Abstract: A streaming media encoder for encoding and delivering media content is disclosed. The streaming media encoder has a media input interface for receiving a media stream, a media encoder for receiving the media stream from the input interface and encoding the media stream, thereby producing an encoded media stream. The media encoder has a first confidence monitor for displaying a video image from the received media stream, a second confidence monitor for displaying a video image from the encoded media stream, and a network interface for providing the encoded media stream to a network.

Abstract: A streaming media encoder for encoding and delivering media content is disclosed. The streaming media encoder has a media input interface for receiving a media stream, a media encoder for receiving the media stream from the input interface and encoding the media stream, thereby producing an encoded media stream. The media encoder has a first confidence monitor for displaying a video image from the received media stream, a second confidence monitor for displaying a video image from the encoded media stream, and a network interface for providing the encoded media stream to a network.

Abstract: A streaming media encoder for encoding and delivering media content is disclosed. The streaming media encoder has a media input interface for receiving a media stream, a media encoder for receiving the media stream from the input interface and encoding the media stream, thereby producing an encoded media stream. The media encoder has a first confidence monitor for displaying a video image from the received media stream, a second confidence monitor for displaying a video image from the encoded media stream, and a network interface for providing the encoded media stream to a network.

Abstract: There is disclosed a system and method of controlling the timing in a system having a number of different elements, each requiring individual timing signals. The system utilizes a RAM memory divided into a number of groups or cycle types, each cycle type having a number of addressable words. The individual bits of each word serve to control the individual system elements. The memory is programmed to allow each group of words to control the system timing in a different manner. Provision is made for the memory to skip certain words in a particular group under control of externally provided signals.

Abstract: There is disclosed a memory controller for controlling addresses to a plurality of different memory types while treating the memory system as a whole so as to create a unified addressing arrangement. The controller is structured to allow for a reprogramming of the split address between the memories and for maintaining contiguously addressed locations. A register is used to hold the split address and the register can be updated at initialization to vary the split depending upon physical memory changes. The controller also maintains a common bit length addressing word regardless of the memory size being addressed by the system processor.

Abstract: An image processor having an image algorithm processor (66) operating under control of a writable control store (94), and a number of parallel image processors (72) operating under control of instruction words from a writable control store (100). An image memory controller (68) receives memory addresses from the image algorithm processor (66) for coordinating the reading and writing of an image memory (82) using pixel data processed by the parallel image processor set (72). The image memory controller (68) arbitrates memory address request cycles, memory refresh cycles and screen refresh cycles. The image memory (82) includes different planes (84, 86 and 88) associated with red, green and blue pixel data. Associated with each image memory plane is a video processor (106) for converting parallel image data to high speed serial image data.

Abstract: An image processor having an image algorithm processor (66) operating under control of a writable control store (94), and a number of parallel image processors (72) operating under control of instruction words from a writable control store (100). An image memory controller (68) receives memory addresses from the image algorithm processor (66) for coordinating the reading and writing of an image memory (82) using pixel data processed by the parallel image processor set (72). The image memory controller (68) arbitrates memory address request cycles, memory refresh cycles and screen refresh cycles. The image memory (82) includes different planes (84, 86 and 88) assocated with red, green and blue pixel data. Associated with each image memory plane is a video processor (106) for converting parallel image data to high speed serial image data.

Abstract: Disclosed is an image processor having an image algorithm processor (66) operating under control of a writable control store (94), and a number of parallel image processors (72) operating under control of instruction words from a writable control store (100). An image memory controller (68) receives memory addresses from the image algorithm processor (66) for coordinating the reading and writing of an image memory (82) using pixel data processed by the parallel image processor set (72). The image memory controller (68) arbitrates memory address request cycles, memory refresh cycles and screen refresh cycles. The image memory (82) includes different planes (84, 86 and 88) associated with red, green and blue pixel data. Associated with each image memory plane is a video processor (106) for converting parallel image data to high speed serial image data.

Abstract: An image processor having an image algorithm processor (66) operating under control of a writable control store (94), and a number of parallel image processors (72) operating under control of instruction words from a writable control store (100). An image memory controller (68) receives memory addresses from the image algorithm processor (66) for coordinating the reading and writing of an image memory (82) using pixel data processed by the parallel image processor set (72). The image memory controller (68) arbitrates memory address request cycles, memory refresh cycles and screen refresh cycles. The image memory (82) includes different planes (84, 86 and 88) associated with red, green and blue pixel data. Associated with each image memory plane is a video processor (106) for converting parallel image data to high speed serial image data.

Abstract: Disclosed is an image processor having an image algorithm processor (66) operating under control of a writable control store (94), and a number of parallel image processors (72) operating under control of instruction words from a writable control store (100). An image memory controller (68) receives memory addresses from the image algorithm processor (66) for coordinating the reading and writing of an image memory (82) using pixel data processed by the parallel image processor set (72). The image memory controller (68) arbitrates memory address request cycles, memory refresh cycles and screen refresh cycles. The image memory (82) includes different planes (84, 86 and 88) associated with red, green and blue pixel data. Associated with each image memory plane is a video processor (106) for converting parallel image data to high speed serial image data.