SOME QUICK # MATHS # FORMULAS
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1. Sum of first n natural numbers = n(n+1)/2
2. Sum of the squares of first n natural numbers
= n(n+1)(2n+1)/6
3. Sum of the cubes of first n natural numbers =
[n(n+1)/2]^2
4. Sum of first n natural odd numbers = n^2
5. Average = (Sum of items)/Number of items
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1. Sum of first n natural numbers = n(n+1)/2
2. Sum of the squares of first n natural numbers
= n(n+1)(2n+1)/6
3. Sum of the cubes of first n natural numbers =
[n(n+1)/2]^2
4. Sum of first n natural odd numbers = n^2
5. Average = (Sum of items)/Number of items
------>>>Arithmetic Progression (A.P.):
An A.P. is of the form a, a+d, a+2d, a+3d, …
where a is called the ‘first term’ and d is called
the ‘common difference’
1. nth term of an A.P. tn = a + (n-1)d
2. Sum of the first n terms of an A.P. Sn =
n/2[2a+(n-1)d] or Sn = n/2(first term + last term)
where a is called the ‘first term’ and d is called
the ‘common difference’
1. nth term of an A.P. tn = a + (n-1)d
2. Sum of the first n terms of an A.P. Sn =
n/2[2a+(n-1)d] or Sn = n/2(first term + last term)
----->>>Geometrical Progression (G.P.):
A G.P. is of the form a, ar, ar2, ar3, …
where a is called the ‘first term’ and r is called
the ‘common ratio’.
1. nth term of a G.P. tn = arn-1
2. Sum of the first n terms in a G.P. Sn = a|1-
rn|/|1-r|
where a is called the ‘first term’ and r is called
the ‘common ratio’.
1. nth term of a G.P. tn = arn-1
2. Sum of the first n terms in a G.P. Sn = a|1-
rn|/|1-r|
---->>>>Permutations and Combinations :
nPr = n!/(n-r)!
nPn = n!
nP1 = n
nCr = n!/(r! (n-r)!)
nC1 = n
nC0 = 1 = nCn
nCr = nCn-r
nCr = nPr/r!
Number of diagonals in a geometric figure of n
sides = nC2-n
nPn = n!
nP1 = n
nCr = n!/(r! (n-r)!)
nC1 = n
nC0 = 1 = nCn
nCr = nCn-r
nCr = nPr/r!
Number of diagonals in a geometric figure of n
sides = nC2-n
------>>>>Tests of Divisibility :
A number is divisible by 2 if it is an even
number.
A number is divisible by 3 if the sum of the
digits is divisible by 3.
A number is divisible by 4 if the number formed
by the last two digits is divisible by 4.
A number is divisible by 5 if the units digit is
either 5 or 0.
A number is divisible by 6 if the number is
divisible by both 2 and 3.
A number is divisible by 8 if the number formed
by the last three digits is divisible by 8.
A number is divisible by 9 if the sum of the
digits is divisible by 9.
A number is divisible by 10 if the units digit is 0.
A number is divisible by 11 if the difference of
the sum of its digits at odd places and the sum
of its digits at even places, is divisible by 11.
H.C.F and L.C.M :
H.C.F stands for Highest Common Factor. The
other names for H.C.F are Greatest Common
Divisor (G.C.D) and Greatest Common Measure
(G.C.M).
The H.C.F. of two or more numbers is the
greatest number that divides each one of them
exactly.
The least number which is exactly divisible by
each one of the given numbers is called their
L.C.M.
Two numbers are said to be co-prime if their
H.C.F. is 1.
H.C.F. of fractions = H.C.F. of numerators/
L.C.M of denominators
L.C.M. of fractions = G.C.D. of numerators/
H.C.F of denominators
Product of two numbers = Product of their
H.C.F. and L.C.M.
number.
A number is divisible by 3 if the sum of the
digits is divisible by 3.
A number is divisible by 4 if the number formed
by the last two digits is divisible by 4.
A number is divisible by 5 if the units digit is
either 5 or 0.
A number is divisible by 6 if the number is
divisible by both 2 and 3.
A number is divisible by 8 if the number formed
by the last three digits is divisible by 8.
A number is divisible by 9 if the sum of the
digits is divisible by 9.
A number is divisible by 10 if the units digit is 0.
