Abstract: A method may include, but is not limited to: providing a volume of feedstock and a volume of oxygen-enriched air to a thermal reformer; reacting the volume of feedstock and the volume of oxygen-enriched air with the thermal reformer at an operating temperature to produce a raw syngas stream; removing particulate matter from the raw syngas stream with a two-stage cyclone assembly, wherein the two-stage cyclone assembly comprises a first cyclone and a second cyclone; scrubbing the raw syngas stream received from the two-stage cyclone assembly with a quench scrubber to produce an engine gas stream; and providing the engine gas stream to a CHP genset to be used as fuel.

Abstract: An enhanced graphics pipeline is provided that enables common core hardware to perform as different components of the graphics pipeline, programmability of primitives including lines and triangles by a component in the pipeline, and a stream output before or simultaneously with the rendering a graphical display with the data in the pipeline. The programmer does not have to optimize the code, as the common core will balance the load of functions necessary and dynamically allocate those instructions on the common core hardware. The programmer may program primitives using algorithms to simplify all vertex calculations by substituting with topology made with lines and triangles. The programmer takes the calculated output data and can read it before or while it is being rendered. Thus, a programmer has greater flexibility in programming.

Abstract: Methods for mapping color data having at least one color associated therewith to an output device based on an input-device profile and an output-device profile, each profile having a tone curve and a color matrix, are provided. In one embodiment, the method includes receiving color data from an input device and determining whether the color data is in a linear space. If it is determined that the color data is not in a linear space, the method further includes applying the tone curve of the input device profile to the color data to convert it into a linear space. The method further includes converting the color(s) associated with the color data from the input linear space to an output linear space by applying the color matrix of the input device profile and the inverse color matrix of the output device profile to create color-converted image data.

Abstract: Systems and methods for applying virtual machines to graphics hardware are provided. In various embodiments of the invention, while supervisory code runs on the CPU, the actual graphics work items are run directly on the graphics hardware and the supervisory code is structured as a graphics virtual machine monitor. Application compatibility is retained using virtual machine monitor (VMM) technology to run a first operating system (OS), such as an original OS version, simultaneously with a second OS, such as a new version OS, in separate virtual machines (VMs). VMM technology applied to host processors is extended to graphics processing units (GPUs) to allow hardware access to graphics accelerators, ensuring that legacy applications operate at full performance. The invention also provides methods to make the user experience cosmetically seamless while running multiple applications in different VMs.

Abstract: A method and system for minimizing an amount of data needed to test data against subarea boundaries in spatially composited digital video is provided. Graphics data for a frame is composed of geometry chunks. Each geometry chunk is defined by its own bounding region, where the bounding region defines the space the geometry chunk occupies on the compositing window. Only the parameters that define the bounding region are communicated to each graphics unit in conjunction with the determination of which graphics unit will render the geometry chunk defined by the bounding region. The actual graphics data that comprises the geometry chunk is communicated only to those geometry units that will actually render the geometry chunk. This reduces the amount of data needed to communicate graphics data information in spatially composited digital video.

Abstract: Computer-readable media, computerized methods, and computer systems for protecting secure data by writing content of the secure data to a protected memory segment are provided. Initially, streaming media is received from a media-reading device and portions of the streaming media are identified as secure data. A data-management process to protect content within the secure data is executed. During execution, the protected memory segment is instantiated, a region of memory is dynamically allocated to hold the protected memory segment, and content of the secure data is written thereto. The protected memory segment is generally a data store that conditionally limits access thereto utilizing hardware-based rules, thereby guarding the content against exposure to unauthorized systems and to attackers. The region of memory may be allocated on CPU hardware, GPU hardware, or a combination thereof. The content may then be encrypted and released for conveyance to one or more presentation devices.

Abstract: Methods for mapping color data having at least one color associated therewith to an output device based on an input-device profile and an output-device profile, each profile having a tone curve and a color matrix, are provided. In one embodiment, the method includes receiving color data from an input device and determining whether the color data is in a linear space. If it is determined that the color data is not in a linear space, the method further includes applying the tone curve of the input device profile to the color data to convert it into a linear space. The method further includes converting the color(s) associated with the color data from the input linear space to an output linear space by applying the color matrix of the input device profile and the inverse color matrix of the output device profile to create color-converted image data.

Abstract: A method and system for minimizing an amount of data needed to test data against subarea boundaries in spatially composited digital video. Spatial compositing uses a graphics unit or pipeline to render a portion (subarea) of each overall frame of digital video images. This reduces the amount of data that each processor must act on and increases the rate at which an overall frame is rendered. Optimization of spatial compositing depends on balancing the processing load among the different pipelines. The processing load typically is a direct function of the size of a given subarea and a function of the rendering complexity for objects within this subarea. Load balancing strives to measure these variables and adjust, from frame to frame, the number, sizes, and positions of the subareas. The cost of this approach is the necessity to communicate, in conjunction with each frame, the graphics data that will be rendered. Graphics data for a frame is composed of geometry chunks.

Abstract: An enhanced graphics pipeline is provided that enables common core hardware to perform as different components of the graphics pipeline, programmability of primitives including lines and triangles by a component in the pipeline, and a stream output before or simultaneously with the rendering a graphical display with the data in the pipeline. The programmer does not have to optimize the code, as the common core will balance the load of functions necessary and dynamically allocate those instructions on the common core hardware. The programmer may program primitives using algorithms to simplify all vertex calculations by substituting with topology made with lines and triangles. The programmer takes the calculated output data and can read it before or while it is being rendered. Thus, a programmer has greater flexibility in programming.

