Explore how your weight differs across the solar system and beyond. Use this calculator for your physics and astronomy studies.
Weight on Planets Calculator
Enter your weight as measured on Earth.
Mercury
Venus
Earth
Moon
Mars
Jupiter
Saturn
Uranus
Neptune
Pluto
Choose the celestial body to calculate your weight on.
Results
— kg
Surface Gravity (m/s²)—
Gravity Factor (vs Earth)—
Planet's Mass (vs Earth)—
Planet's Radius (vs Earth)—
Formula Used: Your weight on a celestial body is calculated by multiplying your Earth weight (mass) by the ratio of that body's surface gravity to Earth's surface gravity. Mathematically, this is: Weight_on_Planet = Earth_Weight * (Surface_Gravity_Planet / Surface_Gravity_Earth). Your mass (weight on Earth) remains constant, but your perceived weight changes due to different gravitational forces.
Weight Comparison Chart
Chart shows your calculated weight on various celestial bodies relative to your Earth weight.
Gravity Comparison Table
Surface Gravity Comparison
Celestial Body
Surface Gravity (m/s²)
Your Weight (kg)
Calculating Weight on Planets Worksheet: A Comprehensive Guide
What is Calculating Weight on Planets Worksheet?
Calculating Weight on Planets Worksheet refers to the process of determining how much an object or person would weigh on different celestial bodies like planets, moons, or even asteroids. Unlike mass, which is an intrinsic property of matter and remains constant regardless of location, weight is the force of gravity acting upon that mass. This concept is fundamental in physics and astronomy, helping us understand the gravitational interactions within our solar system and the universe. A worksheet designed for this purpose provides structured exercises to practice these calculations.
Who should use it? This topic and the associated worksheets are crucial for students in middle school through university studying physics, astronomy, or general science. Educators use these worksheets to reinforce concepts of gravity, mass, and force. Anyone curious about how their weight would change if they visited another planet or moon will also find this topic engaging.
Common misconceptions often revolve around confusing mass and weight. Many people believe their "weight" is what they are, but in scientific terms, weight is a force. Your mass is constant. For example, a 70 kg person has a mass of 70 kg on Earth, the Moon, and Jupiter. However, their weight (the force pulling them down) will vary significantly due to the different gravitational pull of each body.
Weight on Planets Worksheet Formula and Mathematical Explanation
The core principle behind calculating weight on planets involves understanding Newton's Law of Universal Gravitation and the definition of weight as a force. Weight (W) is typically expressed as mass (m) multiplied by the acceleration due to gravity (g): W = m * g. On Earth, this is W_earth = m * g_earth. Since an object's mass (m) remains constant, its weight on another celestial body (W_planet) is simply its mass multiplied by that body's surface gravitational acceleration (g_planet): W_planet = m * g_planet.
To make calculations easier, especially for worksheets, we often use the Earth weight as a reference. Since m = W_earth / g_earth, we can substitute this into the equation for the planet's weight: W_planet = (W_earth / g_earth) * g_planet. This simplifies to: W_planet = W_earth * (g_planet / g_earth).
Variables Explained:
Let's break down the key components used in calculating weight on planets:
Variable
Meaning
Unit
Typical Range (Planets/Moons)
Wearth
Your weight measured on the surface of Earth. This represents your mass multiplied by Earth's gravity.
Kilograms (kg) or Newtons (N)
Depends on individual mass. Commonly used as a baseline.
gplanet
The acceleration due to gravity on the surface of the specific planet or celestial body.
meters per second squared (m/s²)
~0.17 (Moon) to ~24.8 (Jupiter) for major bodies.
gearth
The standard acceleration due to gravity on the surface of Earth.
meters per second squared (m/s²)
Approximately 9.81 m/s²
Wplanet
Your calculated weight on the surface of the specific planet or celestial body.
Kilograms (kg) or Newtons (N)
Varies significantly based on gplanet.
Mass (m)
An intrinsic property of matter, representing the amount of "stuff" in an object. It is constant everywhere.
Kilograms (kg)
Constant for a given object.
The "Gravity Factor" shown in the calculator is simply the ratio (gplanet / gearth), indicating how much stronger or weaker gravity is compared to Earth. A factor of 0.5 means gravity is half as strong as Earth's; a factor of 2 means it's twice as strong.
Practical Examples (Real-World Use Cases)
Understanding how your weight changes is fascinating and highlights the differences in celestial body characteristics. Here are a couple of practical examples:
Example 1: A Trip to the Moon
Imagine an astronaut weighing 80 kg on Earth. They are preparing for a mission to the Moon. The Moon's surface gravity is approximately 1.62 m/s², while Earth's is 9.81 m/s².
Inputs:
Your Weight on Earth: 80 kg
Celestial Body: Moon
Calculation:
Surface Gravity (Moon): 1.62 m/s²
Earth Gravity Factor: 1.62 / 9.81 ≈ 0.165
Weight on Moon = 80 kg * 0.165 ≈ 13.2 kg
Result Interpretation: The astronaut would feel like they only weigh about 13.2 kg on the Moon. This significantly reduced weight is why astronauts can leap so high and move with such apparent ease on the lunar surface. Despite feeling lighter, their mass (and thus their inertia) remains 80 kg.