A number is divisible by 11 if the difference of
the sum of its digits at odd places and the sum
of its digits at even places, is divisible by 11.
H.C.F and L.C.M :
H.C.F stands for Highest Common Factor. The
other names for H.C.F are Greatest Common
Divisor (G.C.D) and Greatest Common Measure
(G.C.M).
The H.C.F. of two or more numbers is the
greatest number that divides each one of them
exactly.
The least number which is exactly divisible by
each one of the given numbers is called their
L.C.M.
Two numbers are said to be co-prime if their
H.C.F. is 1.
H.C.F. of fractions = H.C.F. of numerators/
L.C.M of denominators
L.C.M. of fractions = G.C.D. of numerators/
H.C.F of denominators
Product of two numbers = Product of their
H.C.F. and L.C.M.
------>>>>PERCENTAGES :
If A is R% more than B, then B is less than A by
R / (100+R) * 100
If A is R% less than B, then B is more than A by
R / (100-R) * 100
If the price of a commodity increases by R%,
then reduction in consumption, not to increase
the expenditure is : R/(100+R)*100
If the price of a commodity decreases by R%,
then the increase in consumption, not to
decrease the expenditure is : R/(100-R)*100
R / (100+R) * 100
If A is R% less than B, then B is more than A by
R / (100-R) * 100
If the price of a commodity increases by R%,
then reduction in consumption, not to increase
the expenditure is : R/(100+R)*100
If the price of a commodity decreases by R%,
then the increase in consumption, not to
decrease the expenditure is : R/(100-R)*100
---->>>PROFIT & LOSS :
Gain = Selling Price(S.P.) – Cost Price(C.P)
Loss = C.P. – S.P.
Gain % = Gain * 100 / C.P.
Loss % = Loss * 100 / C.P.
S.P. = (100+Gain%)/100*C.P.
S.P. = (100-Loss%)/100*C.P.
If CP(x), Gain(y), Gain%(z). Then y = x*z/100.
[Same in case of Loss]
Loss = C.P. – S.P.
Gain % = Gain * 100 / C.P.
Loss % = Loss * 100 / C.P.
S.P. = (100+Gain%)/100*C.P.
S.P. = (100-Loss%)/100*C.P.
If CP(x), Gain(y), Gain%(z). Then y = x*z/100.
[Same in case of Loss]
------->>>>RATIO & PROPORTIONS:
The ratio a : b represents a fraction a/b. a is
called antecedent and b is called consequent.
The equality of two different ratios is called
proportion.
If a : b = c : d then a, b, c, d are in proportion.
This is represented by a : b :: c : d.
In a : b = c : d, then we have a* d = b * c.
If a/b = c/d then ( a + b ) / ( a – b ) = ( c + d ) /
( c – d ).
called antecedent and b is called consequent.
The equality of two different ratios is called
proportion.
If a : b = c : d then a, b, c, d are in proportion.
This is represented by a : b :: c : d.
In a : b = c : d, then we have a* d = b * c.
If a/b = c/d then ( a + b ) / ( a – b ) = ( c + d ) /
( c – d ).
------->>>TIME & WORK :
If A can do a piece of work in n days, then A’s 1
day’s work = 1/n
If A and B work together for n days, then (A+B)’s
1 days’s work = 1/n
If A is twice as good workman as B, then ratio
of work done by A and B = 2:1
day’s work = 1/n
If A and B work together for n days, then (A+B)’s
1 days’s work = 1/n
If A is twice as good workman as B, then ratio
of work done by A and B = 2:1
------>>>PIPES & CISTERNS :
If a pipe can fill a tank in x hours, then part of
tank filled in one hour = 1/x
If a pipe can empty a full tank in y hours, then
part emptied in one hour = 1/y
If a pipe can fill a tank in x hours, and another
pipe can empty the full tank in y hours, then on
opening both the pipes,
the net part filled in 1 hour = (1/x-1/y) if y>x
the net part emptied in 1 hour = (1/y-1/x) if x>y
tank filled in one hour = 1/x
If a pipe can empty a full tank in y hours, then
part emptied in one hour = 1/y
If a pipe can fill a tank in x hours, and another
pipe can empty the full tank in y hours, then on
opening both the pipes,
the net part filled in 1 hour = (1/x-1/y) if y>x
the net part emptied in 1 hour = (1/y-1/x) if x>y
------->>>TIME & DISTANCE :
Distance = Speed * Time
1 km/hr = 5/18 m/sec
1 m/sec = 18/5 km/hr
Suppose a man covers a certain distance at x
kmph and an equal distance at y kmph. Then,
the average speed during the whole journey is
2xy/(x+y) kmph.
