Mathematics: Analysis & Approaches SL & HL 1 Page Formula Sheet – First Examinations 2021 – Updated Version 1.3 Topic 3: Geometry and trigonometry – SL & HL Prior Learning SL & HL Area: Parallelogram Area: Triangle Area: Trapezoid Area: Circle Circumference: Circle Volume: Cuboid Volume: Cylinder Volume: Prism Area: Cylinder curve π΄ = πβ , π = base, β = height 1 π΄ = 2 (πβ) , π = base, β = height 1 π΄ = 2 (π + π)β , π, π = parallel sides, β = height π΄ = ππ 2 , π = radius πΆ = 2ππ, π = radius π = ππ 2 β , π = radius, β = height π = π΄β , π΄ = cross-section area, β = height π΄ = 2ππβ , π = radius, β = height Area: Cone curve Volume: Sphere Surface area: Sphere Sine rule Area: Triangle πΉπ is future value, ππ is present value, π is the number of years, π is the number of compounding periods per year, π% is the nominal annual rate of interest Pythagorean identity Reciprocal trigonometric identities Pythagorean identities Compound angle identities Exponents & logarithms Double angle identity for tan log π π₯π¦ = log π π₯ + log π π¦ π₯ log π = log π π₯ − log π π¦ π¦ log π π₯ π = π log π π₯ logπ π₯ log π π₯ = log π π π ∞ = Magnitude of a vector π’1 , |π| < 1 1−π Scalar product ππ + (π1)ππ−1 π+. . . +(ππ)ππ−π ππ +. . . + ππ π! π ( ) = nC r = π π!(π−π)! Topic 1: Number and algebra - HL only Combinations; Permutations nC π! π!(π−π)! ; nP r π! = (π−π)! π(π − 1) π 2 π ( ) +. . . ) ππ (1 + π ( ) + 2! π π π§ = π + ππ Complex numbers Modulus-argument (polar) & Exponential (Euler) form De Moivre’s theorem r= (π + π)π = Extension of Binomial Theorem, π ∈ β π§ = π(cos π + π sin π) = ππ π [π(cos π + π sin π)]π = π (cos ππ π πππ ππ + π sin ππ) = π π Topic 2: Functions – SL & HL Equations of a straight line Gradient formula Axis of symmetry of a quadratic function Solutions of a quadratic equation in the form πππ + ππ + π = π Discriminant Exponential and logarithmic functions = πcisπ π = π cisππ π¦ = ππ₯ + π ; ππ₯ + ππ¦ + π = 0 ; π¦ − π¦1 = π(π₯ − π₯1 ) π¦2 − π¦1 π= π₯2 − π₯1 π(π₯) = ππ₯ 2 + ππ₯ + π ⇒ π₯ = − −π ± √π2 − 4ππ π₯= ,π ≠ 0 2π π 2π β = π2 − 4ππ π π₯ = π π₯ ln π ; log π π π₯ = π₯ = π logπ π₯ where π, π₯ > 0 , π ≠ 1 Topic 2: Functions – HL only Sum & product of the roots of polynomial equations of the form π = sinπ΄ π sinπ΅ = π ∑ ππ π₯ π = 0 π=0 ⇒ Sum is (−1)π π0 −ππ−1 ; product is ππ ππ 1 π΄ = 2 π 2 π , π = radius, π = angle in radians sin π cos π 2 cos 2 π + sin π = 1 Angle between two vectors Vector equ. of a line Parametric form of the equation of a line Cartesian equations of a line Vector product Area of a parallelogram Vector equ. of a plane Equation of a plane Cartesian equ. of a plane 1 ; cos π cosec π = 1 sin π 1 + tan2 π = sec 2 π ; 1 + cot 2 π = cosec 2 π sin(π΄ ± π΅) = sin π΄ cos π΅ ± cos π΄ sin π΅ cos(π΄ ± π΅) = cos π΄ cos π΅ β sin π΄ sin π΅ tan π΄ ± tan π΅ tan(π΄ ± π΅) = 1 β tan π΄ tan π΅ tan 2π = 2 tan π 1 − tan2 π |π| = √π£1 2 + π£2 2 + π£3 2 Μ , of a set of Mean, π data π = π + ππ + ππ Probability