Method for determining geometric characteristics of a hydraulic fracture

What is claimed: 1. A method for determining geometric characteristics of a hydraulic fracture comprising: performing a baseline seismic survey for a geological formation the baseline seismic survey is performed by excitation of first seismic signals by at least one seismic source and registration of first reflected and refracted seismic signals by at least one seismic receiver, creating a velocity model by combining results of the baseline seismic survey and an additional geoscientific information using a computer processor, evaluating seismic properties of the geologic formation by the computer processor, identifying by the computer processor at least one strong flat lithological reflector disposed below a planned fracture using the created velocity model, creating by the computer processor a numerical model of elastic wave propagation in the geologic formation with a fracture with given properties, optimizing position of the seismic sources and receivers and their properties on the basis of the numerical model taking into account the depth of the identified reflector, geometry and position of the planned fracture, performing hydraulic fracturing, performing at least one seismic survey after fracturing when the fracture is maintained open and pressurized, the at least one seismic survey is performed by excitation of second seismic signals by at least one seismic source and registration of second reflected and refracted seismic signals by at least one seismic receiver, and determining the fracture's dimensions and shape by comparing the first and the second reflected and refracted seismic signals and solving an inverse problem by the computer processor with the use of the numerical model. 2. The method of claim 1 wherein log data, or borehole seismic data, or a core sample research results or combination thereof are used as the additional geoscientific information. 3. The method of claim 1 , wherein the seismic properties of the geologic formation comprise accuracy and spatial resolution of the velocity model and rock attenuation. 4. The method of claim 1 , wherein the lithological reflector is identified as interfaces in the velocity model with high contrasts of acoustic impedance, including their depths, dips, reflectivity. 5. The method of claim 1 , wherein at least one additional seismic survey is performed during the fracture formation at different stages of fracture growth. 6. The method of claim 1 , wherein the seismic sources and receivers are disposed at a level of ground surface. 7. The method of claim 1 , wherein the seismic sources and receivers are disposed below ground surface.