Example 2: A Jovian Adventure (Hypothetical)
Consider someone weighing 65 kg on Earth. What would their weight be on Jupiter, the largest planet in our solar system? Jupiter's surface gravity is about 24.8 m/s².
Inputs:
Your Weight on Earth: 65 kg
Celestial Body: Jupiter
Calculation:
Surface Gravity (Jupiter): 24.8 m/s²
Earth Gravity Factor: 24.8 / 9.81 ≈ 2.53
Weight on Jupiter = 65 kg * 2.53 ≈ 164.5 kg
Result Interpretation: On Jupiter, this person would feel incredibly heavy, weighing approximately 164.5 kg. This immense gravitational pull is due to Jupiter's massive size and density. It highlights why only specialized probes can withstand the conditions on gas giants, and humans certainly couldn't survive standing on their "surfaces" (which are more like dense atmospheric layers).
How to Use This Calculating Weight on Planets Worksheet Calculator
Our interactive calculator simplifies the process of understanding weight variations across celestial bodies. Follow these steps:
Enter Your Earth Weight: In the "Your Weight on Earth (kg)" field, input your current weight in kilograms. This is the baseline for all calculations.
Select a Celestial Body: Use the dropdown menu to choose the planet, moon, or dwarf planet you wish to calculate your weight on. The calculator has preset values for common bodies.
Click "Calculate Weight": Press the button, and the results will update instantly.
How to Read Results:
Main Result (Highlighted): This shows your calculated weight in kilograms on the selected celestial body.
Intermediate Values:
Surface Gravity: Displays the gravitational acceleration (in m/s²) of the selected body.
Gravity Factor: Shows how the selected body's gravity compares to Earth's gravity (a value > 1 means stronger gravity, < 1 means weaker).
Planet's Mass & Radius: These provide context about the physical characteristics of the celestial body, which directly influence its gravity.
Table & Chart: These visual aids compare your weight across multiple celestial bodies, offering a broader perspective.
Decision-Making Guidance: While you can't physically visit most of these places, this calculator helps visualize the physical challenges. For instance, understanding the significantly lower gravity on the Moon informs mission planning for astronauts, affecting everything from mobility to equipment design. Conversely, the high gravity of Jupiter shows why it's impossible for humans to stand on its surface.
Key Factors That Affect Calculating Weight on Planets Results
Several physical factors determine the surface gravity of a celestial body, and thus your calculated weight upon it:
Mass: This is the most significant factor. More massive celestial bodies exert a stronger gravitational pull. Jupiter, being the most massive planet in our solar system, has a very high surface gravity.
Radius: Gravity's strength also depends on how close you are to the center of mass. A larger radius means you are farther from the center, weakening the gravitational pull at the surface. This is why Earth and Venus, with similar masses, have different surface gravities – Venus is slightly smaller.
Density: While mass and radius are key, density (mass per unit volume) plays a role. A smaller, denser body can have stronger surface gravity than a larger, less dense one of similar mass.
Composition: The internal structure and composition (rocky vs. gas giant) influence density and overall mass distribution, affecting surface gravity.
Rotation Speed: For rapidly rotating bodies like planets, centrifugal force can slightly reduce the *effective* surface gravity, especially at the equator. However, this effect is usually minor compared to the influence of mass and radius.
Atmospheric Pressure: While not directly part of the weight calculation (which uses gravitational force), extremely dense atmospheres on planets like Venus can create immense pressure that would crush an unprotected object, effectively contributing to the challenge of "standing" on the surface, even if the raw gravitational pull is less than on Jupiter.
Frequently Asked Questions (FAQ)
Q1: Is my mass different on other planets?
No, your mass (the amount of matter in your body) is constant everywhere. Your weight, which is the force of gravity acting on your mass, changes.
Q2: Why does the calculator use kilograms (kg) for weight?
In everyday language, "weight" is often expressed in kilograms. Scientifically, kilograms measure mass. However, for simplicity in this calculator and common usage, we treat the input "Weight on Earth (kg)" as a proxy for your mass and then calculate the resulting force (weight) on other planets, still expressing it in "kg-equivalents" for ease of comparison.
Q3: Can I stand on Jupiter or Saturn?
No. Jupiter and Saturn are gas giants with no solid surface. The immense pressure and gravity would crush any known material, and you would simply sink deeper into their dense atmospheres.
Q4: How accurate are the gravity values used?
The values used are standard approximations for surface gravity. Actual gravity can vary slightly depending on location (e.g., altitude, latitude) on a planet.
Q5: What about weight on stars?
Stars are incredibly massive and have extremely high surface gravities. Calculating weight on a star is theoretically possible but practically impossible for humans due to the intense heat and radiation.
Q6: Does the calculator account for atmospheric pressure?
No, the calculator focuses solely on gravitational force. Atmospheric pressure is a separate physical factor that would significantly impact survival and experience on planets like Venus.
Q7: How does the Moon's gravity differ from Earth's?
The Moon has significantly less mass than Earth, resulting in much weaker gravity – about 1/6th that of Earth. This is why objects appear lighter and astronauts can jump higher.
Q8: What is the relationship between a planet's size and its gravity?
Generally, larger planets (by mass) have stronger gravity. However, radius also matters; if two planets have similar masses, the smaller one (with higher density) will have stronger surface gravity.
Related Tools and Internal Resources
Gravity CalculatorInstantly calculate your weight on any planet using our interactive tool.