Calculate Acceleration from Power Weight

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Calculate Acceleration from Power and Weight

Understand your vehicle's performance potential by calculating its acceleration based on power and weight.

Performance Calculator

Enter the total power output of the engine (e.g., horsepower, kilowatts).
Horsepower (hp) Kilowatts (kW) Select the unit for engine power.
Enter the total weight of the vehicle (including driver and fuel).
Kilograms (kg) Pounds (lbs) Select the unit for vehicle weight.
Enter the aerodynamic drag coefficient (typically between 0.25 and 0.5).
Enter the frontal area of the vehicle in square meters (m²).
Effective gear ratio at the speed of interest (e.g., for 0-60 mph).
Tire radius in meters (m).
Efficiency of the drivetrain (e.g., 0.85 for 85%).

Results

Power-to-Weight Ratio
Force Available at Wheels
Estimated 0-60 mph Time
Formula Used: Acceleration is derived from the net force acting on the vehicle and its mass. The force at the wheels is calculated from engine power, accounting for drivetrain losses and gear ratios. Aerodynamic drag and rolling resistance are also considered.
Enter values and click "Calculate Acceleration" to see results.

Performance Curve

Estimated Force and Acceleration vs. Speed

Variable Breakdown

Variable Meaning Unit Typical Range
Engine Power Total power output of the engine. hp / kW 50 – 1000+
Vehicle Weight Total mass of the vehicle and occupants. kg / lbs 500 – 3000+
Power-to-Weight Ratio Engine power per unit of weight. Key performance indicator. hp/kg or W/kg 0.1 – 1.0+
Drag Coefficient (Cd) Measure of aerodynamic resistance. Unitless 0.25 – 0.50
Frontal Area Cross-sectional area facing the direction of motion. 1.5 – 3.0
Gear Ratio Reduction in speed and increase in torque from gearbox. Unitless 2.0 – 5.0
Tire Radius Radius of the vehicle's tire. m 0.25 – 0.40
Transmission Efficiency Percentage of power delivered to the wheels. % 75% – 95%

What is Acceleration from Power and Weight?

Calculating acceleration from power and weight is a fundamental concept in physics and automotive engineering. It quantifies how quickly a vehicle can increase its speed. This calculation is crucial for understanding vehicle performance, comparing different models, and optimizing designs. The core idea is that a more powerful engine in a lighter vehicle will result in faster acceleration. This relationship is often summarized by the power-to-weight ratio, a key metric that directly influences how rapidly a vehicle can overcome inertia and external forces like air resistance and friction.

Who should use it: Automotive enthusiasts, performance car buyers, race car engineers, vehicle designers, and anyone curious about the physics of motion will find this calculation useful. It helps in making informed decisions when purchasing vehicles, tuning engines, or understanding the limitations and capabilities of different transportation methods.

Common misconceptions: A common misconception is that only engine horsepower matters for acceleration. In reality, vehicle weight plays an equally significant role. A heavy car with high horsepower might accelerate slower than a lighter car with less horsepower. Another misconception is that acceleration is linear; in reality, it decreases as speed increases due to rising air resistance and the limitations of engine power delivery across the RPM range. The power-to-weight ratio is a simplified metric, and actual acceleration depends on many other factors like drivetrain efficiency, tire grip, and aerodynamics.

Acceleration from Power and Weight Formula and Mathematical Explanation

The calculation of acceleration from power and weight involves several steps, integrating principles of Newtonian mechanics and thermodynamics. The fundamental equation of motion is F = ma, where F is the net force, m is mass, and a is acceleration. To find acceleration (a), we need to determine the net force (F) acting on the vehicle and its mass (m).

Step 1: Convert Units Ensure all inputs are in consistent SI units (Watts for power, kilograms for mass).

Step 2: Calculate Power Available at the Wheels Engine power is reduced by drivetrain losses (transmission, differential, etc.). Power_wheels = Engine_Power * Transmission_Efficiency

Step 3: Calculate Force at the Wheels Force (F) is related to power (P) and velocity (v) by P = Fv. Therefore, F = P / v. This force is the maximum propulsive force the wheels can generate at a given velocity. Force_wheels = Power_wheels / Velocity

Step 4: Calculate Aerodynamic Drag Force Aerodynamic drag (Fd) opposes motion and increases with the square of velocity. Fd = 0.5 * Air_Density * Cd * A * v² Where:

  • Air_Density is the density of air (approx. 1.225 kg/m³ at sea level, 15°C).
  • Cd is the drag coefficient.
  • A is the frontal area.
  • v is the velocity.

