A low-power SuperHTM embedded processor core, the SH-X2, has been designed in 90-nm CMOS technology. The power consumption was reduced by using hierarchical fine-grained clock gating to reduce the power consumption of the flip-flops and the clock-tree, synthesis and a layout that supports the implementation of the clock gating, and several-level power evaluations for RTL refinement. With this clock gating and RTL refinement, the power consumption of the clock-tree and flip-flops was reduced by 35% and 59%, including the process shrinking effects, respectively. As a result, the SH-X2 achieved 6,000 MIPS/W using a Renesas low-power process with a lowered voltage. Its performance-power efficiency was 25% better than that of a 130-nm-process SH-X.

A 32-bit embedded RISC microprocessor core integrating a DSP has been developed using a 0.18-µm five-layer-metal CMOS technology. The integrated DSP has a single-MAC and exploits CPU resources to reduce hardware. The DSP occupies only 0.5 mm2. The processor core includes a large on-chip 128 kB SRAM called U-memory. A large capacity on-chip memory decreases the amount of traffic with an external memory. And it is effective for low-power and high-performance operation. To realize low-power dissipation for the U-memory access, the active ratio of U-memory's access is reduced. The critical path is a load path from the U-memory, and we optimized the path through the whole chip. The chip achieves 0.79 mA/MHz executing Dhrystone 1.1 at 108 MHz, which is suitable for mobile applications.

We have developed an application processor optimized for 3G cellular phones. It provides high energy efficiency by using various low power techniques. For low active power consumption, we use a hierarchical clock gating technique with a static clock gating controlled by software and a two-level dynamic clock gating controlled by hardware. This technique reduces clock power consumption by 35%. And we also apply a pointer-based pipeline to in the CPU core, which reduces the pipeline latch power by 25%. This processor contains 256 kB of on-chip user RAM (URAM) to reduce the external memory access power. The URAM read buffer (URB) enables high-throughput, low latency access to the URAM while keeping the CPU clock frequency high because the URAM read data is transferred to the URB in 256-bit widths at half the frequency of the CPU. The average miss penalty is 3.5 cycles at the CPU clock frequency, hit rate is 89% and the energy used for URAM reads is 8% less that what it would be for URAM without a URB. These techniques reduce the power consumption of the CPU core, and achieve 4500 MIPS/W at 1.0 V power supply (Dhrystone 2.1). For the low leakage requirements, we use internal power switches, and provides resume-standby (R-standby) and ultra-standby (U-standby) modes. Signals across a power boundary are transmitted through µI/O circuits to prevent invalid signal transmission. In the R-standby mode, the power supply to almost all the CPU core area, except for the URAM is cut off and the URAM is set to a retention mode. In the U-standby mode, the power supply to the URAM is also turned off for less leakage current. The leakage currents in the R-standby and in the U-standby modes are respectively only 98 and 12 µA. For quick recovery from the R-standby mode, the boot address register (BAR) and control register contents needed immediately after wake-up are saved by hardware into backup latches. The other contents are saved by software into URAM. It takes 2.8 ms to fully recover from R-standby.

A SuperHTM embedded processor core implemented in a 130-nm CMOS process running at 400 MHz achieved 720 MIPS and 2.8 GFLOPS at a power of 250 mW in worst-case conditions. It has a dual-issue seven-stage pipeline architecture but maintains the 1.8 MIPS/MHz of the previous five-stage processor. The processor meets the requirements of a wide range of applications, and is suitable for digital appliances aimed at the consumer market, such as cellular phones, digital still/video cameras, and car navigation systems.

A 197mW 70ms-latency Full-HD 12-channel video-processing SoC for in-vehicle information systems has been implemented in 16nm CMOS. The SoC integrates 17 video processors of 6 types to operate video processing independently of other processing in CPU/GPU. The synchronous scheme between the video processors achieves 70ms low-latency for driver assistance. The optimized implementation of lossy and lossless video-data compression reduces memory access data by half and power consumption by 20%.

SoC has driven the evolution of embedded systems or consumer electronics. Multi-core/multi-IP is the key technology to integrate many functions on a SoC for future embedded applications. In this paper, the transition of SoC and its required functions for cellular phones as an example is described. And the state-of-the-art multi-core technology of homogeneous type and heterogeneous type are shown. When many cores and IPs are integrated on a chip, collaboration between cores and IPs becomes important to meet requirement. To realize it, "MPSoC Platform" concept and elementary technology for this platform is described.

In low-power embedded processors design, stand-by power constraint is also important with average power and operation frequency. Multi-threshold-voltage cells are used in the design and the ratio of low-Vth cells should be controlled. On the other hand, physical synthesis flow is indispensable to achieve high performance and short design time. This paper proposes a physical synthesis methodology under the restriction of maximum low-Vth cell ratio. The experimental results show that our method can achieve only 4 MHz slower logic within 5% margin of the target low-Vth ratio. We have applied this design flow in an application processor design and the designed processor demonstrates 360 MIPS at 200 MHz only with 80 mW at 1.0 V, namely 4500 MIPS/W and 4.2 mA leakage current without any power-cut mode.

Many embedded system application in ubiquitous network strongly require the high performance SoC with overcoming the physical limitations in the advanced CMOS. To develop these SoC, the continuous design efforts have been done. The initial efforts are the primitive level circuit technique and power switching control method for suppressing the standby currents. However, the additional physical limitations and system enhancements becomes main factors, the new design efforts have been proposed. These design efforts are the application-oriented technologies from the system level to device level. This paper introduces the self voltage controlled technique to cancel the PVT (process, voltage, and temperature) variation, power distribution and power management for cellular phone application, parallel algorithm and optimized layout DSP, and massively parallel fine-grained SIMD processor for next multimedia application. The high performance SoC for the embedded are achieved by providing the components of the system level IPs and making the application oriented SoC platform.