Abstract: In an image displaying device that includes a frame rate converting (FRC) portion, deterioration in image quality particularly of a telop part is prevented. The FRC portion 100 includes a motion vector detecting portion 101 and an interpolation frame generating portion 102. The motion vector detecting portion 101 includes a frame delaying portion 1 for delaying an input signal by one frame, an initial displacement vector selecting portion 2 for selecting and outputting an initial displacement vector used for vector detection, a motion vector calculating portion 3 for detecting a motion vector using the initial displacement vector, a vector memory 4 for storing a vector detection result, and a telop information detecting portion 5 for detecting an area where one or more telops exist and a moving speed thereof using a vector detection result in a previous frame supplied from the vector memory 4.

Abstract: It is an object to prevent the image quality deterioration of a moving image likely to include a plurality of the same consecutive images such as a movie video and an animation video due to the motion-compensated frame rate conversion (FRC) processing. An image displaying device is provided with an FRC portion (10) for converting the number of frames in an input image signal by interpolating an image signal to which a motion compensation processing has been given between the frames in the input image signal, a genre determining portion (14) for determining whether the input image signal is a predetermined genre, and a controlling portion (15).

Abstract: Deterioration in image quality of a moving image obtained by special reproduction caused by frame rate conversion (FRC) processing of a motion compensation type is prevented. An image displaying device includes an FRC portion 10 that converts the number of frames of the input image signal by interpolating an image signal to which motion compensation processing has been performed between frames of an input image signal, a special reproduction determining portion 14 that determines whether or not the input image signal is an image signal relating to a predetermined genre, and a controlling portion 15. The FRC portion 10 includes a motion vector detecting portion lie that detects a motion vector between frames of the input image signal, an interpolation vector evaluating portion 11f that assigns an interpolation vector between frames based on the motion vector information, and an interpolation frame generating portion 12d that generates an interpolation frame from the interpolation vector.

Abstract: It is an object to prevent the image quality deterioration of a moving image likely to include a plurality of the same consecutive images such as 2-3 or 2-2 pulldown video due to the motion-compensated frame rate conversion (FRC) processing. An image displaying device is provided with an FRC portion (10) for converting the number of frames in an input image signal by interpolating an image signal to which a motion compensation processing has been given between the frames in the input image signal, a pulldown detecting portion (14) for detecting whether the input image signal is an image signal to which pulldown conversion has been performed, and a controlling portion (15).

Abstract: A video image transmitting device, a video image receiving device, a video image recording device, a video image reproducing device, and a video image displaying device all having video signal processings such as a frame rate conversion (FRC) enable prevention of degradation of the video image reproduced by a video signal generated by superimposing first and second video signals on each other. The video image transmitting device (1) includes an editing device (2) for superimposing first and second video signals on each other according to video combining information, a video image encoding processing portion (3) and a video image composite information encoding processing portion (4) for encoding the output video signal from the editing device (2) and video combining information respectively, a multiplexing processing portion (5) for multiplexing the encoded data, and a transmitting portion (6) for transmitting the multiplexed data.

Abstract: The quality of moving picture image with a large moving amount is prevented from deterioration due to moving compensation type frame rate conversion (FRC) processing. The image display device is comprised of an FRC unit (10) that interpolates an image signal subjected to moving compensation processing between frames so as to convert the number of frames of the input image signal, a moving amount judging unit (14) that judges whether a moving amount of the input image signal between the frames is larger than a predetermined value or not, and a control unit (15). The FRC unit (10) is provided with a moving vector detecting unit (11e) that detects a moving vector between the frames of the input image signal, an interpolation vector evaluating unit (11f) that allocates an interpolation vector between the frames on the basis of the moving vector information and an interpolation frame generating unit (12d) that generates an interpolation frame from the interpolation vector.

