Multi-function appliance knob incorporating multiple rotation modulating mechanisms

What is claimed is: 1. A control knob for an appliance, the control knob comprising: an outer control ring; a stationary hub; a rotation modulating mechanism coupled to the outer control ring and engaged with an outer surface of the stationary hub, wherein the outer control ring is rotationally operable about the stationary hub at a first rate; an indicial ring positioned around the stationary hub, wherein the indicial ring engages a portion of the rotation modulating mechanism, wherein rotation of the outer control ring at the first rate causes the rotation modulating mechanism to rotate the indicial ring about the stationary hub at a second rate, the second rate being different than the first rate; and an encoder shaft positioned within the stationary hub, wherein an inner gearing mechanism extends between an exterior surface of the encoder shaft and one of the outer control ring and the indicial ring. 2. The control knob of claim 1 , wherein when the inner gearing mechanism extends between the encoder shaft and the outer control ring, the first rate is slower than the second rate, and wherein when the inner gearing mechanism extends between the encoder shaft and the indicial ring, and wherein the first rate is faster than the second rate. 3. The control knob of claim 2 , wherein the inner gearing mechanism extends between the encoder shaft and the outer control ring, and wherein the rotation modulating mechanism includes planetary gears that rotationally engage outer cogs defined within the outer surface of the stationary hub and inner cogs defined within an inner surface of the indicial ring, and wherein the outer control ring includes planetary seats that hold the planetary gears in a fixed axial position relative to the outer control ring and allow the planetary gears to rotate within the planetary seats of the outer control ring. 4. The control knob of claim 3 , wherein the outer control ring extends at least from the planetary gears to the inner gearing mechanism, wherein the inner gearing mechanism extends through a portion of the stationary hub to engage the outer control ring. 5. The control knob of claim 4 , wherein the inner gearing mechanism includes a cluster gear having first and second gear portions, wherein the first gear portion engages the outer control ring, and wherein the second gear portion engages the encoder shaft to transfer the rotation of the outer control ring to the encoder shaft, and wherein the rotation of the outer control ring in a first rotational direction causes the encoder shaft to rotate in a second rotational direction that is opposite the first rotational direction. 6. The control knob of claim 5 , wherein the inner gearing mechanism defines an inner reduction mechanism, wherein the first gear portion has a first diameter and the second gear portion has a second diameter, the first diameter being larger than the second diameter. 7. The control knob of claim 1 , further comprising: an auxiliary control ring positioned proximate the outer control ring, wherein the auxiliary control ring rotates independently of the outer control ring, and wherein the auxiliary control ring is in communication with a function encoder; and an appliance control that includes a temperature control and a function control, wherein the temperature control is in communication with the encoder shaft and the function control is in communication with the function encoder. 8. A control knob for an appliance, the control knob comprising: a rotation modulating mechanism having an external portion and an internal portion, wherein rotation of the external portion at a first angular distance causes the internal portion to rotate a second angular distance, the first angular distance being different than the second angular distance; and an internal rotational mechanism having an encoder shaft and a transfer mechanism, wherein the encoder shaft is rotationally connected to an appliance control and the transfer mechanism, and wherein the transfer mechanism engages the internal portion of the rotation modulating mechanism to place a portion of the rotation modulating mechanism in communication with the appliance control, and wherein a rotation of the external portion in a first direction causes a rotation of the encoder shaft in a second direction that is opposite the first direction. 9. The control knob of claim 8 , further comprising: a stationary hub that is in a fixed position relative to the rotation modulating mechanism and the internal rotational mechanism, wherein the rotation modulating mechanism engages an outer surface of the stationary hub and rotates about the stationary hub, and wherein the internal rotational mechanism is disposed at least partially within an interior volume defined by the stationary hub. 10. The control knob of claim 9 , wherein the stationary hub includes a perimetrical wall that defines the interior volume of the stationary hub, and wherein the transfer mechanism of the internal rotational mechanism extends through an aperture defined within the perimetrical wall to engage the external portion of the rotation modulating mechanism. 11. The control knob of claim 8 , wherein the external portion of the rotation modulating mechanism includes planetary gears that extend between a stationary central sun gear and the internal portion of the rotation modulating mechanism, wherein the external portion includes planetary seats that hold the planetary gears in a fixed axial position relative to the external portion and allow the planetary gears to rotate within the planetary seats of the external portion, and wherein the external and internal portions of the rotation modulating mechanism rotate about the stationary central sun gear. 12. The control knob of claim 11 , wherein the external portion of the rotation modulating mechanism extends from at least the planetary gears to the transfer mechanism of the internal rotational mechanism. 13. The control knob of claim 12 , wherein the transfer mechanism includes a cluster gear having first and second gear portions, wherein the first gear portion engages the external portion of the rotation modulating mechanism and wherein the second gear portion engages the encoder shaft to transfer the rotation of the external portion to the encoder shaft. 14. The control knob of claim 13 , wherein the first and second gear portions define an inner reduction mechanism, wherein the first gear portion has a first diameter and the second gear portion has a second diameter, the first diameter being larger than the second diameter. 15. The control knob of claim 8 , further comprising: an auxiliary control ring positioned proximate the external portion of the rotation modulating mechanism, wherein the auxiliary control ring rotates independently of the external portion, and wherein the auxiliary control ring is in communication with a function encoder that operates a function control of the appliance control, and wherein the encoder shaft operates a temperature control of the appliance control. 16. An appliance control knob comprising: a stationary hub extending from a wall of an appliance, the stationary hub having an outer surface that defines a hub flange, wherein an appliance control is in communication with an interior volume of the stationary hub; a rotation modulating mechanism in rotational engagement with the outer surface of the stationary hub; an indicial ring that is positioned about the stationary hub and in rotational engagement with the rotation modulating mechanism, wherein rotation of the rotation modulating mechanism about the s