Shinichi Hattori

A 99-mm/sup 2/, 0.7-W, single-chip MPEG-2 422P@ML video, audio, and system encoder with a 64-Mbit embedded DRAM for portable 422P@HL encoder system

A scalable single-chip 422P@ML MPEG-2 video, audio, and system encoder LSI for portable 422P@HL system is described. The encoder LSI is implemented using 0.13 /spl mu/m embedded DRAM technology. It integrates 3-M logic gates and 64-Mbit DRAM in an area of 99-mm/sup 2/. The power consumption is suppressed to 0.7-Watts by adopting a low power DRAM core. It performs real-time 422P@ML video encoding, audio encoding, and system encoding with no external DRAM. Furthermore, the encoder LSI realizes a 422P@HL video encoder with multi-chip configuration, due to its scalable architecture. This results in a PC-card size 422P@HL encoder with lowest power consumption for portable HDTV codec system.

Nondestructive inspection apparatus for inspecting an internal defect in an object

A nondestructive inspection apparatus includes a vibrating section 11 which is adapted to be placed in pressure contact with a surface of a measuring object 16 for generating an acoustic elastic wave W, a receiving section 12 for receiving a reflected wave, a pushing mechanism 13 for pushing the vibrating section and the receiving section against the measuring object, a pushing force measurement section 14 for detecting pushing forces Fa, Fb during vibration, a vibration control section 10 for driving the vibrating section, and a reception signal processing section 15 for determining the internal defect based on a reception signal R. The reception signal processing section includes a reflection energy calculation section for calculating a reflection energy level due to elasticity vibration of the measuring object, a reflection energy correction section for normalizing the reflection energy level by the pushing force to calculate a correction value; and an internal defect determination section for detecting the internal defect based on the correction value. With this arrangement, the absolute reflection energy level of the reflected wave is determined through comparison, thereby making it possible to improve the evaluation accuracy of the internal defect to a substantial extent.

Rate and quality control for full-field video compression around 10 Mbps

A coding scheme for interlaced video is investigated at rates around 10 Mb/s, with a view toward telecommunication-oriented application and simple implementation. An adaptive motion-compensated prediction scheme is studied. An adaptive arrangement of pixels within a block is then examined. It is shown that the adaptive approach permits effective control and provides a great improvement in picture quality over basic coding schemes.<<ETX>>