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Force Calculator

Calculate force, mass, or acceleration using Newton's second law of motion (F = ma).

Newton's Second Law: F = ma

10 kg
0.1 kg10,000 kg
kg
9.81 m/s²
0 m/s²100 m/s²
m/s²

Quick Presets:

Force (F = ma)

98.1000 N

💪Kilonewtons
0.0981 kN
🇺🇸Pound-force
22.0538 lbf
🔬Dynes
9810000.00 dyn
🌍Weight on Earth
98.10 N

Calculation:

F = m × a = 10 kg × 9.81 m/s² = 98.1000 N

Weight Comparison:

Weight on Earth: 98.10 N (22.05 lbs)

Weight on Moon: 16.20 N

Weight on Mars: 37.10 N

Weight on Jupiter: 247.90 N

Newton's Second Law of Motion

Newton's second law states that the force acting on an object is equal to the mass of that object multiplied by its acceleration. This fundamental law of physics can be written as F = ma, where F is force (in Newtons), m is mass (in kilograms), and a is acceleration (in meters per second squared).

Force Units

Newton (N)

SI unit of force. 1 N = 1 kg·m/s²

Pound-force (lbf)

Imperial unit. 1 lbf ≈ 4.448 N

Dyne (dyn)

CGS unit. 1 dyn = 10⁻⁵ N

Kilonewton (kN)

1 kN = 1000 N

What is Force?

Force is an interaction that causes an object to change its velocity (accelerate), change direction, or deform. Force is a vector quantity measured in Newtons (N).

PropertyDescriptionUnit
MagnitudeStrength of the forceNewtons (N)
DirectionWhere the force pointsDegrees or radians
Point of applicationWhere force acts on objectPosition (m)
Line of actionExtended direction through point

1 Newton is the force required to accelerate a 1 kg mass at 1 m/s².

Newton's Second Law

F = ma

Where:

  • F= Force (Newtons, N)
  • m= Mass (kilograms, kg)
  • a= Acceleration (m/s²)

Types of Forces

Forces are classified into contact and non-contact (field) forces:

Force TypeCategoryExampleFormula
Gravitational (Weight)Non-contactObjects fallingW = mg
Normal forceContactBook on tableN = mg (horizontal)
FrictionContactSliding objectsf = μN
TensionContactRope pullingT (varies)
Spring forceContactCompressed springF = -kx
ElectromagneticNon-contactMagnets, chargesF = kq₁q₂/r²
Applied forceContactPushing a boxF_app (given)
Air resistanceContactSkydivingF_drag = ½ρv²CdA

Newton's Three Laws of Motion

Newton's laws form the foundation of classical mechanics:

LawStatementMathematical FormExample
First Law (Inertia)Objects stay at rest or in motion unless acted upon by a forceIf ΣF = 0, then v = constantSeat belts in cars
Second LawForce equals mass times accelerationΣF = maPushing a cart
Third LawEvery action has an equal and opposite reactionF_AB = -F_BARocket propulsion

Net Force

ΣF = F₁ + F₂ + ... = ma

Where:

  • ΣF= Net (total) force
  • ma= Mass times acceleration

Weight and Gravitational Force

Weight is the gravitational force acting on an object's mass:

Locationg (m/s²)Weight of 70 kg person
Earth (surface)9.81687 N (154 lbs)
Moon1.62113 N (25 lbs)
Mars3.71260 N (58 lbs)
Jupiter24.791,735 N (390 lbs)
Space station (orbit)~0~0 N (weightless)

Note: Mass remains constant; weight changes with gravitational field strength.

Weight Formula

W = mg W = GMm/r² (from distance r)

Where:

  • W= Weight (N)
  • m= Mass (kg)
  • g= Gravitational acceleration (m/s²)
  • G= Universal gravitational constant

Friction Forces

Friction opposes relative motion between surfaces:

TypeFormulaWhen It Applies
Static frictionf_s ≤ μ_s NObject at rest
Kinetic frictionf_k = μ_k NObject sliding
Rolling frictionf_r = μ_r NWheels rolling
Surface Pairμ_s (static)μ_k (kinetic)
Rubber on concrete (dry)1.00.8
Rubber on concrete (wet)0.70.5
Steel on steel0.740.57
Wood on wood0.50.3
Ice on ice0.10.03

Friction Equations

f_s ≤ μ_s N (static) f_k = μ_k N (kinetic)

Where:

  • f= Friction force (N)
  • μ= Coefficient of friction
  • N= Normal force (N)

Free-Body Diagrams

A free-body diagram (FBD) shows all forces acting on an object:

StepActionNote
1Isolate the objectDraw as a point or simple shape
2Identify all forcesContact + non-contact forces
3Draw force vectorsFrom center of object, to scale
4Choose coordinate axesUsually one axis along motion
5Resolve into componentsUse sin/cos for angled forces
6Apply Newton's 2nd lawΣFₓ = maₓ, ΣFᵧ = maᵧ

Common forces to include: Weight (down), Normal (perpendicular to surface), Friction (opposing motion), Tension (along rope), Applied force.

