Method and system for driving piezoelectric MEMS-based active cooling devices

What is claimed is: 1. A system for cooling a heat-generating structure comprising: an array of cooling elements corresponding to regions of the heat-generating structure where heat is generated in response to operation of the heat-generating structure, a cooling element in the array of cooling elements being in a chamber and in communication with a fluid, the cooling element having a first side and a second side opposite to the first side, the first side being distal from the heat-generating structure, the second side being proximate to the heat-generating structure, the cooling element being between an entrance for the chamber and the heat-generating structure, at least a portion of the cooling element undergoing vibrational motion in response to the cooling element being activated, the vibrational motion drawing the fluid into the chamber through the entrance and directing the fluid from to the first side to the second side, the at least the portion of the cooling element undergoing the vibrational motion being integrally formed and valve-free, the array of cooling elements including a plurality of piezoelectric cooling elements; an orifice plate having at least one orifice therein, the orifice plate being disposed between the plurality of piezoelectric cooling elements and the heat-generating structure, the array of cooling elements being at least fifty microns and not more than five hundred microns from the orifice plate, each piezoelectric cooling element of the plurality of piezoelectric cooling elements having a length of at least three millimeters and not more than seven millimeters and wherein the orifice plate is at least fifty microns and not more than five hundred microns from the heat-generating structure; and a controller configured to activate portions of the array of cooling elements based on a determination that the operation of the heat-generating structure is likely to generate the heat in a given region of the heat-generating structure. 2. The system of claim 1 , wherein the heat-generating structure includes a clock and wherein the determination that the operation of the heat-generating structure is likely to generate heat is based on at least one of a junction temperature measurement and a clock measurement for the clock. 3. The system of claim 1 , wherein the determination that the operation of the heat-generating structure is likely to generate heat is based on use of a function. 4. The system of claim 1 , wherein the determination that the operation of the heat-generating structure is likely to generate heat is based on use of an interface. 5. The system of claim 1 , wherein the determination that the operation of the heat-generating structure is likely to generate heat is based on a pattern of usage. 6. The system of claim 1 , wherein the at least the portion of the cooling element includes at least one aperture therein, the aperture providing a fluid path from the first side to the second side. 7. The system of claim 6 , further comprising: an array of valves, a valve of the array of valves corresponding to and separate from the cooling element, the valve alternately opening and closing the at least one aperture for the cooling element. 8. A system for cooling a heat-generating structure comprising: an array of cooling elements corresponding to regions of the heat-generating structure where heat is generated in response to operation of a semiconductor structure, a cooling element in the array of cooling elements being in a chamber and in communication with a fluid, the cooling element having a first side and a second side opposite to the first side, the first side being distal from the heat-generating structure, the second side being proximate to the heat-generating structure, the cooling element being between an entrance for the chamber and the heat-generating structure, at least a portion of the cooling element undergoing vibrational motion in response to the cooling element being activated, the vibrational motion drawing the fluid into the chamber through the entrance and directing the fluid from to the first side to the second side, the at least the portion of the cooling element undergoing the vibrational motion being integrally formed and valve-free, the array of cooling elements including a plurality of piezoelectric cooling elements; an orifice plate having at least one orifice therein, the orifice plate being disposed between the plurality of piezoelectric cooling elements and the heat-generating structure, the array of cooling elements being at least fifty microns and not more than five hundred microns from the orifice plate, each piezoelectric cooling element of the plurality of piezoelectric cooling elements having a length of at least three millimeters and not more than seven millimeters and wherein the orifice plate is at least fifty microns and not more than five hundred microns from the heat-generating structure; and a controller configured to activate portions of the array of cooling elements based on a predictive determination that the operation of the semiconductor structure is likely to generate the heat in a given region of the heat-generating structure, the predictive determination being based on at least one of a clock speed for the heat-generating structure, use of a function by the heat-generating structure, use of an interface and a pattern of usage. 9. The system of claim 8 , wherein each of the piezoelectric cooling elements is configured to direct the fluid such that the fluid moves in a direction that is incident on a surface of the heat-generating structure at a substantially perpendicular angle. 10. A method of cooling a heat-generating structure, comprising: determining, using a controller, that operation of the heat-generating structure is likely to generate heat in a given region of the heat-generating structure; and driving portions of an array of cooling elements corresponding to regions of the heat-generating structure where the heat is generated in response to the determining that the operation of the heat-generating structure is likely to generate the heat, a cooling element in the array of cooling elements being in a chamber and in communication with a fluid, the cooling element having a first side and a second side opposite to the first side, the first side being distal from the heat-generating structure, the second side being proximate to the heat-generating structure, the cooling element being between an entrance for the chamber and the heat-generating structure, at least a portion of the cooling element undergoing vibrational motion in response to the cooling element being activated, the vibrational motion drawing the fluid into the chamber through the entrance and directing the fluid from to the first side to the second side, the at least the portion of the cooling element undergoing the vibrational motion being integrally formed and valve-free, the array of cooling elements including a plurality of piezoelectric cooling elements, an orifice plate having at least one orifice therein being disposed between the plurality of piezoelectric cooling elements and the heat-generating structure, the plurality of piezoelectric cooling elements being at least fifty microns and not more than five hundred microns from the orifice plate, each piezoelectric cooling element of the plurality of piezoelectric cooling elements having a length of at least three millimeters and not more than seven millimeters and wherein the orifice plate is at least fifty microns and not more than five hundred microns from the heat generating structure. 11. The method of claim 10 , wherein the heat-generating structure includes a clock and wherein the determining that the