Method for reducing cross-talk in a field emission display

Method reducing cross-talk between adjacent column conductors in a field emission display (10) that has a plurality of column conductors (17A, 17B, 17C, 18A, 18B, 18C) on which electron emission structures (24) are disposed. The field emission display (10), also includes a plurality of row conductors (27, 28, 29). Cross-talk is prevented by ensuring that adjacent conductors are not in an active state at the same time.

FIELD OF THE INVENTION

The present invention relates, in general, to field emission displays and, more particularly, to methods and circuits for controlling emission current in the field emission displays.

BACKGROUND OF THE INVENTION

Field emission displays (FED's) are well known in the art. A field emission display includes an anode plate and a cathode plate that define a thin envelope. The cathode plate includes a matrix of column conductors and row conductors, which are used to cause electron emission from electron emitter structures such as, Spindt tips. FED's further include ballast resistors between the electron emitter structures and the cathode plate for controlling the electron emission current. In addition to the desired FED components, a parasitic fringe capacitance is formed between adjacent column conductors. These parasitic fringe capacitances allow cross-talk between adjacent column conductors when one of the column conductors switches from a high impedance state to a high voltage state. The cross-talk may result in a glitch on the column conductor that remains in the high impedance state where the glitch introduces error that appears in the picture appearing on the field emission display.

Accordingly, there exists a need for a method for controlling the adjacent column capacitance in a field emission display, which overcomes at least some of these shortcomings.

DETAILED DESCRIPTION OF THE DRAWINGS

Generally, the present invention is for a method of reducing cross-talk between adjacent columns in a Field Emission Display (FED). The method includes activating alternate column conductors of the FED such that adjacent column conductors do not both switch during the same portion of a single line time. In accordance with one embodiment of the present invention, during a single scan, a frame is divided into two sub-frames in which alternate column conductors are activated. In accordance with another embodiment of the present invention, a single line time is divided into two portions. Then a single row is selected and during the first portion of the single line time every other column conductor of the display is activated. During the second portion of the single line time the column conductors not activated during the first portion are activated, i.e., the alternate column conductors that were not activated during the first portion of the single line time are activated during the second portion of the single line time.

FIG. 1 is a partially cut-away isometric view and circuit schematic representation of a field emission display (FED) 10 in accordance with an embodiment of the present invention. FED 10 includes an FED device 11 and control circuitry 12 for controlling emission current in FED device 11 .

FED device 11 includes a cathode plate 13 and an anode plate 14 . Cathode plate 13 includes a substrate 16 , which can be made from glass, silicon, and the like. A plurality of column conductors 17 A, 17 B, and 17 C and a plurality of column conductors 18 A, 18 B, and 18 C are disposed on substrate 16 . Plurality of column conductors 17 A, 17 B, and 17 C are interdigitated with plurality of column conductors 18 A, 18 B, and 18 C. It should be noted that column conductors 17 A, 17 B, and 17 C are related to one another in that they are capable of being activated during a same portion of the line time, while column conductors 18 A, 18 B, and 18 C are turned off or inactivated. Likewise, column conductors 18 A, 18 B, and 18 C are related to one another in that they are capable of being activated during the same portion of the line time, while column conductors 17 A, 17 B, and 17 C are turned off or inactivated. A dielectric layer 21 is disposed upon column conductors 17 A, 17 B, 17 C, 18 A, 18 B, and 18 C, and further defines a plurality of wells 22 .

An electron emitter structure 24 such as, for example, a Spindt tip, is disposed in each of wells 22 . Row conductors 27 , 28 , and 29 are formed on dielectric layer 21 . Row conductors 27 , 28 , and 29 are spaced apart from and proximate to electron emitter structures 24 . Row conductors 27 , 28 , and 29 include a plurality of apertures 30 which cooperate with corresponding wells 22 and electron emitter structures 24 to form current emission regions 31 . Column conductors 17 A, 17 B, 17 C, 18 A, 18 B, and 18 C and row conductors 27 , 28 , and 29 are used to selectively address electron emitter structures 24 .

To facilitate understanding the present invention, FIG. 1 depicts only three row conductors and six column conductors. However, it is desired to be understood that any number of row and column conductors can be employed. An exemplary number of row conductors for an FED device is 240 and an exemplary number of column conductors is 960 . Methods for fabricating cathode plates for matrix-addressable field emission displays are known to one of ordinary skill in the art.

