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Large distance is measured by
parallax method
Parallax angle=
•1
O=1.745 x 10-2 rad
•1"=4.85×106 rad.
•1‛=2.91×104 rad.
•1 AU = 1.496×1011 m
•1 ly = 9.46 × 1015 m
•1parsec= 3.08 x 1016 m
•Size of proton: 10-15 m
•Radius Of Earth: 107m
•Distance to Boundary Of
Observable Universe : 1026 m
For very small sizes, optical microscope,
tunneling microscope, electron microscope
are used.
7 Base units and 2 supplementary units
SI SYSTEM
Base Units
Supplementary Units
Quantity
Quantity
Plane angle
Solid angle
radian
steradian
rad
sr
NO.
1
2
Unit Symbol
Length
NO.
1
Unit
meter
Symbol
m
Mass
2kilogram kg
Time
3second s
Temperature
4kelvinK
Electric current
5ampereA
Luminous intensity
6candela cd
Amount of
substance
7molemol
What is the unit of permittivity
of free space ?
ε0
(a) coloumb/newton-metre
(b) newton-metre2 /coloumb²
(c) coloum/newton-metre2
(d) coloumb2/(newton-metre)2
MEASUREMENT OF LENGTH
RULES FOR SIGNIFICANT FIGURES
BASIS
DISTANCE
MEASUREMENT OF MASS & TIME
TIME
MASS
SI unit is second (based on caesium clock with an
uncertainity less than 1 part in 10-13
ie,s loss every year)
Timespan of unstable particle: 10-24 s
Age of universe: 1017 s
•1amu =(1/12)th mass of
one C12 atom
•1amu = 1.66×10-27 kg
•Electron mass- 10-30 kg
•Earth mass : 1025 kg
•Observable Universe 1055 kg
Unified atomic mass unit(amu) is used to measure
mass of atoms & molecules
SIGNIFICANT FIGURES
RULES FOR ROUNDING OF A MEASUREMENT
RULES FOR ROUNDING OF A MEASUREMENT
The digits in a measured quantity which are reliable and confidence
in our measurement + the digit which is uncertain.
1. All non-zero digits are significant. For example, 42.3 has three
significant figures; 243.4 has four significant figures; and 24.123 has
five significant figures.
2. A zero becomes significant figure if it appears between two
non-zero digits. For example, 5.03 has three significant figures;
5.604 has four significant figures; and 4.004 has four significant
figures.
3. Leading zeros or the zeros placed to the left of the number are
never significant. For example,0.543 has three significant figures;
0.045 has two significant figures; and 0.006 has one significant figure.
4. Trailing zeros or the zeros placed to the right of the number are
significant. For example, 4.330 has four significant figures; 433.00
has five significant figures; and 343.000 has six significant figures.
5. In exponential notation, the numerical portion gives the number of
significant figures. For example,1.32 x 10-² has three significant
figures and 1.32 x 104 has three significant figures.
1. If the digit to be dropped is less than 5, then the preceding digit is
left unchanged. For example,x = 7.82 is rounded off to 7.8 and
x = 3.94 is rounded off to 3.9.
2. If the digit to be dropped is more than 5, then the preceding digit
is raised by one. For example, x = 6.87 is rounded off to 6.9 and
x = 12.78 is rounded off to 12.8.
3. If the digit to be dropped is 5 followed by digits other than zero,
then the preceding digit is raised by one. For example, x = 16.351 is
rounded off to 16.4 and x = 6.758 is rounded off to 6.8.
4. If the digit to be dropped is 5 or 5 followed by zeros, then the
preceding digit, if it is even, is left unchanged. For example,
x = 3.250 becomes 3.2 on rounding off and x = 12.650 becomes 12.6
on rounding off.
5. If the digit to be dropped is 5 or 5 followed by zeros, then the
preceding digit, if it is odd, is raised by one. For example,
x = 3.750 is rounded off to 3.8, again x = 16.150 is rounded off
to 16.2.
In SI Units, the dimensions of
is:
ERRORS IN MEASUREMENT
COMBINATION OF ERRORS
Difference between true value
& measured value of a quantity
Systematic Errors
Instrumental Experimental Personal
Random Errors
Errors which tend to occur
only in one direction,
either positive or negative
Least count error is the smallest value that can be measured by
