Young-Taek Kim

Fast exploration of parameterized bus architecture for communication-centric SoC design

For successful SoC design, efficient and scalable communication architecture is crucial. Some bus interconnects now provide configurable structures to meet this requirement of an SoC design. Furthermore, bus IP vendors provide software tools that automatically generate RTL codes of a bus once its designer configures it. Configurability, however, imposes more challenges upon designers because complexity involved in optimization increases exponentially as the number of parameters grows. In this paper, we present a novel approach with which effort requirement can be dramatically reduced. An automated optimization tool we developed is used and it exploits a genetic algorithm for fast design exploration. This paper shows that the time for the optimizing task can be reduced by more than 90% when the tool is used and, more significantly the task can be done without an experts hand while ending up with a better solution.

Fast and Accurate Transaction Level Modeling of an Extended AMBA2.0 Bus Architecture

A transaction level modeling (TLM) approach is used to meet the simulation speed as well as cycle accuracy for large scale SoC performance analysis. We implemented the transaction-level model of a proprietary bus called AHB+ which supports an extended AMBA2.0 protocol. The AHB+ transaction-level model is shown to be 353 times faster than the pin-accurate RTL model, while maintaining 97% accuracy on average. We also present the TLM development procedure of a bus architecture.

A systematic IP and bus subsystem modeling for platform-based system design

The topic on platform-based system modeling has received a great deal of attention today. One of the important tasks that significantly affect the effectiveness and efficiency of the system modeling is the modeling of IP components and communication between IPs. To be effective, it is generally accepted that the system modeling should be performed in two steps; In the first step, a fast but some inaccurate system modeling is considered to facilitate the simultaneous development of software and hardware. The second step then refines the models of the software and hardware blocks (i.e., IPs) to increase the simulation accuracy for the system performance analysis. Here, one critical factor required for a successful system modeling is a systematic modeling of the IP blocks and bus subsystem connecting the IPs. In this respect, this work addresses the problem of systematic modeling of the IPs and bus subsystem in different levels of refinements. In the experiments, we found that by applying our proposed IP and bus modeling methods to the MPEG-4 application, we are able to achieve 4times performance improvement and at the same time, reduce the software development time by 35%, compared to that by conventional modeling methods