Multi-node data synchronous acquisition system and method for real-time monitoring of underwater surface deformation

What is claimed is: 1. A multi-node data synchronous acquisition system for real-time monitoring of underwater surface deformation, comprising: a central controller, and sensor array provided with MEMS attitude sensors; wherein the system comprises at least four sensor arrays, each of the sensor arrays consists of a plurality of sections of strip-shaped rigid substrates connected by movable joints, three sensor units and one slave station data acquisition unit are arranged on each section of rigid substrate; each sensor unit comprises a compressive cabin outside and an MEMS attitude sensor and a power supply inside, and each slave station data acquisition unit comprises a compressive cabin outside and a slave station data acquisition unit control board and a power supply inside; the three sensor units are respectively connected to the slave station data acquisition unit through cables, and the slave station data acquisition unit is connected to the central controller through a cable; each central controller comprises a compressive cabin outside and an embedded controller and a power supply inside; and each slave station data acquisition unit acquires data from the MEMS attitude sensors and then transmits it to the embedded controller. 2. The system according to claim 1 , wherein the slave station data acquisition units are connected with the sensor units and the central controllers through waterproof connectors and cables, respectively. 3. The system according to claim 1 , wherein the MEMS attitude sensors are 3-axis acceleration sensors configured to measure acceleration data to obtain attitude information and displaying it in a data form of a quaternion or Euler angle. 4. The system according to claim 1 , wherein a radial surrounding clamp is disposed outside the compressive cabin of each sensor unit, and each sensor unit is mounted on a mounting position of each rigid substrate by the clamp. 5. The system according to claim 1 , wherein the compressive cabin of the central controller is provided with a spike fixing member for fixation at the lower end and an annular suspension hook at the upper end. 6. The system according to claim 1 , wherein the rigid substrates are stainless steel plates, the movable joint connecting adjacent rigid substrates is a stainless steel movable hinge, a rotary suspension ring for connecting an underwater mechanical arm is arranged at a head end of each sensor array, the power supply comprises a 5V mobile power supply and a 24V lithium battery pack, wherein the 5V mobile power supply supplies power to the slave station data acquisition unit, and the 24V lithium battery pack is formed by series or parallel connection of lithium batteries to supply power to each central controller, the sensor units and the slave station data acquisition units realize data transmission through analog IIC buses, the slave station data acquisition units and the central controllers realize data transmission through CAN buses, and synchronous time signals are transmitted and issued by I/O port. 7. A multi-node data synchronous acquisition method for real-time monitoring of underwater surface deformation using the system according to claim 1 , comprising: (1) building a synchronous acquisition system, assembling the synchronous acquisition system, wherein each central controller is provided with at least four sensor arrays, a circuit connection relationship between the central controllers and slave station data acquisition units as well as sensor units is as follows: every three sensor units as a group are connected to one slave station data acquisition unit, and independently transmit data through three analog IIC buses, each of the analog IIC buses comprises an SDA cable and an SCL cable, and the SDA cable and the SCL cable are respectively connected to a VCC interface of the acquisition unit through pull-up resistors, each slave station data acquisition unit transmits data to the central controller through a common CAN bus, the CAN bus comprises a CAN_H, a CAN_L and two 120Ω terminal resistors, and a CAN controller determines a bus level based on a potential difference between the two cables CAN_H and CAN_L; (2) lowing the synchronous acquisition system to the seabed by an underwater winch, and mounting it by utilizing an underwater robot, so that the spike fixing member at the lower end of the central controller is inserted into a underwater formation for fixation, and grasping a rotary suspension ring at the head end of each sensor array by the underwater robot to drag each sensor array to be evenly arranged on the seabed in a radial direction using the central controller as a center; (3) taking a clock of the central controller as a master clock of the system, sequentially transmitting calibration time point information to each slave station data acquisition unit through a CAN bus in advance, simultaneously issuing time signals by I/O, and simultaneously calibrating respective time by the slave station data acquisition unit after receiving the time signals to achieve relative clock synchronization of the data acquisition system; and (4) after the sensor units acquire acceleration data of each physical point, transmitting the data to the adjacent slave station data acquisition unit through an analog IIC bus, time-stamping the data by the slave station data acquisition unit after classifying and numbering it, then transmitting the data to the CAN bus, and summarizing the data of the slave station data acquisition units by the central controller through the CAN bus to complete storage and preprocessing of the data.