1 km/hr = 5/18 m/sec
1 m/sec = 18/5 km/hr
Suppose a man covers a certain distance at x
kmph and an equal distance at y kmph. Then,
the average speed during the whole journey is
2xy/(x+y) kmph.
--------->>>PROBLEMS ON TRAINS :
Time taken by a train x metres long in passing a
signal post or a pole or a standing man is equal
to the time taken by the train to cover x metres.
Time taken by a train x metres long in passing a
stationary object of length y metres is equal to
the time taken by the train to cover x+y metres.
Suppose two trains are moving in the same
direction at u kmph and v kmph such that u>v,
then their relative speed = u-v kmph.
If two trains of length x km and y km are moving
in the same direction at u kmph and v kmph,
where u>v, then time taken by the faster train to
cross the slower train = (x+y)/(u-v) hours.
Suppose two trains are moving in opposite
directions at u kmph and v kmph. Then, their
relative speed = (u+v) kmph.
If two trains of length x km and y km are moving
in the opposite directions at u kmph and v kmph,
then time taken by the trains to cross each other
= (x+y)/(u+v)hours.
If two trains start at the same time from two
points A and B towards each other and after
crossing they take a and b hours in reaching B
and A respectively, then A’s speed : B’s speed =
(√b : √a)
signal post or a pole or a standing man is equal
to the time taken by the train to cover x metres.
Time taken by a train x metres long in passing a
stationary object of length y metres is equal to
the time taken by the train to cover x+y metres.
Suppose two trains are moving in the same
direction at u kmph and v kmph such that u>v,
then their relative speed = u-v kmph.
If two trains of length x km and y km are moving
in the same direction at u kmph and v kmph,
where u>v, then time taken by the faster train to
cross the slower train = (x+y)/(u-v) hours.
Suppose two trains are moving in opposite
directions at u kmph and v kmph. Then, their
relative speed = (u+v) kmph.
If two trains of length x km and y km are moving
in the opposite directions at u kmph and v kmph,
then time taken by the trains to cross each other
= (x+y)/(u+v)hours.
If two trains start at the same time from two
points A and B towards each other and after
crossing they take a and b hours in reaching B
and A respectively, then A’s speed : B’s speed =
(√b : √a)
-------->>>>SIMPLE & COMPOUND INTERESTS :
Let P be the principal, R be the interest rate
percent per annum, and N be the time period.
Simple Interest = (P*N*R)/100
Compound Interest = P(1 + R/100)^N – P
Amount = Principal + Interest
when rate of interest time n principal are
constant den principal=(C.I.-S.I.)*(100/R)^N
percent per annum, and N be the time period.
Simple Interest = (P*N*R)/100
Compound Interest = P(1 + R/100)^N – P
Amount = Principal + Interest
when rate of interest time n principal are
constant den principal=(C.I.-S.I.)*(100/R)^N
------>>>LOGARITHM:
If a^m = x , then m = loga(x).
Properties :
logx(x) = 1
logx(1) = 0
loga(x*y) = loga(x) + loga(y)
loga(x/y) = log ax – log ay
loga(x) = 1/logx(a)
loga(x^p) = p(loga(x))
loga(x) = logb(x)/logb(a)
Properties :
logx(x) = 1
logx(1) = 0
loga(x*y) = loga(x) + loga(y)
loga(x/y) = log ax – log ay
loga(x) = 1/logx(a)
loga(x^p) = p(loga(x))
loga(x) = logb(x)/logb(a)
Note : Logarithms for base 1 does not exist.
----->>>AREA & PERIMETER :
Shape Area Perimeter
Circle ∏ (Radius)2 2∏(Radius)
Square (side)2 4(side)
Rectangle length*breadth 2(length+breadth)
Area of a triangle = 1/2*Base*Height or
Area of a triangle = √ (s(s-(s-b)(s-c)) where
a,b,c are the lengths of the sides and s = (a+b
+c)/2
Area of a parallelogram = Base * Height
Area of a rhombus = 1/2(Product of diagonals)
Area of a trapezium = 1/2(Sum of parallel sides)
(distance between the parallel sides)
Area of a quadrilateral = 1/2(diagonal)(Sum of
sides)
Area of a regular hexagon = 6(√3/4)(side)2
Area of a ring = ∏(R2-r2) where R and r are the
outer and inner radii of the ring.