Anode plate 14 is disposed to receive an emission current 32 , which is defined by the electrons emitted by electron emitter structures 24 . Anode plate 14 includes a transparent substrate 33 made from, for example, glass. An anode 34 is disposed on transparent substrate 33 . Anode 34 is preferably made from a transparent conductive material, such as indium tin oxide. In the preferred embodiment, anode 34 is a continuous layer that opposes the entire emissive area of cathode plate 13 . That is, anode 34 preferably opposes the entirety of electron emitter structures 24 .

A plurality of phosphors 36 is disposed upon anode 34 . Phosphors 36 are cathodoluminescent. Thus, phosphors 36 emit light upon activation by emission current 32 . Methods for fabricating anode plates for matrix-addressable field emission displays are also known to one of ordinary skill in the art.

FIG. 2 is a schematic diagram of cathode plate 13 of FED 10 . What is shown in FIG. 2 is a schematic representation of column conductors 17 A, 17 B, 17 C, 18 A, 18 B, and 18 C, column conductor driver circuits 47 A, 47 B, 47 C, 48 A, 48 B, and 48 C, row conductors 27 , 28 , and 29 , and row conductor driver circuits 37 , 38 , and 39 . It should be understood that although three row conductor driver circuits and six column conductor driver circuits are shown, there may be a fewer number or a greater number of row conductor driver circuits and a fewer number or a greater number of column conductor driver circuits.

FIG. 2 further illustrates electron emission structures, sub-pixel capacitances, parasitic fringe capacitances, and ballast resistors associated with each row and column of FED 10 . More particularly, sub-pixel capacitance 51 , sub-pixel ballast resistor 52 , and electron emission structure 24 (27, 17A) associated with sub-pixel 50 are shown as being coupled to row conductor 27 and column conductor 17 A. Electron emission structure 24 (27, 17A) is shown as a lumped element representing all the electron emission structures associated with sub-pixel 50 . It should be understood that the reference number 24 has been used to identify electron emitter structures in general. To help explain the embodiment shown in FIG. 2 , the electron emission structures have been further defined by appending subscripts to reference number 24 . For example, the electron emission structures associated with row conductor 27 and column conductor 17 A have been identified by reference number 24 (27, 17A) the electron emission structures associated with row conductor 28 and column conductor 17 A have been identified by reference number 24 (28, 17A) , the electron emission structures associated with row conductor 27 and column conductor 18 A have been identified by reference number 24 (27, 18A) , etc.

Sub-pixel capacitance 53 , sub-pixel ballast resistor 54 , and electron emission structure 24 (28, 17A) associated with sub-pixel 57 are shown as being coupled to row conductor 28 and column conductor 17 A. Electron emission structure 24 (28, 17A) is shown as a lumped element representing all the electron emission structures associated with sub-pixel 57 .

Sub-pixel capacitance 55 , sub-pixel ballast resistor 56 , and electron emission structure 24 (29, 17A) associated with sub-pixel 58 are shown as being coupled to row conductor 29 and column conductor 17 A. Electron emission structure 24 (29, 17A) is shown as a lumped element representing all the electron emission structures associated with sub-pixel 58 .

Sub-pixel capacitance 61 , sub-pixel ballast resistor 62 , and electron emission structure 24 (27, 18A) associated with sub-pixel 60 are shown as being coupled to row conductor 27 and column conductor 18 A. Electron emission structure 24 (27 18A) is shown as a lumped element representing all the electron emission structures associated with sub-pixel 60 .

Sub-pixel capacitance 63 , sub-pixel ballast resistor 64 , and electron emission structure 24 (28, 18A) associated with sub-pixel 67 are shown as being coupled to row conductor 28 and column conductor 18 A. Electron emission structure 24 (28, 18A) is shown as a lumped element representing all the electron emission structures associated with sub-pixel 67 .

Sub-pixel capacitance 65 , sub-pixel ballast resistor 66 , and electron emission structure 24 (29, 18A) associated with sub-pixel 68 are shown as being coupled to row conductor 29 and column conductor 18 A. Electron emission structure 24 (29, 18A) is shown as a lumped element representing all the electron emission structures associated with sub-pixel 68 .

Sub-pixel capacitance 71 , sub-pixel ballast resistor 72 , and electron emission structure 24 (27, 17B) associated with sub-pixel 70 are shown as being coupled to row conductor 27 and column conductor 17 B. Electron emission structure 24 (27, 17B) is shown as a lumped element representing all the electron emission structures associated with sub-pixel 70 .