Real-World Force Applications

Force calculations in everyday life:

ApplicationTypical ForceNotes
Handshake5-50 NVaries with grip
Pushing grocery cart20-50 NTo overcome friction
Bicycle braking200-400 NEmergency stop
Car braking (4 wheels)5,000-15,000 NDepends on speed, mass
Airplane thrust (jet)100,000-500,000 NPer engine
Rocket launch (Saturn V)35,000,000 NTotal thrust

Worked Examples

Calculate Force from Mass and Acceleration

Problem:

A 1,500 kg car accelerates at 3 m/s². What force does the engine provide?

Solution Steps:

  1. 1Identify given values: m = 1,500 kg, a = 3 m/s²
  2. 2Apply Newton's second law: F = ma
  3. 3Substitute: F = 1,500 × 3
  4. 4Calculate: F = 4,500 N

Result:

Engine force = 4,500 N (about 1,012 lbs)

Calculate Weight on Different Planets

Problem:

An astronaut has mass 75 kg. Calculate their weight on Earth and Mars.

Solution Steps:

  1. 1Earth: W = mg = 75 × 9.81 = 735.75 N
  2. 2Mars: W = mg = 75 × 3.71 = 278.25 N
  3. 3Ratio: Mars weight is 278/736 = 38% of Earth weight

Result:

Earth: 736 N, Mars: 278 N

Friction Force Problem

Problem:

A 20 kg box on a floor (μ_k = 0.3) is pushed horizontally. What force is needed for constant velocity?

Solution Steps:

  1. 1At constant velocity, applied force = friction
  2. 2Normal force: N = mg = 20 × 9.81 = 196 N
  3. 3Friction: f = μN = 0.3 × 196 = 58.9 N
  4. 4Required push force = 58.9 N

Result:

Applied force needed = 58.9 N

Tips & Best Practices

  • Always draw a free-body diagram before solving force problems
  • Weight always points straight down toward Earth's center
  • Normal force is perpendicular to the contact surface, not always vertical
  • Friction opposes relative motion (or potential motion), not the applied force
  • When ΣF = 0, velocity is constant (including zero)—not necessarily at rest
  • Convert weight in pounds to Newtons: multiply by 4.45
  • Action-reaction pairs act on different objects—they never cancel

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Frequently Asked Questions

Mass is the amount of matter in an object, measured in kilograms, and is constant everywhere. Weight is the gravitational force on that mass, measured in Newtons, and varies by location. A 70 kg person has the same mass on Earth and Moon, but weighs 687 N on Earth and only 113 N on the Moon. Weight = mass × gravitational acceleration (W = mg).
When surfaces are stationary relative to each other, molecules have time to settle into microscopic interlocking patterns and form temporary bonds. Once motion begins, there's less time for these bonds to form, reducing friction. This is why it's harder to start an object moving than to keep it moving. Always μ_static > μ_kinetic for the same surfaces.
Newton's third law states that forces always come in pairs: if object A exerts a force on object B, then B exerts an equal and opposite force on A. These forces act on different objects, so they don't cancel. Example: When you push a wall, it pushes back on you. You standing still means the floor pushes up on you (normal force) equal to your weight pushing down on the floor.
One Newton is roughly the force of gravity on a small apple (about 100 grams). It's the force needed to accelerate 1 kg at 1 m/s². A pound-force is about 4.45 N. Your body weight in Newtons is your mass in kg times 9.81. A 70 kg person weighs about 686 N or 154 lbs.
While heavier objects have more gravitational force (weight), they also have more inertia (resistance to acceleration). The mass cancels out: F = ma, and F = mg, so a = g regardless of mass. All objects fall at 9.81 m/s² in vacuum. Air resistance is what makes a feather fall slower than a bowling ball in atmosphere.
Break each force into x and y components using trigonometry: Fₓ = F·cos(θ), Fᵧ = F·sin(θ). Add all x-components together and all y-components together. Then use Pythagorean theorem: F_net = √(ΣFₓ² + ΣFᵧ²). Direction: θ = tan⁻¹(ΣFᵧ/ΣFₓ). Apply Newton's 2nd law to each component separately.

Sources & References

Last updated: 2026-01-22

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