Optimized subsonic projectiles and related methods

The invention claimed is: 1. A subsonic ammunition cartridge comprising: a casing having a base end and an open end wherein said casing has an internal volume; a primer inserted in said base end of said casing; a projectile comprised of a nose cone, a body, and a boattail, wherein said body is disposed between said nose cone and said boattail, wherein a portion of the body section in proximity to said boattail of said projectile is inserted in the open end of said casing and press fitted to the portion of the body section; and a propellant wherein said propellant is placed within said casing surrounding said boattail; wherein said nose or body are formed with at least one turbulence generator comprising a ring or groove structure formed into said nose, body, or boattail that is perpendicular to a first axis formed by a line drawn from a center of said nose section to a center of said boattail section; wherein said boattail is formed with a plurality of rebated or stepped structures that are formed spaced apart into said boattail; wherein said nose cone is formed into an elliptical shape with a flattened meplat on said center of said nose cone section; wherein said projectile is formed with a center of pressure further from said center of said nose section along said first axis than a center of gravity; wherein said projectile is formed with a body to boattail transition having an angle of 8 degrees as defined by a first plane collinear with an external surface of said body and a second plane collinear with an external surface of said boattail; wherein said boattail extends from a point of said body to boattail transition to said base end of said casing but not in contact with said primer, wherein said point of said body to boattail transition is further from said center of said nose cone section along said first axis than said open end of said casing when said projectile is inserted inside said casing and said casing is press fitted to said projectile; wherein said propellant charge is selected so as to produce a force to maximize subsonic speed of said projectile as it enters an external ballistics phase to no more than a critical Mach number of less than Mach 1 at a temperature at which said projectile is functioning. 2. The subsonic ammunition cartridge of claim 1 , wherein said nose cone is elliptical and wherein said nose cone minimizes a pressure coefficient, and said nose cone has a subsonic drag in the range of 0 to 0.0001. 3. The subsonic ammunition cartridge of claim 1 , wherein said boattail is conical in shape. 4. The subsonic ammunition cartridge of claim 3 , wherein said stepped structure of said boattail has a 90 degree step or shoulder formed into said boattail. 5. The subsonic ammunition cartridge of claim 1 , wherein said projectile is selected from the group consisting of all tungsten, tungsten and aluminum, or all aluminum. 6. The subsonic ammunition cartridge of claim 1 , wherein said projectile interior nose cone is comprised of tungsten and said body and said boattail are comprised of aluminum. 7. The subsonic ammunition cartridge of claim 1 , wherein said boattail has a plurality of flat spots or grooves. 8. A method of manufacturing a subsonic ammunition cartridge comprising: providing a casing having a base end and an open end wherein said casing has an internal volume; providing a primer inserted in said base end of said casing; providing a projectile comprised of a nose cone, a body, and a boattail, wherein said body is disposed between said nose cone and said boattail, wherein a portion of the body section in proximity to said boattail of said projectile is inserted in the open end of said casing and press fitted to the portion of the body section; providing a propellant wherein said propellant is placed within said casing surrounding said boattail; wherein said nose or body are formed with at least one turbulence generator comprising a ring or groove structure formed into said nose, body, or boattail that is perpendicular to a first axis formed by a line drawn from a center of said nose section to a center of said boattail section; wherein said boattail is formed with a plurality of rebated or stepped structures that are formed spaced apart into said boattail; wherein said nose cone is formed into an elliptical shape with a flattened meplat on a center of said nose cone section; wherein said projectile is formed with a center of pressure further from said center of said nose section along said first axis than a center of gravity; wherein said projectile is formed with a body to boattail transition having an angle of 8 degrees as defined by a first plane collinear with an external surface of said body and a second plane collinear with an external surface of said boattail; wherein said boattail extends from a point of said body to boattail transition to said base end of said casing but not in contact with said primer, wherein said point of said body to boattail transition is further from said center of said nose cone section along said first axis than said open end of said casing when said projectile is inserted inside said casing and said casing is press fitted to said projectile; and wherein said propellant charge is selected so as to produce a force to maximize subsonic speed of said projectile as it enters an external ballistics phase to no more than a critical Mach number of less than Mach 1 at a temperature at which said projectile is functioning. 9. The method of claim 8 , wherein said nose cone is elliptical wherein said nose cone minimizes a pressure coefficient, and said nose cone has a subsonic drag in the range of 0 to 0.0001. 10. The method of claim 8 , wherein said boattail is conical in shape. 11. The method of claim 10 , wherein said stepped structure of said boattail has a 90 degree step or shoulder formed into said boattail. 12. The method of claim 8 , wherein said projectile is selected from the group consisting of all tungsten, tungsten and aluminum, or all aluminum. 13. The method of claim 8 , wherein said projectile interior nose cone is comprised of tungsten and said body and said boattail are comprised of aluminum. 14. The method of claim 8 , wherein said boattail has a plurality of flat spots or grooves. 15. A method associated with a projectile system comprising the steps of: determining a caliber of a projectile associated with a projectile launcher and casing combination that will fit within a first fit dimension determined based on a chamber length of said projectile launcher and a non-interference fit diameter of a passage through a barrel of said projectile launcher, wherein said projectile comprises a first, second, and third section, said first section is a nose cone section, said second section is a body section, and said third section is a boattail section, wherein said casing comprises a throat area configured to receive and pressfit to a section of said second section and a primer disposed on an opposing end of said casing from said throat area, said first section comprises an elliptical nose shape, said second section comprises a cylindrical shape, and third section is formed in a cone shape, wherein said third section is formed with a plurality of rebated or stepped structures, said first section is formed with a flat meplat on a top of a center section of said first section, wherein said projectile is formed with a second section to third section transition having an angle of eight degrees as defined by a first plane collinear with an external surface of said second section and a second plane collinear with an external surface of said