Slot die position adjustment control

The invention claimed is: 1. A method of controlling a slot die, the slot die including: an applicator slot extending about a width of the slot die, wherein the applicator slot is in fluid communication with a fluid flow path through the slot die, a plurality of measurement instruments, each one being configured to provide a local measurement of a cross-directional thickness of the fluid flow path at the location of the respective measurement instrument; and a plurality of actuators spaced about the width of the applicator slot of the slot die, wherein each actuator in the plurality of actuators is operable to adjust the cross-directional thickness of the fluid flow path at its respective location to provide a local adjustment of fluid flow through the applicator slot, the method comprising: providing a controller in communication with each actuator and measurement instrument, wherein the controller is configured to set a position of each actuator according to one of a plurality of discrete settings, measuring, via the plurality of measurement instruments, a first die slot thickness profile including the local measurements of the cross-directional thickness of the fluid flow path at the location of the respective measurement instruments; operating the slot die by passing an extrudate through the fluid flow path and out the applicator slot with the actuators positioned according to the first die slot thickness profile; measuring, via a sensor, a cross-web thickness profile of the extrudate after it exits the applicator slot; determining, via the controller, an improved die slot thickness profile based on a fluid dynamic model of the die incorporating parameters of die dimensions and fluid rheology, the fluid dynamic model including determining the improved die slot thickness profile as a function of variables including the measured cross-web thickness profile, the preselected cross-web thickness profile, and the measured first die slot thickness profile including the local measurements of the cross-directional thickness of the fluid flow path, the improved die slot thickness profile corresponding to an improved set of discrete settings from the plurality of discrete settings, the improved set of discrete settings being configured to provide an improved cross-web thickness profile of the extrudate after it exits the applicator slot that more closely matches the preselected cross-web thickness profile; adjusting, via the controller, the location of each actuator according to the improved set of discrete settings; and continuing to operate the slot die by passing the extrudate through the fluid flow path and out the applicator slot while adjusting the actuators according to the improved set of discrete settings. 2. The method of claim 1 , further comprising retrieving, with the controller, the preselected cross-web thickness profile from a non-transitory computer readable medium. 3. The method of claim 1 , further comprising receiving, with the controller, the preselected cross-web thickness profile from a user input. 4. The method of claim 1 , wherein the slot die is selected from a group consisting of: a film slot die; a multi-layer slot die; a hot melt extrusion coating die; a drop die; a rotary rod die; an adhesive slot die; a solvent coating slot die; a water-based coating die; and a slot fed knife die. 5. The method of claim 1 , wherein the slot die further comprising at least one of a choker bar extending across the width of the applicator slot, the plurality of actuators being attached to and providing local adjustment of the choker bar, a rotary rod and die lip opposing the rotary rod, the applicator slot being between the rotary rod and die lip, and the plurality of actuators being operable to move the rotary rod relative to the die lip, or a flexible die lip on one side of the applicator slot, the plurality of actuators being operable to move the flexible die lip. 6. The method of claim 1 , wherein the improved die slot thickness profile is determined further based on a preselected die cavity pressure. 7. The method of claim 1 , wherein the function of the improved die slot thickness profile B′ i is expressed as: B i ′ = B i ⁡ ( t i ′ t i ) ( 1 / 2 + 1 n ) wherein t i is the measured cross-web thickness profile, t′ i is the preselected cross-web thickness profile, B i is the measured first die slot thickness profile, and n is a power law index. 8. A method of controlling a slot die, the slot die including: an applicator slot extending about a width of the slot die, wherein the applicator slot is in fluid communication with a fluid flow path through the slot die, said flow path including a die cavity upstream of the applicator slot, a plurality of measurement instruments each one being configured to provide a local measurement of a cross-directional thickness of the fluid flow path at the location of the respective measurement instrument; and a plurality of actuators spaced about the width of the applicator slot of the slot die, wherein each actuator in the plurality of actuators is operable to adjust the cross-directional thickness of the fluid flow path at its respective location to provide a local adjustment of fluid flow through the applicator slot, the method comprising: providing a controller in communication with each actuator and measurement instrument, wherein the controller is configured to set the position of each actuator according to one of a plurality of discrete settings, measuring, via the plurality of measurement instruments, a first die slot thickness profile including the local measurements of the cross-directional thickness of the fluid flow path at the location of the respective measurement instruments; operating the slot die by passing an extrudate through the fluid flow path and out the applicator slot with the actuators positioned according to the first die slot thickness profile; measuring a die cavity pressure while operating the slot die; determining, via the controller, an improved die slot thickness profile based on a fluid dynamic model of the die incorporating parameters of die dimensions and fluid rheology including the measured first die slot thickness profile, the measured die cavity pressure, and a preselected die cavity pressure, the improved die slot thickness profile corresponding to an improved set of discrete settings from the plurality of discrete settings, the improved set of discrete settings being configured to provide a die cavity pressure that more closely matches the preselected die cavity pressure; adjusting, via the controller, the location of each actuator according to the improved set of discrete settings; and