Table of Information and Equation Tables for AP Physics Exams The accompanying Table of Information and Equation Tables will be provided to students when they take the AP Physics Exams. Therefore, students may NOT bring their own copies of these tables to the examination room, although they may use them throughout the year in their classes in order to become familiar with their content. Table of Information For both the Physics B and Physics C Exams, the Table of Information is printed near the front cover of the multiple-choice section and on the green insert provided with the free-response section. The tables are identical for both exams except for one convention as noted. Equation Tables For both the Physics B and Physics C Exams, the equation tables for each exam are printed only on the green insert provided with the free-response section. The equation tables may be used by students when taking the free-response sections of both exams, but NOT when taking the multiple-choice sections. The equations in the tables express the relationships that are encountered most frequently in AP Physics Courses and Exams. However, the tables do not include all equations that might possibly be used. For example, they do not include many equations that can be derived by combining other equations in the tables. Nor do they include equations that are simply special cases of any that are in the tables. Students are responsible for understanding the physical principles that underlie each equation and for knowing the conditions for which each equation is applicable. The equation tables are grouped in sections according to the major content category in which they appear. Within each section, the symbols used for the variables in that section are defined. However, in some cases the same symbol is used to represent different quantities in different tables. It should be noted that there is no uniform convention among textbooks for the symbols used in writing equations. The equation tables follow many common conventions, but in some cases consistency was sacrificed for the sake of clarity. Some explanations about notation used in the equation tables: 1. The symbols used for physical constants are the same as those in the Table of Information and are defined in the Table of Information rather than in the right-hand columns of the tables. 2. Symbols in bold face represent vector quantities. 3. Subscripts on symbols in the equations are used to represent special cases of the variables defined in the right-hand columns. 4. The symbol D before a variable in an equation specifically indicates a change in the variable (i.e., final value minus initial value). 5. Several different symbols (e.g. d, r, s, h, A ) are used for linear dimensions such as length. The particular symbol used in an equation is one that is commonly used for that equation in textbooks. TABLE OF INFORMATION FOR 2006 and 2007 CONSTANTS AND CONVERSION FACTORS UNITS 1 unified atomic mass unit, Proton mass, 1 u = 1.66 ¥ 10 -27 kg Name = 931 MeV c 2 meter m kilogram kg m p = 1.67 ¥ 10 -27 kg Neutron mass, mn = 1.67 ¥ 10 -27 kg Electron mass, me = 9.11 ¥ 10 -31 kg Electron charge magnitude, Avogadro’s number, Universal gas constant, Boltzmann’s constant, Speed of light, Planck’s constant, PREFIXES Symbol second s e = 1.60 ¥ 10 -19 C ampere A N 0 = 6.02 ¥ 1023 mol -1 kelvin R = 8.31 J (moliK) mole k B = 1.38 ¥ 10 -23 J K c = 3.00 ¥ 10 m s 8 h = 6.63 ¥ 10 -34 J is hertz