Abstract
This paper proposes a novel pixel circuit design and driving method for active-matrix organic light-emitting diode (AM-OLED) displays that use low-temperature polycrystalline-silicon thin-film transistors (LTPS-TFTs) as driving element. The automatic integrated circuit modeling simulation program with integrated circuit emphasis (AIM-SPICE) simulator was used to verify that the proposed pixel circuit, which comprises five transistors and one capacitor, can supply uniform output current. The voltage programming method of the proposed pixel circuit comprises three periods: reset, compensation with data input, and emission periods. The simulated results reflected excellent performance. For instance, whenΔVTH=±0.33 V, the average error rate of the OLED current variation was low (<0.8%), and whenΔVTH_OLED=+0.33 V, the error rate of the OLED current variation was 4.7%. Moreover, when theI×R(current × resistance) drop voltage of a power line was 0.3 V, the error rate of the OLED current variation was 5.8%. The simulated results indicated that the proposed pixel circuit exhibits high immunity to the threshold voltage deviation of both the driving poly-Si TFTs and OLEDs, and simultaneously compensates for theI×Rdrop voltage of a power line.
Highlights
The most critical advantage of organic light-emitting diode (OLED) displays over conventional liquid crystal displays (LCD) is that OLED displays do not require backlight module systems
active-matrix organic light-emitting diode (AM-OLED) have the advantage of using less driving current compared with PM-OLEDs, which can increase the lifetime of OLED materials [1]
The proposed pixel circuit, which comprises five ntype LTPS-TFTs and one capacitor, can compensate for the nonuniformity of OLED currents caused by the threshold voltage variations of driving TFTs (DTFTs) and OLEDs
Summary
The most critical advantage of organic light-emitting diode (OLED) displays over conventional liquid crystal displays (LCD) is that OLED displays do not require backlight module systems. This issue is exacerbated as the size of a display increases. Instead of improving TFT processes, several studies have attempted to reduce the brightness variation across display panels by altering pixel circuit designs, which can use voltage driving, current driving, and digital driving compensation approaches [8,9,10,11,12,13,14,15]. The proposed pixel circuit, which comprises five ntype LTPS-TFTs and one capacitor, can compensate for the nonuniformity of OLED currents caused by the threshold voltage variations of DTFTs and OLEDs. The pixel circuit can simultaneously compensate for the OLED luminance degradation caused by the I × R drop voltage of a power line. The simulation results indicated that the proposed pixel circuit successfully supplies a highly stable OLED current and is suitable for larger AM-OLED displays
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