三维渲染管道中的CoarseZ缓冲带宽模型

First International Multi-Symposiums on Computer and Computational Sciences (IMSCCS'06) Pub Date : 2006-06-20 DOI:10.1109/IMSCCS.2006.44

Ke Yang, Ke Gao, Jiaoying Shi, Xiaohong Jiang, Hua Xiong

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引用次数: 2

摘要

深度流量占据了3D图形内存带宽的很大一部分。为了减少深度读取，我们建议在逐像素测试前使用低分辨率深度缓冲区(即CoarseZ缓冲区)进行瓦片级深度剔除。tile的最大深度存储在CoarseZ缓冲区的相应条目中。仿真结果表明，较小的CoarseZ缓冲区可以获得非常高的剔除率，并显著降低z读取带宽。我们建立了一个模型，量化了CoarseZ设计参数对其效率和带宽的影响。工业基准测试结果表明，块大小为4，位深为16的CoarseZ是减少内存带宽的最佳选择

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CoarseZ Buffer Bandwidth Model in 3D Rendering Pipeline

Depth traffic occupies a major portion of 3D graphics memory bandwidth. In order to reduce depth reading, we propose employing a low-resolution depth buffer, namely CoarseZ buffer, for tile-level depth culling before per-pixel test. The maximum depth of a tile is stored in the corresponding entry of CoarseZ buffer. Simulation results show that a small CoarseZ buffer can achieve remarkably high culling rate and significantly reduce z-reading bandwidth. We build a model that quantifies the influence of the CoarseZ design parameters on its efficiency and bandwidth. Test results of industrial benchmarks show that CoarseZ with tile size of 4 and bit depth of 16 can be a best selection to reduce memory bandwidth

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First International Multi-Symposiums on Computer and Computational Sciences (IMSCCS'06)

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