Area of a circle=πr^2 or πd^2/4
Area of semi-circle=πr^2/2
Area of a quadrant of a circle=πr^2/4
Area enclosed by two concentric circles=π(R^2-r
^2)
Area of a sector=Ɵ/180 degree *πr
No of revolutions completed by a rotating wheel
in 1 minute=distance moved in 1 minute/
circumference
Circle ∏ (Radius)2 2∏(Radius)
Square (side)2 4(side)
Rectangle length*breadth 2(length+breadth)
Area of a triangle = 1/2*Base*Height or
Area of a triangle = √ (s(s-(s-b)(s-c)) where
a,b,c are the lengths of the sides and s = (a+b
+c)/2
Area of a parallelogram = Base * Height
Area of a rhombus = 1/2(Product of diagonals)
Area of a trapezium = 1/2(Sum of parallel sides)
(distance between the parallel sides)
Area of a quadrilateral = 1/2(diagonal)(Sum of
sides)
Area of a regular hexagon = 6(√3/4)(side)2
Area of a ring = ∏(R2-r2) where R and r are the
outer and inner radii of the ring.
Area of a circle=πr^2 or πd^2/4
Area of semi-circle=πr^2/2
Area of a quadrant of a circle=πr^2/4
Area enclosed by two concentric circles=π(R^2-r
^2)
Area of a sector=Ɵ/180 degree *πr
No of revolutions completed by a rotating wheel
in 1 minute=distance moved in 1 minute/
circumference
------>>>VOLUME & SURFACE AREA
Cube :
Let a be the length of each edge. Then,
Volume of the cube = a3 cubic units
Surface Area = 6a2 square units
Diagonal = √ 3 a units
Let a be the length of each edge. Then,
Volume of the cube = a3 cubic units
Surface Area = 6a2 square units
Diagonal = √ 3 a units
Cuboid :
Let l be the length, b be the breadth and h be
the height of a cuboid. Then
Volume = lbh cu units
Surface Area = 2(lb+bh+lh) sq units
Diagonal = √ (l2+b2+h2)
Let l be the length, b be the breadth and h be
the height of a cuboid. Then
Volume = lbh cu units
Surface Area = 2(lb+bh+lh) sq units
Diagonal = √ (l2+b2+h2)
Cylinder :
Let radius of the base be r and height of the
cylinder be h. Then,
Volume = ∏r2h cu units
Curved Surface Area = 2∏rh sq units
Total Surface Area = 2∏rh + 2∏r2 sq units
Let radius of the base be r and height of the
cylinder be h. Then,
Volume = ∏r2h cu units
Curved Surface Area = 2∏rh sq units
Total Surface Area = 2∏rh + 2∏r2 sq units
Cone :
Let r be the radius of base, h be the height, and l
be the slant height of the cone. Then,
l2 = h2 + r2
Volume = 1/3(∏r2h) cu units
Curved Surface Area = ∏rl sq units
Total Surface Area = ∏rl + ∏r2 sq units
Let r be the radius of base, h be the height, and l
be the slant height of the cone. Then,
l2 = h2 + r2
Volume = 1/3(∏r2h) cu units
Curved Surface Area = ∏rl sq units
Total Surface Area = ∏rl + ∏r2 sq units
Sphere :
Let r be the radius of the sphere. Then,
Volume = (4/3)∏r3 cu units
Surface Area = 4∏r2 sq units
Let r be the radius of the sphere. Then,
Volume = (4/3)∏r3 cu units
Surface Area = 4∏r2 sq units
Hemi-sphere :
Let r be the radius of the hemi-sphere. Then,
Volume = (2/3)∏r3 cu units
Curved Surface Area = 2∏r2 sq units
Total Surface Area = 3∏r2 sq units
Let r be the radius of the hemi-sphere. Then,
Volume = (2/3)∏r3 cu units
Curved Surface Area = 2∏r2 sq units
Total Surface Area = 3∏r2 sq units
Prism :
Volume = (Area of base)(Height)
Volume = (Area of base)(Height)
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