Controllable optical sensing

What is claimed is: 1. An optical sensing device comprising: a light source; a multi-focal lens having a plurality of foci configured to focus light, at a single time instant, from the light source into a space at a plurality of focal points related to the plurality of foci, wherein the multi-focal lens comprises a liquid crystal configured to vary amounts of energy of the focused light among the plurality of focal points; and a sensor configured to sense the focused light of the light source reflected from an object in the space to sense the object or features of the object. 2. The optical sensing device of claim 1 , wherein an electrical voltage is applied to the liquid crystal to vary amounts of energy of light at the plurality of focal points. 3. The optical sensing device of claim 1 , wherein the multi-focal lens comprises a diffractive lens with a diffractive pattern, and the liquid crystal is applied on top of a surface of the diffractive lens. 4. The optical sensing device of claim 3 , wherein the diffractive pattern of the diffractive lens changes based upon controlling an electrical voltage applied to the liquid crystal to vary amounts of energy of light at the plurality of focal points. 5. The optical sensing device of claim 3 , wherein the liquid crystal fills diffractive teeth of the surface of the diffractive lens. 6. The optical sensing device of claim 3 , wherein the diffractive pattern has an apodized diffractive profile. 7. The optical sensing device of claim 3 , wherein: the liquid crystal is divided into a plurality of zones on the diffractive lens, and a different electrical voltage is applied to each of the zones creating an apodized surface function of the multi-focal lens. 8. The optical sensing device of claim 7 , wherein each of the zones contributes a different amount of energy of light at each of the focal points. 9. The optical sensing device of claim 3 , wherein the diffractive lens comprises two diffractive surfaces, and the liquid crystal is applied on top of one of the diffractive surfaces. 10. The optical sensing device of claim 9 , wherein the two diffractive surfaces provide different amounts of energy of light at the plurality of focal points by controlling an electrical voltage applied to the liquid crystal. 11. The optical sensing device of claim 1 , further comprising a light structuring unit for adding structure to light of the light source. 12. The optical sensing device of claim 1 , wherein the space is a three-dimensional space and the plurality of foci comprises foci at two different distances. 13. An optical sensing method comprising: shining light from a light source on a multi-focal lens having a plurality of foci configured to focus light, at a single time instant, from the light source into a space at a plurality of focal points related to the plurality of foci, wherein the multi-focal lens comprises a liquid crystal configured to vary amounts of energy of the focused light among the plurality of focal points; and sensing the focused light of the light source reflected from an object in the space to sense the object or features of the object. 14. The optical sensing method of claim 13 , further comprising applying an electrical voltage to the liquid crystal to vary amounts of energy of light at the plurality of focal points. 15. The optical sensing method of claim 13 , wherein the multi-focal lens comprises a diffractive lens with a diffractive pattern, and the liquid crystal is applied on top of a surface of the diffractive lens. 16. The optical sensing method of claim 15 , further comprising changing the diffractive pattern of the diffractive lens based upon controlling an electrical voltage applied to the liquid crystal to vary amounts of energy of light at the plurality of focal points. 17. The optical sensing method of claim 15 , wherein the liquid crystal is divided into a plurality of zones on the diffractive lens, and the method further comprising applying a different electrical voltage to each of the zones creating an apodized surface function of the multi-focal lens. 18. The optical sensing method of claim 17 , wherein each of the zones contributes a different amount of energy of light at each of the focal points. 19. The optical sensing method of claim 17 , further comprising directing light from the light source sequentially between the plurality of zones on the diffractive lens. 20. The optical sensing method of claim 13 , further comprising adding structure to light of the light source for sensing the focused light of the light source reflected from the object.