Display Apparatus

Organization Name

SEMICONDUCTOR ENERGY LABORATORY CO., LTD.

Inventor(s)

Daisuke Kubota of Atsugi, Kanagawa (JP)

Kenichi Okazaki of Atsugi, Kanagawa (JP)

Koji Kusunoki of Isehara, Kanagawa (JP)

Display Apparatus - A simplified explanation of the abstract

This abstract first appeared for US patent application 18563066 titled 'Display Apparatus

Simplified Explanation:

This patent application describes a display apparatus with an image capturing function that includes a high aperture ratio. The display apparatus consists of a light-emitting element, a light-receiving element, and various layers stacked in a specific order to enhance performance.

• The display apparatus includes a light-emitting element and a light-receiving element.
• Specific layers are stacked in a particular order within the light-emitting and light-receiving elements to optimize performance.
• The second organic layer in the light-receiving element contains a photoelectric conversion layer.
• Two additional layers are included in a region between the light-emitting and light-receiving elements to improve functionality.
• The end portions of the organic layers and additional layers face each other in the region between the two elements.

Key Features and Innovation:

• Display apparatus with image capturing function and high aperture ratio.
• Specific layer stacking order for optimal performance.
• Inclusion of a photoelectric conversion layer in the second organic layer.
• Additional layers in the region between light-emitting and light-receiving elements.
• End portions of layers facing each other for improved functionality.

Potential Applications:

This technology could be applied in:

• High-resolution displays
• Imaging devices
• Camera systems
• Medical imaging equipment
• Security cameras

Problems Solved:

• Improved image quality
• Enhanced light sensitivity
• Increased aperture ratio
• Better performance in low-light conditions
• Enhanced functionality in various applications

Benefits:

• Higher quality images
• Improved performance in low-light environments
• Enhanced sensitivity to light
• Versatile applications in different industries
• Increased efficiency in image capturing

Commercial Applications:

Potential commercial uses include:

• Consumer electronics
• Medical imaging devices
• Security and surveillance systems
• Photography equipment
• Display technology markets

Questions about the Technology: 1. What are the specific materials used in the organic layers of the display apparatus? 2. How does the inclusion of the photoelectric conversion layer in the second organic layer improve performance?

Frequently Updated Research:

Stay updated on advancements in display technology, image capturing functions, and organic layer materials to enhance the performance of similar devices.

Original Abstract Submitted

A display apparatus having an image capturing function is provided. A display apparatus or an image capturing with a high aperture ratio is provided. The display apparatus includes a light-emitting element and a light-receiving element. A first pixel electrode, a first organic layer, and a common electrode are stacked in this order in the light-emitting element. A second pixel electrode, a second organic layer, and the common electrode are stacked in this order in the light-receiving element. The second organic layer includes a photoelectric conversion layer. A first layer and a second layer are included in a region between the first light-emitting element and the light-receiving element. The first layer overlaps with the second organic layer and contains a material the same as a material of the first organic layer. The second layer overlaps with the first organic layer and contains a material the same as a material of the second organic layer. An end portion of the first organic layer and an end portion of the first layer face each other in the region between the light-emitting element and the light-receiving element. An end portion of the second organic layer and an end portion of the second layer face each other in the region between the light-emitting element and the light-receiving element.