The term encompasses the detailed technical specifications of a specific motorcycle model. This includes data pertaining to the engine, chassis, dimensions, performance figures, and other measurable attributes of the vehicle. For example, the engine displacement, horsepower, torque, weight, fuel capacity, suspension travel, and braking system components all fall under this classification.
These specifications are crucial for potential buyers as they provide objective data for comparison against competing models and influence purchasing decisions. They offer insight into the machine’s capabilities and suitability for various riding styles and purposes. Historically, manufacturers have provided this information to enable informed choices and showcase their engineering prowess.
The following sections will delve into the specific engine configuration, chassis design, performance metrics, and physical attributes defining the machine in question, offering a comprehensive overview of its technical profile.
1. Engine Displacement
Engine displacement is a fundamental aspect of the motorcycle and a critical component within its technical profile. It represents the total volume swept by the pistons inside the cylinders during one complete engine cycle. It has a direct correlation with performance characteristics detailed in the complete technical information.
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Cylinder Configuration
The engine’s cylinder arrangement impacts its overall dimensions and performance characteristics. A single-cylinder configuration, common in smaller displacement engines, often prioritizes simplicity and compactness. This configuration contributes to a narrow engine profile, which can enhance maneuverability. However, it may also lead to increased vibration compared to multi-cylinder designs. The specific engine is characterized by its single cylinder layout.
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Bore and Stroke
Bore and stroke measurements define the cylinder’s dimensions. Bore refers to the cylinder’s diameter, while stroke is the distance the piston travels within the cylinder. A larger bore, combined with a shorter stroke, generally favors higher engine speeds and increased horsepower. Conversely, a smaller bore and longer stroke tend to produce more torque at lower engine speeds. These dimensional characteristics are explicitly stated in the machine’s specifications.
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Compression Ratio
The compression ratio is the ratio between the volume of the cylinder when the piston is at the bottom of its stroke and the volume when the piston is at the top of its stroke. A higher compression ratio can lead to increased engine efficiency and power output, but it also necessitates the use of higher-octane fuel to prevent pre-ignition. This parameter is a standard element within the published specifications.
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Impact on Performance
The engine size is correlated with the vehicle’s power and torque output. A larger engine displacement generally allows for a greater volume of air and fuel to be combusted, resulting in increased power. However, it can also impact fuel efficiency and overall weight. The engine size directly influences acceleration, top speed, and the motorcycle’s ability to handle various riding conditions.
These elements, when considered together, offer a comprehensive understanding of the engine’s capabilities and its contribution to the overall performance profile. The specifics concerning engine displacement provide essential insight into the intended application and riding experience associated with the motorcycle.
2. Power Output
Power output, expressed in horsepower (hp) or kilowatts (kW), is a critical specification directly influencing the motorcycle’s performance capabilities. Within the context of the data, it represents the rate at which the engine can perform work. This figure is a function of engine displacement, compression ratio, and other design parameters; thus, it is intrinsically linked to other engine-related measurements. A higher power output generally translates to quicker acceleration and a higher top speed. It directly affects the rider’s experience, influencing the motorcycle’s responsiveness and ability to handle various riding conditions, such as climbing hills or overtaking vehicles.
The specified power output shapes the motorcycle’s intended use case. A relatively low power output suggests a focus on fuel efficiency and ease of handling, making it suitable for urban commuting or novice riders. Conversely, a higher power output implies a more performance-oriented design, potentially catering to experienced riders seeking thrilling acceleration and high-speed capabilities. Real-world examples include comparing similar motorcycles within the same displacement class; variations in power output often reflect differences in engine tuning, intake design, or exhaust systems, each contributing to distinct riding characteristics.
Understanding the power output specifications allows prospective buyers to objectively assess the motorcycle’s performance relative to their individual needs and preferences. While raw power is important, the power-to-weight ratio, calculated by dividing the power output by the motorcycle’s weight, provides a more nuanced understanding of its acceleration potential. This specification serves as a benchmark for comparing motorcycles and evaluating their suitability for specific riding styles or environments. Accurately interpreting power output figures, therefore, is essential for making an informed purchasing decision and appreciating the machine’s performance characteristics.
3. Chassis Dimensions
Chassis dimensions are fundamental parameters within the technical data, directly impacting handling characteristics and overall stability. Specific measurements such as wheelbase, rake, trail, and seat height are critical components. Wheelbase, the distance between the front and rear axles, affects stability; a longer wheelbase typically enhances stability at higher speeds, while a shorter wheelbase often contributes to increased agility. Rake, the angle of the steering head relative to the vertical, and trail, the distance between the steering axis and the point where the front tire contacts the ground, influence steering responsiveness and stability at different speeds. Seat height affects rider ergonomics and the ability to reach the ground. These dimensions, accurately defined in the technical specifications, are essential for understanding the motorcycle’s dynamic behavior and suitability for different rider sizes and experience levels.
Variations in chassis dimensions directly correlate with intended use cases. For example, a motorcycle with a shorter wheelbase and steeper rake angle is likely designed for nimble handling in urban environments, while a machine with a longer wheelbase and shallower rake angle is often optimized for long-distance touring and high-speed stability. Comparing two motorcycles within the same category reveals that subtle differences in these measurements can significantly alter the riding experience. Furthermore, adjustments to chassis dimensions, through modifications to suspension components or aftermarket parts, can alter the motorcycle’s handling characteristics, albeit potentially compromising other aspects of its performance. The technical information is provided by the manufacturer and enables buyers to make informed choices.
Understanding the chassis dimensions, and their influence on handling, constitutes an important factor during vehicle selection. The documented specification offers a concrete basis for evaluating a motorcycle’s intended handling properties. The knowledge of a specific motorcycle’s chassis dimensions allows one to estimate its ability to fulfill requirements based on terrain and riding preferences. The technical data serves as a crucial resource that empowers both experienced and novice riders in their assessment and purchase decision process.
Conclusion
The examination of the defined parameters has illuminated the core technical attributes. Engine displacement, power output, and chassis dimensions each contribute to the overall performance profile. Understanding these specifications enables a comprehensive assessment of the vehicle’s capabilities and its suitability for particular applications. The interplay between these elements dictates the motorcycle’s handling, power delivery, and intended riding experience.
Rigorous evaluation based on data is crucial for informed decision-making. Continued advancements in motorcycle technology necessitate ongoing analysis and refinement of technical understanding. Prospective buyers and enthusiasts are encouraged to consult detailed product documentation and expert reviews to further enhance their appreciation for the intricate engineering represented by the defined term.