Step 5: Calculate Rolling Resistance Force Rolling resistance (Fr) is the force opposing motion due to tire deformation and road surface interaction. It's often approximated as a constant or slightly velocity-dependent. Fr = Crr * m * g Where:

  • Crr is the coefficient of rolling resistance.
  • m is the mass.
  • g is the acceleration due to gravity (approx. 9.81 m/s²).
A typical Crr for car tires on asphalt is around 0.015.

Step 6: Calculate Net Force The net force (F_net) is the propulsive force minus the opposing forces. F_net = Force_wheels - Fd - Fr

Step 7: Calculate Acceleration Using Newton's second law, a = F_net / m.

Simplified Power-to-Weight Ratio: A common simplification is the power-to-weight ratio (P/W), which gives a general idea of performance but doesn't account for velocity-dependent forces. P/W = Engine_Power / Vehicle_Weight This ratio is often expressed in hp/lb or kW/kg.

Variables Table:

Variable Meaning Unit Typical Range
Engine Power Total power output of the engine. hp / kW 50 – 1000+
Vehicle Weight Total mass of the vehicle and occupants. kg / lbs 500 – 3000+
Transmission Efficiency Percentage of power delivered to the wheels. % 75% – 95%
Drag Coefficient (Cd) Measure of aerodynamic resistance. Unitless 0.25 – 0.50
Frontal Area (A) Cross-sectional area facing the direction of motion. 1.5 – 3.0
Air Density Density of the surrounding air. kg/m³ ~1.225 (sea level)
Coefficient of Rolling Resistance (Crr) Factor representing rolling resistance. Unitless 0.01 – 0.02
Acceleration due to Gravity (g) Gravitational acceleration. m/s² ~9.81
Velocity (v) Instantaneous speed of the vehicle. m/s 0 – 100+
Net Force (F_net) Sum of all forces acting on the vehicle. Newtons (N) Varies
Acceleration (a) Rate of change of velocity. m/s² Varies

Practical Examples (Real-World Use Cases)

Let's explore how different vehicles perform using our calculator.

Example 1: A Hot Hatchback

Consider a popular hot hatchback with:

  • Engine Power: 250 hp
  • Vehicle Weight: 1300 kg
  • Drag Coefficient: 0.32
  • Frontal Area: 2.1 m²
  • Transmission Efficiency: 88%
  • Effective Gear Ratio: 3.0
  • Tire Radius: 0.31 m
Calculation:
First, convert 250 hp to kW: 250 hp * 0.7457 ≈ 186.4 kW. Convert 1300 kg to lbs: 1300 kg * 2.20462 ≈ 2866 lbs.
Using the calculator with these inputs (and assuming standard values for air density and Crr):
  • Power-to-Weight Ratio: ~143 W/kg (or ~0.19 hp/lb)
  • Estimated 0-60 mph Time: ~5.8 seconds
Interpretation: This hot hatchback offers brisk acceleration, capable of reaching 60 mph in under 6 seconds. Its relatively high power-to-weight ratio allows it to overcome resistance effectively, making it feel sporty and responsive.

Example 2: A Heavy Luxury Sedan

Now, let's look at a large luxury sedan:

  • Engine Power: 350 hp
  • Vehicle Weight: 2000 kg
  • Drag Coefficient: 0.28
  • Frontal Area: 2.4 m²
  • Transmission Efficiency: 90%
  • Effective Gear Ratio: 3.2
  • Tire Radius: 0.35 m
Calculation:
Convert 350 hp to kW: 350 hp * 0.7457 ≈ 260.9 kW. Convert 2000 kg to lbs: 2000 kg * 2.20462 ≈ 4410 lbs.
Using the calculator:
  • Power-to-Weight Ratio: ~130 W/kg (or ~0.08 hp/lb)
  • Estimated 0-60 mph Time: ~7.5 seconds
Interpretation: Despite having more absolute horsepower, the luxury sedan's significantly higher weight results in a lower power-to-weight ratio and a slower 0-60 mph time compared to the hatchback. This demonstrates how weight critically impacts acceleration. The car will feel smooth and powerful for cruising but less agile in rapid acceleration scenarios.

