The invention relates to a method of healing low-ohmic defects in a flat display. “Low-ohmic” means that a leakage current caused by the defect affects the visual performance of the display for human eye.
A flat display is a stacked arrangement of structured layers comprising at least one transparent electrode layer, a light-emitting or light-absorbing or polarizable layer or any other kind of light modulating layer and a counterelectrode layer. One or all electrode layers and the light modulating layer are structured to allow individual addressing of subareas of the display, typically by means of switched driving of the subareas. In a matrix-type display, this subarea consists of a single pixel, whereas in segmented displays, each segment defines a subarea.
Self-emitting passive segmented or matrix displays based on light-emitting polymers have come into the market several years ago. Such displays make use of the phenomenon of electroluminescence, which originates from an organic material comprising, for example, a luminescent compound. This organic layer is sandwiched between two electrodes which are in contact with the organic layer. By applying a suitable voltage, the negative electrode, i.e. the cathode, will inject electrons, and the positive electrode, i.e. the anode, will inject holes. The recombination of these electrons and holes may generate light. When biased in opposite (reversed) direction, current flow is reduced to a residual leakage level, thus generating a diode-like current-voltage characteristic. This type of displays is also referred to as (polymer) light-emitting diode (LED) display. Deposition of the light-emitting organic layer can be done either by non-vacuum wet-chemical processes like spin-coating or printing, or by vacuum deposition technologies like evaporation or chemical vapor deposition. Non-vacuum processes make us of organic materials of high molecular mass compared to the vacuum deposition processes. To differentiate between both types of display, the non-vacuum variant is typically named Polymer LED display (PLED), whereas the vacuum variant is typically named Organic LED (OLED) type display.
In passive matrix driving schemes, one electrode layer is connected to a cathode (e. g. line) driver, and the second electrode layer is connected to the anode (e. g. column) driver. The display information is updated with a given frame rate. By time-multiplexed switching of either anodes or cathodes with a given multiplex rate (typically equal to the number of anodes or cathodes of the display), each anode or cathode is addressed for a maximum time interval of 1/[(multiplex rate) times (frame rate)], typically referred to as line time. In active matrix driving schemes, an arrangement of addressable semiconductor switches is placed close to each display subarea. Refresh of the switching position is done with the given frame rate. Time-mulitplexing of the driving anode or cathode lines is not required. The available line time thus becomes less or equal than 1/[frame rate]. Refresh of the display information is done by programming of the data and address lines of each display subarea.
Common to all displays is a severe lifetime problem, generated by sudden or gradual increase in leakage current through the light modulating layer. This insulation resistance failure is generated by defects or structural inhomogeneities, for example by particles adhering on a substrate, particle contamination during processing of the display or particles coming from the packaging process or materials. Structural inhomogeneities are for example pinholes or hillocks in the layers. Screening or bum-in procedures are no guarantee against the activation of these defects during lifetime.
A reliable display having good visual performance must have small leakage currents. Small means that the luminance and contrast are not affected by parasitic current flow through local defects. For example, a subarea of a light-emitting passive driven display exhibiting increased leakage current will emit less or even no light. Further, there may be extra light in the shorted anode or cathode. Damage may propagate in the active part of the cell, due to overstressing of other parts of the display. Finally, there is a risk of total failure due to overloading of the driver electronics and the interconnections between electronics and display.
Defects can never be excluded. Therefore, the lifetime of a display may drop below the intrinsic lifetime of the light-emitting layer. To avoid this, it is known to passivate a local defect, either by using special gas fillings in the cavity of the display, or by application of extra layers, for example on top of the cathode layer. Other measures are aiming at an improved selection procedure in the outgoing inspection of finished products, for example as disclosed in WO 01/22504.
It is the object of the present invention to provide a method of healing low ohmic-defects in a flat display by utilizing the built-in self-healing properties of the layer stack.
This object is solved by passing an extra current during a predetermined time period through the affected subarea of the flat display, said current being selected to turn at least one defect or specific surrounding of at least one defect into a high-ohmic state which has a resistance higher than the initial resistance of said at least one defect. “Extra current” means that it is a current different from that of normal operation. Specifically, the extra current may be a reverse current.
In particular, “high-ohmic” means that leakage currents can be neglected and the healed defect does no longer affect the visual performance of the display for human eye. For organic or polymer light-emitting diode display, the high-ohmic state is characterized in that the relation I(−V) <<I(+V) holds, +V being the polarity of light emission, for all voltages relevant for display driving.
For an organic or polymer LED display, the invention is based on fusing off the defect by exposure of the display or part of the display to a defined electrical stress in reversed direction of a bad pixel or segment. This current must stay within certain boundaries in order to avoid destruction of the display. When the defect is fused, it is switched back into a high-ohmic state by this electrical overstress.
