A debug system for heterogeneous multiple processors in a single chip has been developed. The system consists of the debug interface circuit integrated on the chip, the interface circuit board between the chip and PC, and the debug software implemented on a PC. This debug system has been designed for a multimedia communication processor, which includes an original video processor core, a RISC processor, and a DSP. The RISC processor controls the Video Processing Unit that includes an original video processor and other hardware functions. While in debug mode, the external debugger can control the Video Processing Unit in the same manner as the RISC processor. The JTAG based interface circuit contains registers for bus transaction for command, address, and data to be written, etc. and a bus transaction sequencer. In fact, this system can realize the same bus transaction control as the RISC processor's. By applying proposed debug system, simultaneous debug of the RISC Processing Unit and the Video Processing Unit can be realized. This allows problems to be investigated more quickly and the total time required for debugging is efficiently reduced. Without this technology an estimated 19 weeks is required to debug the chip, whereas use of this technology allowed debugging to be completed in 9 weeks.

An architectural design of a media processor core optimized for MPEG4/H26x video codec targeted for use in mobile multimedia terminals is presented. The architecture consists of a maximum 6.4 GOPS SIMD (Single Instruction Multiple Data) processor, RISC-processor, VLC-processor, and intelligent DMA controller. The unique SIMD processor completes 2-D DCT processing in 132 clock cycles, or block matching (16 by 16 pixels) in 24 clock-cycles. VLC-processor allows the completion of 8 by 8 block run-level coding in average 10 clock cycles in the case of low bit-rates. The functions of transpose-registers in the SIMD processor, data sub-sampling technique in the DMA, or data-sliding technique between PEs (Processor Elements) in the SIMD processor eliminate a large amount of cycle loss for data handling, and extract the highest level of performance. Through the use of the above architecture and the lower power approach, CIF 30 frames/s MPEG4 Simple Profile video codec @ 100 MHz can be achieved. Estimated dissipation is as low as 280 mW. 300 kgates and 16 kBytes four port SRAM are contained on a 12 mm2 area by using 0.18 µm process technology. The combination of the RISC-processor and SIMD-processor can also operate MPEG4 core profile (shape coding) that requires flexibility and performance.