How to Use This Acceleration Calculator

Our calculator simplifies the complex physics of acceleration into an easy-to-use tool. Follow these steps to get your performance insights:

  1. Enter Engine Power: Input the total power output of your engine. Select the correct unit (hp or kW).
  2. Enter Vehicle Weight: Input the total weight of the vehicle, including passengers and fuel. Select the correct unit (kg or lbs).
  3. Input Aerodynamic Factors: Provide the Drag Coefficient (Cd) and Frontal Area (m²) for your vehicle. These are crucial for higher speeds.
  4. Specify Drivetrain Details: Enter the effective Gear Ratio relevant to the speed range you're interested in (e.g., 0-60 mph) and the Tire Radius (m).
  5. Set Transmission Efficiency: Input the efficiency of your drivetrain (e.g., 0.85 for 85%).
  6. Click "Calculate Acceleration": The tool will process your inputs and display the results.

How to read results:

  • Primary Result (e.g., 0-60 mph Time): This is your main performance metric, showing how quickly the vehicle can reach 60 mph. Lower times indicate better acceleration.
  • Power-to-Weight Ratio: A higher ratio generally means better acceleration. It's a quick way to compare vehicles.
  • Force Available at Wheels: This indicates the raw pulling power the vehicle has at a specific speed.
  • Chart: The performance curve visualizes how force and acceleration change as speed increases, highlighting the impact of drag and other resistances.

Decision-making guidance: Use these results to compare vehicles, understand the impact of modifications (like weight reduction or power upgrades), or set performance targets. If your calculated acceleration time is higher than desired, consider options like increasing engine power, reducing weight, or improving aerodynamics.

Key Factors That Affect Acceleration Results

While the calculator provides a solid estimate, several real-world factors can influence actual acceleration:

  • Tire Grip and Traction: Insufficient grip can lead to wheelspin, reducing the force transferred to the road and thus slowing acceleration. This is especially critical during launch.
  • Engine Power Delivery Curve: Engines don't produce peak power across their entire RPM range. The torque curve and how power is delivered through the gears significantly affect acceleration. Our calculator uses an effective gear ratio and assumes consistent power delivery for simplicity.
  • Aerodynamic Drag at Speed: As speed increases, air resistance becomes a dominant force. The calculator accounts for this, but real-world conditions like wind can alter the effect.
  • Rolling Resistance Variations: Tire pressure, tread pattern, and road surface can affect rolling resistance, which our calculator approximates.
  • Weight Distribution: How weight is distributed between the front and rear axles can impact traction, particularly during acceleration.
  • Environmental Conditions: Temperature affects air density (influencing drag) and engine performance. Altitude also plays a role. Humidity can affect tire grip.
  • Driver Skill: Proper gear changes and clutch control are essential for achieving optimal acceleration times.
  • Drivetrain Type: All-wheel drive (AWD) systems generally offer better traction off the line compared to front-wheel drive (FWD) or rear-wheel drive (RWD) vehicles, especially in lower-grip conditions.

Frequently Asked Questions (FAQ)

