Fixed Gear Calculator

Optimize your drivetrain: calculate gear ratio, gear inches, and skid patches instantly.

Common Fixed Gear Ratios & Skid Patches

Ratio (Chainring/Cog)	Ratio Value	Gear Inches (700x25c)	Skid Patches

What is a Fixed Gear Calculator?

A fixed gear calculator is a specialized tool designed for track cyclists, urban commuters, and fixed-gear enthusiasts to determine the mechanical output of their bicycle’s drivetrain. Unlike geared bicycles where you can shift through various combinations, a fixed-gear bike relies on a single chainring and a single rear cog. This means choosing the right teeth count is critical for performance, comfort, and longevity.

Cyclists use a fixed gear calculator to balance the “heaviness” of a gear (how hard it is to pedal) against the number of “skid patches” (how quickly the rear tire wears down). Whether you are sprinting on a velodrome or navigating city traffic, understanding your gear inches and development is the first step to a better ride.

Common misconceptions include the idea that a higher gear ratio always means more speed. In reality, if a gear is too heavy for your strength or the terrain, your cadence will drop, making you slower and potentially causing knee strain. A fixed gear calculator helps you find that “Goldilocks” zone.

Fixed Gear Calculator Formula and Mathematical Explanation

The physics behind a fixed gear drivetrain is relatively straightforward but involves several variables that interact to determine your final output. Here is the step-by-step derivation:

• Gear Ratio: This is the simplest calculation. It is the number of teeth on the chainring divided by the teeth on the cog. Formula: R = T_chainring / T_cog.
• Gear Inches: A legacy measurement representing the diameter of an equivalent direct-drive wheel. Formula: GI = (T_chainring / T_cog) * Wheel_Diameter_Inches.
• Meters of Development: The distance the bike travels with one full rotation of the pedals. Formula: D = (T_chainring / T_cog) * Circumference_Meters.
• Skid Patches: This depends on the simplified fraction of your gear ratio. If you simplify 48/16 to 3/1, you have only 1 skid patch. If it’s 47/17 (prime), you have 17.

Variable	Meaning	Unit	Typical Range
T_chainring	Front sprocket teeth	Teeth	42 – 52
T_cog	Rear sprocket teeth	Teeth	13 – 19
Cadence	Pedal rotations	RPM	70 – 110
Circumference	Outer tire distance	mm	2080 – 2150

Practical Examples (Real-World Use Cases)

Example 1: The Urban Commuter

An urban rider uses a 46-tooth chainring and a 16-tooth cog on 700x25c tires. Using the fixed gear calculator, the gear ratio is 2.875. The gear inches are 75.8″. While this is a comfortable ratio for flat ground, the simplified fraction (46/16 = 23/8) reveals only 8 skid patches. If the rider skids frequently, the tire will wear in 8 specific spots very quickly.

Example 2: The Track Sprinter

A track racer might use a much larger 50-tooth chainring and a 14-tooth cog. The fixed gear calculator shows a ratio of 3.57. With a cadence of 120 RPM, the rider would be traveling at roughly 54 km/h (33.5 mph). This setup is designed for maximum speed on a smooth velodrome rather than stop-and-go city riding.

How to Use This Fixed Gear Calculator

Follow these simple steps to get the most accurate data for your bike setup:

1. Enter Chainring Teeth: Count the teeth on your front chainring. Most standard road conversions use 42 to 48.
2. Enter Cog Teeth: Count the teeth on your rear cog. Small changes here (e.g., from 16 to 17) have a bigger impact than changes to the chainring.
3. Select Tire Size: Choose your tire from the dropdown. This is vital for the fixed gear calculator to calculate actual distance and speed.
4. Input Cadence: If you use a computer, enter your average RPM. Otherwise, 90 RPM is a standard benchmark for efficient cycling.
5. Review Results: The primary gear ratio and skid patches will update in real-time. Use the chart to see your speed potential.

