Dual duty cycle OLED to enable dynamic control for reduced motion blur control with constant brightness in augmented reality experiences

What is claimed is: 1. A head-mounted display device, comprising: a microdisplay, the microdisplay is configured to display an augmented reality image and comprises a panel of light-emitting diodes arranged in rows; a sensor, the sensor is configured to sense an angular velocity of a user's head; and at least one control circuit, the at least one control circuit, to reduce motion blur of the augmented reality image, is configured to control the microdisplay responsive to the angular velocity by concurrently decreasing a row duty cycle of the rows and increasing a panel duty cycle of the panel. 2. The head-mounted display device of claim 1 , wherein: a decrease in the row duty cycle is proportional to an increase in the panel duty cycle so that an on time for each light-emitting diode and, therefore, a brightness level of the panel, is substantially constant during a frame period of the augmented reality image. 3. The head-mounted display device of claim 1 , wherein: the row duty cycle is decreased and the panel duty cycle is increased in proportion to the angular velocity. 4. The head-mounted display device of claim 1 , wherein: the angular velocity is in an azimuthal direction with respect to a coordinate system of the head-mounted display device. 5. The head-mounted display device of claim 1 , wherein: for each row, the row duty cycle is provided according to a respective row duty cycle control signal which transitions from an associated on level to an associated off level; the panel duty cycle is provided according to a panel duty cycle control signal which transitions between associated on and off levels; and the light-emitting diodes of each row are on when the row duty cycle is at the associated on level concurrently with the panel duty cycle being at the associated on level, and are off at other times. 6. The head-mounted display device of claim 1 , wherein: each light-emitting diode comprises a capacitor which is charged to a desired level according to a desired brightness of the light-emitting diode; and for each light-emitting diode, the capacitor is in a charged state when a respective row duty cycle control signal is at an associated on level and in a discharged state when the respective row duty cycle control signal transitions to an associated off level. 7. The head-mounted display device of claim 6 , wherein: for each light-emitting diode, the capacitor is provided in the discharged state by writing blackout data to the light-emitting diode. 8. The head-mounted display device of claim 1 , wherein: the augmented reality image comprises a frame of image data which is written to the light-emitting diodes in a frame period; the panel has an angular resolution; the at least one control circuit is configured to determine a number of pixels which are subtended in the frame period according to a product of the angular velocity and the angular resolution and the frame period, each pixel comprising one or more of the light-emitting diodes; and the row duty cycle is decreased and the panel duty cycle is increased according to the number of pixels which are subtended in the frame period. 9. The head-mounted display device of claim 1 , wherein: the augmented reality image is locked to a fixed location in a world coordinate system while the row duty cycle of the rows is creased and the panel duty cycle of the panel is increased. 10. A method for controlling a head-mounted display device, comprising: displaying an augmented reality image using a panel of light-emitting diodes arranged in rows; sensing a rotation of a user's head; and determining when the rotation indicates that motion blur of the augmented reality image may occur; and when the rotation indicates that motion blur of the augmented reality image may occur, reducing or avoiding the motion blur by concurrently decreasing a row duty cycle of the rows and increasing a panel duty cycle of the panel. 11. The method of claim 10 , wherein: the rotation indicates that motion blur of the augmented reality image may occur when an angular velocity of the head exceeds a threshold. 12. The method of claim 10 , wherein: a decrease in the row duty cycle is proportional to an increase in the panel duty cycle so that an on time for each light-emitting diode and, therefore, a brightness level of the panel, is substantially constant during a frame period of the augmented reality image. 13. The method of claim 10 , wherein: for each row, the row duty cycle is provided according to a respective row duty cycle control signal which alternates between associated on and off levels; the panel duty cycle is provided according to a panel duty cycle control signal which alternates between associated on and off levels; and the light-emitting diodes of each row are on when the row duty cycle is at the associated on level concurrently with the panel duty cycle being at the associated on level, and are off at other times. 14. The method of claim 10 , wherein: the augmented reality image is locked to a fixed location in a world coordinate system during the rotation of the user's head over multiple frames of the augmented reality image. 15. A computer-readable hardware memory having computer-readable software embodied thereon for programming a processor to perform a method for controlling a head-mounted display device, the method comprising: controlling a panel of light-emitting diodes arranged in rows to display an augmented reality image, the controlling comprises setting a row duty cycle of the rows at an associated initial level and setting and a panel duty cycle of the panel at an associated initial level; determining that a user's head is rotating during a time period; and during the time period, setting the row duty cycle at a lower level than the associated initial level of the rows and setting the panel duty cycle to a higher level than the associated initial level of the panel. 16. The computer-readable hardware memory of claim 15 , wherein: the lower level and the higher level are in proportion to an angular velocity of the user's head. 17. The computer-readable hardware memory of claim 15 , wherein the method performed further comprises: after the time period, setting the row duty cycle at the associated initial level of the rows and setting the panel duty cycle at the associated initial level of the panel. 18. The computer-readable hardware memory of claim 15 , wherein: the time period extends over multiple frame periods of the augmented reality image. 19. The computer-readable hardware memory of claim 15 , wherein: the augmented reality image is locked to a fixed location in a world coordinate system. 20. The computer-readable hardware memory of claim 15 , wherein: a brightness level of the panel, is substantially constant during the time period.