Sub-pixel capacitance 73 , sub-pixel ballast resistor 74 , and electron emission structure 24 (28, 17B) associated with sub-pixel 77 are shown as being coupled to row conductor 28 and column conductor 17 B. Electron emission structure 24 (28, 17B) is shown as a lumped element representing all the electron emission structures associated with sub-pixel 77 .

Sub-pixel capacitance 75 , sub-pixel ballast resistor 76 , and electron emission structure 24 (29, 17B) associated with sub-pixel 78 are shown as being coupled to row conductor 29 and column conductor 17 B. Electron emission structure 24 (29, 17B) is shown as a lumped element representing all the electron emission structures associated with sub-pixel 78 .

Sub-pixel capacitance 81 , sub-pixel ballast resistor 82 , and electron emission structure 24 (27, 18B) associated with sub-pixel 80 are shown as being coupled to row conductor 27 and column conductor 18 B. Electron emission structure 24 (27, 18B) is shown as a lumped element representing all the electron emission structures associated with sub-pixel 80 .

Sub-pixel capacitance 83 , sub-pixel ballast resistor 84 , and electron emission structure 24 (28, 18B) associated with sub-pixel 87 are shown as being coupled to row conductor 28 and column conductor 18 B. Electron emission structure 24 (28, 18B) is shown as a lumped element representing all the electron emission structures associated with sub-pixel 87 .

Sub-pixel capacitance 85 , sub-pixel ballast resistor 86 , and electron emission structure 24 (29, 18B) associated with sub-pixel 88 are shown as being coupled to row conductor 29 and column conductor 18 B. Electron emission structure 24 (29, 18B) is shown as a lumped element representing all the electron emission structures associated with sub-pixel 88 .

Sub-pixel capacitance 91 , sub-pixel ballast resistor 92 , and electron emission structure 24 (27, 17C) associated with sub-pixel 90 are shown as being coupled to row conductor 27 and column conductor 17 C. Electron emission structure 24 (27, 17C) is shown as a lumped element representing all the electron emission structures associated with sub-pixel 90 .

Sub-pixel capacitance 93 , sub-pixel ballast resistor 94 , and electron emission structure 24 (28, 17C) associated with sub-pixel 97 are shown as being coupled to row conductor 28 and column conductor 17 C. Electron emission structure 24 (28, 17C) is shown as a lumped element representing all the electron emission structures associated with sub-pixel 97 .

Sub-pixel capacitance 95 , sub-pixel ballast resistor 96 , and electron emission structure 24 (29, 17C) associated with sub-pixel 98 are shown as being coupled to row conductor 29 and column conductor 17 C. Electron emission structure 24 (29, 17C) is shown as a lumped element representing all the electron emission structures associated with sub-pixel 98 .

Sub-pixel capacitance 101 , sub-pixel ballast resistor 102 , and electron emission structure 24 (27, 18C) associated with sub-pixel 100 are shown as being coupled to row conductor 27 and column conductor 18 C. Electron emission structure 24 (27, 18C) is shown as a lumped element representing all the electron emission structures associated with sub-pixel 100 .

Sub-pixel capacitance 103 , sub-pixel ballast resistor 104 , and electron emission structure 24 (28, 18C) associated with sub-pixel 107 are shown as being coupled to row conductor 28 and column conductor 18 C. Electron emission structure 24 (28, 18C) is shown as a lumped element representing all the electron emission structures associated with sub-pixel 107 .

Sub-pixel capacitance 105 , sub-pixel ballast resistor 106 , and electron emission structure 24 (29, 18C) associated with sub-pixel 108 are shown as being coupled to row conductor 29 and column conductor 18 C. Electron emission structure 24 (29, 18C) is shown as a lumped element representing all the electron emission structures associated with sub-pixel 108 .

Column conductor 17 A is coupled to column conductor 18 A via a parasitic fringe capacitance 111 . Capacitance 111 couples cross-talk between a column conductor that is switching from being in a high impedance state to one at a high voltage. For example if sub-pixels 50 and 60 are both on, i.e., emitting current, then column driver circuits 47 A and 48 A are in a high impedance state. Capacitances 51 and 61 are discharging and capacitors 53 , 63 , 55 , and 65 are discharging at rates defined by the currents being emitted by the respective sub-pixels 50 and 60 . When sub-pixel 50 has emitted a sufficient charge, column driver circuit 17 A switches to a high voltage, V COL , thereby turning off sub-pixel 50 . Assuming sub-pixel 60 has not yet emitted enough charge, column driver circuit 48 A remains in a high impedance state. However, a voltage glitch is produced on column conductor 18 A by the switching of column conductor driver circuit 47 A.

