Clear ice maker

What is claimed is: 1. An ice maker comprising: an ice making tray having an array of individual ice cube compartments, the ice making tray having a transverse axis and at least one pivot axle aligned with the transverse axis, wherein the tray defines a median wall extending parallel with the transverse axis and having a uniform height along an entirety of the wall; and a mechanical oscillating motor coupled to the ice making tray, wherein the oscillating motor rotates the tray from a horizontal plane along the transverse axis at an angle ϕ of about 20° to about 40° such that water in the tray cascades over the median wall. 2. The ice maker of claim 1 , wherein a frequency of an oscillation (ω) of the ice making tray is about equal to or about twice a frequency of movement of water in the tray. 3. The ice maker of claim 1 , wherein the tray has a floor which is a thermoelectric plate operated at a temperature below freezing for freezing water in the tray against the thermoelectric plate. 4. The ice maker of claim 3 , wherein, subsequent to the freezing of water in the ice making tray, the thermoelectric plate is heated to a temperature above freezing. 5. The ice maker of claim 4 , wherein the ice making tray is rotated by the oscillating motor to at least partially invert the ice making tray to allow ice cubes formed therein to be discharged from the tray. 6. The ice maker of claim 5 , wherein the oscillating motor rotates the tray to flex the tray to discharge ice cubes from the tray. 7. The ice maker of claim 2 , wherein ω is from about 0.4 to about 0.5 cycles per second. 8. An ice maker, comprising: a source of water; an ice making tray having a removable grid defining an array of individual ice cube compartments separated by a median wall having a uniform height; a valve coupling the source of water to the ice making tray; a mechanical oscillating motor coupled to the ice making tray, wherein the oscillating motor oscillates the tray at an angle ϕ of from about 20° to about 40°, such that water cascades over the median wall, and wherein an oscillation frequency (ω) is harmonically related to a frequency of movement of water in the tray; and a source of freezing temperature coupled to the ice making tray to freeze water in the tray. 9. The ice maker of claim 8 , wherein w is about equal to or about twice the frequency of movement of water in the tray. 10. The ice maker of claim 8 , wherein w is from about 0.4 to about 0.5 cycles per second. 11. The ice maker of claim 8 , wherein the ice making tray has a transverse axis and pivot axles at opposite ends of the tray offset from the transverse axis, and wherein the oscillating motor is coupled to one end of the tray to rotate the ice making tray on the transverse axis. 12. The ice maker of claim 11 , wherein the rotation is reciprocal through an arc of from about 40° to about 80°. 13. The ice maker of claim 8 , wherein the source of freezing temperature comprises a thermoelectric plate for freezing water in the tray. 14. The ice maker of claim 13 , wherein the floor of the ice making tray is made of a thermally conductive material which is in a thermally conductive relationship with the thermoelectric plate. 15. The ice maker of claim 14 , wherein, subsequent to the freezing of water in the ice making tray, the floor is heated by the thermoelectric plate. 16. The ice maker of claim 15 , wherein the ice making tray is rotated by the oscillating motor to at least partially invert the ice making tray to allow ice cubes formed therein to be discharged from the tray. 17. The ice maker of claim 16 , wherein the oscillating motor rotates the tray to flex the tray to discharge the ice cubes from the tray. 18. A method of making clear ice in a compartmentalized ice cube tray comprising the steps of: filling the ice cube tray with water; rotating the ice cube tray while exposing the tray to below freezing temperatures, the rotation step rotating the tray to allow unfrozen water to move from one tray compartment to at least an adjacent compartment such that a horizontal top portion of frozen ice formed at a substantially uniform height on the bottom of the tray compartment is exposed; and continuing the rotation until the water is frozen solid in the ice cube tray. 19. The method of claim 18 , wherein a frequency of the rotating step is harmonically related to the frequency of movement of water in the tray during rotation. 20. The method of claim 18 , further comprising the step: flexing the ice cube tray to discharge ice cubes from the ice cube tray.