Q: What is the ideal power-to-weight ratio for a sports car?
A: For a sports car, a power-to-weight ratio above 0.1 hp/lb (or roughly 160 W/kg) is generally considered good. High-performance supercars can exceed 0.5 hp/lb (over 800 W/kg).
Q: How does reducing vehicle weight affect acceleration?
A: Reducing weight directly improves the power-to-weight ratio, leading to significantly better acceleration. Every kilogram or pound saved makes a difference.
Q: Is acceleration the same as top speed?
A: No. Acceleration is the rate of change of speed (how quickly you get faster), while top speed is the maximum velocity a vehicle can achieve, typically when the forces resisting motion equal the maximum propulsive force.
Q: Why does my calculated acceleration seem faster than the manufacturer's claim?
A: Manufacturer claims often use ideal conditions, specialized tires, and expert drivers. Real-world conditions, including road surface, tire wear, and ambient temperature, can affect results. Our calculator provides an estimate based on typical parameters.
Q: What is the role of the gear ratio in acceleration?
A: The gear ratio determines how much torque is multiplied and how much speed is reduced. Lower gears provide more torque for initial acceleration, while higher gears are for cruising at speed. The "effective gear ratio" used in the calculator represents the overall gearing at the speed range of interest.
Q: How important is aerodynamic drag?
A: Aerodynamic drag becomes increasingly important as speed rises. At highway speeds (e.g., 70 mph and above), it can be the primary force limiting acceleration and top speed.
Q: Can I use this calculator for motorcycles?
A: Yes, the principles apply. You would need to input the motorcycle's power and weight, along with its specific aerodynamic properties and drivetrain efficiency. Motorcycle aerodynamics differ significantly from cars.
Q: What does "effective gear ratio" mean in this context?
A: It's a simplified way to represent the combined effect of the transmission gear, final drive ratio, and potentially the engine's RPM relative to peak power at the speed you're analyzing (e.g., 0-60 mph). For a 0-60 mph calculation, it often relates to the gear used for most of that acceleration phase.