of an event A P(π΄) = π π(π΄) π(π’) , where π = ∑ππ=1 ππ Mutually exclusive events Derivative of ππ Area between curve π = π(π) & π-axis Derivative of π¬π’π§ π Derivative of ππ¨π¬ π Derivative of ππ Derivative of π₯π§ π Chain rule Product rule Quotient rule Acceleration Conditional probability Independent events Expected value: Discrete random variable X Binomial distribution Mean ; Variance Standardized normal variable P(π΄|π΅) = P(π΄ ∩ π΅) P(π΅) P(π΄ ∩ π΅) = P(π΄)P(π΅) E(π) = ∑ π₯ P(π = π₯) π~B(π, π) E(π) = ππ ; Var(π) = ππ(1 − π) π₯−π π§= π IB Math Practice Exams (Full Length) IB Math Practice Exams by Topic IB Math Practice Exams by Difficulty Voted #1 IB Mathematics Resource & used by 350,000+ IB Students & Teachers Worldwide − π2 π Var(π) = E[(π − π)2 ] = E(π 2 ) − [E(π)]2 Var(π) = ∑(π₯ − π)2 P(π = π₯) = ∑ π₯ 2 P(π = π₯) − π2 ∞ Var(π) = ∫−∞(π₯ − π)2 π(π₯)dπ₯ ∞ = ∫−∞ π₯ 2 π(π₯)dπ₯ − π2 π(π₯) = π₯ π ⇒ π′(π₯) = ππ₯ π−1 π₯ π+1 ∫ π₯ π ππ₯ = + πΆ , π ≠ −1 π+1 π π΄ = ∫ π¦ ππ₯ , where π(π₯) > 0 π π(π₯) = sin π₯ ⇒ π′(π₯) = cos π₯ π(π₯) = cos π₯ ⇒ π′(π₯) = − sin π₯ π(π₯) = π π₯ ⇒ π′(π₯) = π π₯ 1 π(π₯) = ln π₯ ⇒ π′(π₯) = π₯ ππ¦ ππ¦ ππ’ π¦ = π(π’) , π’ = π(π₯) ⇒ = × ππ₯ ππ’ ππ₯ ππ¦ ππ£ ππ’ π¦ = π’π£ ⇒ =π’ +π£ ππ₯ ππ₯ ππ₯ ππ£ ππ’ π’ ππ¦ π£ ππ₯ − π’ ππ₯ π¦= ⇒ = π£2 π£ ππ₯ dπ£ d2 π π= = 2 dπ‘ dπ‘ π‘2 π‘2 dist = ∫ |π£(π‘)| ππ‘ ; disp = ∫ π£(π‘) ππ‘ π‘1 π‘1 1 ∫ ππ₯ = ln|π₯| + πΆ π₯ ∫ sin π₯ ππ₯ = − cos π₯ + πΆ ∫ cos π₯ ππ₯ = sin π₯ + πΆ ∫ π π₯ ππ₯ = π π₯ + πΆ π Area enclosed by a curve and π-axis π΄ = ∫ |π¦| ππ₯ Derivative of π(π) from first principles π(π₯ + β) − π(π₯) dπ¦ = π′(π₯) = lim ( ) β→0 β dπ₯ π Topic 5: Calculus – HL only Standard derivatives P(π΄ ∪ π΅) = P(π΄) + P(π΅) − P(π΄ ∩ π΅) P(π΄ ∪ π΅) = P(π΄) + P(π΅) π Topic 5: Calculus - SL & HL Complementary events P(π΄) + P(π΄′ ) = 1 Combined events 2 ∑π π=1 ππ (π₯π −π) = ∞ Variance of a continuous random variable X ππ₯ + ππ¦ + ππ§ = π ∑π π=1 ππ π₯π π E(π) = π = ∫−∞ π₯π(π₯)dπ₯ Variance of a discrete random variable X π β π = π β π (using the normal vector) π₯Μ = π=√ Variance π₯ − π₯0 π¦ − π¦0 π§ − π§0 = = π π π π΄ = |π × π| , where π and π form two adjacent sides of a parallelogram 2 ∑π π=1 ππ π₯π E(ππ + π) = πE(π) + π Var(ππ + π) = π2 Var(π) Standard integrals π£2 π€3 − π£3 π€2 π × π = (π£3 π€1 − π£1 π€3 ) π£1 π€2 − π£2 π€1 |π × π| = |π||π| sin π where π is the angle between π and π 2 ∑π π=1 ππ (π₯π −π) Linear transformation of a single random variable π₯ = π₯0 + ππ, π¦ = π¦0 + ππ, π§ = π§0 + ππ IQR = π3 − π1 P(π΅π )P(π΄|π΅π ) P(π΅1 )P(π΄|π΅1 ) + P(π΅2 )P(π΄|π΅2 ) + P(π΅3 )P(π΄|π΅3 ) Standard Deviation π Distance; Displacement travelled from ππ to ππ π = π + ππ P(π΅)P(π΄|π΅) P(π΅)P(π΄|π΅) + P(π΅′ )P(π΄|π΅′ ) π2 = Topic 4: Statistics and probability - SL & HL Interquartile range P(π΅π |π΄) = Variance ππ π β π = π£1 π€1 + π£2 π€2 + π£3 π€3 π β π = |π||π| cos π where π is the angle between π and π π£1 π€1 + π£2 π€2 + π£3 π€3 cos π = |π||π| www.revisionvillage.com