The present invention generally relates to active matrix displays of any type (e.g., active matrix electrophoretic displays and active matrix liquid crystal displays). The present invention specifically relates to an addressing scheme for active matrix displays employing pixels with each pixel having a memory element in the form of ferroelectric thin film transistor.
In operation, ferroelectric thin film transistor 15 can be switched between a conductive state commonly known as a normally-on state and a non-conductive state commonly known as a normally-off state based on a differential voltage VGS between a gate voltage VG and a source voltage VS and a differential voltage VDS between drain voltage VD and the source voltage VS both having an amplitude that generates an electric field over ferroelectric insulator layer 16 that is higher than a coercive electric field associated with ferroelectric insulator layer 16. Specifically, differential voltages VGS and VDS both having an amplitude that is equal to or less than a negative switching threshold −ST generates an electric field over ferroelectric insulator layer 16 that switches ferroelectric thin film transistor 15 to a normally-on state. Conversely, differential voltages VGS and VDS both having an amplitude that is equal to or greater than a positive switching threshold +ST generates an electric field over ferroelectric insulator layer 16 that switches ferroelectric thin film transistor 15 to a normally-off state.
The present invention provides a new and unique addressing scheme for active matrix displays employing pixels having memories elements in the form of ferroelectric thin film transistors in view of selectively switching each ferroelectric thin film transistor between a conductive state and a non-conductive state during an addressing period for an corresponding pixel.
In one form of the present invention, a display comprises a row driver, a column driver and a pixel, which includes a memory element in the form of a ferroelectric thin film transistor operably coupled to the row driver and the column driver, and a display element operably coupled to the ferroelectric thin film transistor. The row driver and the column driver are operable to apply different sets of drive voltages to the ferroelectric thin film transistor during a beginning phase, an intermediate phase and an ending phase of an addressing period for the pixel. The ferroelectric thin film transistor is operable to be set to a conductive state in response to a conductive row drive voltage and a conductive column drive voltage being applied to the ferroelectric thin film transistor by the row driver and the column driver during the beginning phase of the addressing period for the pixel. The ferroelectric thin film transistor is further operable to facilitate a charging of the display element in response to a charging row drive voltage and a charging column drive voltage being applied to the ferroelectric thin film transistor by the row driver and the column driver during the intermediate phase of the addressing period for the pixel. The ferroelectric thin film transistor is further operable to be reset to a non-conductive state in response to a non-conductive row drive voltage and a non-conductive column drive voltage being applied to the ferroelectric thin film transistor by the row driver and the column driver during the ending phase of the addressing period for the pixel.
The foregoing form and other forms of the present invention as well as various features and advantages of the present invention will become further apparent from the following detailed description of various embodiments of the present invention read in conjunction with the accompanying drawings. The detailed description and drawings are merely illustrative of the present invention rather than limiting, the scope of the present invention being defined by the appended claims and equivalents thereof.
A display 20 of the present invention as illustrated in
A memory element 60 in the form of a ferroelectric thin film transistor and a display element 62 of the present invention are illustrated in
In operation, a row drive voltage VR can be applied to gate electrode G of ferroelectric thin film transistor 60 by row driver 30 and a column drive voltage VC can be applied to a source electrode S of ferroelectric thin film transistor 60 by column driver 40 whereby display element 62 can be selectively charged in dependence of a differential between a drain electrode voltage VDE and a common electrode voltage VCE. The present invention provides a new and unique active matrix addressing scheme representative by a flowchart 70 as illustrated in
Referring to
A stage S74 of flowchart 70 encompasses applying row drive voltage VR as a charging row drive voltage VIRD to gate electrode G of ferroelectric thin film transistor 60 and applying column drive voltage VC as a charging column drive voltage VICD to source electrode S of ferroelectric thin film transistor 60 during an intermediate phase of the addressing period for the pixel. In this intermediate phase, differential voltage VGS between charging row drive voltage VIRD and charging column drive voltage VICD is designed to be less than the positive switching threshold +ST whereby ferroelectric thin film transistor 60 is maintained in the normally-on state.
A stage S76 of flowchart 70 encompasses applying row drive voltage VR as a non-conductive row drive voltage VERD to gate electrode G of ferroelectric thin film transistor 60 and applying column drive voltage VC as a non-conductive column drive voltage VECD to source electrode S of ferroelectric thin film transistor 60 during an ending phase of the addressing period for the pixel. In this ending phase, differential voltage VGS between non-conductive row drive voltage VERD and non-conductive column drive voltage VECD is designed to be equal to or greater than the positive switching threshold +ST whereby ferroelectric thin film transistor 60 is switched to a normally-off state (i.e., a non-conductive state) that results in the charging of the pixel during the intermediate phase being retained by the pixel.
To facilitate an understanding of the active matrix addressing scheme of the present invention as embodied in
Referring to
The result is the transistors of pixels P(12), P(21) and P(32) being switched to a normally-on state (i.e., conductive state) while the transistors of the remaining pixels are maintained in the initial normally-off state as illustrated in
Referring to
Referring to
Referring to
The result is transistors of pixels P(11), P(13) and P(33) being switched to a normally-on state (i.e., conductive state) while the transistors of the remaining pixels are maintained in the initial normally-off state as illustrated in
Referring to
Referring to
A total time for addressing the 3×3 pixel matrix based on a width/length ratio of transistors 60 being 20 is equal to stage S82: (3 rows×1 microsecond)+stage S84: (−15 volt charging time)+stage S86: (1 microsecond)+stage S88: (3 rows×1 microsecond)+stage S90: (+15 volt charging time)+stage S92: (1 microsecond) with the total time for addressing one or more additional rows increasing by 2 microseconds per additional row. This supports the beneficial use of larger panels with small transistors 60 having low field-effect mobility.
To further facilitate an understanding of the active matrix addressing scheme of the present invention as embodied in
Referring to
Referring to
Referring to
Referring to
While the embodiments of the invention disclosed herein are presently considered to be preferred, various changes and modifications can be made without departing from the spirit and scope of the invention. The scope of the invention is indicated in the appended claims, and all changes that come within the meaning and range of equivalents are intended to be embraced therein.
Filing Document | Filing Date | Country | Kind | 371c Date |
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PCT/IB2006/054107 | 11/3/2007 | WO | 00 | 5/30/2008 |
Publishing Document | Publishing Date | Country | Kind |
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WO2007/057811 | 5/24/2007 | WO | A |
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