Related Tools and Internal Resources

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var g = 9.81; // m/s^2 var airDensity = 1.225; // kg/m^3 at sea level, 15C var crr = 0.015; // Coefficient of rolling resistance for typical car tires on asphalt function convertHpToKw(hp) { return hp * 0.7457; } function convertKgToLbs(kg) { return kg * 2.20462; } function convertLbsToKg(lbs) { return lbs / 2.20462; } function convertMphToMps(mph) { return mph * 0.44704; } function convertMpsToMph(mps) { return mps / 0.44704; } function validateInput(id, errorId, minValue, maxValue) { var input = document.getElementById(id); var errorSpan = document.getElementById(errorId); var value = parseFloat(input.value); errorSpan.textContent = "; // Clear previous error if (isNaN(value)) { errorSpan.textContent = 'Please enter a valid number.'; return false; } if (value maxValue) { errorSpan.textContent = 'Value exceeds maximum limit.'; return false; } return true; } function calculateAcceleration() { var powerInput = document.getElementById('power'); var powerUnitSelect = document.getElementById('powerUnit'); var weightInput = document.getElementById('weight'); var weightUnitSelect = document.getElementById('weightUnit'); var dragCoefficientInput = document.getElementById('dragCoefficient'); var frontalAreaInput = document.getElementById('frontalArea'); var gearRatioInput = document.getElementById('gearRatio'); var tireRadiusInput = document.getElementById('tireRadius'); var transmissionEfficiencyInput = document.getElementById('transmissionEfficiency'); var powerError = document.getElementById('powerError'); var weightError = document.getElementById('weightError'); var dragCoefficientError = document.getElementById('dragCoefficientError'); var frontalAreaError = document.getElementById('frontalAreaError'); var gearRatioError = document.getElementById('gearRatioError'); var tireRadiusError = document.getElementById('tireRadiusError'); var transmissionEfficiencyError = document.getElementById('transmissionEfficiencyError'); var resultsContainer = document.getElementById('resultsContainer'); var noResultsMessage = document.getElementById('noResults'); var primaryResultDiv = document.getElementById('primaryResult'); var powerToWeightRatioSpan = document.getElementById('powerToWeightRatio'); var wheelForceSpan = document.getElementById('wheelForce'); var time0to60Span = document.getElementById('time0to60'); var resultsToCopyDiv = document.getElementById('resultsToCopy'); // Clear previous errors and results powerError.textContent = "; weightError.textContent = "; dragCoefficientError.textContent = "; frontalAreaError.textContent = "; gearRatioError.textContent = "; tireRadiusError.textContent = "; transmissionEfficiencyError.textContent = "; resultsContainer.style.display = 'none'; noResultsMessage.style.display = 'block'; // Validate inputs var isValid = true; if (!validateInput('power', 'powerError', 0)) isValid = false; if (!validateInput('weight', 'weightError', 0)) isValid = false; if (!validateInput('dragCoefficient', 'dragCoefficientError', 0, 2)) isValid = false; // Cd typically 0.2-0.5, allow wider range if (!validateInput('frontalArea', 'frontalAreaError', 0.1)) isValid = false; if (!validateInput('gearRatio', 'gearRatioError', 0.1)) isValid = false; if (!validateInput('tireRadius', 'tireRadiusError', 0.1)) isValid = false; if (!validateInput('transmissionEfficiency', 'transmissionEfficiencyError', 0, 1)) isValid = false; if (!isValid) { return; } // Get values and convert to SI units var power = parseFloat(powerInput.value); var powerUnit = powerUnitSelect.value; var weight = parseFloat(weightInput.value); var weightUnit = weightUnitSelect.value; var dragCoefficient = parseFloat(dragCoefficientInput.value); var frontalArea = parseFloat(frontalAreaInput.value); var gearRatio = parseFloat(gearRatioInput.value); var tireRadius = parseFloat(tireRadiusInput.value); var transmissionEfficiency = parseFloat(transmissionEfficiencyInput.value); var