Coil skew detection and correction techniques for electric-potential driven shade, and/or associated methods

What is claimed is: 1. An insulating glass (IG) unit, comprising: a controller; first and second substrates, each having interior and exterior major surfaces, the interior major surface of the first substrate facing the interior major surface of the second substrate; a spacer system helping to maintain the first and second substrates in substantially parallel spaced apart relation to one another and to define a gap therebetween; a sensor located in the gap; and a dynamically controllable shade interposed between the first and second substrates, the shade including: a first conductive coating provided, directly or indirectly, on the interior major surface of the first substrate; a dielectric or insulator film provided, directly or indirectly, on the first conductive coating; and a shutter including a polymer substrate supporting a second conductive coating, wherein the polymer substrate is extendible to a shutter closed position and retractable to a shutter open position; wherein at least one of the first or second conductive coatings are electrically connectable to a power source that is controllable to set up an electric potential difference and create electrostatic forces to drive the polymer substrate to the shutter closed position; wherein the shutter, which has a coil in the shutter open position, is caused to uncoil when the polymer substrate is driven to the shutter closed position and re-coil when the polymer substrate returns to the shutter open position; wherein the sensor is configured to generate coil skew data indicative of measured coil skew when the polymer substrate is being driven to the shutter closed position and when the polymer substrate is returning to the shutter open position; and wherein the controller is configured to receive the generated coil skew data from the sensor, determine whether coil skew is occurring, and affect at least one of shutter extension or shutter retraction in response to a determination that coil skew is occurring. 2. The IG unit of claim 1 , wherein the coil skew data is indicative of positions of multiple areas of the shutter's coil. 3. The IG unit of claim 1 , wherein the coil skew data is processible to generate an image of the coil of the shutter. 4. The IG unit of claim 1 , wherein the sensor is a time-of-flight sensor. 5. The IG unit of claim 1 , wherein the sensor is a microphone. 6. The IG unit of claim 5 , wherein the microphone is configured to capture tick sounds, and wherein the controller is configured to determine whether coil skew has occurred by detecting two tick sounds separated from one another by more than a predetermined amount of time. 7. The IG unit of claim 1 , wherein the controller, in response to the determination that coil skew is occurring, is configured to apply or withdraw voltage to cause at least a portion of the shutter to move. 8. The IG unit of claim 1 , wherein the controller is configured to cause the shutter to: partially re-coil when it is determined that coil skew is occurring while the polymer substrate is being driven to the shutter closed position, and partial uncoil when it is determined that coil skew is occurring while the polymer substrate is returning to the shutter open position. 9. The IG unit of claim 1 , wherein the controller is configured to: determine whether coil skew is still present after partial re-coiling and after partial uncoiling, and in response to a determination that coil skew is still present, cause the shutter to continue re-coiling or uncoiling. 10. The IG unit of claim 1 , wherein the controller is further configured to use sensor data to determine whether the shutter is at least one of extending or retracting at a speed outside of an expected tolerance. 11. The IG unit of claim 1 , wherein the controller is further configured to use sensor data to determine shutter coil position after power to the IG unit is interrupted. 12. The IG unit of claim 1 , wherein the first conductive coating is divided into a plurality of zones that are electrically isolated from one another, the zones being individually powerable to cause selective movement of the shutter. 13. The IG unit of claim 12 , the sensor includes circuitry configured to detect coil skew based on (a) different zones having measured capacitances that differ from one another by more than a predetermined threshold, or (b) different zones having measured capacitances that differ from reference capacitance(s) by more than a predetermined threshold. 14. A glass substrate, comprising a dynamically controllable shade provided thereon, the shade including: a first conductive coating provided, directly or indirectly, on a major surface of the substrate; a dielectric or insulator film provided, directly or indirectly, on the first conductive coating; and a shutter including a polymer substrate supporting a second conductive coating, wherein the polymer substrate is extendible to a shutter closed position and retractable to a shutter open position; wherein at least one of the first or second conductive coatings are electrically connectable to a power source that is controllable to set up an electric potential difference and create electrostatic forces to drive the polymer substrate to the shutter closed position; wherein the shutter, which has a coil in the shutter open position, is caused to uncoil when the polymer substrate is driven to the shutter closed position and re-coil when the polymer substrate returns to the shutter open position; wherein a sensor coupleable to the substrate is configured to generate coil skew data indicative of measured coil skew when the polymer substrate is being driven to the shutter closed position and when the polymer substrate is returning to the shutter open position; and wherein a controller is configured to receive the generated coil skew data from the sensor, determine whether coil skew is occurring, and affect at least one of shutter extension or shutter retraction in response to a determination that coil skew is occurring. 15. A method of making an insulating glass (IG) unit, the method comprising: having first and second substrates, each having interior and exterior major surfaces, the interior major surface of the first substrate facing the interior major surface of the second substrate; providing a dynamically controllable shade on at least one of the first or second substrate, the shade including: a first conductive coating provided, directly or indirectly, on the interior major surface of the first substrate, the first conductive coating being divided into a plurality of zones that are electrically isolated from one another; a dielectric or insulator film provided, directly or indirectly, on the first conductive coating; and a shutter including a polymer substrate supporting a second conductive coating, wherein the polymer substrate is extendible to a shutter closed position and retractable to a shutter open position; connecting the first and second substrates to one another in substantially parallel, spaced apart relation, such that a gap is defined therebetween and such that the dynamically controllable shade is located in the gap; wherein a sensor is located in the gap; wherein at least one of the first or second conductive coatings are electrically connectable to a power source that is controllable to set up an electric potential difference and create electrostatic forces to drive the polymer substrate to the shutter closed position; wherein the shutter, which has a coil in the shutter open position, is caused to uncoil when the polymer substrate is driven to the shutter c