Patent Document ID: 4641100
Application ID: 06385228
Patent Flag: 1

Claim One:
1. A method of direct airborne electromagnetic prospecting of hydrocarbon deposits, comprising the steps of: (a) transmitting many primary electromagnetic fields over an area comprising known hydrocarbon bearing and known barren locations, said many primary electromagnetic fields being transmitted from an induction transmitter loop mounted on a helicopter over many frequencies within the range of from 0.1 to 10 Hz, with many helicopter altitudes and with many positions of the plane of the induction transmitter loop; (b) detecting, over each of a number of said known hydrocarbon bearing and known barren locations, any deviation of amplitude and phase of all said many primary electromagnetic fields due to secondary electromagnetic fields over said known locations, said deviations of amplitude and phase being measured separately for each of the orthogonal electromagnetic components H.sub.x, H.sub.y, and H.sub.z by means of three orthogonal induction receiver antennae, and separately for each combination of said frequencies, helicopter altitudes and positions of the plane of the induction transmitter loop; (c) storing electronically said amplitude and phase data separately for each known hydrocarbon bearing and known barren location in said area; (d) converting said amplitude and phase data for each said known location into a multidimensional vector which represents the geophysical pattern of said known location, each said vector being a function of helicopter flight altitude, frequency, transmitter loop direction and inclination angle and the three induction receiver antenna orientations; (e) electronically processing said vectors to obtain the factors of discriminant functions on the basis of pattern recognition theory, cumulatively as flights over said known locations proceed, said discriminant functions being normalized such that they provide values between 0.8 and 1.0 for said locations over said known hydrocarbon bearing locations, and values of -0.8 to -1.0 over said known barren locations, said values being a measure of probability level of petroleum presence and absence; (f) transmitting said many primary electromagnetic fields over any designed number of measuring locations within an area to be explored; (g) detecting, at said measuring locations, said deviations of amplitude and phase of said many primary electromagnetic fields due to secondary electromagnetic fields over said area to be explored; (h) storing electronically said amplitude and phase data separately for each said measuring location; (i) converting said amplitude and phase data into multidimensional vectors which represent the geophysical patterns of measuring locations within said area to be explored, said vectors being functions of flight altitude, frequency, transmitter loop direction and inclination angle, and the orientation of the three induction receiver antenna; (j) processing electronically said vectors into a set of probability levels of petroleum presence or absence on the basis of pattern recognition theory cumulatively as flights over said measuring locations proceed, and probability level computed for measuring locations within said area to be explored, with the use of said normalized discriminant functions, selecting electronically, over said measuring locations within said area to be explored, the measuring locations having a high probability level, i.e. a pattern vector similar to those of points over said known locations; and (k) visually indicating and presenting thus computed probability levels on a monitor and providing a map of hydrocarbon occurrence probability contours.