OLED display technology and features: Does power supply affect display quality?

Market Environment

All major mobile phone companies have now launched one or more models using OLED displays. Sony has taken the lead in mass-producing OLED TVs, and many other companies have also launched their first prototype models. OLED displays have wide color gamut, high contrast, wide viewing angles, and fast response times, making them very suitable for multimedia applications. Self-luminous OLED technology does not require backlighting, and its power consumption depends on the display content, which is much lower than that of LCDs using backlighting. As the panel size increases, the high-quality characteristics of OLED become more obvious, and the future application level will still be dominated by TV panels. Another OLED display market is flexible displays. The current prospects for OLED and electrophoretic display technology are quite promising, and electrophoretic or bistable displays used in e-readers need to improve color quality. On the other hand, OLED displays are still not suitable for mass production when using completely flexible materials, which mainly depends on the development of backplane technology.

Backplane technology enables flexible displays

High-resolution color active-matrix organic light-emitting diode (AMOLED) displays require an active-matrix backplane that uses active switches to turn each pixel on and off. Liquid crystal (LC) display amorphous silicon processes are now mature enough to provide low-cost active-matrix backplanes that can be used for OLEDs. Many companies are currently developing organic thin-film transistor (OTFT) backplane processes for flexible displays, which can also be used for OLED displays to enable full-color flexible displays. Whether standard or flexible OLED, the same power supply and driving technology are required. To understand OLED technology, its capabilities, and its interaction with the power supply, it is necessary to look deeper into the technology itself. OLED displays are a self-emissive display technology that does not require any backlight at all. The materials used in OLEDs are organic materials with a suitable chemical structure.

OLED technology requires current-controlled driving method

Figure 1 is a simplified circuit diagram showing only one pixel. OLEDs have electrical characteristics quite similar to standard organic light-emitting diodes (LEDs), and the brightness depends on the LED current. To turn the OLED on and off and control the OLED current, a control circuit using a thin-film transistor (TFT) is required.

In Figure 1, transistor T2 is the pixel control transistor that turns the pixel on and off, similar to any other active matrix LCD technology. T1 is treated as a current source, and the current is driven by this gate voltage source. The storage capacitor is Cs, which is used to maintain a stable T1 gate voltage and lock the supply current until the pixel is reconfigured. In Figure 1, the simple single transistor current source has a significant cost advantage because only two transistors are required. The disadvantage of this simple circuit is that the current will vary, which varies due to process variations and Vdd voltage variations. OLED power supply circuits usually provide two voltage supply rails, Vdd and Vss. The voltage rail Vdd must be very tightly regulated to achieve the best picture quality and avoid image flicker. Vss is usually a negative voltage, and its voltage regulation accuracy can be reduced because it is less likely to affect the LED current. Figure 2 shows the effect of voltage fluctuations caused by Vdd on an OLED display. When the voltage supply Vdd varies, the OLED brightness will also vary. Superimposed voltage ripples on Vdd can cause horizontal streaks in the image due to different brightness levels. Depending on the display, voltage ripples greater than 20mV may cause this phenomenon. The extent to which horizontal streaks appear depends on the amplitude and frequency of the superimposed voltage ripples. When the frequency interferes with the frame frequency, streaks will appear. In normal experimental conditions, the superimposed voltage ripples on Vdd are usually less than 20mV. This problem occurs when the display and power supply are integrated into a system. As soon as any subcircuit in the system draws pulsating current from the system power supply, voltage ripples will appear. This is true for all circuits connected to the system power supply. Typical subcircuits that draw pulsating current include GSM power amplifiers, motor drivers, audio power amplifiers, etc. in mobile phones. In these systems, superimposed voltage ripples will appear on the system supply rails. If the AMOLED power supply does not suppress this ripple, the ripples will appear at the output and cause the image distortion mentioned above. To avoid such problems, the power supply of AMOLED needs to have extremely high power supply rejection ratio and line transient response.

For the power supply of AMOLED, the positive voltage rail Vdd requires a boost converter, and the negative voltage rail Vss requires a buck-boost converter or inverter. This is a big challenge for IC manufacturers who provide suitable power supplies, because manufacturers need to provide quite accurate positive voltage rail Vdd and negative voltage rail Vss to achieve the lowest component height and smallest solution size.

To meet all these requirements, a new power supply topology needs to be selected to provide both positive and negative output voltage rails from the Li-Ion battery using only a single inductor.

SIMO voltage regulator technology for best-in-class image quality

Figure 3 shows a general application circuit using the TPS65136, which uses single inductor multiple output (SIMO) regulator technology and operates in a four-switch buck-boost converter topology. SIMO technology achieves best-in-class line transient regulation, buck-boost mode for both outputs, and highest efficiency over the entire load current range. Advanced power-saving mode achieves highest efficiency

As with any battery-powered device, long battery standby times can only be achieved when the converter operates at maximum efficiency over the entire load current range, which is particularly important for OLED displays. OLED displays consume the most power when displaying full white, and less current for any other displayed color, because only white requires all red, green, and blue sub-pixels to be fully illuminated. For example, a 2.7-inch display requires 80mA to display a full white image, but only 5mA to display other icons or graphics. Therefore, OLED power supplies require high converter efficiency for all load currents. To achieve such efficiency, advanced power-saving mode techniques are used to reduce the load current to reduce the converter switching frequency. Because this is done through a voltage-controlled oscillator (VCO), possible EMI issues are minimized and the minimum switching frequency can be controlled outside the typical 40kHz audio range, which avoids noise generation from ceramic input or output capacitors. This is particularly important when using such devices in mobile applications and simplifies the design process.

in conclusion

Since OLED display technology is still in its infancy, there is still much room for improvement in terms of energy saving, improving OLED efficiency, and minimizing the size of the overall solution. As OLED matures, it can be applied to architectural lighting or LCD display backlighting. Compared with traditional lighting solutions, OLED provides lower power consumption and higher design flexibility for these two uses, so there are great business opportunities. For OLED technology, the future is definitely bright.