Abstract: An enhanced graphics pipeline is provided that enables common core hardware to perform as different components of the graphics pipeline, programmability of primitives including lines and triangles by a component in the pipeline, and a stream output before or simultaneously with the rendering a graphical display with the data in the pipeline. The programmer does not have to optimize the code, as the common core will balance the load of functions necessary and dynamically allocate those instructions on the common core hardware. The programmer may program primitives using algorithms to simplify all vertex calculations by substituting with topology made with lines and triangles. The programmer takes the calculated output data and can read it before or while it is being rendered. Thus, a programmer has greater flexibility in programming.

Abstract: A method and system for minimizing an amount of data needed to test data against subarea boundaries in spatially composited digital video. Spatial compositing uses a graphics unit or pipeline to render a portion (subarea) of each overall frame of digital video images. This reduces the amount of data that each processor must act on and increases the rate at which an overall frame is rendered. Optimization of spatial compositing depends on balancing the processing load among the different pipelines. The processing load typically is a direct function of the size of a given subarea and a function of the rendering complexity for objects within this subarea. Load balancing strives to measure these variables and adjust, from frame to frame, the number, sizes, and positions of the subareas. The cost of this approach is the necessity to communicate, in conjunction with each frame, the graphics data that will be rendered. Graphics data for a frame is composed of geometry chunks.

Abstract: A method of chip authentication is presented. The method includes verifying a driver identity. The method also includes establishing a Diffie Hellman key. Further, the method includes hashing the Diffie Hellman key. The method also includes picking a seed. Further, the method includes performing a hardware functional scan with the seed.

Abstract: A method and system for minimizing an amount of data needed to test data against subarea boundaries in spatially composited digital video. Spatial compositing uses a graphics unit or pipeline to render a portion (subarea) of each overall frame of digital video images. This reduces the amount of data that each processor must act on and increases the rate at which an overall frame is rendered. Optimization of spatial compositing depends on balancing the processing load among the different pipelines. The processing load typically is a direct function of the size of a given subarea and a function of the rendering complexity for objects within this subarea. Load balancing strives to measure these variables and adjust, from frame to frame, the number, sizes, and positions of the subareas. The cost of this approach is the necessity to communicate, in conjunction with each frame, the graphics data that will be rendered. Graphics data for a frame is composed of geometry chunks.

Abstract: Video frame buffers are controlled using a sequence of new-frame-indicators (e.g., FLIP) and no-new-frame-indicators (e.g., NOFLIP) in a frame indicator queue that is accessed with each display refresh. Video samples are loaded into a chain of video frame buffers that is “rotated” during the vertical blanking signal of the display to swap an old frame buffer out for a new frame buffer. The rotations of the frame buffer chain are controlled based on the frame indicators in the frame indicator queue to present new video samples to the display in a regular pattern, thereby providing smooth video playback.

Abstract: An enhanced graphics pipeline is provided that enables common core hardware to perform as different components of the graphics pipeline, programmability of primitives including lines and triangles by a component in the pipeline, and a stream output before or simultaneously with the rendering a graphical display with the data in the pipeline. The programmer does not have to optimize the code, as the common core will balance the load of functions necessary and dynamically allocate those instructions on the common core hardware. The programmer may program primitives using algorithms to simplify all vertex calculations by substituting with topology made with lines and triangles. The programmer takes the calculated output data and can read it before or while it is being rendered. Thus, a programmer has greater flexibility in programming.

Abstract: A method, medium, and system are provided for a generic surface manager which allows graphics surfaces generated according to various existing and/or new graphics protocols to be rendered by a graphics consumer. The generic surface manager functions as an interface between a graphics consumer and one or more applications that generate graphics surfaces. Support is provided for various existing graphics protocols and the generic surface manager can be easily modified to accept surfaces generated according to new graphics protocols. An extensible system is thereby provided that can support a variety of graphics protocols without requiring modifications to be made to the graphics consumer.

Abstract: Computer-readable media, computerized methods, and computer systems for protecting secure data by writing content of the secure data to a protected memory segment are provided. Initially, streaming media is received from a media-reading device and portions of the streaming media are identified as secure data. A data-management process to protect content within the secure data is executed. During execution, the protected memory segment is instantiated, a region of memory is dynamically allocated to hold the protected memory segment, and content of the secure data is written thereto. The protected memory segment is generally a data store that conditionally limits access thereto utilizing hardware-based rules, thereby guarding the content against exposure to unauthorized systems and to attackers. The region of memory may be allocated on CPU hardware, GPU hardware, or a combination thereof. The content may then be encrypted and released for conveyance to one or more presentation devices.

Abstract: Systems and methods for verifying the authenticity of a graphics chip or other hardware chips or hardware devices by performing a hardware functionality scan.

Abstract: An enhanced graphics pipeline is provided that enables common core hardware to perform as different components of the graphics pipeline, programmability of primitives including lines and triangles by a component in the pipeline, and a stream output before or simultaneously with the rendering a graphical display with the data in the pipeline. The programmer does not have to optimize the code, as the common core will balance the load of functions necessary and dynamically allocate those instructions on the common core hardware. The programmer may program primitives using algorithms to simplify all vertex calculations by substituting with topology made with lines and triangles. The programmer takes the calculated output data and can read it before or while it is being rendered. Thus, a programmer has greater flexibility in programming.

Abstract: Systems for rendering Effect graphs for non-destructively processing digital image data which integrate Central Processing Unit (CPU) processing and Graphics Processing Unit (GPU) processing are provided. Additionally provided are systems for processing digital image data utilizing Effect graphs. The systems of the present invention integrate CPU processing and GPU processing to facilitate accelerated rendering of Effect graphs and, consequently, accelerated processing of digital images. Methods for processing digital image data utilizing the systems herein described are also provided.