Systems and methods for computing surface of fracture per volume of rock

What is claimed is: 1. A method, comprising: a. measuring resistivity of a formation with a resistivity tool and generating a borehole image from resistivity measurements, wherein the borehole image comprises a zonal resistivity map; b. extracting linear segments corresponding to fractures from the borehole image; c. defining a set of angular classes; d. sorting the segments by angular class; e. calculating a cumulated segment length for each angular class to obtain an actual distribution of cumulated segment length over angular class; f. correlating the actual cumulated segment length distribution with a theoretical segment length distribution for each of the angular classes to obtain the length of fracture segment per surface of borehole (P 21 ) contributions of each angular class (P 21 (x→y) ); g. computing a surface of fracture per volume of rock P 32 for each angular class (P 32 (x→y) )from each P 21 (x→y) ; and, h. summing together the computed P 32 (x→y) to arrive at a total surface of fracture per volume of rock P 32 (P 32 (tot ). 2. A method according to claim 1 , wherein the borehole image is in the form of a zonal resistivity map. 3. A method according to claim 1 , wherein the angular classes are nine angular classes. 4. A method according to claim 3 , wherein the nine angular classes are first angular class representing a dip class up to 10 degrees, a second angular class representing a dip class from over 10 degrees up to 20 degrees, a third angular class representing a dip class from over 20 degrees up to 30 degrees, a fourth angular class representing a dip class from over 30 degrees up to 40 degrees, a fifth angular class representing a dip class from over 40 degrees up to 50 degrees, a sixth angular class representing a dip class from over 50 degrees up to 60 degrees, a seventh angular class representing a dip class from over 60 degrees up to 70 degrees, an eighth angular class representing a dip class from over 70 degrees up to 80 degrees, and a ninth angular class representing a dip class from over 80 degrees up to 90 degrees. 5. A method according to claim 4 , wherein P 32 (x→Y) is derived from a value of the ratio of P 32 (x→y) / P 21 (x→y) and a value of P 21 (x→Y) . 6. A method according to claim 1 , wherein the correlating comprises determining P 32 (x→y) in descending order. 7. A system, comprising: a. a downhole resistivity tool for measuring resistivity of a formation; and, b. a processor including machine-readable instructions for generating a borehole image from resistivity measurements, wherein the borehole image comprises a zonal resistivity map, and estimating surface of fracture per volume of rock (P 32 ) from the borehole image wherein the estimation comprises i. extracting linear segments corresponding to fractures from the borehole image; ii. defining a set of angular classes; iii. sorting the segments by angular class; iv. calculating a cumulated segment length for each angular class to obtain an actual distribution of cumulated segment length over angular class; v. correlating the actual cumulated segment length distribution with a theoretical segment length distribution for each of the angular classes to obtain the length of fracture segment per surface of borehole (P 21 ) contributions of each angular class (P 21 (x→y) ); vi. computing a surface of fracture per volume of rock P 32 for each angular class (P 32( x→y) ) from each P 21 (x→y) ; and, vii. summing together the computed P 32 (x→y) to arrive at a total P 32 (P 32 (tot) ).