红外双幅度脉冲间隔调制通信系统传感器稳定性控制模型

A Sensor Stability Control Model For Infrared Dual-Amplitude Pulse Interval Modulation Communication system

传统脉冲系统传感器稳定性控制模型忽略了对脉冲控制器驱动全域总线的设计,导致无法实现脉冲信号的全域连通,因此传统控制方法存在较大偏差。为此,构建新的红外双幅度脉冲间隔调制通信系统有限时间传感器稳定性控制模型。采集脉冲同态数据,完成脉冲资源文件信息的重新配置。设计脉冲控制器驱动全域总线,重组数据传输结构。应用脉冲内部领域微控制器,将脉冲信号转换为数字信号,连通脉冲全域总线完成全区域脉冲连通。组合和划分区域内脉冲能量簇,依靠各层级的驱动节点实现逐级控制,实现整体性传感器稳定性控制。实验所得数据表明:所设计的传感器稳定性控制模型的脉冲发条高频和红外低频脉冲控制偏差较小,与传统模型相比具有明显应用优势。

The traditional pulse system sensor stability control model ignores the design of pulse controller driving global bus, which makes it impossible to realize the global connection of pulse signal, so the traditional control method has a large deviation. For this reason, a new finite time sensor stability control model of infrared dual amplitude pulse interval modulation communication system is constructed. The pulse homomorphic data is collected and the pulse resource file information is reconfigured. The pulse controller is designed to drive the global bus and reorganize the data transmission structure. The pulse signal is converted into digital signal by using the pulse internal domain microcontroller, and the pulse global bus is connected to complete the whole area pulse connection. By combining and dividing the pulse energy clusters in the region, and relying on the driving nodes of each level to achieve step-by-step control, the overall sensor stability control is realized. The experimental data show that: the designed sensor stability control model has less deviation of high frequency and low frequency pulse control, and has obvious application advantages compared with the traditional model.