AP Physics 1 Formulas

AP Physics 1 Formulas

memorize.aimemorize.ai (lvl 286)
Section 1

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unit for energy

Front

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Last updated

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Date created

Mar 14, 2020

Cards (82)

Section 1

(50 cards)

unit for energy

Front

J = Nm = kgm^2/s^2

Back

unit for angular momentum

Front

kg*m^2/s

Back

unit for force

Front

N = kg*m/s^2

Back

universal gravitation constant

Front

G = 6.67x10^-11 m^3/kg*s^2

Back

unit for displacement, distance, length

Front

meters

Back

unit for angular velocity

Front

radians/second

Back

centripetal acc

Front

v^2/r

Back

g=

Front

F(of gravity)/m

Back

friction

Front

Ffinal =< coeff of fric (Fnormal)

Back

acceleration due to gravity

Front

a = 9.8 m/s^2

Back

unit for power

Front

w = j/s (watts = joule/second)

Back

first kinematic equation

Front

v=vo+at

Back

neutron mass

Front

1.67x10^-27 kg

Back

unit for momentum

Front

kg*m/s

Back

unit for current

Front

A = C/s (Ampere = Coulomb/second)

Back

acceleration formula

Front

Δv/Δt = Fnet/m

Back

unit for impulse

Front

N*s

Back

centi (c)

Front

10^-2

Back

unit for density

Front

kg/m^3

Back

micro (u)

Front

10^-6

Back

proton mass

Front

1.67x10^-27 kg

Back

second kinematic equation

Front

Δx=vo=1/2at^2

Back

unit for velocity, speed

Front

m/s

Back

unit for torque

Front

N*m

Back

kilo (k)

Front

10^3

Back

unit for angular acceleration

Front

rads/s^2

Back

electron mass

Front

9.11x10^-31 kg

Back

electron charge magnitude

Front

e = 1.60x10^-19

Back

speed of light, c

Front

3x10^8 m/s

Back

unit for electric charge

Front

C

Back

unit for resistance

Front

Ω = V/A (ohms = voltage/ampere)

Back

period of spring

Front

2pi(k/m)^.5

Back

unit for frequency

Front

Hz = 1/s

Back

Coulomb's constant

Front

f = 1/4piEo = 9.0x10^9 Nm^2/kgs^2

Back

period formula

Front

1/f = 2pi/omega

Back

milli (m)

Front

10^-3

Back

Δp

Front

FΔt

Back

third kinematic equation

Front

v^2=vo^2+2aΔx

Back

Δpot grav

Front

mgΔy

Back

mega (M)

Front

10^6

Back

unit for acceleration

Front

m/s^2

Back

density formula

Front

mass/volume

Back

unit for angular displacement/angular distance

Front

radians

Back

force equation

Front

f = ma

Back

unit for voltage

Front

V = J/C (Voltage = Joules/Coulomb)

Back

unit for time

Front

seconds

Back

period of pendulum

Front

2pi(l/g)^.5

Back

pot. energy of gravity

Front

-GMm/r

Back

unit for mass

Front

kg

Back

unit for period

Front

seconds

Back

Section 2

(32 cards)

Rotational Kinetic Energy

Front

𝟏/𝟐(ğ‘°ğŽ^𝟐)

Back

Angular Acceleration

Front

𝜶 = 𝒂/r

Back

angular kinematic equations

Front

Back

|Fe|

Front

k|q1q2/2^2|

Back

ΔL

Front

torqueΔt

Back

Angular Position

Front

𝜽 = 𝒔/r

Back

Kepler's 3rd Law

Front

= (𝟒𝝅^𝟐/𝑮𝑴)*𝑹^𝟑

Back

Electrical Power VariationsFund.

Front

𝑷 = 𝑰^𝟐𝑹 = v^2/R

Back

Range Equation

Front

𝑹 =ğ’—ğŸŽ^𝟐/𝒈(𝒔𝒊𝒏(𝟐𝜽))

Back

momentum (p)

Front

mass/volume

Back

Angular Momentum

Front

𝑳 = ğ’Žğ’—ğ’“ = 𝒑𝒓

Back

Fund. Frequency Closed End Tube:

Front

𝒇𝟏 =𝒗/𝟒𝑳

Back

resistance (R)

Front

resistivity (length) / time

Back

kinetic energy

Front

1/2(mv^2)

Back

Kirchoff's Loop Rule

Front

ğ‘½ğŸŽ = ±âˆ†ğ‘½ğŸ ± ∆𝑽𝟐 + ⋯

Back

Kirchoff's Junction Rule

Front

ğ‘°ğŸŽ = 𝑰𝟏 + 𝑰𝟐 +...

Back

Fund. Frequency Open Tube

Front

𝒇𝟏 =𝒗/𝟐L

Back

Rs

Front

summation of Ri

Back

power (P)

Front

IΔV

Back

angular momentum (L)

Front

I (omega)

Back

Frequency Standing String:

Front

𝒇𝟏 =𝒗/𝟐L

Back

momentum

Front

mass(volume)

Back

wavelength

Front

speed/frequency

Back

kinetic energy (angular)

Front

1/2I (omega)^2

Back

Power (P)

Front

ΔE/t

Back

Angular Velocity

Front

𝝎 = 𝒗/r

Back

Moment of Inertia (point particle)

Front

𝑰 = ğ’Žğ’“^2

Back

1/Rp

Front

summation of 1/Ri

Back

I (current)

Front

Δq/Δt = ΔV/R

Back

ΔE (change in energy)

Front

W = F(parallel)d = Fd cos Θ

Back

|Fspring|

Front

k|x|

Back

torque

Front

rF(perpendicular) = rFsinΘ

Back