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Generally, it is thought that control is simpler than an Internal Combustion Engine (ICE)-Motorcycle(MC) as for the Electric Vehicle(EV) type MC. However, there is few characteristic to the ICE-MC to the EV-MC and it cannot get good performance without control for EV-MC. We study the methodology for design and evaluation an EV-MC. In this approach, we developed the prototype EV-MC having manual transmission. In our study, we think that EV-MC having manual transmission is feature in comparison with other general EV-MC. From this feature, we had to develop the function control in addition to standard EV-MC function control. This paper provides a function control for EV-MC having manual transmission. In this paper, we arrange the problem points of EV-MC which put electric propulsion motor and manual transmission together at first. And report the result that studied a method to solve the problem points.

As for automobile, the mass production period of Electric Vehicle(EV) has begun by the rapid progress of the battery performance. But for EV-Motorcycle(MC), it is limited for the venture companies' releases. The design and evaluation methodologies are not yet established or standardized so far. This paper provides the practical and the experimental examples. To study the feasibility of EV-MC, we developed the prototypes in the present technical and suppliers' parts environments, and evaluated them by the practical view of the MC usage. The developed EV-MC has the equivalent driving performance of the 250cc internal combustion engine(ICE)-MC and a cruising range of 100km in normal use.

Motorcycle engines are required to have high output levels but low exhaust gas emission levels. Measuring the combustion condition proves useful for understanding the engine's operating condition. We developed a compact, high-performance combustion analyzer for measuring the combustion condition of motorcycle engines. This newly developed combustion analyzer is capable of analyzing the indicated mean effective pressure at each engine cycle at the engine speeds exceeding 10,000 rpm required of a high-performance motorcycle engine. Its compact size makes it easily applicable for onboard use, allowing measurement in any operating condition, including circuit travel, which has never been possible with conventional combustion analyzers. We used this new combustion analyzer to measure combustion condition not only on a chassis dynamo but also during circuit travel, when the motorcycle and engine are subjected to much harsher operating conditions.

There is an unceasing demand for motorcycle operating performance levels to rise higher and for exhaust gas emission levels to fall lower. And decreasing the development term is also important demand. Therefore in the development of motorcycles that can satisfy that demand, the ability to carry out measurements under actual driving conditions is of enormous importance. In particular, if the pressure inside the engine cylinder can be measured, a broad range of information can be obtained. The authors are engaged in the development and improvement of combustion analyzers that can be mounted on motorcycles, thereby making it possible to conduct measurements even while driving on a circuit. This paper is the authors' second report on the background to and the latest results of that development effort.

In many cases of the development of motorcycle engines, the combustion analysis has been of the engine in laboratory, not of the one onto actual motorcycles. It is mainly because the combustion analyzer in the market is too large to load onto a motorcycle. Pressure sensor, crank angle detector, arithmetic unit and data record device are necessary to analyze the combustion. The arithmetic unit is to process detected signals and generally needs the largest space among them. Needless to say, more reliable results of the combustion analysis could not be obtained under such limited experimental conditions. Therefore, we developed a compact combustion analyzer, which is possible to be loaded onto a motorcycle. The width of the arithmetic unit is 91mm, the depth 98mm and the thickness 20mm. The core chip has the calculation ability of 78MIPS at a clock speed 60MHz, and it has AD converter, DA converter and high-speed counter.