The approximate amplitude of the voltage glitch, V GLI47A , is approximated by:

where

V COL is the column switching voltage;

C 111 is the capacitance value of capacitance 111 ;

C 51 is the capacitance value of capacitance 51 ;

C 53 is the capacitance value of capacitance 53 ; and

C 55 is the capacitance value of capacitance 55 .

In another example, if sub-pixels 97 and 107 are both on, i.e., emitting current, then column driver circuits 47 C and 48 C are in a high impedance state. Capacitances 93 and 103 are discharging and capacitances 91 , 95 , 101 , and 105 are charging at rates defined by the currents being emitted by the respective sub-pixels 97 and 107 . When sub-pixel 107 has emitted a sufficient charge, column driver circuit 47 C switches to a high voltage, thereby turning off sub-pixel 107 . Assuming sub-pixel 97 has not yet emitted enough charge, column driver circuit 48 C remains in a high impedance state. However, a voltage glitch is produced on column conductor 17 C by the switching of column conductor driver circuit 48 C.

The approximate amplitude of the voltage glitch, V GLI48C , is given by:

where

V COL the column switching voltage;

C 115 is the capacitance value of capacitance 115 ;

C 103 is the capacitance value of capacitance 103 ;

C 101 is the capacitance value of capacitance 101 ; and

C 105 is the capacitance value of capacitance 105 .

If the glitch is too large, it will degrade the image quality of the display of FED 10 . It should be noted that each column conductor is coupled to an adjacent column conductor by a parasitic fringe capacitance. In the present embodiment, column conductor 18 A is coupled to column conductor 17 B by fringe capacitance 112 ; column conductor 17 B is coupled to column conductor 18 B by fringe capacitance 113 ; column conductor 18 B is coupled to column conductor 17 C by fringe capacitance 114 ; and column conductor 17 C is coupled to column conductor 18 C by fringe capacitance 115 .

Thus, FED 10 is operated so adjacent column conductors are not in an active mode at the same time. For example, if column conductor 18 A is in an active mode, column conductors 17 A and 17 B are inactive or turned off. It should be understood that when in an active mode, the electron emitter structures are capable of emitting electrons. That is to say, they are not necessarily emitting electrons, whereas an in inactive mode, the electron emitter structures are incapable of emitting electrons because the column conductor driver circuits place voltages on the column conductors that prevent the electron emitter structures 24 from emitting current.

At time t 1 , column conductor driver circuits 47 A, 47 B, and 47 C are placed in a high impedance state and are, therefore, electrically disconnected from FED 10 . Row conductor driver circuits 37 , 38 , and 39 are then sequentially activated as indicated in timing diagram 200 shown in FIG. 3 . Activating row conductor driver circuits such as row conductor driver circuits 37 , 38 , and 39 is also referred to as applying a row select voltage to the corresponding row electrodes. Similarly, activating a column driver circuit such as, column driver circuits 47 A, 47 B, 47 C, 48 A, 48 B, 48 C is also referred to as applying a column select voltage to the corresponding column conductor. At time t 1 , row conductor driver circuits 37 , 38 , and 39 are outputting, for example, zero volts. This places zero volts on row conductors 27 , 28 , and 29 , respectively. The outputs of column conductor driver circuits 47 A, 47 B, and 47 C remain in a high impedance state and the outputs of column conductor driver circuits 48 A, 48 B, and 48 C are at a high voltage.

At time t 2 , row conductor driver circuit 37 is activated and places a voltage greater than the threshold voltage of the electron emitter structures on row conductor 27 . By way of example, the voltage placed on row conductor 27 is eighty volts. Row conductor driver circuits 38 and 39 continue to maintain row conductors 28 and 29 , respectively, at zero volts.

When the column conductor driver circuits are in a high impedance state and the electron emitter structures are emitting current, the column conductor driver circuits preferably monitor the voltage on the column conductor. The change in voltage measured on the column conductor is proportional to the charge or current emitted by the electron emitter structures. It should be understood that column conductor driver circuits 47 A, 47 B, and 47 C monitor the voltage on column conductors 17 A, 17 B, and 17 C, respectively, and electron emitter structures 24 (27, 17A) 24 (27, 17B) and 24 (27, 17C) emit electrons or current. Column conductor driver circuits 47 A, 47 B, and 47 C compare the measured change in voltage on the respective column conductors 17 A, 17 B, and 17 C to voltages proportional to the desired intensity of sub-pixels 50 , 70 , and 90 , which proportional voltages were previously determined as described in the U.S. Patent application having Ser. No. 09/658,514 by Robert T. Smith, and assigned to Motorola, Inc, which patent application has been incorporated herein by reference. After electron emitter structures 24 (27, 17A) , 24 (27, 17B) , and 24 (27, 17C) have emitted the desired current, they are turned off by switching column conductor driver circuits 47 A, 47 B, and 47 C from the high impedance state to a high voltage state. This is shown as occurring at time t 3 in FIG. 3 .

