revision notes for religious studies for the edexcel igcse specification
Reision note MRCS and Frcs
'
Full book summary Edexcel M1 Revision Notes (1) for edexcel gce examinations 2014, chapters included: 1) Kinematics 2) Dynamics 3) Moments 4) Vectors 5) StaticsFull description
Biology IGCSE notesFull description
Revision Notes for Edexcel Biology AS. Feel free to use this for your revision & good luck with your exams.Full description
Full description
Reision note MRCS and FrcsFull description
C4 summarised notes
Core Mathematics 1 Pearson's Edexcel AS and A Level Modular Mathematics This book is designed to provide you with the best preparation possible for you Edexcel C1 unit examination.Full description
Descripción: ejercios tema 4
ejercios tema 4Full description
Descripción: SP3D sheet revision
Formula sheet for all formulas in Statistics 1 of the Edexcel Specification.Full description
asFull description
It contains everything u took in unit 1 but not in full details these are just for revising not for first time studying hope u enjoy da notes and wish u best of luck :D
A complete set of flashcards to help revise for Physics unit 2
Full description
Full description
EDEXCEL STUDENT CONFERENCE 2006
A2 MATHEMATICS
STUDENT NOTES
South: Thursday 23rd March 2006, London
EXAMINATION HINTS Before the examination Obtain a copy of the formulae book – and use it! Write a list of and LEARN any formulae not in the formulae book Learn basic definitions Make sure you know how to use your calculator! Practise all the past papers - TO TIME!
At the start of the examination Read the instructions on the front of the question paper and/or answer booklet Open your formulae book at the relevant page
During the examination Read the WHOLE question before you start your answer Start each question on a new page (traditionally marked papers) or Make sure you write your answer within the space given for the question (on-line marked papers) Draw clear well-labelled diagrams Look for clues or key words given in the question Show ALL your working - including intermediate stages Write down formulae before substituting numbers Make sure you finish a ‘prove’ or a ‘show’ question – quote the end result Don’t fudge your answers (particularly if the answer is given)! Don’t round your answers prematurely Make sure you give your final answers to the required/appropriate degree of accuracy Check details at the end of every question (e.g. particular form, exact answer) Take note of the part marks given in the question If your solution is becoming very lengthy, check the original details given in the question If the question says “hence” make sure you use the previous parts in your answer Don’t write in pencil (except for diagrams) or red ink Write legibly! Keep going through the paper – go back over questions at the end if time
At the end of the examination If you have used supplementary paper, fill in all the boxes at the top of every page
C3 KEY POINTS C3 Algebra and functions Simplification of rational expressions (uses factorising and finding common denominators) Domain and range of functions Inverse function, f–1(x) [ ff–1(x) = f–1f(x) = x] Knowledge and use of: domain of f = range of f–1; range of f = domain of f–1 Composite functions e.g. fg(x) The modulus function Use of transformations (as in C1) with functions used in C3 Transformation
Description ⎛0⎞ Translation of y = f(x) through ⎜⎜ ⎟⎟ ⎝a⎠
y = f(x) + a
a>0
y = f(x + a)
a>0
⎛ – a⎞ Translation of y = f(x) through ⎜⎜ ⎟⎟ ⎝ 0 ⎠
y = af(x)
a>0
Stretch of y = f(x) parallel to y-axis with scale factor a
y = f(ax)
a>0
Stretch of y = f(x) parallel to x-axis with scale factor
y = |f(x)|
For y ≥ 0, sketch y = f(x) For y < 0, reflect y = f(x) in the x-axis
y = f(|x|)
For x ≥ 0, sketch y = f(x) For x < 0, reflect [y = f(x) for x > 0] in the y-axis
1 a
