초록 ▼

A shock wave in a gas is modified by emitting energy to form an extended path in the gas; heating gas along the path to form a volume of heated gas expanding outwardly from the path; and directing a path. The volume of heated gas passes through the shock wave and modifies the shock wave. This elimin

A shock wave in a gas is modified by emitting energy to form an extended path in the gas; heating gas along the path to form a volume of heated gas expanding outwardly from the path; and directing a path. The volume of heated gas passes through the shock wave and modifies the shock wave. This eliminates or reduces a pressure difference between gas on opposite sides of the shock wave. Electromagnetic, microwaves and/or electric discharge can be used to heat the gas along the path. This application has uses in reducing the drag on a body passing through the gas, noise reduction, controlling amount of gas into a propulsion system, and steering a body through the gas. An apparatus is also disclosed.

대표청구항 ▼

What is claimed is: 1. A method of decreasing drag of a body passing subsonically along a direction through a fluid, comprising the steps of: emitting energy along an extended path in the fluid; heating fluid along the path to decrease the density of fluid around the path and to form a volume of he

What is claimed is: 1. A method of decreasing drag of a body passing subsonically along a direction through a fluid, comprising the steps of: emitting energy along an extended path in the fluid; heating fluid along the path to decrease the density of fluid around the path and to form a volume of heated fluid expanding outwardly from the path; and directing the path parallel to the direction the body passes through the fluid, wherein the body passes through the volume of decreased-density heated fluid and whereby the reduction of density of the fluid decreases the drag on the body, and the heating of the fluid at different points along the path occurs simultaneously. 2. The method according to claim 1, wherein electromagnetic energy heats the fluid along the path. 3. The method according to claim 1, further comprising the step of repeating said steps of emitting energy, heating fluid, and directing the path. 4. The method according to claim 1, wherein multiple paths are formed within the fluid. 5. The method according to claim 1, wherein said energy is emitted from said body. 6. A method of decreasing drag of a body passing subsonically along a direction through a fluid, comprising the steps of: emitting energy along an extended path in the fluid; heating fluid along the path to decrease the density of fluid around the path and to form a volume of heated fluid expanding outwardly from the path; and directing the path parallel to the direction the body passes through the fluid, wherein the body passes through the volume of decreased-density heated fluid and whereby the reduction of density of the fluid decreases the drag on the body, and wherein the fluid includes a liquid. 7. The method according to claim 6, wherein said energy is emitted from said body. 8. A method of decreasing drag of a body passing subsonically along a direction through a fluid, comprising the steps of: emitting energy along an extended path in the fluid; heating fluid along the path to decrease the density of fluid around the path and to form a volume of heated fluid expanding outwardly from the path; actively changing a direction of the path through the fluid; and directing the path parallel to the direction the body passes through the fluid, wherein the body passes through the volume of decreased-density heated fluid and whereby the reduction of density of the fluid decreases the drag on the body. 9. The method according to claim 8, wherein the step of heating the fluid causes lateral movement of the fluid away from an area in the fluid to which the energy is applied. 10. The method according to claim 8, wherein said energy is emitted from said body. 11. A method of decreasing drag of a body passing transonically along a direction through a fluid, comprising the steps of: emitting energy along an extended path in the fluid; heating fluid along the path to decrease the density of fluid around the path and to form a volume of heated fluid expanding outwardly from the path; and directing the path parallel to the direction the body passes through the fluid, wherein the body passes through the volume of decreased-density heated fluid and whereby the reduction of density of the fluid decreases the drag on the body, and the heating of the fluid at different points along the path occurs simultaneously. 12. The method according to claim 11, wherein electromagnetic energy heats the fluid along the path. 13. The method according to claim 11, further comprising the step of repeating said steps of emitting energy, heating fluid, and directing the path. 14. The method according to claim 11, wherein multiple paths are formed within the fluid. 15. The method according to claim 11, wherein said energy is emitted from said body. 16. A method of decreasing drag of a body passing transonically along a direction through a fluid, comprising the steps of: emitting energy along an extended path in the fluid; heating fluid along the path to decrease the density of fluid around the path and to form a volume of heated fluid expanding outwardly from the path; and directing the path parallel to the direction the body passes through the fluid, wherein the body passes through the volume of decreased-density heated fluid and whereby the reduction of density of the fluid decreases the drag on the body, and wherein the fluid includes a liquid. 