At time t 4 , the output voltage of row conductor driver circuit 37 and column conductor driver circuits 47 A, 47 B, and 47 C are switched from a high voltage, e.g., eighty volts, to a low voltage, e.g., zero volts; thereby discharging capacitances 51 , 71 , and 91 associated with column conductors 17 A, 17 B, and 17 C, respectively.

At time t 5 , column conductor driver circuits 47 A, 47 B, and 47 C are placed in a high impedance state and the output voltage of row conductor driver circuit 38 transitions from a low voltage state, e.g., zero volts, to a high voltage state, e.g., eighty volts. Column conductor driver circuits 47 A, 47 B, and 47 C monitor the voltage on column conductors 17 A, 17 B, and 17 C, respectively, and electron emitter structures 24 (28, 17A) 24 (28, 17B) and 24 (28, 17C) emit current. Column conductor driver circuits 47 A, 47 B, and 47 C compare the measured change in voltage on the respective column conductors 17 A, 17 B, and 17 C to voltages proportional to the desired intensity of sub-pixels 57 , 77 , and 97 , which proportional voltages were previously determined. Column conductor driver circuits 47 A, 47 B, and 47 C shut off sub-pixels 57 , 77 , and 97 , respectively, after the proper amount of charge or current has been emitted. After the electron emitter structures 24 (28, 17A) , 24 (28, 17B) and 24 (28, 17C) have emitted the desired current, they are turned off by switching column conductor driver circuits 47 A, 47 B, and 47 C from the high impedance state to a high voltage state. This is shown as occurring at time t 6 in FIG. 3 .

At time t 7 , the output voltage of row conductor driver circuit 38 and column conductor driver circuits 47 A, 47 B, and 47 C switch from a high voltage, e.g., eighty volts, to a low voltage, e.g., zero volts; thereby discharging capacitances 53 , 73 , and 93 associated with column conductors 17 A, 17 B, and 17 C, respectively.

At time t 8 , column conductor driver circuits 47 A, 47 B, and 47 C are placed in a high impedance state and the output voltage of row conductor driver circuit 39 transitions from a low voltage state, e.g., zero volts, to a high voltage state, e.g., eighty volts. Column conductor driver circuits 47 A, 47 B, and 47 C monitor the voltages on column conductors 17 A, 17 B, and 17 C and electron emitter structures 24 (29, 17A) , 24 (29, 17B) and 24 (29, 17C) emit current. Column conductor driver circuits 47 A, 47 B, and 47 C compare the measured change in voltage on column conductors 17 A, 17 B, and 17 C, respectively, to a voltage proportional to the desired intensity of sub-pixels 58 , 78 , and 98 , which proportional voltage was previously determined. Column conductor driver circuits 47 A, 47 B, and 47 C shut off sub-pixels 58 , 78 , and 98 after the proper amount of charge or current has been emitted.

After the electron emitter structures 24 (29, 17A) 24 (29, 17B) , and 24 (29, 17C) have emitted the desired current, they are turned off by switching column conductor driver circuits 47 A, 47 B, and 47 C from the high impedance state to a high voltage state. This is shown as occurring at time t 9 in FIG. 3 . It should also be noted that at time t 9 , the output voltage of row conductor driver circuit 39 switches from a high voltage, e.g. eighty volts, to a low voltage, e.g., zero volts and the outputs of column conductor circuits 47 A, 47 B, and 47 C are maintained at a high voltage state since the pixels associated with column conductors 17 A, 17 B, and 17 C must remain inactive during second sub-frame 202 of frame 200 .; thereby discharging capacitances 55 , 75 , and 95 associated with column conductors 17 A, 17 B, and 17 C, respectively.

