The microring circuit is designed to form the upstream and downstream quantum communications. There are one space and two-time functions applied to form the transmission. A circuit consists of 3 microring resonators, where there are three processes of each transmission. Firstly, the space function pulse (soliton) fed into the system via the main ring input port. The whispering gallery mode (WGM) is generated at the center ring with suitable parameters. The dipole oscillation is formed by the coupling between plasmonic wave and gold grating, which will change in the dipole oscillation frequency inducing the change in the plasmonic sensor. The flip-flop signals obtained from the bright and dark soliton via the throughput and drop ports can apply for the transmission clock signals. Secondly, the quantum codes formed by a time-energy function input into the system via a silicon ring, which induced the four-wave mixing induced by the coherent light in a GaAsInP ring, can be identified and the quantum bits(qubits) formed by the polarized signal orientation. The quantum information is multiplexed into the system. Thirdly, the carrier time function will input via the add port main ring. By using the resonant condition, the multiplexed signals of those processes will transmit via either WGM or throughput port for wireless or cable transmission, respectively. The downstream process is processed the same way as the upstream, where the multiplexer is placed by the de-multiplexer. By varying the input power, the manipulation result has shown the potential realistic application for quantum and telepathic communications.

微环电路被设计为形成上游和下游量子通信。应用一次空间和两次函数来形成传输。一个电路由3个微环谐振器组成，每个传输有3个过程。首先，空间功能脉冲（孤子）通过主环输入端口馈入系统。在中心环处使用合适的参数生成回音壁模式（WGM）。偶极子振荡是由等离子波和金光栅之间的耦合形成的，偶极子振荡频率的变化将引起等离子传感器的变化。通过吞吐量和分接端口从亮和暗孤子获得的触发器信号可以应用于传输时钟信号。其次，可以识别GaAsInP环并通过极化信号取向形成量子位（qubit）。量子信息被多路复用到系统中。第三，载波时间功能将通过添加端口主环输入。通过使用谐振条件，这些过程的多路复用信号将分别通过WGM或吞吐量端口传输，以进行无线或电缆传输。下游进程的处理方式与上游相同，其中多路复用器由解复用器放置。通过改变输入功率，操纵结果显示了在量子和心灵感应通信中的潜在现实应用。