IB Math Exam Questionbanks IB Math Learning Videos IB Math Past Paper Video Solutions Bayes’ theorem Integral of ππ sin 2π = 2 sin π cos π cos 2π = cos 2 π − sin2 π = 2 cos 2 π − 1 = 1 − 2 sin2 π sec π = P(π΅|π΄) = Expected value: Continuous random variable X π sinπΆ Topic 3: Geometry and trigonometry – HL only Exponents & logarithms π = π ⇔ π₯ = log π π , π, π > 0, π ≠ 1 Binomial coefficient π΄ = 4ππ 2 , π = radius Double angle identities π₯ Binomial Theorem for π ∈ β, (π + π)π = 4 π = 3 ππ 3 , π = radius π’1 (π π − 1) π’1 (1 − π π ) = ,π ≠ 1 π−1 1−π π ππ πΉπ = ππ × (1 + ) 100π ), for endpoints (π₯1 , π¦1), (π₯2 , π¦2 ) π π = The sum of an infinite geometric sequence π΄ = πππ , π= radius, π = slant height tan π = 2 π’π = π’1 π π−1 Sum of π terms of a finite geometric seq. 1 π = 3 ππ 2 β , π= radius, β = height Identity for πππ§ π½ , Cosine rule Length of an arc The πth term of a geometric sequence 1 Volume: Right-pyramid π = 3 π΄β , π΄ = base area, β = height Area of a sector 2 π’π = π’1 + (π − 1)π Sum of π terms of an arithmetic sequence π₯1 + π₯2 π¦1 + π¦2 π§1 + π§2 , , ) 2 2 2 π π π π = (2π’1 + (π − 1)π) = (π’1 + π’π ) 2 2 ( The πth term of an arithmetic sequence ( π 2 = π2 + π2 − 2ππ cos πΆ π2 + π2 − π 2 cos πΆ = 2ππ 1 π΄ = ππ sin πΆ 2 π = ππ , π = radius, π = angle in radians π₯1 +π₯2 π¦1 +π¦2 Topic 1: Number and algebra - SL & HL Compound interest Coordinates of midpoint of a line with endpoints (ππ , ππ , ππ ) , (ππ , ππ , ππ ) Volume: Right cone π = ππ€β , π = length, π€ = width, β = height Distance between two )2 (π¦ )2 points (ππ , ππ ) , (ππ , ππ ) π = √(π₯1 − π₯2 + 1 − π¦2 Coordinates of midpoint Distance between 2 points π = √(π₯1 − π₯2 )2 + (π¦1 − π¦2 )2 + (π§1 − π§2 )2 (ππ , ππ , ππ ) , (ππ , ππ , ππ ) Topic 4: Statistics and probability – HL only Standard integrals π(π₯) = tan π₯ ⇒ π ′ (π₯) = sec 2 π₯ π(π₯) = sec π₯ ⇒ π ′ (π₯) = sec π₯ tan π₯ π(π₯) = cosec π₯ ⇒ π ′ (π₯) = −cosec π₯ cot π₯ π(π₯) = cot π₯ ⇒ π ′ (π₯) = −cosec 2 π₯ π(π₯) = π π₯ ⇒ π ′ (π₯) = π π₯ (ln π) 1 π(π₯) = logπ π₯ ⇒ π ′ (π₯) = π₯ ln π 1 π(π₯) = arcsin π₯ ⇒ π ′ (π₯) = √1 − π₯ 2 1 π(π₯) = arccos π₯ ⇒ π ′ (π₯) = − √1 − π₯ 2 1 π(π₯) = arctan π₯ ⇒ π ′ (π₯) = 1 + π₯2 1 ∫ π π₯ dπ₯ = ln π π π₯ + πΆ 1 1 π₯ ∫ π2 +π₯2 dπ₯ = π arctan (π) + πΆ 1 π₯ Integration by parts ∫ √π2 −π₯2 dπ₯ = arcsin (π) + πΆ , |π₯| < π Area enclosed by a curve and π-axis π΄ = ∫π |π₯| ππ¦ Volume of revolution about π or π-axes Euler’s method Integrating factor for π′ + π·(π)π = πΈ(π) Maclaurin series dπ£ dπ’ ∫ π’ dπ₯ ππ₯ = π’π£ − ∫ π£ dπ₯ ππ₯ π= π π ∫π ππ¦ 2 ππ₯ π or π = ∫π ππ₯ 2 ππ¦ π¦π+1 = π¦π + β × π(π₯π , π¦π ); π₯π+1 = π₯π + β where β is a constant (step length) π ∫ π(π₯)dπ₯ π(π₯) = π(0) + π₯π ′ (0) + 2 Maclaurin series for special functions π₯ 2 ′′ π (0)+ . .. 2! 2 3 β π π₯ = 1 + π₯ + π₯2! + ... β ln(1 + π₯) = π₯ − π₯2 + π₯3 − ... 3 5 2 4 β sin π₯ = π₯ − π₯3! + π₯5! − ... β cos π₯ = 1 − π₯2! + π₯4! − ... 3 5 β arctan π₯ = π₯ − π₯3 + π₯5 − ...