05.15.23
OLED microdisplays have so far been developed predominantly on 200mm wafers. These conventional CMOS technologies and the associated backplane design have limited the number and size of pixels until now.
At the Fraunhofer Institute for Organic Electronics, Electron Beam and Plasma Technology FEP, OLED microdisplays have been realized for the first time in a 28-nanometer backplane technology on 300mm wafers within the "Backplane" project funded by the Saxon State Ministry of Economics, Labor and Transport (SMWA).
Components with a display diagonal of 0.18 inches and pixel sizes of only 2.5 micrometers have been manufactured. This corresponds to a pixel density of 10,000 dpi – an as-yet unattained level in the global OLED microdisplay market. These unique OLED microdisplays will be presented for the first time at SID Display Week, May 23–25, 2023, at the German Joint Booth, No. 1110, in Los Angeles, USA.
In Silicon Saxony, the German location with world-leading microelectronics and semiconductor manufacturers as well as research institutions, work on forward-looking innovations is carried out daily.
Fraunhofer FEP, as part of this closely interlinked network, is the leading institute for the development of customer- and application-specific microdisplays and sensors based on OLED-on-silicon technology.
The institute's continuous microdisplay developments in recent years have been driven by various requirements such as pixel density, energy efficiency, color, brightness, or frame rate. Fraunhofer FEP has developed a wide range of microdisplays in full-color or monochrome, from ultra-low power versions to high-resolution variants for the use in augmented- (AR) and virtual-reality (VR) applications and other wearables.
The majority of microdisplays on the market are currently developed and manufactured on 200 mm wafers in 250 nm to 90 nm CMOS process nodes. At Fraunhofer FEP, too, these are established design technologies in cooperation with various semiconductor manufacturers, depending on the requirements and customers' wishes. The manufacturing of microdisplays on 300 mm wafers has been rare so far.
On the one hand, this is due to technical reasons, such as the availability of suitable transistors for the corresponding control of the OLED, and on the other hand to economic reasons.
However, market requirements for image quality, pixel density and integrated functionality are continuously increasing. Therefore, Fraunhofer researchers have been examining the scaling effects in smaller CMOS technologies and investigating the use of 300 mm backplane processes as part of the "Backplane" project funded by the SMWA.
In this context, the researchers have now succeeded in making the next major leap forward in development: For the first time, they realized an OLED microdisplay with tiny 2.5 µm pixels (corresponding to 10,000 dpi) at a display diagonal of 0.18 inch. This demonstrated the feasibility of developing displays based on 28 nm small-node technology on 300 mm wafers and realized the world's smallest pixels of an OLED microdisplay.
Philipp Wartenberg, head of the department for IC and system design, explains the new technology.
"In so-called ‘small node technologies, there is always the challenge of realizing the voltages required for driving in complex photonic systems,” said Wartenberg. “Thanks to an interdisciplinary research team and a completely new type of display architecture, we have succeeded in doing this for the first time in this project, while at the same time realizing extremely small pixels with a size of just 2.5 µm.”
The newly developed OLED microdisplays have a resolution of 1440 × 1080 pixels in monochrome or 720 × 540 pixels in full color. On the one hand, the flexible display architecture allows the refresh rate to be reduced to 0 Hz in extreme cases when the display content remains unchanged, thus avoiding all unnecessary data transfer - an enormous advantage for power consumption.
Depending on the design, the new displays can be used in lifestyle products such as sports glasses or as head-mounted displays in motorcycle helmets, in industrial scenarios for wearables in logistics or for remote maintenance solutions. The now even smaller dimensions pave the way for even more ergonomic systems.
At the Fraunhofer Institute for Organic Electronics, Electron Beam and Plasma Technology FEP, OLED microdisplays have been realized for the first time in a 28-nanometer backplane technology on 300mm wafers within the "Backplane" project funded by the Saxon State Ministry of Economics, Labor and Transport (SMWA).
Components with a display diagonal of 0.18 inches and pixel sizes of only 2.5 micrometers have been manufactured. This corresponds to a pixel density of 10,000 dpi – an as-yet unattained level in the global OLED microdisplay market. These unique OLED microdisplays will be presented for the first time at SID Display Week, May 23–25, 2023, at the German Joint Booth, No. 1110, in Los Angeles, USA.
In Silicon Saxony, the German location with world-leading microelectronics and semiconductor manufacturers as well as research institutions, work on forward-looking innovations is carried out daily.
Fraunhofer FEP, as part of this closely interlinked network, is the leading institute for the development of customer- and application-specific microdisplays and sensors based on OLED-on-silicon technology.
The institute's continuous microdisplay developments in recent years have been driven by various requirements such as pixel density, energy efficiency, color, brightness, or frame rate. Fraunhofer FEP has developed a wide range of microdisplays in full-color or monochrome, from ultra-low power versions to high-resolution variants for the use in augmented- (AR) and virtual-reality (VR) applications and other wearables.
The majority of microdisplays on the market are currently developed and manufactured on 200 mm wafers in 250 nm to 90 nm CMOS process nodes. At Fraunhofer FEP, too, these are established design technologies in cooperation with various semiconductor manufacturers, depending on the requirements and customers' wishes. The manufacturing of microdisplays on 300 mm wafers has been rare so far.
On the one hand, this is due to technical reasons, such as the availability of suitable transistors for the corresponding control of the OLED, and on the other hand to economic reasons.
However, market requirements for image quality, pixel density and integrated functionality are continuously increasing. Therefore, Fraunhofer researchers have been examining the scaling effects in smaller CMOS technologies and investigating the use of 300 mm backplane processes as part of the "Backplane" project funded by the SMWA.
In this context, the researchers have now succeeded in making the next major leap forward in development: For the first time, they realized an OLED microdisplay with tiny 2.5 µm pixels (corresponding to 10,000 dpi) at a display diagonal of 0.18 inch. This demonstrated the feasibility of developing displays based on 28 nm small-node technology on 300 mm wafers and realized the world's smallest pixels of an OLED microdisplay.
Philipp Wartenberg, head of the department for IC and system design, explains the new technology.
"In so-called ‘small node technologies, there is always the challenge of realizing the voltages required for driving in complex photonic systems,” said Wartenberg. “Thanks to an interdisciplinary research team and a completely new type of display architecture, we have succeeded in doing this for the first time in this project, while at the same time realizing extremely small pixels with a size of just 2.5 µm.”
The newly developed OLED microdisplays have a resolution of 1440 × 1080 pixels in monochrome or 720 × 540 pixels in full color. On the one hand, the flexible display architecture allows the refresh rate to be reduced to 0 Hz in extreme cases when the display content remains unchanged, thus avoiding all unnecessary data transfer - an enormous advantage for power consumption.
Depending on the design, the new displays can be used in lifestyle products such as sports glasses or as head-mounted displays in motorcycle helmets, in industrial scenarios for wearables in logistics or for remote maintenance solutions. The now even smaller dimensions pave the way for even more ergonomic systems.