New AMOLED TV Costs Ten Times More than LCD TV to Produce
The manufacturing cost of a 55" oxide TFT-based AMOLED
using white OLED with color filters is 8 times that of a
high-end 55" TFT LCD display of equal size, a research
says.
Active-matrix organic light-emitting diode (AMOLED)
represents a rapidly growing and highly promising
technology for all display applications. Based on planned
investments, NPD DisplaySearch forecasts that the market
will grow nearly tenfold from 2.3M square meters in 2012 to
more than 22M in 2016.
Most AMOLED capacity is currently dedicated to small/medium production for smart phones, but much of the capacity increase going forward is expected to be driven by fabs dedicated to TV production. There are many unknowns about how far and how fast it will develop, though, since AMOLED technology has not yet been proven in large-size TVs.
According to the NPD DisplaySearch AMOLED Process Roadmap Report, the manufacturing cost of a 55" oxide TFT-based AMOLED using white OLED with color filters is 8 times that of a high-end 55" TFT LCD display of equal size. The cost multiplier of a 55" AMOLED module using red, green, and blue OLED is 10 times. These higher costs are mainly a result of low yields and high materials costs.
Jae-Hak Choi, Senior Analyst, FPD Manufacturing for NPD DisplaySearch, noted, "While cost reduction in LCDs has slowed, large panel AMOLED cost reduction is in its infancy. In the long-term, new and improved processes, printing technology, and higher performance materials will reduce AMOLED costs to levels equal to or lower than LCD."
Due to greater process maturity, the manufacturing cost premium for a 4" AMOLED is less than 1.3 times that of a similar-sized LCD. Samsung Display has been highly successful in its small/medium AMOLED production because it has been able to raise yields to near-LCD levels. This implies that manufacturers can potentially lower large size AMOLED TV costs to be competitive with LCD TVs in the future.
In order to scale up to large sizes, advancements in several aspects of AMOLED manufacturing are needed, including the active matrix backplane, organic material deposition, and encapsulation. Because oxide TFT requires lower capital costs and is similar to existing amorphous silicon TFT, it offers a strong alternative to the low-temperature polysilicon (LTPS) TFT currently used for AMOLED. However, there are many hurdles for mass production of oxide TFT, particularly threshold voltage shifts, which are continuing to prove problematic for AMOLED production.
While indium gallium zinc oxide (IGZO) and other forms of oxide TFT show great promise for backplanes, progress in scaling up LTPS production is also being made by increasing the excimer laser beam width to 1300 mm. In addition, the current method of depositing red, green, and blue materials by evaporation through a fine metal mask is being continuously improved. Pixel densities of 250 ppi are now possible, and over 280 ppi is feasible.
"Despite these advancements, high resolution continues to be a relative weakness for small/medium AMOLED compared to LCDs. High resolution patterning such as laser induced thermal imaging (LITI) and material improvements are still required for AMOLED to be highly competitive for super high resolution flat panel displays," Choi added.
Most AMOLED capacity is currently dedicated to small/medium production for smart phones, but much of the capacity increase going forward is expected to be driven by fabs dedicated to TV production. There are many unknowns about how far and how fast it will develop, though, since AMOLED technology has not yet been proven in large-size TVs.
According to the NPD DisplaySearch AMOLED Process Roadmap Report, the manufacturing cost of a 55" oxide TFT-based AMOLED using white OLED with color filters is 8 times that of a high-end 55" TFT LCD display of equal size. The cost multiplier of a 55" AMOLED module using red, green, and blue OLED is 10 times. These higher costs are mainly a result of low yields and high materials costs.
Jae-Hak Choi, Senior Analyst, FPD Manufacturing for NPD DisplaySearch, noted, "While cost reduction in LCDs has slowed, large panel AMOLED cost reduction is in its infancy. In the long-term, new and improved processes, printing technology, and higher performance materials will reduce AMOLED costs to levels equal to or lower than LCD."
Due to greater process maturity, the manufacturing cost premium for a 4" AMOLED is less than 1.3 times that of a similar-sized LCD. Samsung Display has been highly successful in its small/medium AMOLED production because it has been able to raise yields to near-LCD levels. This implies that manufacturers can potentially lower large size AMOLED TV costs to be competitive with LCD TVs in the future.
In order to scale up to large sizes, advancements in several aspects of AMOLED manufacturing are needed, including the active matrix backplane, organic material deposition, and encapsulation. Because oxide TFT requires lower capital costs and is similar to existing amorphous silicon TFT, it offers a strong alternative to the low-temperature polysilicon (LTPS) TFT currently used for AMOLED. However, there are many hurdles for mass production of oxide TFT, particularly threshold voltage shifts, which are continuing to prove problematic for AMOLED production.
While indium gallium zinc oxide (IGZO) and other forms of oxide TFT show great promise for backplanes, progress in scaling up LTPS production is also being made by increasing the excimer laser beam width to 1300 mm. In addition, the current method of depositing red, green, and blue materials by evaporation through a fine metal mask is being continuously improved. Pixel densities of 250 ppi are now possible, and over 280 ppi is feasible.
"Despite these advancements, high resolution continues to be a relative weakness for small/medium AMOLED compared to LCDs. High resolution patterning such as laser induced thermal imaging (LITI) and material improvements are still required for AMOLED to be highly competitive for super high resolution flat panel displays," Choi added.