The second sub-frame 202 of frame 200 begins at a time between times t 9 and t 10 . During second half 202 , column conductor driver circuits 47 A, 47 B, and 47 C output, for example, eighty volts; thereby inactivating column conductors 17 A, 17 B, and 17 C, respectively. Column conductor driver circuits 48 A, 48 B, and 48 C, on the other hand, are activated. At time t 10 , display capacitances 61 , 63 , 65 , 81 , 83 , 85 , 101 , 103 , and 105 are discharged to zero volts because the output voltages of column conductor driver circuits 48 A, 48 B, and 48 C and row conductor driver circuits 37 , 38 , and 39 are such as to prevent electron emitter structures 24 from emitting current. By way of example, the output voltages of column conductor driver circuits 48 A, 48 B, and 48 C and the output voltages of row conductor driver circuits 37 , 38 , and 39 are driven to zero volts.

At time t 10 , column conductor driver circuits 48 A, 48 B, and 48 C are placed in a high impedance state and are, therefore, electrically disconnected from FED 10 . Row conductor driver circuits 37 , 38 , and 39 are then sequentially activated as indicated in timing diagram 200 shown in FIG. 3 . At time t 10 , row conductor driver circuits 37 , 38 , and 39 are outputting, for example, zero volts. This places zero volts on row conductors 27 , 28 , and 29 , respectively.

At time t 11 , row conductor driver circuit 37 is activated and places a voltage greater than the threshold voltage of the electron emitter structures on row conductor 27 . By way of example, the voltage placed on row conductor 27 is eighty volts. Row conductor driver circuits 38 and 39 continue to maintain row conductors 28 and 29 , respectively, at zero volts.

When the column conductor driver circuits are in a high impedance state and the electron emitter structures are emitting current, the column conductor driver circuits preferably monitor the voltage on the column conductor. The change in voltage measured on the column conductor is proportional to the charge or current emitted by the electron emitter structures. After the electron emitter structures 24 (27, 18A) , 24 (27, 18B) , and 24 (27, 18C) have emitted the desired current, they are turned off by switching column conductor driver circuits 48 A, 48 B, and 48 C from the high impedance state to a high voltage state. This is shown as occurring at time t 12 in FIG. 3 .

At time t 13 , the output voltages of row conductor driver circuit 37 and column conductor driver circuits 48 A, 48 B, and 48 C are switched from a high voltage, e.g., eighty volts, to a low voltage, e.g., zero volts; thereby discharging capacitances 61 , 81 , and 101 associated with column conductors 18 A, 18 B, and 18 C.

At time t 14 , column conductor driver circuits 48 A, 48 B, and 48 C are placed in a high impedance state and the output voltage of row conductor driver circuit 38 transitions from a low voltage state, e.g., zero volts, to a high voltage state, e.g., eighty volts. Column conductor driver circuits 48 A, 48 B, and 48 C monitor the voltage on column conductors 18 A, 18 B, and 18 C, respectively, and electron emitter structures 24 (28, 18A) 24 (28, 18B) , and 24 (28, 18C) emit current. Column conductor driver circuits 48 A, 48 B, and 48 C compare the measured change in voltage on the respective column conductors 18 A, 18 B, and 18 C to voltages proportional to the desired intensity of sub-pixels 67 , 87 , and 107 , which proportional voltages were previously determined. Column conductor driver circuits 48 A, 48 B, and 48 C shut off the respective sub-pixels 67 , 87 , and 107 after the desired amount of charge or current has been emitted. After electron emitter structures 24 (28, 18A) 24 (28, 18B) , and 24 (28, 18C) have emitted the desired current, they are turned off by switching column conductor driver circuits 48 A, 48 B, and 48 C from the high impedance state to a high voltage state. This is shown as occurring at time t 15 in FIG. 3 .

At time t 16 , the output voltage of row conductor driver circuit 38 and column conductor driver circuits 48 A, 48 B, and 48 C switch from a high voltage, e.g. eighty volts, to a low voltage, e.g., zero volts; thereby discharging capacitances 63 , 83 , and 103 associated with column conductors 18 A, 18 B, and 18 C, respectively.

At time t 17 , column conductor driver circuits 48 A, 48 B, and 48 C are placed in a high impedance state and the output voltage of row conductor driver circuit 39 transitions from a low voltage state, e.g., zero volts, to a high voltage state, e.g., eighty volts. Column conductor driver circuits 48 A, 48 B, and 48 C monitor the voltage on column conductors 18 A, 18 B, and 18 C and electron emitter structures 24 (29, 18A) , 24 (29, 18B) , and 24 (29, 18C) emit current. Column conductor driver circuits 48 A, 48 B, and 48 C compare the measured change in voltage on column conductors 18 A, 18 B, and 18 C, respectively, to a voltage proportional to the desired intensity of sub-pixels 68 , 88 , and 108 , which proportional voltage was previously determined. Column conductor driver circuits 48 A, 48 B, and 48 C shut off sub-pixels 68 , 88 , and 108 after the proper amount of charge or current has been emitted.

