Process and apparatus for extracting a useful signal having a finite spatial extension at all times and which is variable with time

1. A process for the extraction of a time-variable useful signal of finite spatial extension by an array of N sensors, N being equal to or greater than 3, receiving said useful signal from a magnetic object moving in the vicinity of this array, to which have been added q spatially coherent additive noises, q being less than N, the measurements being performed on a sufficiently large surface to enable the detecting perimeter of each sensor of the array not to contain all the other sensors at once, said process comprising the following steps:

• acquiring unprocessed signals on the output of each sensor,band-pass filtering said signals in order to restrict to the frequency band of the useful signals,digitizing said filtered signals,calculating space prediction error signals of the noise during which;
  
  a. a particular sensor from the array of N sensors is chosen,b. the remaining N-1 sensors are distributed into groups of the same size having q sensors, whereby the same sensor can belong to more than one group, and one group is used for constructing a prediction error signal if the q signals of the group are independent,c. for each admissible group of q sensors is constructed a spatial prediction of the signal of said particular sensor by constructing q transfer functions inherent in the chosen admissible group of q sensors and said particular sensor with the aid of elements of intersensor transfer functions characteristic of the distribution of the noises at all times and applied respectively to the signals of the sensors of the admissible group of q sensors considered and combining the q thus constructed signals for each group in order to construct the prediction signal of said particular sensor andd. the prediction of said particular sensor is compared by a comparison operator with the signal of said particular sensor in order to construct a prediction error signal on said particular sensor andanalyzing prediction error signals so as to carry out the detection of the useful signal and its separation from the q additive noises,wherein said analyzing prediction signals comprises the steps of calculating detection indexes, andgenerating at all times a subdivision of the array of sensors into an array of sensors receiving the useful signal and noise and an array of sensors only receiving the noise, and weightings corresponding to said subdivision, and performing a weighted projection by associating the thus calculated weightings with the signal of each corresponding sensor for generating N weighted signals, and then applying an antenna processing method to the N weighted signals in order to carry out a source space/noise space separation, knowing the transfer functions of the noises, the N signals of the noise space being estimates of the useful signal present in each channel of the initial signal, andwherein the steps a, b, c, and d are performed simultaneously for the N sensors and the admissible groups of q sensors of the network and this takes place at all times.