The Frequency Shift Keying (FSK) dual-transmission mode for short-range communication using the silicon microring resonator arrangement is proposed. FSK generated by an optical modified add-drop multiplexer embedded gold grating connected to three other microring resonators. The proposed system consists of a transmitted microring with two nano-ring phase modulators, which connected through a 10 km fiber channel to a receiver. The user end consists of three similar microring systems. A gold grating embedded on two side ring center (sensor probe) to introduce the plasmonic polariton, from which each of sensor probe identified by the Bragg wavelength. The frequency of n photonic oscillator is in the range of plasmonic frequencies, where the Whispering Gallery Mode (WGM) due to the light propagations can be obtained by controlling the used two sides smaller ring resonator in the proposed ring structures. The WGM beam can be used as another mode of transmission called light fidelity (LiFi) transmission. In manipulation, the FSK light source wavelength of 1.55 μm fed into the system. The transmission bit rates of 200 Tbits⁻¹is achieved. The Bit Error Rate (BER) obtained at the user ends increases with increasing input power. Each sensor node identified the Bragg wavelength, while the change in Bragg wavelength on each sensor obtained and shown the linear trend, which is useful for sensing application. In applications, the proposed system is capable of dual mode of transmission either cable or wireless and in this case, the cable transmission of data using LiFi is more reliable than WiFi in terms of security, efficiency, availability, and safety.

提出了使用硅微环谐振器装置进行短距离通信的频移键控（FSK）双传输模式。由光学改进的分插复用器嵌入的金光栅连接到其他三个微环谐振器生成的FSK。所提出的系统包括一个带有两个纳米环相位调制器的发射微环，它们通过10 km光纤通道连接到接收器。用户端由三个类似的微环系统组成。嵌入在两个侧环中心（传感器探针）上的金光栅，以引入等离激元极化，从中每个传感器探针都通过布拉格波长来识别。n光子振荡器的频率在等离子体频率范围内，可以通过控制所提出的环形结构中使用的两侧较小的环形谐振器来获得由于光传播而产生的耳语画廊模式（WGM）。WGM光束可用作另一种传输模式，称为光保真（LiFi）传输。在操作中，波长为1.55μm的FSK光源进入系统。200 Tbit的传输比特率达到s ^-1。用户端获得的误码率（BER）随着输入功率的增加而增加。每个传感器节点识别出布拉格波长，而每个传感器上的布拉格波长变化得到并显示出线性趋势，这对于传感应用很有用。在应用中，所提出的系统能够以有线或无线两种方式传输数据，在这种情况下，就安全性，效率，可用性和安全性而言，使用LiFi进行的电缆数据传输比WiFi更可靠。