After the electron emitter structures 24 (29, 18A) , 24 (29, 18B) , and 24 (29, 18C) have emitted the desired current, they are turned off by switching column conductor driver circuits 48 A, 48 B, and 48 C from the high impedance state to a high voltage state. This is shown as occurring at time t 18 in FIG. 3 . It should also be noted that at time t 18 , the output voltage of row conductor driver circuit 39 switches from a high voltage, e.g. eighty volts, to a low voltage, e.g., zero volts; thereby discharging capacitances 65 , 85 , and 105 associated with column conductors 18 A, 18 B, and 18 C, respectively.

FIG. 4 is a timing diagram 300 illustrating a method for operating FED 10 in a display mode in accordance with an alternative embodiment in which a single line time is divided into two sub-line times. In accordance with this embodiment, a single row is selected and every other column of the display is activated in a first half of the line time, then in a second half of the line time the alternate columns of the display are activated. For example, only row 27 is selected and columns 17 A, 17 B, and 17 C of the display are activated during a first half of the line time and columns 18 A, 18 B, and 18 C are selected during a second half of the line time. Then another row such as, for example, row 28 is selected.

In accordance with this present embodiment, during a portion 302 of line time 301 , row driver circuit 37 selects row 27 and alternate column conductors are placed in an active mode, i.e., column conductors 17 A, 17 B, and 17 C are placed in an active mode by column conductor driver circuits 47 A, 47 B, and 47 C, respectively. At the same time column conductors 18 A, 18 B, and 18 C are placed in an inactivate mode or turned off by column conductor driver circuits 48 A, 48 B, and 48 C, respectively. During a portion 303 of line time 301 , row 27 is still selected, however, column conductors 18 A, 18 B, and 18 C are placed in an active mode by column conductor driver circuits 48 A, 48 B, and 48 C, respectively, whereas column conductors 17 A, 17 B, and 17 C are placed in an inactive mode by column conductor driver circuits 47 A, 47 B, and 47 C, respectively. In other words, during portion 302 sub-pixels 50 , 70 , and 90 are capable of conducting current, whereas sub-pixels 60 , 80 , and 100 are turned off. During portion 303 of line time 301 , sub-pixels 60 , 80 , and 100 , are capable of conducting current whereas sub-pixels 50 , 70 , and 90 are turned off. It should be noted that the sub-pixels associated with the other rows of display 10 , i.e., rows 28 and 29 are turned off, because these rows are not being selected during this time.

At time t 0 , display capacitances 51 , 53 , 55 , 71 , 73 , 75 , 91 , 93 , and 95 are discharged to zero volts by driving the output voltage of column conductor driver circuits 47 A, 47 B, and 47 C and row conductor driver circuits 37 , 38 , and 39 to voltages that prevent the corresponding electron emitter structures from emitting current. By way of example, the output voltages of column conductor driver circuits 47 A, 47 B, and 47 C and the output voltages of row conductor driver circuits 37 , 38 , and 39 are driven to zero volts. Likewise, display capacitances 61 , 63 , 65 , 81 , 83 , 85 , 101 , 103 , and 105 are charged to a high voltage by driving the output voltage of column conductor driver circuits 48 A, 48 B, and 48 C to a high voltage. At time t 1 , column conductor driver circuits 47 A, 47 B, and 47 C are placed in a high impedance state and are, therefore, electrically disconnected from FED 10 . At time t 1 , row conductor driver circuit 37 is outputting, for example, zero volts. This places zero volts on row conductor 27 . The outputs of column conductor driver circuits 47 A, 47 B, and 47 C remain in a high impedance state and the outputs of column conductor driver circuits 48 A, 48 B, and 48 C remain in a high voltage state.

At time t 2 , row conductor driver circuit 37 is activated and places a voltage greater than the threshold voltage of the electron emitter structures on row conductor 27 . By way of example, the voltage placed on row conductor 27 is eighty volts. Row conductor driver circuits 38 and 39 continue to maintain row conductors 28 and 29 , respectively, at zero volts.

