Biomedical tasks in a physiological medium (blood) by nanoscopic programmable matters can be coordinated and executed efficiently by realizing a communication channel to and from the outside of the body. In this paper, we discuss the feasibility of self synchronized radio communication between nanorobots in the physiological medium. We present a magnetic-based method for synchronization, analysis, and a simulation for a previously designed carbon nanotube (CNT) based cantilever device, oscillating due to an electrostatic force to emit radio signals. A magnetic field can modify the electrostatic force, which induces the communicating cantilever device. A resultant magnetic field emitted from every nanorobot to its neighbors is suggested as a means for self-synchronization, where the sum of mutual influences gradually self synchronize the radio signals to form an in-phase higher amplitude strong signal. In another design, an external magnetic field is applied for a long enough per...

中文翻译：

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迈向In-Vivo纳米机器人的无线电通信同步

通过实现往返于身体外部的通信通道，可以有效地协调和执行由纳米级可编程物质在生理介质（血液）中进行的生物医学任务。在本文中，我们讨论了纳米机器人在生理介质中进行自同步无线电通信的可行性。我们介绍了一种基于磁的方法，用于对先前设计的基于碳纳米管（CNT）的悬臂设备进行同步，分析和仿真，该方法由于静电力而振荡，从而发出无线电信号。磁场可以改变静电力，从而感应出连通的悬臂装置。建议将每个纳米机器人发射到其邻居的合成磁场作为自同步的一种手段，相互影响的总和逐渐使无线电信号自同步，以形成同相的更高幅度的强信号。在另一种设计中，外部磁场施加的时间要足够长。