Abstract: It is an object to prevent the image quality deterioration of a moving image likely to include a plurality of the same consecutive images such as a movie video image or a CG video image due to the motion-compensated frame rate conversion (FRC) processing. An image displaying device is provided with an FRC portion (10) for converting the number of frames in an input image signal by interpolating an image signal to which a motion compensation processing has been given between the frames in the input image signal, a controlling portion (14) for controlling each portion according to an image tone mode selected by a user.

Abstract: An audio-visual environment control system is provided with a function to control illumination for optimum audio-visual environment in accordance with a scene situation of an displayed image. A data transmission device is comprised of a data multiplexing portion for multiplexing scene situation data indicating scene setting situations of each scene of image data, and a transmitting portion for modulating and transmitting the image data in which the scene situation data are multiplexed. A data receiving apparatus is comprised of a data separating portion 22 for separating the scene situation data from the received image data, a CPU 23 for controlling illumination light of an illuminating device 27 in accordance with the scene situation data, and an illumination control data generating portion 24.

Abstract: In an image displaying apparatus including a motion compensated rate converting (FRC) portion, deterioration of image quality is prevented in an image having a high-speed region and a low-speed region mixed. The FRC portion includes a motion vector detecting portion 11e and an interpolation frame generating portion 12b. The motion vector detecting portion 11e includes a first region detecting means 112e1 that detects a first region (high-speed region) including a motion amount equal to or greater than a first predetermined amount from an input image signal, a second region detecting means 112e2 that detects a second region (low-speed region) including a motion amount equal to or less than a second predetermined amount from the input image signal, and a third region detecting means 113e that detects a still region from an inter-frame difference of the input image signal.

Abstract: An image display device comprising a frame rate converting (FRC) portion can prevent image degradation at a screen boundary part attributed to the FRC processing when displaying an image obtained by combining a plurality of screens. The image display device comprises an FRC portion 10 for converting the number of frames of an input image signal by interpolating an image signal subjected to a motion compensation process between frames of the input image signal and a screen combining portion 13 for combining a plurality of screens. When displaying an image obtained by combining a plurality of screens, the screen combining portion 13 combines a plurality of screens by matching a motion detection block boundary when performing the motion compensation process by the FRC portion 10 with the respective screen boundaries of the plurality of screens.

Abstract: Provided is an audio visual environment control system capable of realizing optimal audio-visual environment illumination control in accordance with the illumination condition upon shooting of a display image. A data transmission device comprises: a data multiplexing portion for multiplexing the shooting illumination data indicating the illumination condition at the shooting of each scene of video data on the video data, and a transmitting portion for modulating and transmitting the video data on which the shooting illumination data is multiplexed. A data receiving apparatus which receives the data comprises: a data separating portion 22 for separating the shooting illumination data from the video data, a CPU 23 for controlling the illuminating light of an illuminating device 27 in accordance with the illumination data, and an illumination control data generating portion 24.

Abstract: During reproduction of received wide-field video data by use of a receiving side apparatus, whatever may be the type, size, resolution and orientation of a receiving side display apparatus, the video information is converted, based on information transmitted together with the video information, such that the video information is suitable for the reproducing side display apparatus, thereby achieving a faithful display. A wide-field video generating/displaying system has a virtual video display system comprising one or more display apparatus (114) and also has a real video display system comprising one or more display apparatuses (105-107) that display the video information.

Abstract: In an image display device having a frame rate converting (FRC) portion, it is possible to prevent image degradation of a combined image display portion such as an OSD and PinP attributed to the FRC process. The image display device includes: an FRC portion 10 for converting the number of frames of an input image signal by interpolating an image signal subjected to a motion compensation process between the frames of the input image signal; an OSD processing portion 14 for superposing an OSD signal on the input image signal, and a controlling portion 15. The FRC portion 10 has a motion vector detecting portion 11e for detecting a motion vector between the frames of the input image signal, an interpolation vector evaluating portion 11f for allocating interpolation vector between frames based on the motion vector information, and an interpolation frame generating portion 12d for generating an interpolation frame from the interpolation vector.