pascal Pa = 4.14 ¥ 10 eV is hc = 1.99 ¥ 10 -25 J im joule J = 1.24 ¥ 103 eV inm ⑀0 = 8.85 ¥ 10 -12 C2 N im 2 watt W coulomb C Coulomb’s law constant, k = 1 4 p ⑀ 0 = 9.0 ¥ 10 9 N im 2 C2 volt V Vacuum permeability, m0 = 4 p ¥ 10 -7 (T im) A ohm W henry H farad F tesla T degree Celsius C electronvolt eV Magnetic constant, k ¢ = m0 4 p = 10 -7 (T im) A Universal gravitational constant, Acceleration due to gravity at Earth’s surface, 1 atmosphere pressure, 1 electron volt, G = 6.67 ¥ 10 -11 m 3 kgis2 g = 9.8 m s2 1 atm = 1.0 ¥ 10 N m 5 = 1.0 ¥ 105 Pa 1 eV = 1.60 ¥ 10 -19 J 2 10 giga G 10 6 mega M 10 3 kilo k centi c milli m micro m nano n pico p 10 -2 -3 -6 10 -9 10 Hz N Symbol 10 mol newton Prefix 9 10 K -15 Vacuum permittivity, Factor -12 VALUES OF TRIGONOMETRIC FUNCTIONS FOR COMMON ANGLES θ sin θ cos θ tan θ 0 0 1 0 30 1/2 3 /2 3 /3 37 3/5 4/5 3/4 45 2 /2 2 /2 1 53 4/5 3/5 4/3 60 3 /2 1/2 3 90 1 0 ∞ The following conventions are used in this exam. I. Unless otherwise stated, the frame of reference of any problem is assumed to be inertial. II. The direction of any electric current is the direction of flow of positive charge (conventional current). III. For any isolated electric charge, the electric potential is defined as zero at an infinite distance from the charge. *IV. For mechanics and thermodynamics equations, W represents the work done on a system. *Not on the Table of Information for Physics C, since Thermodynamics is not a Physics C topic. ADVANCED PLACEMENT PHYSICS B EQUATIONS FOR 2006 and 2007 NEWTONIAN MECHANICS u = u0 + at x = x0 + u0 t + 1 2 at 2 u 2 = u0 2 + 2a ( x - x0 )  F = Fnet = ma F fric £ m N ac = u2 r t = r F sin q p = mv J = FDt = Dp K = 1 2 mu 2 DUg = mgh W = F Dr cos q Pavg = Fs = - k x 1 2 kx 2 Ts = 2 p m k Tp = 2p A g T = = = = = = = = = = = = = = = = = = = = = = = acceleration force frequency height impulse kinetic energy spring constant length mass normal force power momentum radius or distance period time potential energy velocity or speed work done on a system position coefficient of friction angle torque F = 1 q1q2 4 p⑀0 r 2 E= F q UE = qV = Eavg = V = C = C = 1 q1q2 4 p⑀0 r V d q  rii 1 4 p⑀0 i Q V ⑀0 A d 1 1 QV = CV 2 2 2 Uc = I avg DQ = Dt R= rA A V = IR W Dt P = F u cos q Us = a F f h J K k A m N P p r T t U u W x m q t ELECTRICITY AND MAGNETISM P = IV  Ci Cp = i 1 1 = Cs i Ci Rs =  Ri i 1 = Rp 1 ÂR i i FB = qu B sin q FB = BI A sin q 1 f B= FG = - Gm1m2 UG = - Gm1m2 r r2 m0 I 2p r fm = BA cos q eavg e =- = BAu Dfm Dt A B C d E e F I A P Q q R r t U V = = = = = = = = = = = = = = = = = u = r = q = fm = area magnetic field capacitance distance electric field emf force current length power charge point charge resistance distance time potential (stored) energy electric potential or potential difference velocity or speed resistivity angle magnetic flux ADVANCED PLACEMENT PHYSICS B EQUATIONS FOR 2006 and 2007 FLUID MECHANICS AND THERMAL PHYSICS WAVES AND OPTICS P = P0 + r gh u = fl Fbuoy = rVg A1u1 = A2 u2 P + r gy + 1 2 ru = const. 