Key Factors That Affect Fixed Gear Calculator Results

When using a fixed gear calculator, consider these six critical factors:

• Terrain: If you live in a hilly area, a lower ratio (e.g., 2.5) is necessary. For flat coastal cities, a 3.0+ ratio is manageable.
• Leg Strength: Starting from a dead stop on a fixed gear requires significant torque. Higher ratios place more stress on the knees.
• Skid Patches: As shown by the fixed gear calculator, choosing a prime number for the cog (like 17 or 19) significantly increases skid patches.
• Tire Pressure: While the calculator uses a standard circumference, actual roll distance varies slightly with PSI and rider weight.
• Crank Length: Longer cranks (175mm) provide more leverage, making a “heavy” gear feel easier to turn than shorter cranks (165mm).
• Mechanical Efficiency: A dirty chain or worn-out bearings can add resistance that no fixed gear calculator can account for.

Frequently Asked Questions (FAQ)

Why are skid patches important?

Because on a fixed gear bike, the relationship between the pedals and the wheel is constant. If you stop the pedals in the same position, the tire hits the ground in the same spot. More patches mean longer tire life.

What is a good gear ratio for a beginner?

Most beginners find a gear ratio between 2.6 and 2.8 (e.g., 44/16 or 46/17) to be a perfect balance for city riding and moderate hills.

How does tire size affect the calculation?

Larger tires (700x32c) have a larger circumference than thin tires (700x23c). This means one pedal stroke moves you further, effectively increasing your gear inches.

What are “Gear Inches”?

It is a measurement that dates back to the “Penny Farthing” era. It tells you the diameter of the wheel if the bike were a direct-drive unicycle.

Does chain tension affect the ratio?

No, the gear ratio is purely a function of the number of teeth. However, proper tension is vital for safety and drivetrain efficiency.

Can I use this for a single-speed bike?

Yes! The gear ratio, development, and speed calculations are identical. However, “skid patches” don’t apply since you can coast on a single speed.

What is “Meters of Development”?

It is the metric equivalent of gear inches, representing the actual distance in meters the bike travels for every full 360-degree crank rotation.

Why do track riders use such high ratios?

Track racing involves high speeds on a frictionless surface. Riders use high ratios (3.5+) to maintain momentum and reach speeds over 60 km/h.

Optimize your drivetrain: calculate gear ratio, gear inches, and skid patches instantly.

Common Fixed Gear Ratios & Skid Patches

Ratio (Chainring/Cog)	Ratio Value	Gear Inches (700x25c)	Skid Patches

What is a Fixed Gear Calculator?

A fixed gear calculator is a specialized tool designed for track cyclists, urban commuters, and fixed-gear enthusiasts to determine the mechanical output of their bicycle’s drivetrain. Unlike geared bicycles where you can shift through various combinations, a fixed-gear bike relies on a single chainring and a single rear cog. This means choosing the right teeth count is critical for performance, comfort, and longevity.

Cyclists use a fixed gear calculator to balance the “heaviness” of a gear (how hard it is to pedal) against the number of “skid patches” (how quickly the rear tire wears down). Whether you are sprinting on a velodrome or navigating city traffic, understanding your gear inches and development is the first step to a better ride.

Common misconceptions include the idea that a higher gear ratio always means more speed. In reality, if a gear is too heavy for your strength or the terrain, your cadence will drop, making you slower and potentially causing knee strain. A fixed gear calculator helps you find that “Goldilocks” zone.

Fixed Gear Calculator Formula and Mathematical Explanation

The physics behind a fixed gear drivetrain is relatively straightforward but involves several variables that interact to determine your final output. Here is the step-by-step derivation:

• Gear Ratio: This is the simplest calculation. It is the number of teeth on the chainring divided by the teeth on the cog. Formula: R = T_chainring / T_cog.
• Gear Inches: A legacy measurement representing the diameter of an equivalent direct-drive wheel. Formula: GI = (T_chainring / T_cog) * Wheel_Diameter_Inches.
• Meters of Development: The distance the bike travels with one full rotation of the pedals. Formula: D = (T_chainring / T_cog) * Circumference_Meters.
• Skid Patches: This depends on the simplified fraction of your gear ratio. If you simplify 48/16 to 3/1, you have only 1 skid patch. If it’s 47/17 (prime), you have 17.

