique is versatile and can be tailored to various modulation schemes by adapting the chirp design and correlation algorithms to match the unique features of each scheme.
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