Koichi Terada

A 45nm 37.3GOPS/W heterogeneous multi-core SoC

We develop a heterogeneous multi-core SoC for applications, such as digital TV systems with IP networks (IP-TV) including image recognition and database search. Figure 5.3.1 shows the chip features. This SoC is capable of decoding 1080i audio/video data using a part of SoC (one general-purpose CPU core, video processing unit called VPU5 and sound processing unit called SPU) [1]. Four dynamically reconfigurable processors called FE [2] are integrated and have a total theoretical performance of 41.5GOPS and power consumption of 0.76W. Two 1024-way matrix-processors called MX-2 [3] are integrated and have a total theoretical performance of 36.9GOPS and power consumption of 1.10W. Overall, the performance per watt of our SoC is 37.3GOPS/W at 1.15V, the highest among comparable processors [4–6] excluding special-purpose codecs. The operation granularity of the CPU, FE and MX-2 are 32bit, 16bit, and 4bit respectively, and thus we can assign the appropriate processor for each task in an effective manner. A heterogeneous multi-core approach is one of the most promising approaches to attain high performance with low frequency, or low power, for consumer electronics application and scientific applications, compared to homogeneous multi-core SoCs [4]. For example, for image-recognition application in the IP-TV system, the FEs are assigned to calculate optical flow operation [7] of VGA (640×480) size video data at 15fps, which requires 0.62GOPS. The MX-2s are used for face detection and calculation of the feature quantity of the VGA video data at 15fps, which requires 30.6GOPS. In addition, general-purpose CPU cores are used for database search using the results of the above operations, which requires further enhancement of CPU. The automatic parallelization compilers analyze parallelism of the data flow, generate coarse grain tasks, schedule tasks to minimize execution time considering data transfer overhead for general-purpose CPU and FE.

Real‐time explosive particle detection using a cyclone particle concentrator

RATIONALE There is a need for more rapid methods for the detection of explosive particles. We have developed a novel real-time analysis technique for explosive particles that uses a cyclone particle concentrator. This technique can analyze sample surfaces for the presence of particles from explosives such as TNT and RDX within 3 s, which is much faster than is possible by conventional methods. METHODS Particles are detached from the sample surface with air jet pulses, and then introduced into a cyclone particle concentrator with a high pumping speed of about 80 L/min. A vaporizer placed at the bottom of the cyclone particle concentrator immediately converts the particles into a vapor. The vapor is then ionized in the atmospheric pressure chemical ionization (APCI) source of a linear ion trap mass spectrometer. RESULTS An online connection between the vaporizer and a mass spectrometer enables high-speed detection within a few seconds, compared with the conventional off-line heating method that takes more than 10 s to raise the temperature of a sample filter unit. Since the configuration enriched the number density of explosive particles by about 80 times compared with that without the concentrator, a sub-ng amount of TNT particles on a surface was detectable. CONCLUSIONS The detection limit of our technique is comparable with that of an explosives trace detector using ion mobility spectrometry. The technique will be beneficial for trace detection in security applications, because it detects explosive particles on the surface more speedily than conventional methods.