instrument (occurs with random & systematic errors)
• Absolute Error :- Δa = ai-amean , amean=
• Relative Error:-
General rule:
,Then the maximum fractional relative
error in Z will be:
Due to inbuilt defect
of measuring instrumentLimitations in
experimental
technique
Due to individual
bias,Lack of proper
setting of apparatus
Irregular and random
in magnitude & direction
a1+a2+a3+ ....+an
n
Δa1Δa2 Δa3+ ....+Δan
n
amean
Δamean Δamean=
Percentage Error:- amean
Δamean x 100
ΔZ
Z
ΔA
A
ΔB
B
ΔC
C
Operations
SumA+B ΔA+ ΔB
ΔA+ ΔB
AΔB+ BΔA
B2
BΔA+ AΔB
A-B
AxB
An
A
A
B
Difference
Multiplication
Division
Power
Root
Formula Z Absolute
error ΔZ
Percentage error
100 x ΔZ/Z
Relative
error ΔZ/Z
ΔA ΔB
A B
1
n1
n
A+B
ΔA+ΔB
A-B
ΔA+ΔB
n A n-1ΔA
AΔA
+
ΔA ΔB
A
ΔA
A
B
+
n
ΔA
A
ΔA ΔB
A B
1
n
A+B
ΔA+ΔB
A-B
ΔA+ΔB
+
ΔA ΔB
A
ΔA
A
B
+
n
ΔA
A
x 100
x 100
x 100
x 100
x 100
x 100
(
(
(
(
If Z =APBq
Cr
=p +q +r
P= a2b2
cd
In an expirement four quantities a,b,c
and d are measured with percentage
error1%, 2%, 3% and 4% respectievely.
Quantity P is calculated as shown below.
What is the percentage error in P?
(a) 14% (b) 10%
(c) 7% (d) 4%
If L=2.331cm, B= 2.1cm,then L+B = ?
(a) 4.431 cm (b) 4.43 cm
(c) 4.4 cm (d) 4 cm
Dimensional Analysis
INSTRUMENTS
Least Count:
Smallest quantity an instrument can
measure
mm scalevernier scalescrew gauge
a)A
-1
T M L
3
b)A T
2
M
-1
L
-1
c)A T
-3
M
L
3/2
d)A
2
T
3
M
-1
L
-2
UNITS & MEASUREMENTS
μ
0
ε
0
DIMENSIONAL FORMULA
1) Pressure=stress=Youngs modulus=ML-1 T-2
2) Work=Energy=Torque=M L2 T-2
3) Power P=M L2 T-3
4) Gravitational constant G=M-1 L3 T-2
5) Force constant=Spring constant=M T-2
6) Coefficient of viscosity=M L-1 T-1
7) Latent heat = L2 T-2
μ0
10) Capacitance=M-1 L-2 T4 A2
11) Permittivity ε0=M-1 L-3 T4 A2
12) Angular momentum = planck‛s constant
=M1 L2 T-1
ε0
=M L2 T-3 A-2
I
8
9
DIMENSIONLESS
QUANTITIES
1) Strain
2) Refractive index
3) Relative density
4) Plane angle
5) Solid angle
1mm
0.1mm
0.01mm
VERNIER CALIPERS
Least Count = 1 MSD - 1VSD
Least Count = 1MSD -
Total Reading = Main Scale Reading + (coinciding
Vernier Scale division x least count)
In a vernier calipers, one main scale division is x cm
& n division of vernier scale coincide with n-1 divisions
of the main scle. The least count (in cm) of the
calipers is;
If n VSD Coincides with (n-1)
MSD,
then (n-1) MSD= n VSD
1VSD = MSD
n-1
n
MSD = 1MSD
n-1
nn
Least Count = pitch
Total no.of divisions on
circlular scale
Pitch =
Dimensions of a physical quantity are the powers to which units of base
quantity are raised. Eg: [M]a [L]b [T]c [A]d [K]e
checking the correctness of
various formulae
Eg: If Z=A+B,[Z]=[A]=[B]
Deducing relation
among physical
quantity
conversion of one system
of unit into another
n1u1=n2u2
Eg: n1[M1
A L1
B T1
C] = n2[M2
A L2
B T2
C]
APPLICATIONS
M1
A
M2
]
[L1
B
L2 ]
[T1
C
T2 ]
[
n1= n2
Main Scale Reading
No.of rotations
a) n-1
n
( )xb) nx
n-1
( ) c) x
n-1
( ) d) x
n
The least count of the main scale of a screw gauge
is 1mm. The minimum no.of divisions on its circular
scale required to measure 5μm diameter of wire is;
a) 200 b) 50 c) 400 d) 100
x
b
x
p
=b
x
Total Reading = Linear Scale Reading + circular scale
reading x least count
SCREW GAUGE
L
RRC LC
= =
T l
gm
k
R
g
α α α
Time period
13)M= k k
hc
GL= hG
c2T=k hG
c5
In addition or subtraction, the final result should be reported
to the same number of decimal places as that of the original
number with minimum number of decimal places
When numbers are multiplied or divided, the number of
significant figures in the answer equals the smallest number
of significant figures in any of the original numbers
(has two decimal places)
(Answer should be reported to two decimal
places after rounding off)
Answer = 3.47
3.1421
0.241
+0.09
3.4731
ADDITION & SUBTRACTION
MULTIPLICATION & DIVISION
(Three significant figures)
(Answer should have three significant figures
after rounding off)
Answer = 66.8
51.028
x 1.31
66.84668
++
1
n
1
n-1

