Active-type multi-level wireless networking transmission system under high and low frequency stresses for ocean engineering structure

1 . An active-type multi-level wireless networking transmission system under high and low frequency stresses for ocean engineering structures, comprising sensor units, a multi-channel data acquisition unit, a micro-control processor unit, a data wireless transmission unit, a server unit and a feedback monitoring unit, wherein the sensor unit is configured to monitor vibration responses of ocean engineering structures and convert mechanical vibrations into electrical signals for output; the multi-channel data acquisition unit, connected to multiple sensor units, is configured to acquire an output signal of monitoring data of the sensor units, convert the output signal into a digital signal, and transmit the digital signal to the micro-control processor unit; the micro-control processor unit is configured for preprocessing the monitoring data and data storage, and is connected to the data wireless transmission unit via serial port communication; the data wireless transmission unit is configured to send monitoring data pre-processed by the micro-control processor unit to the server unit in real time; the data wireless transmission unit contains a high and low frequency remote data wireless transmission module, adopting an encoding and decoding algorithm combining Hamming codes and parity check codes to transmit data, and setting a high and low frequency conversion threshold value; in a low frequency operation mode of 1 hz, the acquired data, when less than the threshold value, is transmitted to the server unit in a low frequency manner; and the acquired data, when greater than the threshold value, is transmitted to the server unit in a high frequency manner, triggering a frequency of 55 hz for data transmission; the server unit is configured to receive the monitoring data in real time, perform data processing, storage, and visual analysis on monitoring results and perform early warning; and the feedback monitoring unit is configured to realize feedback monitoring and threshold value correction for multiple sensing systems. 2 . The active-type multi-level wireless networking transmission system under high and low frequency stresses for ocean engineering structures according to claim 1 , wherein the sensor units are placed at key positions of the ocean engineering structures to monitor abnormal vibration response data of the structures; and when the structure vibrates, a sensor material is subject to force change to generate an electric charge distribution change based on a piezoelectric effect, generating an electric signal. 3 . The active-type multi-level wireless networking transmission system under high and low frequency stresses for ocean engineering structures according to claim 1 , wherein the multi-channel data acquisition unit comprises eight input channels, adopting a differential input mode, each channel receiving different types of sensor input signals and performing acquisition and conversion. 4 . The active-type multi-level wireless networking transmission system under high and low frequency stresses for ocean engineering structures according to claim 1 , wherein a micro-control processor performs data filtering on monitoring data acquired by the multi-channel data acquisition unit to eliminate invalid junk data, performs data conversion, and automatically compares the acquired monitoring data with the threshold value set in the high and low frequency remote data wireless transmission module. 5 . The active-type multi-level wireless networking transmission system under high and low frequency stresses for ocean engineering structures according to claim 1 , wherein the Hamming code detects errors occurring during transmission by adding redundant data, corrects the errors according to the redundant data, and increases an effective distance of data transmission by correcting the errors during transmission. 6 . The active-type multi-level wireless networking transmission system under high and low frequency stresses for ocean engineering structures according to claim 1 , wherein the parity check code helps to verify the integrity of the data by adding parity check bits to the data, and discover and correct the errors during transmission in time to reduce an error rate of data transmission. 7 . The active-type multi-level wireless networking transmission system under high and low frequency stresses for ocean engineering structures according to claim 1 , wherein when the high and low frequency remote data wireless transmission module transmits in a high frequency mode and after an occurrence time of a last high frequency event is greater than 5 s, all data are less than the threshold value, and the high and low frequency remote data wireless transmission module automatically switches to a low frequency mode for transmission. 8 . The active-type multi-level wireless networking transmission system under high and low frequency stresses for ocean engineering structures according to claim 1 , wherein the server unit processes all the monitoring data in real time, calculates a weight of data evaluation indexes to obtain a data monitoring result, and performs visual display by an electronic map to realize early warning. 9 . The active-type multi-level wireless networking transmission system under high and low frequency stresses for ocean engineering structures according to claim 1 , wherein the server unit may introduce meteorological data, display meteorological information of an area on the electronic map, and provide short-duration rainfall and early warning information for business managers. 10 . The active-type multi-level wireless networking transmission system under high and low frequency stresses for ocean engineering structures according to claim 1 , wherein the feedback monitoring unit centrally displays service statuses of the ocean engineering structures, and integrates monitoring data of multiple ocean engineering in the area, realizing centralized monitoring and early warning of multiple ocean engineering structures according to visualization and early warning results of the server unit, and simultaneously providing support for interactive feedback between the ocean engineering.