2 D A = a A 0 DT H = kA DT L P= F A PV = nRT = Nk BT K avg 3 = k BT 2 urms = 3 RT = M W = - P DV DU = Q + W e= W QH ec = TH - TC TH 3k B T m A = area e = efficiency F = force h = depth H = rate of heat transfer k = thermal conductivity Kavg = average molecular kinetic energy A = length L = thickness M = molar mass n = number of moles N = number of molecules P = pressure Q = heat transferred to a system T = temperature U = internal energy V = volume u = velocity or speed urms = root-mean-square velocity W = work done on a system y = height a = coefficient of linear expansion m = mass of molecule r = density ATOMIC AND NUCLEAR PHYSICS E = hf = pc K max = hf - f l = h p D E = ( Dm ) c 2 E= f = K= m= p = l= f= energy frequency kinetic energy mass momentum wavelength work function n= c u n 1 sin q1 = n 2 sin q2 sin qc = n2 n1 1 1 1 + = si s0 f h s M = i =- i h0 s0 R 2 d sin q = ml f = xm ⬃ d = separation f = frequency or focal length h = height L = distance M = magnification m = an integer n = index of refraction R = radius of curvature s = distance u = speed x = position l = wavelength q = angle m lL d GEOMETRY AND TRIGONOMETRY Rectangle A = bh Triangle 1 A = bh 2 Circle A = pr2 C = 2p r Parallelepiped V = Awh Cylinder V = p r 2A A= C= V= S = b = h = A= w= r = area circumference volume surface area base height length width radius S = 2p r A + 2p r 2 Sphere 4 V = pr3 3 S = 4p r 2 Right Triangle a 2 + b2 = c 2 a sin q = c b cos q = c a tan q = b c a 90° q b ADVANCED PLACEMENT PHYSICS C EQUATIONS FOR 2006 and 2007 MECHANICS u = u0 + at x = x0 + u0 t + 1 2 at 2 u 2 = u02 + 2a ( x - x0 )  F = Fnet = ma F= dp dt J = Ú F dt = Dp p = mv F fric £ m N W = ÚF K = 1 2 mu 2 P= dW dt ∑ dr P = Fⴢv DUg = mgh ac = 2 u = w2 r r a = F = f = h = I = J = K = k = A = L = m= N = P = p = r = r = T = t = U= u = W= x = m = q = t = w = a = ELECTRICITY AND MAGNETISM acceleration force frequency height rotational inertia impulse kinetic energy spring constant length angular momentum mass normal force power momentum radius or distance position vector period time potential energy velocity or speed work done on a system position coefficient of friction angle torque angular speed angular acceleration Fs = - k x t=r¥F  t = t net = I a Us = I = Ú r 2 dm =  mr 2 T = 1 2 kx 2 u = rw L = r ¥ p = Iw 1 K = I w2 2 FG = - w = w0 + at q = q0 + w0t + Tp = 2 p 1 2 at 2 UG r2 Gm1m2 =r F q vÚ E dA= ∑ 1 4 p⑀0 V = ⑀0 dV dr E =- q  rii Q V C = k⑀0 A d 1 q1q2 4 p⑀0 r  Ci Cp = i 1 1 = Cs i Ci I = dQ dt Uc = 1 1 QV = CV 2 2 2 R= rA A Rs = rˆ  Ri 1 = Rp F I J L A n = = = = = = = = = = = = area magnetic field capacitance distance electric field emf force current current density inductance length number of loops of wire per unit length number of charge carriers per unit volume power charge point charge resistance distance time potential or stored energy electric potential velocity or speed resistivity magnetic flux dielectric constant i UE = qV = C = A B C d E e Q V = IR A g Gm1m2 E= I = Neud A m k Ts = 2 p 1 q1q2 4 p⑀ 0 r 2 E = rJ 2p 1 = f w rcm =  mr  m F = N = P Q q R r t U = = = = = = = V= u = r = fm = k = vÚ B ∑ d ᐉ = m0 I dB = F= Ú I dᐉ ¥ B Bs = m0 nI fm = Ú B ∑ d A i 1 ÂR i i P = IV FM = qv ¥ B m0 I d ᐉ ¥ r 4p r 3 d fm dt e =- e = -L UL = dI dt 1 2 LI 2 ADVANCED PLACEMENT PHYSICS C EQUATIONS FOR 2006 and 2007 GEOMETRY AND TRIGONOMETRY Rectangle A = bh A= C= V= S = b = h = A= w= r = Triangle A= 1 bh 2 Circle A = pr2 C = 2p r CALCULUS area circumference volume surface area base height length width radius df d f du = dx du dx d n ( x ) = nxn -1 dx d x (e ) = e x dx d (1n x ) = 1 dx x d (sin x ) = cos x dx Parallelepiped V = Aw h Cylinder d (cos x ) = - sin x dx V = p r 2A S = 2p r A + 2p r Úx 2 Úe Sphere V = 4 3 pr 3 Ú Right Triangle b cos q = c tan q = a b x dx = e x dx = ln x x Ú sin x dx = - cos x a 2 + b2 = c 2 a c dx = Ú cos x dx = sin x S = 4p r 2 sin q = 1 x n + 1 , n π -1 n +1 n c a 90° q b