The Requirements and Production Workflow of 2K, 4K, and 8K Formats - Paper Example

Introduction

The 2K, 4K, and 8K high-resolution videos are used for a wide variety of purposes in the science, arts and entertainment industries. Viewing 4K videos has become easier through the development of the 4K image equipment, including the cameras and playback system (Kitamura et al., 2011). Moreover, the new technology increases video image resolution through the 8K system, which can unify several digital resolutions at the same time. The contemporary video transmission system can synchronize multiple 4K transmission systems to attain the 2K and 8K image resolutions. As such, techniques for attaining reliable transmission of 2K, 4K and 8K formats through the acquisition, ingestion, editing, storage, and screening are gaining popularity (Holub et al., 2013). A keen observation of the production workflow and outcome of the 2K, 4K, and 8K formats suggests that video production cannot achieve the same results without the use of this technology.

Acquisition

In the filming process, several sensors have caused constraints on image quality. The 2D and 3D have had technical compatibilities with their camera sizes and lenses being obstacles in the creation of digital contents (Hamacher et al., 2015). The 2K, 4K, and 8K video formats are acquired using the single large camera sensors with the standard contents. When 3D considerations are met, the artifacts such as the chromatic aberration are achieved.

The 8K equipment is under development, and it lacks enough content (Nazir and Kaleem, 2016). The 8K high-resolution system is thought to be the most ultimate equipment with its high-resolution digital system (Gohshi, 2014). The already developed 2K and 4K digital contents are to be converted to the sufficient level of the high-quality resolution to acquire the 8K digital system (Holub et al., 2013). The video format possessed by the 4K resolution system will have to change. The higher frequency of the 4K content will also be converted to the convenient frequency of the 8K high-resolution system.

The 8K video system of high resolution can be acquired using the digital cameras. The high-resolution video is for the large-scale sports events like in a football scenario where the camera has to capture both sides of the playing field. The 8K high-resolution system created with a joint panoramic view resolution using image processing algorithms that are sophisticated. The 8K system has an immersive screened modular with high resolution of the multi-projection system (Fehn et al., 2006).

Ingestion

The developments in the broadcasting industries and medical imaging applications which have quickly adopted the 2K and 4K resolutions require the 8K high-resolution system. The medical and broadcasting industries require the processing and editing of the image sources in time and at a faster rate. With the adoption of the 2K and 4K resolutions already in the broadcasting and medical industries, high-resolution images and the multiple streams required are being achieved. The acquisition of the 8K video system that is four times the 4K resolution system will bring more development in the broadcasting and medical industry. With the wider deployment of 8K high-resolution system of the high-quality digital resolution in the medical and broadcasting industries, performance will automatically improve (Saleh, Mohammad, and Maalouf, 2013).

The 8K resolution system best suits the architectures due to its simplicity and independent of nature. Its implementation will create an open-source platform for high video transmission over the high-speed network. The implementation of the 2K, 4K, and 8K digital formats will allow the offline processes and other storage applications to accelerate the performance achievement in various fields that require real-time image sources at a faster rate. The implementation will also reduce the costs of workflow and the complexities in real-time image processing in the broadcasting and the medical industries through the applicability of the 2K, 4K, and 8K resolution systems.

Editing

The 8K high-resolution systems execute high arrays of streaming multiprocessors. The system incorporates the shared memory visible within a block and the global memory registered to expose the instruction required for the digital resolutions. The 8K high-resolution system is also capable of computing the applications of the utilized the raw capacity of computed data to provide sufficient degree of editing. The workflow which includes the loading of data and the processing of the data from the host memory to the device while using the shared memory and copying data to the host memory can all be edited through the 8K system of high resolution.

The 8K resolution system provides optimized implementations of common signal processing algorithms that accelerate digital video editing and transformation. The advanced coding schemes in the 8K high-resolution system accelerate video coding (Yamashita et al., 2016). Also, specific video algorithms including the motion estimation and motion compensation in the 8K system make it possible for editing.

The frame independence of the 8K resolution system gives it an advantage in the editing of the digital cinematography. The 8K higher frame resolution and frame results into high data rates. As a result, the video data gain large size and rate hence achieving the video coding algorithmic standards. The basic 2K and 4K resolution systems compress the color information into 64-bit code word and add only 64 bit necessary for encoding the alpha channel. However, with the rise of new technology and demands of high-quality video, there is no need to have variant standards. The 8K resolution system utilizes the higher sensitivity to bring together and store the 64 bits using the 8-bit colors (Cheng et al., 2015).