Also useful y = –f(x)
Reflection of y = f(x) in the x-axis (line y = 0)
y = f(–x)
Reflection of y = f(x) in the y-axis (line x = 0)
C3 Trigonometry
sec x =
1 cos x
cosec x =
sin2x + cos2x = 1;
1 sin x
cot x =
1 + tan2x = sec2x;
sin(A ± B) = sinAcosB ± cosAsinB tan A ± tan B tan(A ± B) = 1 m tan A tan B
cos x 1 = tan x sin x
1 + cot2x = cosec2x cos(A ± B) = cosAcosB m sinAsinB
sin 2x = 2sin x cos x; cos 2x = cos2x – sin2x = 2 cos2x – 1 = 1 – 2 sin2x;
tan 2x =
2 tan x 1 − tan 2 x
Graphs of inverse trig. functions – π/2 ≤ arcsin x ≤ π/2 0 ≤ arccos x ≤ π – π/2 < arctan x < π/2 Expressing acosθ + bsinθ in the form rcos(θ ± α) or rsin(θ ± α) and applications (e.g. solving equations, maxima, minima)
C3 Exponentials and logarithms Graphs of y = ex and y = lnx and use of transformations to sketch e.g. y = e3x + 2 Solutions to equations using ex and lnx (e.g. e2x + 1 = 3) exlna = ax
C3 Differentiation d (e x ) = ex dx
d (e kx ) = e kx dx
d (sin kx) = k cos kx dx
d (ln x) 1 = dx x
d (cos kx) = –k sin kx dx
d (ln kx) 1 = dx x
d (tan kx) 2 = k sec kx dx
Differentiation of other trig. functions: see formulae book Chain rule
dy dy du = × dx du dx
Product rule
d(uv) dv du +v =u dx dx dx
dy 1 = dx ⎛ dy ⎞ ⎜ ⎟ ⎝ dx ⎠ Quotient rule
d( uv ) dx
v
=
du dv −u dx dx v2
C3 Numerical methods For a continuous function, a change in sign of f(x) in the interval (a, b) ⇒ a root of f(x) = 0 in the interval (a, b) Accuracy of roots by choosing an interval (e.g. 1.47 to 2 d.pl. test f(1.465) and f(1.475) for change of sign) Iterative methods: rearranging equations in the form xn+1 = f(xn) and using repeated iterations
C4 KEY POINTS C4 Algebra and functions Partial fractions: Methods for dealing with degree of numerator ≥ degree of denominator, partial fractions of the form 5− x A B C 2x + 3 A B C ≡ + + and ≡ + + 2 x + 2 x − 3 ( x − 3) 2 x( x − 1)(2 x + 1) x x − 1 2 x + 1 ( x + 2)( x − 3)
C4 Coordinate geometry Changing equations of curves between Cartesian and parametric form dx Use of ∫ y dt to find area under a curve dt
C4 Sequences are series Expansion of (ax + b)n for any rational n and for |x| <
b a
, using n(n − 1) 2 n(n − 1)(n − 2) x + + ... + x n (1 + x)n = 1 + nx + n C 2 x 2 + ... + n C r x r + ... + x n = 1 + nx + 2! 3! n! where nCr = r!(n − r )!
C4 Differentiation Implicit and parametric differentiation including applications to tangents and normals Exponential growth and decay d(a x ) = ax ln a dx
Formation of differential equations
C4 Integration
∫ ex dx = ex + c 1
∫ x dx = ln | x | +c ∫ cos kx dx =
Use of
∫ ekx dx = 1
1 kx e +c k
1 1
1
∫ ax dx = ∫ a . x dx = a ln | x | +c
1 sin kx + c k
1
1 k
∫ sin kx dx = – cos kx + c
f ′( x) ∫ f ( x) dx = ln | f ( x) | +c and
n ∫ f ′( x)[f ( x)] dx =
Integration of other trig. functions: see formulae book Volume: use of ∫ π y2 dx when rotating about x-axis Integration by substitution Integration by parts
or
1
1
∫ ax dx = a ln | ax | +c ∫ sec2kx dx =
[f ( x)]n +1 +c n +1
2
1 tan kx + c k
Use of partial fractions in integration Differential equations: first order separable variables g( y ) h ( x) dy dy = ∫ dx e.g. f( x)g ( y ) = h ( x)k( y ) ⇒ ∫ k( y) f ( x) dx Trapezium rule applied to C3 and C4 functions b
∫ f ( x ) dx ≈
1 2
h[y0 + yn + 2(y1 + ... + yn–1)]
where yi = f(a + ih) and h =
a
b−a n
C4 Vectors If a = xi + yj + zk, |a| = √(x2 + y2 + z2)
If a = xi + yj + zk, the unit vector in the direction of a is [(xi + yj + zk) ÷ √(x2 + y2 + z2)] Scalar product: If OP = p = xi + yj + zk and OQ = q = ai + bj + ck and ∠POQ = θ, then p.q = |p||q| cosθ
and p.q = (xi + yj + zk) . (ai + bj + ck) = xa + by + cz
If OP and OQ are perpendicular, p.q = 0 Vector equation of line where a is the position vector of a point on the line and m is a vector parallel to the line: r = a + λm Vector equation of line where a and b are the position vectors of points on the line: r = a + λ ( b – a)