This paper explores a cooperative molecular communication (MC) system with imperfect transmitters, where information is encoded on the types of molecules. The transmitters consist of two reservoirs containing different types of molecules, and free energy is consumed to move molecules between the reservoirs, creating concentration differences for information encoding.
The key highlights and insights are:
The performance of the transmitters is primarily influenced by the energy costs, which directly impact the overall system performance. To address this, the paper focuses on optimizing the energy allocation among the transmitters to enhance their performance.
For a two-user scenario, the paper provides a theoretical analysis to show that the optimal energy allocation is achieved when the energy is equally distributed between the two transmitters.
For scenarios with more than two users, a genetic algorithm is employed to determine the optimal energy allocation strategy that minimizes the total bit error rate (BER) across all transmitters.
Numerical results demonstrate the effectiveness of the proposed energy allocation strategies in improving the BER performance of the considered cooperative MC system.
The study reveals a crucial thermodynamic tradeoff between BER and the size of the reservoirs, including the number of molecules in the reservoirs and the transmitted molecules.
The comprehensive analysis and the proposed energy allocation strategies provide valuable insights for designing more efficient cooperative MC systems under energy constraints.
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by Dongliang Ji... kl. arxiv.org 04-04-2024
https://arxiv.org/pdf/2404.02286.pdfDybere Forespørgsler