The 8K high-resolution system can encode the image by converting it into color spaces that allow compensation ratio. The components of the colors are transformed independently by the 8K resolution system to specific data units. The 8K system is also used to process the compressed data during the decoding process sequentially. The compression process has various phases that the 8K system is suitable for. It can encode the image through the processing transformation of various colors. On the other hand, the transformation of the color components into a single stream through decoding is possible by the 8K resolution system.

Storage

The computing power regarding the storage capacity has attracted much attention. For maximum portability and performance, the 8K high-resolution system that provides flexibility in digital resolution is required. The rapid increase in storage requirements in the high-quality digital resolution has a great impact on the access to high-quality digital media content. According to Liu et al. (2011), to achieve high-quality digital content, the issue of storage platform suitable capable of handling the quality digital media should be addressed. The optical network of the 8K high-resolution system can be used to interconnect several sites to achieve the required quality digital media.

The 2K, 4K and 8K high video resolutions with digital still images and other digital audio formats require quality storage requirements. Building tools for storage and transferring high definition digital content and data management is one of the storage requirements needed for high-quality digital resolutions and reliable digital system. The capacity limits of the physical storage have been freed by the digital workflows commonly found in the 8K resolution system which accommodates the basic operations of the digital content.

The 8K digital cameras capture finer details and at high speed. The production equipment is available for faster production, and it is effective for resource sharing and digital storage with the content creation.

For uncompressed 8K video transmission, the plastic optical fiber cable that is consumer friendly are developed and interconnected with the ballpoint pen. Using a storage device with a large-scale makes it possible to achieve a stronger coupling. Therefore, a thinner 8K cable is feasible for use in multiple transmissions with high speed and low noise (Koike and Inoue, 2016).

Screening

The 8K digital systems have transformed the information flow through the application of various infrastructures (Nazir and Kaleem, 2016). The improvement of the cinematography is among the benefits of the 2K and 4K digital resolution systems. The digital cinema that supports the transmission of high-resolution content has arisen due to the advancement of the 8K resolution system that supports optical communication and video compression. With the acquisition and ingestion of the 2K, 4K, and 8K high definition, the recording in the cinema workflow has been high. Many screening devices with high definition resolutions have become possible. Also, the 8K high resolution has made it possible for image quality and the quality content produced by the 8K resolution for the cinema can be adopted for the TV and mobile viewing devices. The scalability features of the 8K resolution system enable high video coding standards (Fehn et al., 2006).

The cinema, TV and mobile viewing screens have gained digitalized workflow through the 8K high-resolution systems. The real-time data and images, the audio and video streaming can be played back. The digital cinema content can be removed from the screen and data of a single ultra-high definition can be formatted. With the 8K resolution system, the cinema content can be stored at the movie theatre and streamlined ahead of the show timings. The development of the 8K resolution system has also led to the live streaming and cinema projection facilities can be used to cover the operas and sports events (Choi et al., 2012).

The digital streaming of movies requires communication architecture that supports high data rates, and the 8K resolution system has the capability. The content of the 8K high-resolution system comprises the optical and gigabit Ethernet that supports the digital cinema content. Therefore, the viewer's expectations are met through the multiple video streams that are beyond frame resolutions. The trend of the mobile technology revolution with the 4K resolution is changing with the innovative technologies of 8K high-resolution system (Shirai et al., 2011).

The digital video streaming uses higher frame resolutions that display high-resolution rates. With the emergence of new technologies, there is need to meet the evolving 8K resolution system that supports the viewing experience.

Conclusion

In conclusion, the progress in technology demands high-quality video resolutions. The spread of the 8K high-resolution system has made it possible for quality performance in both broadcasting and medical industries. Also, the development of the 8K video streaming system with high resolutions supports various video formats to achieve a media exchange platform. The 8K system streaming multiple images as well as utilizing the 4K images even in a remote environment with no 4K equipment is an achievement in the new technology era. It has proven the feasibility of the collaboration between multiple points of the 4K equipment and the schemes dealing with the bandwidths beyond the 800 megabits. It serves the purpose of creating lower resolution videos as it incorporates the cropping techniques and the downsampling techniques. In the film editing, the 8K system with its high resolution helps to shoot at a further distance.

The 8K imaging system as compared to the 2K and 4K resolution systems is capable of leading to future changes both in the broadcasting and medical indus...