When the column conductor driver circuits are in a high impedance state and the electron emitter structures are emitting current, the column conductor driver circuits preferably monitor the voltage on the respective column conductors. The change in voltage measured on the column conductor is proportional to the charge or current emitted by the electron emitter structures. It should be understood that column conductor driver circuits 47 A, 47 B, and 47 C monitor the voltage on column conductors 17 A, 17 B, and 17 C, respectively, and electron emitter structures 24 (27, 17A) , 24 (27, 17B) and 24 (27, 17C) emit current. Column conductor driver circuits 47 A, 47 B, and 47 C compare the measured change in voltage on the respective column conductors 17 A, 17 B, and 17 C to voltages proportional to the desired intensity of sub-pixels 50 , 70 , and 90 , which proportional voltages were previously determined as described in the U.S. Patent application having attorney docket number FD20024 by Robert T. Smith, and assigned to Motorola, Inc, which patent application has been incorporated herein by reference. After electron emitter structures 24 (27, 17A) , 24 (27, 17B) , and 24 (27, 17C) have emitted the desired current, they are turned off by switching column conductor driver circuits 47 A, 47 B, and 47 C from the high impedance state to a high voltage state. Column conductor driver circuits 47 A, 47 B, and 47 C remain in this state until the end of line time 301 so that they remain inactive This is shown as occurring at time t 3 in FIG. 4 .

It should be understood that the time period between times to and t 4 represent the first half 302 of the line time 301 . After time t 4 , the second half 303 of the line time 301 begins. During the second half 303 of the line time, column conductors 18 A, 18 B, and 18 C are exercised by means of column conductor driver circuits 48 A, 48 B, and 48 C, respectively. During the second half 302 of the line time, column conductor driver circuits 47 A, 47 B, and 47 C continue to place a high voltage on column conductors 17 A, 17 B, and 17 C, respectively so that the pixels associated with column conductors 17 A, 17 B, and 17 C remain inactive during the second half 303 of line time 301 . At time t 4 , column conductor driver circuits 48 A, 48 B, and 48 C transition to a low voltage state thereby discharging capacitances 63 , 65 , 83 , 85 , 103 , and 105 and charge capacitances 61 , 81 , and 101 .

At time t 5 , column conductor driver circuits 48 A, 48 B, and 48 C are placed in a high impedance state and are, therefore, electrically disconnected from FED 10 . It should be understood that the time interval from times t 4 and t 5 is just long enough to charge and discharge the capacitances.

When the column conductor driver circuits are in a high impedance state and the electron emitter structures are emitting current, the column conductor driver circuits preferably monitor the voltage on the column conductor. The change in voltage measured on the column conductor is proportional to the charge or current emitted by the electron emitter structures. It should be understood that column conductor driver circuits 48 A, 48 B, and 48 C monitor the voltage on column conductors 18 A, 18 B, and 18 C, respectively, and electron emitter structures 24 (27, 18A) , 24 (27, 18B) and 24 (27, 18C) emit current. Column conductor driver circuits 48 A, 48 B, and 48 C compare the measured change in voltage on the respective column conductors 18 A, 18 B, and 18 C to voltages proportional to the desired intensity of sub-pixels 60 , 80 , and 100 , which proportional voltages were previously determined. After electron emitter structures 24 (27, 18A) , 24 (27, 18B) , and 24 (27 18C) have emitted the desired current, they are turned off by switching column conductor driver circuits 48 A, 48 B, and 48 C from the high impedance state to a high voltage state. This is shown as occurring at time t 6 in FIG. 4 .

At time t 7 , the output voltage of row conductor driver circuit 37 and column conductor driver circuits 48 A, 48 B, and 48 C are switched from a high voltage, e.g., eighty volts, to a low voltage, e.g., zero volts; thereby discharging capacitances 61 , 81 , and 101 associated with column conductors 18 A, 18 B, and 18 C, respectively.

This process is then repeated to activate the next row conductor, e.g., row conductor 28 . The process is repeated until all the row conductors have been activated, one row at a time.

By now it should be appreciated that a method for preventing voltage glitches caused by cross-talk in a field emitter display has been provided. The present invention prevents voltage glitches arising from a switching column conductor from being capacitively coupled to an adjacent non-switching column conductor, thereby preventing degradation of the image output by the FED. In particular, the method of the present invention includes preventing a column conductor from switching from one operating state to another operating state when a column conductor driver circuit is placing a high impedance on the adjacent column conductor.

While specific embodiments of the present invention have been shown and described, further modifications and improvements will occur to those skilled in the art. It is understood that the invention is not limited to the particular forms shown and it is intended for the appended claims to cover all modifications which do not depart from the spirit and scope of this invention. For example, the row and column conductor driver circuits can be implemented using a microprocessor.