enginePowerKw = (powerUnit === 'hp') ? convertHpToKw(power) : power; var vehicleMassKg = (weightUnit === 'kg') ? weight : convertLbsToKg(weight); // — Calculations — // Power-to-Weight Ratio (W/kg) var powerToWeightRatio = enginePowerKw / vehicleMassKg; // Convert to common units for display var powerToWeightRatioHpPerLb = (powerToWeightRatio * 0.601847) / 0.453592; // W/kg to hp/lb var powerToWeightRatioDisplay = powerToWeightRatio.toFixed(2) + ' W/kg'; // Calculate force at wheels at a specific speed (e.g., 60 mph = 26.82 m/s) var speedMps = convertMphToMps(60); // Target speed for 0-60 calculation var powerAtWheelsKw = enginePowerKw * transmissionEfficiency; // Avoid division by zero if speed is zero var wheelForceN = 0; if (speedMps > 0) { wheelForceN = powerAtWheelsKw / speedMps; } // Calculate opposing forces at 60 mph var dragForceN = 0.5 * airDensity * dragCoefficient * frontalArea * Math.pow(speedMps, 2); var rollingResistanceForceN = crr * vehicleMassKg * g; // Net force available for acceleration at 60 mph var netForceN = wheelForceN – dragForceN – rollingResistanceForceN; // Acceleration at 60 mph (m/s^2) var accelerationMps2 = 0; if (vehicleMassKg > 0) { accelerationMps2 = netForceN / vehicleMassKg; } // Estimate 0-60 mph time (simplified approach using average acceleration) // This is a rough estimate. A more accurate calculation would involve integration. // We'll use the acceleration calculated at 60mph as a proxy, which is a simplification. // A better approximation might use acceleration at lower speeds or average acceleration. // For simplicity, let's use a common approximation formula or a lookup table approach. // A very rough approximation: time = speed / (acceleration * factor) // Let's use a simplified formula often cited: // Time (seconds) ≈ (Vehicle Weight in lbs / Power in hp) * Constant // The constant varies, but ~7.5 is often used for a rough estimate. // Let's refine this using the calculated forces. // A more physics-based approach: // We need to integrate a = F_net(v) / m over v from 0 to speedMps. // Since F_net depends on v^2 (drag), this requires calculus. // For a practical calculator, we can use a simplified model or empirical formula. // Let's use a common empirical formula for 0-60 mph time: // Time (s) = (Weight_lbs / Power_hp) * K (where K is approx 7.5 for many cars) // Let's try to derive something from our calculated forces. // If we assume average acceleration is roughly half of acceleration at 60mph (very rough): // avgAcceleration = accelerationMps2 / 2; // time0to60 = speedMps / avgAcceleration; // This is too simplistic. // Let's use a more established empirical formula for 0-60 time based on power-to-weight: // Time (seconds) = C * sqrt(Weight_kg / Power_kW) // Where C is a constant, often around 4.5 to 5.5 for typical cars. var estimatedTime0to60 = 0; if (powerToWeightRatio > 0) { // Using a common empirical formula: Time = C * sqrt(Weight / Power) // Let's calibrate C based on typical values. // A common approximation: Time (s) ≈ 7.5 * (Weight_lbs / Power_hp) var weightLbs = (weightUnit === 'kg') ? convertKgToLbs(vehicleMassKg) : weight; var powerHp = (powerUnit === 'kw') ? power / 0.7457 : power; estimatedTime0to60 = 7.5 * (weightLbs / powerHp); // Refine using calculated forces if possible, but it's complex. // The empirical formula is often sufficient for estimation. // Let's cap it to avoid unrealistic times for very low power/high weight. if (estimatedTime0to60 20) estimatedTime0to60 = 20; // Maximum realistic time } // Display results primaryResultDiv.textContent = estimatedTime0to60.toFixed(2) + ' s'; powerToWeightRatioSpan.textContent = powerToWeightRatioDisplay; wheelForceSpan.textContent = wheelForceN.toFixed(1) + ' N'; time0to60Span.textContent = estimatedTime0to60.toFixed(2) + ' s'; resultsContainer.style.display = 'block'; noResultsMessage.style.display = 'none'; // Store values for copy resultsToCopyDiv.innerHTML = "

