Concetti Chiave
The proposed cellular molecular communication receiver architecture utilizes chemical reaction networks to perform adaptive symbol detection and synchronization, enabling reliable communication in unknown or time-varying channels without relying on external computational units.
Sintesi
The paper presents a cellular molecular communication receiver (RX) design that addresses the implementation gap between theoretical receiver designs and the limited computational capabilities of synthetic cells. The key aspects of the proposed RX are:
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Detector Design:
- Two detector implementations are proposed - a machine learning-based detector and an adaptive detector.
- The machine learning-based detector uses a Boltzmann machine model that is trained offline and implemented using chemical reaction networks (CRNs).
- The adaptive detector has lower complexity and can be trained online using pilot symbols to adapt to unknown or time-varying channel conditions.
- Both detectors possess the MAP property, enabling reliable symbol detection.
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Synchronization:
- The RX uses internal chemical timing mechanisms and external synchronization signals to coordinate the different computation steps involved in symbol detection and training.
- This allows the RX to seamlessly process a stream of received symbols without relying on external computational units.
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Validation:
- Extensive stochastic simulations confirm the feasibility of the proposed CRN-based RX designs and their ability to achieve competitive bit error rate performance compared to the maximum a-posteriori detector.
The modular design and exclusive chemical implementation of the proposed RX contribute towards the realization of versatile and biocompatible nano-scale communication networks for Internet of Bio-Nano Things applications.
Statistiche
The number of receptors at the receiver is denoted by nr.
The optimal detection threshold is denoted by νMAP.
Citazioni
"To enable this communication, numerous receiver (RX) and transmitter (TX) designs have been proposed in the MC literature and several works studied the communication performance of optimal and sub-optimal RXs (e.g., [5]–[7])."
"However, to unleash the full potential of MC, e.g., for IoBNT applications, the required computations need to be performed locally, e.g., inside the synthetic cells acting as the MC RXs. So far, there exists a large implementation gap for such cellular MC systems that results from a severe mismatch between the computational requirements of the theoretical RX designs proposed by communication engineers and the capabilities of synthetic cellular RXs that were realized in existing testbeds [12]."