Flat drop cable with features for enhanced gel retention and stripability

The invention claimed is: 1. A fiber optic cable having a central longitudinal axis, the fiber optic cable comprising: a jacket having a length that extends along the central longitudinal axis of the fiber optic cable, the jacket defining a transverse cross-sectional profile having a thickness and a width, the thickness being smaller than the width, the transverse cross-sectional profile of the jacket defining a major axis that extends across the width of the jacket and a minor axis that extends across the thickness of the jacket, the major and minor axes being perpendicular to one another and also being perpendicular to the central longitudinal axis of the fiber optic cable, and the major axis and the minor axis intersecting each other at the central longitudinal axis; a core, including an optical fiber and a cylindrical buffer layer surrounding the optical fiber, positioned within the jacket, wherein the central longitudinal axis extends along within an outer cylindrical perimeter of the buffer layer; and an open-sided notch formed in the jacket that extends along the length of the jacket, the open-sided notch being positioned at a location offset from the minor axis, wherein the open-sided notch includes an inner portion closest to the core and the inner portion is formed as an empty rounded valley, wherein tearing the jacket at the inner portion of the open-sided notch leads to access of the buffer layer within the jacket, wherein the open-sided notch is a first open-sided notch, the rounded valley is a first rounded valley having a first radius of curvature, and the first radius of curvature is at least 0.1 mm. 2. The fiber optic cable of claim 1 , wherein the open-sided notch is provided in a part of the jacket outside of an area between first and second lines that are tangent to the outer perimeter of the optical fiber and the buffer layer and that are perpendicular to the major axis. 3. The fiber optic cable of claim 1 , wherein the open-sided notch is defined by first and second surfaces that are formed at an oblique angle relative to one another and that converge as the first and second surfaces extend into the jacket to attach to sides of the rounded valley. 4. The fiber optic cable of claim 3 , wherein the oblique angle between the first and second surfaces is between 35 degrees and 70 degrees. 5. The fiber optic cable of claim 3 , further comprising: a second open-sided notch formed in the jacket that extends along the length of the jacket, the second open-sided notch being positioned at a location offset from the minor axis, wherein the second open-sided notch includes an inner portion closest to the core and the inner portion is formed as an empty second rounded valley, wherein tearing the jacket at the inner portion of the second open-sided notch leads to access of the buffer layer within the jacket, wherein the second open-sided notch is defined by third and fourth surfaces that are formed at an oblique angle relative to one another and that converge as the third and fourth surfaces extend into the jacket to attach to sides of the second rounded valley. 6. The fiber optic cable of claim 5 , wherein the jacket defines first and second sides separated by the thickness and first and second rounded ends separated by the width, wherein the first open-sided notch is formed in the first side of the jacket between the minor axis and the first rounded end of the jacket, wherein the second open-sided notch is formed in the second side of the jacket between the minor axis and the second rounded end, wherein the second rounded valley has a second radius of curvature, and wherein a first line passing through a center of the first radius of curvature and passing through a center of the second radius of curvature also passes through the central longitudinal axis of the fiber optic cable. 7. The fiber optic cable of claim 6 , wherein the second radius of curvature is at least 0.1 mm, and wherein the first line forms a first angle relative to the major axis of the fiber optic cable, and wherein the first angle is between 40 to 60 degrees. 8. The fiber optic cable of claim 6 , wherein the first side is flat except for the first open-sided notch, and wherein the second side is flat except for the second open-sided notch. 9. The fiber optic cable of claim 8 , wherein a first shoulder is formed between the first surface and the flat first side of the jacket and the first shoulder has a third radius of curvature, wherein a second shoulder is formed between the second surface and the flat first side of the jacket and the second shoulder has a fourth radius of curvature, wherein a third shoulder is formed between the third surface and the flat second side of the jacket and the third shoulder has a fifth radius of curvature, and wherein a fourth shoulder is formed between the fourth surface and the flat second side of the jacket and the fourth shoulder has a sixth radius of curvature. 10. The fiber optic cable of claim 9 , wherein a second line passing through a center of the third radius of curvature and passing through a center of the sixth radius of curvature also passes through the central longitudinal axis of the fiber optic cable, and wherein a third line passing through a center of the fourth radius of curvature and passing through a center of the fifth radius of curvature also passes through the central longitudinal axis of the fiber optic cable. 11. The fiber optic cable of claim 10 , wherein the first angle of the first line is between 47 and 50 degrees, wherein the second line forms a second angle relative to the major axis of the fiber optic cable and the second angle is between 35 to 40 degrees, and wherein the third line forms a third angle relative to the major axis of the fiber optic cable and the third angle is between 70 to 75 degrees. 12. A fiber optic cable having a central longitudinal axis, the fiber optic cable comprising: a jacket having a length that extends along the central longitudinal axis of the fiber optic cable, the jacket defining a transverse cross-sectional profile having a thickness and a width, the thickness being smaller than the width, the jacket also defining first and second sides separated by the thickness and first and second rounded ends separated by the width; a first reinforcing member embedded in the jacket proximate the first rounded end; a second reinforcing member embedded in the jacket proximate the second rounded end; a core, including an optical fiber and a cylindrical buffer layer surrounding the optical fiber, positioned within the jacket, wherein the central longitudinal axis extends along within an outer cylindrical perimeter of the buffer layer; wherein a transverse cross-sectional profile of the jacket defines a major axis that extends across the width of the jacket and intersects centers of the first reinforcing member, the second reinforcing member and the core; wherein the transverse cross-sectional profile of the jacket also defines a minor axis that extends across the thickness of the jacket, the major and minor axes being perpendicular to one another and also being perpendicular to the central longitudinal axis of the fiber optic cable, the major axis and the minor axis intersecting each other at the central longitudinal axis; a first open-sided notch formed in the first side of the jacket, the first open-sided notch extending along the length of the jacket, the first open-sided notch being positioned at a location between the minor axis and the first rounded end, the first open-sided notch being defined by first and second surfaces that are formed at an oblique angle relative to one another and that converge as the first and seco