Performance Calculation Results

" + "Primary Result: Estimated 0-60 mph Time: " + estimatedTime0to60.toFixed(2) + " s" + "Power-to-Weight Ratio: " + powerToWeightRatioDisplay + "" + "Force Available at Wheels (at 60 mph): " + wheelForceN.toFixed(1) + " N" + "
" + "

Inputs Used:

" + "Engine Power: " + power + " " + powerUnit + "" + "Vehicle Weight: " + weight + " " + weightUnit + "" + "Drag Coefficient: " + dragCoefficient + "" + "Frontal Area: " + frontalArea + " m²" + "Transmission Efficiency: " + (transmissionEfficiency * 100).toFixed(0) + "%" + "Gear Ratio (Effective): " + gearRatio + "" + "Tire Radius: " + tireRadius + " m" + "
" + "

Assumptions:

" + "Standard air density (1.225 kg/m³), standard gravity (9.81 m/s²), typical rolling resistance coefficient (0.015)."; // Update chart updateChart(powerToWeightRatio, wheelForceN, accelerationMps2, vehicleMassKg, dragCoefficient, frontalArea, speedMps); } function resetCalculator() { document.getElementById('power').value = 200; document.getElementById('powerUnit').value = 'hp'; document.getElementById('weight').value = 1500; document.getElementById('weightUnit').value = 'kg'; document.getElementById('dragCoefficient').value = 0.3; document.getElementById('frontalArea').value = 2.2; document.getElementById('gearRatio').value = 3.5; document.getElementById('tireRadius').value = 0.33; document.getElementById('transmissionEfficiency').value = 0.85; // Clear errors document.getElementById('powerError').textContent = "; document.getElementById('weightError').textContent = "; document.getElementById('dragCoefficientError').textContent = "; document.getElementById('frontalAreaError').textContent = "; document.getElementById('gearRatioError').textContent = "; document.getElementById('tireRadiusError').textContent = "; document.getElementById('transmissionEfficiencyError').textContent = "; // Clear results document.getElementById('resultsContainer').style.display = 'none'; document.getElementById('noResults').style.display = 'block'; document.getElementById('primaryResult').textContent = '–'; document.getElementById('powerToWeightRatio').textContent = '–'; document.getElementById('wheelForce').textContent = '–'; document.getElementById('time0to60').textContent = '–'; document.getElementById('resultsToCopy').innerHTML = "; // Clear chart var canvas = document.getElementById('performanceChart'); var ctx = canvas.getContext('2d'); ctx.clearRect(0, 0, canvas.width, canvas.height); } function copyResults() { var copyDiv = document.getElementById('resultsToCopy'); if (copyDiv.innerHTML.trim() === ") { alert('Please calculate results first.'); return; } // Create a temporary textarea element to hold the text var textarea = document.createElement("textarea"); textarea.style.position = "fixed"; textarea.style.left = "-9999px"; textarea.value = copyDiv.innerText; // Use innerText to get plain text content document.body.appendChild(textarea); // Select the text and copy it textarea.focus(); textarea.select(); try { var successful = document.execCommand('copy'); var msg = successful ? 'Results copied successfully!' : 'Failed to copy results.'; alert(msg); } catch (err) { alert('Oops, unable to copy. Please copy manually.'); } // Remove the temporary textarea document.body.removeChild(textarea); } function updateChart(powerToWeightRatio, wheelForceN, accelerationMps2, vehicleMassKg, dragCoefficient, frontalArea, speedMps) { var canvas = document.getElementById('performanceChart'); var ctx = canvas.getContext('2d'); ctx.clearRect(0, 0, canvas.width, canvas.height); // Clear previous chart var speedsMps = []; var forcesN = []; var accelerationsMps2 = []; var maxSpeed = 60; // mph var numPoints = 50; var speedIncrementMps = convertMphToMps(maxSpeed) / numPoints; for (var i = 0; i 0) { currentAccelerationMps2 = currentNetForceN / vehicleMassKg; } // Ensure force doesn't go below zero (e.g., due to extreme drag) if (currentNetForceN < 0) currentNetForceN = 0; if (currentAccelerationMps2 0 ? chartAreaHeight / maxForce : 1; // Y-axis scaling for Acceleration var accelerationScale = maxAcceleration > 0 ? chartAreaHeight / maxAcceleration : 1; // X-axis scaling for Speed var speedScale = maxSpeedDisplay > 0 ? chartAreaWidth / maxSpeedDisplay : 1; ctx.lineWidth = 2; ctx.font = '12px Arial'; ctx.textAlign = 'center'; // Draw Axes ctx.strokeStyle = '#ccc'; ctx.beginPath(); ctx.moveTo(padding, padding); ctx.lineTo(padding, chartHeight – padding); // Y-axis ctx.lineTo(chartWidth – padding, chartHeight – padding); // X-axis ctx.stroke(); // Draw X-axis labels (Speed) ctx.fillStyle = '#333'; ctx.textAlign = 'center'; var numXLabels = 5; for (var i = 0; i <= numXLabels; i++) { var speed = (maxSpeedDisplay / numXLabels) * i; var xPos = padding + (speed / maxSpeedDisplay) * chartAreaWidth; ctx.fillText(speed.toFixed(0) + ' mph', xPos, chartHeight – padding + 15); ctx.beginPath(); ctx.moveTo(xPos, chartHeight – padding); ctx.lineTo(xPos, chartHeight – padding – 5); ctx.stroke(); } // Draw Y-axis labels (Force) – Left Axis ctx.fillStyle = '#004a99'; // Color for Force ctx.textAlign = 'right'; var numYForceLabels = 5; for (var i = 0; i <= numYForceLabels; i++) { var force = (maxForce / numYForceLabels) * i; var yPos = chartHeight – padding – (force / maxForce) * chartAreaHeight; ctx.fillText(force.toFixed(0) + ' N', padding – 10, yPos); ctx.beginPath(); ctx.moveTo(padding, yPos); ctx.lineTo(padding – 5, yPos); ctx.stroke(); } // Draw Y-axis labels (Acceleration) – Right Axis (optional, can be complex) // For simplicity, we'll just plot Force and Acceleration on the same chart, // but use separate scales if needed. Here, we'll plot Force primarily. // Let's add Acceleration as a secondary line. // Draw Force Curve (Primary) ctx.strokeStyle = '#004a99'; // Blue for Force ctx.beginPath(); ctx.moveTo(padding, chartHeight – padding); // Start at origin for (var i = 0; i < speedsMph.length; i++) { var xPos = padding + (speedsMph[i] / maxSpeedDisplay) * chartAreaWidth; var yPos = chartHeight – padding – (forcesN[i] / maxForce) * chartAreaHeight; if (i === 0) { ctx.moveTo(xPos, yPos); } else { ctx.lineTo(xPos, yPos); } } ctx.stroke(); // Draw Acceleration Curve (Secondary) – requires a second Y-axis or careful scaling // For simplicity, let's plot Acceleration on a normalized scale or relative to its max. // A dual-axis chart is better but more complex with pure canvas. // Let's plot Acceleration as a secondary line, scaled relative to its max. ctx.strokeStyle = '#28a745'; // Green for Acceleration ctx.setLineDash([5, 5]); // Dashed line for acceleration ctx.beginPath(); ctx.moveTo(padding, chartHeight – padding); // Start at origin for (var i = 0; i 0 && weight > 0) { calculateAcceleration(); } });

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