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Velocity Acceleration Distance traveled under uniform acceleration Final velocity under uniform acceleration Newton's Law for force Net force under friction Centripetal force Force of gravity between objects Kepler's third law Momentum Work Kinetic energy Coulomb's law Field intensity Potential difference Energy of a circuit Ohm's law Power in a circuit Heat energy across a resistor Voltage in a series circuit Resistance in a series circuit Current in a parallel circuit Resistance in a parallel circuit Force on a wire in a magnetic field Force on a particle in a field EMF Voltage output of a transformer Velocity of a wave Index of refraction Snell's law Focal Length of a concave mirror Magnification Curved mirror equation Fresnel's diffraction discovery Young's wavelength equation Scattering of light |
v =  d / ta = v / ta = vf - vi / t d = vit + ½at^2 v_final^2 = v_initial^2 + 2ad v_final = v_initial + at F = ma Net force = Applied Force + Friction F = m v^2 / r F = G m_object1 m_object2 / d^2 (T1 / T2)^2 = (R1 / R2)^3 p = m v p = F t Momentum = Impulse W = F d W = P t KE = (mv^2) / 2 F=K q_object1 q_obejct2 / d^2 E = F / q V = E d E= q V R = V / I P = V I P = I^2 R E = I^2 R t Vtotal = IR + IR + IR ... Rtotal = R + R + R ... Itotal = I + I + I ... 1 / Rtotal = 1/R + 1/R +1/R ... F = B I L F = B q v EMF = B L v V_out = Loops_out * V_in / Loops_in v =  f n = C / v n = _wave1 / _wave2 n1 * sin angle 1 = n2 * sin angle 2 f = R / 2 M = h_image / h_reflection 1 / d_object + 1 / d_image = 1 / focal_length Diffraction = = nodal_dist * slit_dist / screen_dist
Scatter = 1 / E4
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