Hyperbolic ceiling-reflector for directional light sources

What is claimed is: 1. A downlight reflector, comprising: a reflective wall that bounds: a circular upper aperture having a first diameter and centered about an axis, and a circular lower aperture having a second diameter and centered about the axis, the second diameter being greater than the first diameter; wherein: the reflective wall increases continuously in diameter from the circular upper aperture to the circular lower aperture, the downlight reflector has no intervening structure between the reflective wall and the axis, and between the circular upper aperture and the circular lower aperture, such that light can pass unimpeded from the circular upper aperture to the circular lower aperture, save for the reflective wall, and at least an inner surface of the reflective wall, facing the axis, defines a curved shape that is convex with respect to the axis; wherein when a light source is positioned to provide emitted light through the circular upper aperture, the curved shape defines a threshold dividing the inner surface into an upper area, closer to the circular upper aperture, that receives light directly from the light source, and a lower area, adjoining the circular lower aperture, that is shadowed such that the lower area does not receive light directly from the light source. 2. The downlight reflector of claim 1 , wherein the curved shape is hyperbolic in cross-section on each side of the axis. 3. The downlight reflector of claim 1 , wherein the upper area of the reflective wall reflects a portion of the emitted light toward the circular lower aperture such that the curved shape spreads the portion of the emitted light. 4. The downlight reflector of claim 1 , wherein the curved shape creates a cut-off angle in the range of 50 to 55 degrees with respect to the axis. 5. The downlight reflector of claim 1 , wherein: the circular upper aperture and the circular lower aperture are separated by a reflector height, and a ratio of the reflector height to the second diameter is within the range of 0.29 to 0.53. 6. The downlight reflector of claim 1 , wherein all portions of the reflective wall from the circular upper aperture to the circular lower aperture are convex with respect to the axis. 7. A downlight fixture, comprising: a housing; a heat sink coupled with the housing; a light-emitting diode (LED) light engine in thermal communication with the heat sink, the LED light engine having at least one LED such that the LED light engine emits light rays in a generally downward direction that is centered about an axis; and a reflective wall that: is coupled with the housing; defines an upper aperture having a first diameter, wherein the upper aperture is centered about the axis; defines a lower aperture having a second diameter, wherein the lower aperture is centered about the axis and the second diameter is greater than the first diameter; and increases continuously in diameter from the upper aperture to the lower aperture; wherein: at least an inner surface of the reflective wall, facing the axis, defines a curved shape that is convex with respect to the axis; no intervening structure exists, between the reflective wall and the axis, and between the upper aperture and the lower aperture, such that light can pass unimpeded from the upper aperture to the lower aperture save for the reflective wall; and when the LED light engine provides emitted light through the upper aperture, the curved shape defines a threshold dividing the inner surface into an upper area, closer to the upper aperture, that receives a portion of the emitted light directly from the LED light engine, but the curved shape blocks the emitted light from contacting a lower area of the inner surface adjoining the lower aperture. 8. The downlight fixture of claim 7 , wherein the portion of the emitted light provided by the LED light engine that illuminates the upper area does not pass through a lens between the LED light engine and the upper area. 9. The downlight fixture of claim 8 , wherein the upper area of the reflective wall reflects the portion of the emitted light toward the lower aperture such that the curved shape spreads the portion of the emitted light such that the downlight fixture achieves comparable optical performance and improved efficacy, as compared to a light fixture of substantially the same external dimensions, that utilizes a parabolic reflector and a lens. 10. The downlight fixture of claim 7 , wherein all portions of the reflective wall from the upper aperture to the lower aperture are convex with respect to the axis. 11. The downlight fixture of claim 10 , wherein the curved shape is hyperbolic in cross-section on each side of the axis. 12. The downlight fixture of claim 7 , wherein the LED light engine is mounted directly to the heat sink. 13. The downlight fixture of claim 7 , wherein the LED light engine is mounted flush with the upper aperture. 14. The downlight fixture of claim 7 , wherein the curved shape creates a cut-off angle in the range of 50 to 55 degrees with respect to the axis. 15. The downlight fixture of claim 7 , wherein the upper aperture and the lower aperture are separated by a height, extending along the axis, and a ratio of the height to the second diameter is within the range of 0.29 to 0.53. 16. The downlight fixture of claim 15 , wherein: the first diameter is about 1.5 inches; the second diameter is about 4.3 inches; and the height is about 2.3 inches. 17. The downlight reflector of claim 5 , wherein: the threshold and the circular lower aperture are vertically separated by a threshold height; and a ratio of the threshold height to the reflector height is greater than 0.2. 18. The downlight reflector of claim 17 , wherein: an inner diameter of the reflective wall at the threshold is a threshold diameter; and a ratio of the threshold diameter to the second diameter is less than 0.8, so that the lower area reduces undesired brightness adjacent to the circular lower aperture. 19. A downlight reflector, comprising a reflective wall that: defines an upper aperture that is centered about an axis and that defines an entry area; defines a lower aperture that is centered about the axis and that defines an exit area, the exit area being greater than the entry area; and defines a curved shape that is convex with respect to the axis, along at least part of the axis, wherein: a distance from the axis to the reflective wall does not decrease, at any point along the axis, as the reflective wall proceeds from the upper aperture to the lower aperture, such that the entry area is continuously connected to the exit area via the reflective wall at every point along the axis between the upper aperture and the lower aperture, and such that light can pass unimpeded from the upper aperture to the lower aperture save for the reflective wall; and the curved shape is configured to create a threshold dividing an inner surface of the reflective wall into: a non-illuminated area that adjoins the lower aperture, and an illuminated area that is closer to the upper aperture than is the non-illuminated area; wherein, when a light source that is centered on the axis emits light through the upper aperture, a portion of the emitted light can pass in a straight line from the light source to the illuminated area, but the curved shape blocks the emitted light from passing in a straight line from the light source to the non-illuminated area.