17. The method according to claim 16, wherein said energy is emitted from said body. 18. A method of decreasing drag of a body passing transonically along a direction through a fluid, comprising the steps of: emitting energy along an extended path in the fluid; heating fluid along the path to decrease the density of fluid around the path and to form a volume of heated fluid expanding outwardly from the path; actively changing a direction of the path through the fluid; and directing the path parallel to the direction the body passes through the fluid, wherein the body passes through the volume of decreased-density heated fluid and whereby the reduction of density of the fluid decreases the drag on the body. 19. The method according to claim 18, wherein the step of heating the fluid causes lateral movement of the fluid away from an area in the fluid to which the energy is applied. 20. The method according to claim 18, wherein said energy is emitted from said body. 21. A method of decreasing drag of a body passing along a direction through a fluid, comprising the steps of: emitting energy through an aerodynamic window along an extended path in the fluid, wherein the aerodynamic window maintains a pressure gradient between a controlled atmosphere cavity within the body and the external atmosphere; heating fluid along the path to decrease the density of fluid around the path and to form a volume of heated fluid expanding outwardly from the path; and directing the path parallel to the direction the body passes through the fluid, wherein the body passes through the volume of decreased-density heated fluid and whereby the reduction of density of the fluid decreases the drag on the body, and the heating of the fluid at different points along the path occurs simultaneously. 22. The method according to claim 21, wherein said energy is emitted from said body. 23. The method according to claim 21, wherein the aerodynamic window comprises a gas stream that is roughly transverse to the emitting energy. 24. The method according to claim 21, wherein the body is traveling transonically or subsonically. 25. A method of forming a channel in a fluid, comprising the steps of: emitting energy along an extended path in the fluid, wherein said energy is emitted from a body moving subsonically through said fluid; heating fluid along the path to decrease the density of fluid around the path and to form a volume of heated fluid expanding outwardly from the path to create a channel of decreased-density heated fluid; and directing the path parallel to the direction the body moves through the fluid, wherein the body moves through the channel, and the heating of the fluid at different points along the path occurs simultaneously. 26. The method according to claim 25, wherein the fluid includes a liquid. 27. The method according to claim 25, wherein the fluid includes a liquid. 28. A method of forming a channel in a fluid, comprising the steps of: emitting energy along an extended path in the fluid, wherein said energy is emitted from a body moving subsonically through said fluid; heating fluid along the path to decrease the density of fluid around the path and to form a volume of heated fluid expanding outwardly from the path to create a channel of decreased-density heated fluid; actively changing a direction of the path through the fluid; and directing the path parallel to the direction the body moves through the fluid, wherein the body moves through the channel. 29. A method of forming a channel in a fluid, comprising the steps of: emitting energy along an extended path in the fluid, wherein said energy is emitted from a body moving transonically through said fluid; heating fluid along the path to decrease the density of fluid around the path and to form a volume of heated fluid expanding outwardly from the path to create a channel of decreased-density heated fluid; and directing the path parallel to the direction the body moves through the fluid, wherein the body moves through the channel, and the heating of the fluid at different points along the path occurs simultaneously. 30. A method of forming a channel in a fluid, comprising the steps of: emitting energy along an extended path in the fluid, wherein said energy is emitted from a body moving transonically through said fluid; heating fluid along the path to decrease the density of fluid around the path and to form a volume of heated fluid expanding outwardly from the path to create a channel of decreased-density heated fluid; actively changing a direction of the path through the fluid; and directing the path parallel to the direction the body moves through the fluid, wherein the body moves through the channel. 31. A method of forming a channel in a fluid, comprising the steps of: emitting energy through an aerodynamic window along an extended path in the fluid, wherein said energy is emitted from a moving body; heating fluid along the path to decrease the density of fluid around the path and to form a volume of heated fluid expanding outwardly from the path to create a channel of decreased-density heated fluid; and directing the path parallel to the direction the body moves through the fluid, wherein the body moves through the channel, and the heating of the fluid at different points along the path occurs simultaneously.