Variable	Meaning	Unit	Typical Range
T_chainring	Front sprocket teeth	Teeth	42 – 52
T_cog	Rear sprocket teeth	Teeth	13 – 19
Cadence	Pedal rotations	RPM	70 – 110
Circumference	Outer tire distance	mm	2080 – 2150

Practical Examples (Real-World Use Cases)

Example 1: The Urban Commuter

An urban rider uses a 46-tooth chainring and a 16-tooth cog on 700x25c tires. Using the fixed gear calculator, the gear ratio is 2.875. The gear inches are 75.8″. While this is a comfortable ratio for flat ground, the simplified fraction (46/16 = 23/8) reveals only 8 skid patches. If the rider skids frequently, the tire will wear in 8 specific spots very quickly.

Example 2: The Track Sprinter

A track racer might use a much larger 50-tooth chainring and a 14-tooth cog. The fixed gear calculator shows a ratio of 3.57. With a cadence of 120 RPM, the rider would be traveling at roughly 54 km/h (33.5 mph). This setup is designed for maximum speed on a smooth velodrome rather than stop-and-go city riding.

How to Use This Fixed Gear Calculator

Follow these simple steps to get the most accurate data for your bike setup:

1. Enter Chainring Teeth: Count the teeth on your front chainring. Most standard road conversions use 42 to 48.
2. Enter Cog Teeth: Count the teeth on your rear cog. Small changes here (e.g., from 16 to 17) have a bigger impact than changes to the chainring.
3. Select Tire Size: Choose your tire from the dropdown. This is vital for the fixed gear calculator to calculate actual distance and speed.
4. Input Cadence: If you use a computer, enter your average RPM. Otherwise, 90 RPM is a standard benchmark for efficient cycling.
5. Review Results: The primary gear ratio and skid patches will update in real-time. Use the chart to see your speed potential.

Key Factors That Affect Fixed Gear Calculator Results

When using a fixed gear calculator, consider these six critical factors:

• Terrain: If you live in a hilly area, a lower ratio (e.g., 2.5) is necessary. For flat coastal cities, a 3.0+ ratio is manageable.
• Leg Strength: Starting from a dead stop on a fixed gear requires significant torque. Higher ratios place more stress on the knees.
• Skid Patches: As shown by the fixed gear calculator, choosing a prime number for the cog (like 17 or 19) significantly increases skid patches.
• Tire Pressure: While the calculator uses a standard circumference, actual roll distance varies slightly with PSI and rider weight.
• Crank Length: Longer cranks (175mm) provide more leverage, making a “heavy” gear feel easier to turn than shorter cranks (165mm).
• Mechanical Efficiency: A dirty chain or worn-out bearings can add resistance that no fixed gear calculator can account for.

Frequently Asked Questions (FAQ)

Why are skid patches important?

Because on a fixed gear bike, the relationship between the pedals and the wheel is constant. If you stop the pedals in the same position, the tire hits the ground in the same spot. More patches mean longer tire life.

What is a good gear ratio for a beginner?

Most beginners find a gear ratio between 2.6 and 2.8 (e.g., 44/16 or 46/17) to be a perfect balance for city riding and moderate hills.

How does tire size affect the calculation?

Larger tires (700x32c) have a larger circumference than thin tires (700x23c). This means one pedal stroke moves you further, effectively increasing your gear inches.

What are “Gear Inches”?

It is a measurement that dates back to the “Penny Farthing” era. It tells you the diameter of the wheel if the bike were a direct-drive unicycle.

Does chain tension affect the ratio?

No, the gear ratio is purely a function of the number of teeth. However, proper tension is vital for safety and drivetrain efficiency.

Can I use this for a single-speed bike?

Yes! The gear ratio, development, and speed calculations are identical. However, “skid patches” don’t apply since you can coast on a single speed.

What is “Meters of Development”?

It is the metric equivalent of gear inches, representing the actual distance in meters the bike travels for every full 360-degree crank rotation.

Why do track riders use such high ratios?

Track racing involves high speeds on a frictionless surface. Riders use high ratios (3.5+) to maintain momentum and reach speeds over 60 km/h.