In a preferred embodiment, said current is gradually increased from a starting value to a maximum value.
Said predetermined time period may be a fraction of the line time of said display or a complete line time or frame time.
Said display is preferably an organic or polymer light emitting diode display, but any other type of flat display can be used. This includes electroluminescent displays, liquid crystal displays and any other flat displays.
In a passively driven display, the healing current may be generated by connecting one or several anode or cathode lines to either ground or supply voltage by means of the attached anode or cathode drivers, thus maximizing the potential difference or current flow through the affected subarea. In an actively driven display, the supply voltage line is either switched to opposite polarity, or the ground and supply voltage lines are exchanged by means of a switch. The semiconductor switches used to drive the pixels must be designed as a bi-directional switch.
In case of an organic or polymer LED display, the healing current is advantageously flowing in reversed direction of the diode.
The healing current can be adjusted by means of changing the analog supply voltage in amplitude and polarity, by means of parallel switching or shorting of anodes or cathodes, or by means of adaption of the output impedance of the analog driving electronics. This allows for an impedance matching between resistance of said at least one defect and effective output resistance of the analog driving circuit, to maximize or adjust the power dissipation at the defect site, enabling efficient healing of a single defect or several defects.
The method according to the invention is advantageously applied to a passively driven display with programmable drivers for each anode and cathode line of the display, or to an actively driven display with programmable address and data lines.
An apparatus for healing low-ohmic defects in a flat display is characterized by means for providing an extra current selected by control means to turn at least one defect or a specific surrounding of at least one defect into a high-ohmic state which has a resistance higher than the initial resistance of said at least one defect and means for passing said extra current during a predetermined time period through the affected sub-area of the flat display. Said predetermined time period may also be set by said control means.
Preferably, said apparatus includes means for lowering the effective electrode resistance of the display by parallel switching or shorting of anodes or cathodes.
If a driver for each line or cathode and column or anode of the display is provided, the apparatus may include means for connecting one or several of said column drivers or anode drivers or said line drivers or cathode drivers to either ground or supply voltage.
In an application to actively driven matrix displays, means for changing the potential of the analogue supply voltage line or both analogue supply and ground voltage line may be provided.
Also, the apparatus may include means for adapting the output impedance of at least one of said drivers or the output impedance of the analogue supply or voltage.
In the following, these and other aspects of the invention are further explained with reference to the drawings, wherein
The invention is exemplarily illustrated with reference to organic or polymer light emitting diode displays.
An alternative of coupling to ground is provided in
A combination of the measures under 1. to 3. can be taken to heal a defect in a light emitting diode display.
A method of improving lifetime of a passively or actively driven display by applying the method according to the invention may use three different strategies.
In a first strategy, referred to as “forced defect healing”, one of the above measures 1. to 3. is taken at a predetermined time or regularly in certain time intervals. A predetermined time may be the time of powering up the display, leaving the stand-by modus or the like. Suitable time intervals can be periods of every n-frames, where n is an integer. The healing method must be applied to the whole display, since in this situation the location of the defect is not known.
If sensed defect healing is applied, it is feasible to change the output characteristic of the cathode driver depending on the defect resistance level. If the defect healing was not successful, the output resistance can be changed, for example by using a tuneable resistor in the output line of the cathode driver, as shown in
The embodiments have been explained with a display driver concept based on multiplexing in line direction which usually means cathode direction. However, the proposed measures are also suitable for multiplexing in column direction, which is usually anode direction.
The invention uses the source and sink capabilities of cathode and/or anode driver for the healing energy supplied to the defect to heal the defect with an optimum amount of energy.
In actively driven circuits, the healing methods can be applied in an analog way.
To heal defects by means of reversed current flow, the potential of the analog supply voltage line can be changed from positive to negative against ground, or the ground and analog supply voltages can be exchanged during the healing cycle, as shown in
Sensing of defects is possible in actively driven matrix displays by monitoring of current level on analog supply or ground lines during a period where the pixel luminance is programmed to zero.
Controlled defect healing can be achieved by adapting the output impedance of the analog supply voltage, or by adjusting the amplitude of the analog supply voltage during a healing cycle.
As an alternative, the on-resistance (resistance of a switch in the conductive state) of the semiconductor switch (or switches) used to drive the pixel can be adjusted by means of adjusting appropriate voltages at the data line and the address line.
Number | Date | Country | Kind |
---|---|---|---|
011301660 | Dec 2001 | EP | regional |
Filing Document | Filing Date | Country | Kind |
---|---|---|---|
PCT/IB02/05564 | 12/17/2002 | WO |