Stimulation method

The invention claimed is: 1. A method for improving fuel collection from an underground deposit comprising stimulating at least a first fuel-containing section of an underground formation, the at least first section being situated between at least one first well and a second well, the at least one first well being either an injection well or a production well and the second well being either an injection well or a production well, the method comprising: providing at least one mechanical wave generation device downhole within at least the at least one first well; arranging at least a first mechanical wave sensor in at least the second well, the first mechanical wave sensor being configured to receive and interpret mechanical waves transmitted from the at least one mechanical wave generation device; injecting a pressurised fluid into the formation from at least one injection well of the at least one first well and the second well in a direction towards a production well of the at least one first well or the second well; activating the at least one mechanical wave generation device downhole to project a preselected range of frequencies or single frequency into the formation after or simultaneously with injecting the pressurised fluid into the formation; receiving the mechanical waves transmitted by the at least one mechanical wave generation device through the formation via the at least first mechanical wave sensor; and creating a tomography of water, gas, and/or oil interfaces in the at least first section of the formation using data gathered by the at least first mechanical wave sensor. 2. The method according to claim 1 , wherein the at least one mechanical wave generation device generates a mechanical wave by utilizing the group consisting of pressurised fluid, explosives detonations, a motor, a chemical composition, and solid fuel. 3. The method according to claim 1 , wherein the at least one mechanical wave generation device is selected from the group consisting of a downhole perforation gun, a fluid-activated gun, a seismic source, a chemical reaction gun, and a solid fuel gun. 4. The method according to claim 1 , further comprising transmitting information to a user regarding the tomography of water, gas and/or oil interfaces in the at least first section in such a way as to enable the user to monitor movement of water, gas and/or oil interfaces during injection of a fluid into the formation. 5. The method according to claim 4 , further comprising controlling a preselected range of frequencies or a single frequency depending on the information received by the user regarding the tomography of water, gas, and/or oil interfaces, wherein the preselected range of frequencies or the single frequency is increased if the information on the tomography of water, gas and/or oil interfaces indicates that oil or gas in the monitored part of the formation is moving slower than a predetermined value, and/or the preselected range of frequencies or the single frequency is decreased if the information on the tomography of water, gas, and/or oil interfaces indicates that the oil or gas in the monitored part of the formation is moving faster than a predetermined value. 6. The method according to claim 1 , wherein said at least one first well comprises a plurality of first wells and the method further comprises: arranging a plurality of mechanical wave generation devices configured to transmit mechanical waves in the plurality of first wells, respectively, said first wells encircling at least the second well, the second well being centrally located relative to the plurality of first wells; injecting a pressurised fluid into the formation from a plurality of injection wells towards the production well, activating the plurality of mechanical wave generation devices with a preselected range of frequencies or a single frequency, receiving the mechanical waves transmitted by the plurality of mechanical wave generation devices through the formation via the at least one mechanical wave sensor; and creating a tomography of water, gas and/or oil interfaces in the at least first section of the formation. 7. The method according to claim 6 , further comprising: transmitting information to a user regarding the tomography of water, gas and/or oil interfaces in the at least first section of the formation in such a way as to enable a user to monitor movement of water, gas and/or oil interfaces during injection of the fluid from the injection wells, and determining when a water, gas, or oil interface during injection of the fluid from the injection wells has passed the at least one first or second well. 8. The method according to claim 6 , wherein at least one third well comprising a central injection well is provided within the formation encircled by the first wells, further comprising: injecting a fluid into the formation from the at least one third well towards the production well. 9. The method according to claim 8 , further comprising arranging a mechanical wave generation device in the second well or the at least one third well. 10. The method according to claim 6 , further comprising activating the plurality of mechanical wave generation devices arranged in the plurality of first wells in a predetermined pattern to optimise the creation of a tomography of the water, gas and/or oil interfaces. 11. The method according to claim 1 , wherein a tool having a receiving unit enters the production well for receiving information from the at least first mechanical wave sensor from which information regarding the tomography of water, gas and/or oil interfaces may be derived. 12. The method according to claim 1 , further comprising creating a three-dimensional representation of the tomography of water, gas and/or oil interfaces in the first section of the formation. 13. The method according to claim 1 , wherein the at least one injection well from which injection fluids are pumped into the formation is a first well. 14. The method according to claim 1 , wherein the production well towards which injection fluids are pumped is a second well. 15. The method according to claim 1 , wherein the production well is at a distance which traverses the formation from the injection well. 16. A downhole stimulation system for stimulating oil- or gas-containing parts of a formation, comprising: at least a first well, the first well being an injection well or a production well; at least a second well, the second well being a production well or an injection well; at least one mechanical wave generation device, the at least one mechanical wave generation device being arranged downhole within at least the first well; and at least a first mechanical wave sensor arranged in the at least second-well configured to receive mechanical waves transmitted from the at least one mechanical wave generation device; wherein: the at least one mechanical wave generation device is configured to project a mechanical wave into the formation such that the wave comes into contact with and passes through the oil- or gas-containing parts of the formation located between the at least first well and the at least second well; and the at least one mechanical wave generation device is configured to be activated after or simultaneously while injection fluid is pumped into the formation. 17. The downhole stimulation system according to claim 16 , further comprising a tool having a receiving unit for receiving information from the at least first mechanical wave sensor from which information of a tomography of water, gas and/or oil interfaces m