Method for making a magnetic gradiometer with high detection accuracy and success rate

What is claimed is: 1. A method for making a magnetic gradiometer, comprising the steps of: a, establishing a complete magnetic detection model to calculate position and magnetic moment of a magnetic target as detected by the magnetic gradiometer, which comprises the steps of: 1) establishing a magnetic target model based on a magnetic dipole model to obtain a magnetic field ({right arrow over (B O )}) generated only by the magnetic target; 2) superposing a noise signal generated by a noise model (No(μ,σ 2 ) onto the magnetic field {right arrow over (B O )} to obtain a superposed magnetic field ({right arrow over (B r )}); 3) establishing a magnetic sensor model based on the resolution of the magnetic sensor and using the magnetic sensor model to perform data processing on the superposed magnetic field {right arrow over (B r )} a to obtain an output value of the magnetic sensor ({right arrow over (B S )}); 4) establishing a tensor model based on the structure of the magnetic gradiometer and using the output value of the magnetic sensor ({right arrow over (B S )}) as an input for the tensor model data processing to obtain an output value of the magnetic gradiometer ({right arrow over (G)}); 5) establishing an inversion model based on the magnetic detection method and using the output value of the magnetic gradiometer ({right arrow over (G)}) as an input for the inversion model data processing to obtain calculated position and magnetic moment of the magnetic target; b, establishing a direction-attitude-sphere model of the magnetic target to represent the entire zone of all possible positions and attitudes of the magnetic target, wherein the attitude of the magnetic target is represented by its unit magnetic moment vector ({right arrow over (m 0 )}) the direction of the magnetic target is represented by its unit position vector ({right arrow over (r 0 )}), and an included angle between the unit magnetic moment vector ({right arrow over (m 0 )}) and the unit position vector ({right arrow over (r 0 )}) is ϕ, wherein a direction-sphere is formed by making the unit position vector ({right arrow over (r 0 )}) cover the entire direction-sphere, wherein for each unit position vector ({right arrow over (r 0 )}), there is an attitude-sphere formed by making the unit magnetic moment vector ({right arrow over (m 0 )}) cover the entire attitude-sphere, and wherein the coordinate system of the direction-sphere coincides with the coordinate system of the magnetic gradiometer, and the axis z′ of the coordinate system of the attitude-sphere and the unit position vector ({right arrow over (r 0 )}) are aligned on the same straight line; c, determining value ranges of a group of influencing parameters consisting of signal intensity of the magnetic target (Ms), resolution of magnetic sensors in the magnetic gradiometer (S), a distance ratio (K), and the magnetic field noise No(μ,σ 2 ); d, calculating detection success rates of the magnetic gradiometer under various influencing parameters using the magnetic detection model and the direction-attitude-sphere model, and drawing a relationship graph to demonstrate the influence of various influencing parameters on the performance of the magnetic gradiometer; and f, adjusting values of the influencing parameters to design a magnetic gradiometer with high performance and/or high cost-efficiency based on knowledge of the influence of various influencing parameters on the performance of the magnetic gradiometer.