Recently, In terms of broadcasting and transferring the procedures related to this area of contemporary technology, as well as in terms of its fundamental processing and coding, digital television has taken a while to gain traction. It is well recognized that the challenges associated with fundamental digital processing methods and digital image storage are the primary cause of this observed delay. It has taken a while for digital television to gain traction, both in terms of basic processing and coding as well as in terms of broadcasting and transferring the procedures related to this area of contemporary technology. It is well recognized that the primary cause of this observed delay is the challenges associated with digital image storage and fundamental digital processing methods. To enable digital picture reception on handheld devices, a few options are suggested. Digital Multimedia Broadcasting DMB (Asia), Media Flo (USA), and Digital Video Broadcasting-Handheld DVB-H (Europe) are the three primary standards that have been authorized. They are using the same notional TV or DAB platform transport stream. In this work, we provide a novel way to integrate digital video into GSM interfaces without altering any of the standard’s specifications. The novel suggested technique therefore makes it possible to accomplish this goal by utilizing GSM channels directly. The primary goal is to use the H265 advanced standard to reduce the bit rate coming from the video encoder by inserting a novel design known as a “Brewer-buffer”. To create the RF channels, the outputs of this newly suggested element will be routed to the GSM norm’s time division multiple access TDMA frames. Our receiver has to have the symmetric component “Invert brewerbuffer” in order to restore the digital video. In fact, we will also suggest a new receiver architecture for this handheld video reception application. We illustrate the basic architecture and define the uniqueness of the suggested approach.

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Design and Hardware Implementation of a Novel Protocol for Digital Video in GSM Interfaces

  • Dalenda Bouzidi,
  • Youssef Oudhini,
  • Fahmi Ghozzi

摘要

Recently, In terms of broadcasting and transferring the procedures related to this area of contemporary technology, as well as in terms of its fundamental processing and coding, digital television has taken a while to gain traction. It is well recognized that the challenges associated with fundamental digital processing methods and digital image storage are the primary cause of this observed delay. It has taken a while for digital television to gain traction, both in terms of basic processing and coding as well as in terms of broadcasting and transferring the procedures related to this area of contemporary technology. It is well recognized that the primary cause of this observed delay is the challenges associated with digital image storage and fundamental digital processing methods. To enable digital picture reception on handheld devices, a few options are suggested. Digital Multimedia Broadcasting DMB (Asia), Media Flo (USA), and Digital Video Broadcasting-Handheld DVB-H (Europe) are the three primary standards that have been authorized. They are using the same notional TV or DAB platform transport stream. In this work, we provide a novel way to integrate digital video into GSM interfaces without altering any of the standard’s specifications. The novel suggested technique therefore makes it possible to accomplish this goal by utilizing GSM channels directly. The primary goal is to use the H265 advanced standard to reduce the bit rate coming from the video encoder by inserting a novel design known as a “Brewer-buffer”. To create the RF channels, the outputs of this newly suggested element will be routed to the GSM norm’s time division multiple access TDMA frames. Our receiver has to have the symmetric component “Invert brewerbuffer” in order to restore the digital video. In fact, we will also suggest a new receiver architecture for this handheld video reception application. We illustrate the basic architecture and define the uniqueness of the suggested approach.