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Download Is important for me yes and more Cheat Sheet Mathematics in PDF only on Docsity!

•Large distance is measured by

parallax method

•Parallax angle=

O

=1.745 x 10-2^ rad

•1"=4.85×10^6 rad.

•1‛=2 .91×10^4 rad.

•1 AU = 1.496×10^11 m

•1 ly = 9.46 × 10^15 m

•1parsec= 3.08 x 10^16 m

•Size of proton: 10-15^ m

•Radius Of Earth: 10^7 m

•Distance to Boundary Of

Observable Universe : 10^26 m

•For very small sizes, optical microscope,

tunneling microscope, electron microscope

are used.

7 Base units and 2 supplementary units

SI SYSTEM

Base Units

Supplementary Units

Quantity

Quantity Plane angle Solid angle

radian steradian

rad sr

NO.

1 2

Unit Symbol

Length

NO.

1

Unit

meter

Symbol

m 2 Mass kilogram kg 3 Time second s 4 Temperature kelvin K 5 Electric current ampere A 6 Luminous intensity candela cd Amount of substance 7 mole mol

What is the unit of permittivity

of free space ε?

(a) coloumb/newton-metre (b) newton-metre^2 /coloumb²

(c) coloumb²/newton-metre^2

(d) coloumb^2 /(newton-metre)^2

MEASUREMENT OF LENGTH

RULES FOR SIGNIFICANT FIGURES

BASIS DISTANCE

MEASUREMENT OF MASS & TIME

TIME

MASS

  • SI unit is second (based on caesium clock with an

uncertainity less than 1 part in 10-

ie, 3μ s loss every year)

  • Timespan of unstable particle: 10-24^ s
  • Age of universe: 10^17 s

•1amu =(1/12)th^ mass of

one C^12 atom

•1amu = 1.66×10-27^ kg

•Electron mass- 10-30^ kg

•Earth mass : 10^25 kg

•Observable Universe 10^55 kg

  • Unified atomic mass unit(amu) is used to measure

mass of atoms & molecules

SIGNIFICANT FIGURES

RULES FOR ROUNDING OF A MEASUREMENT

RULES FOR ROUNDING OF A MEASUREMENT

The digits in a measured quantity which are reliable and confidence in our measurement + the digit which is uncertain.

  1. All non-zero digits are significant. For example, 42.3 has three significant figures; 243.4 has four significant figures; and 24.123 has five significant figures.
  2. A zero becomes significant figure if it appears between two non-zero digits. For example, 5.03 has three significant figures; 5.604 has four significant figures; and 4.004 has four significant figures.
  3. Leading zeros or the zeros placed to the left of the number are never significant. For example,0.543 has three significant figures; 0.045 has two significant figures; and 0.006 has one significant figure.
  4. Trailing zeros or the zeros placed to the right of the number are significant. For example, 4.330 has four significant figures; 433. has five significant figures; and 343.000 has six significant figures.
  5. In exponential notation, the numerical portion gives the number of significant figures. For example,1.32 x 10-² has three significant figures and 1.32 x 10^4 has three significant figures.
    1. If the digit to be dropped is less than 5, then the preceding digit is left unchanged. For example,x = 7.82 is rounded off to 7.8 and x = 3.94 is rounded off to 3.9.
    2. If the digit to be dropped is more than 5, then the preceding digit is raised by one. For example, x = 6.87 is rounded off to 6.9 and x = 12.78 is rounded off to 12.8.
  6. If the digit to be dropped is 5 followed by digits other than zero, then the preceding digit is raised by one. For example, x = 16.351 is rounded off to 16.4 and x = 6.758 is rounded off to 6.8.
  7. If the digit to be dropped is 5 or 5 followed by zeros, then the preceding digit, if it is even, is left unchanged. For example, x = 3.250 becomes 3.2 on rounding off and x = 12.650 becomes 12. on rounding off.
  8. If the digit to be dropped is 5 or 5 followed by zeros, then the preceding digit, if it is odd, is raised by one. For example, x = 3.750 is rounded off to 3.8, again x = 16.150 is rounded off to 16.2.

In SI Units, the dimensions of

is:

ERRORS IN MEASUREMENT

COMBINATION OF ERRORS

Difference between true value

& measured value of a quantity

Systematic Errors

Instrumental (^) Experimental Personal

Random Errors Errors which tend to occur only in one direction, either positive or negative

  • Least count error is the smallest value that can be measured by instrument (occurs with random & systematic errors)
  • Absolute Error :- Δ a = ai-amean , amean=
  • Relative Error:-

General rule:

,Then the maximum fractional relative error in Z will be:

Due to inbuilt defect of measuring instrument

Limitations in experimental technique

Due to individual bias,Lack of proper setting of apparatus

Irregular and random in magnitude & direction

a 1 +a 2 +a 3 + ....+an n Δ a 1 Δ a 2 Δ a 3 + ... .+Δ an amean n

Δ amean Δ amean=

  • Percentage Error:- (^) a mean

Δ amean x 100

Δ Z Z

Δ A A

Δ B B

Δ C C

Operations

Sum (^) A+B Δ A+ Δ B

Δ A+ Δ B

A Δ B+ B Δ A

B^2

B Δ A+ A Δ B

A-B

A x B

A n

A

A B

Difference

Multiplication

Division

Power

Root

Formula Z Absolute error Δ Z

Percentage error 100 x Δ Z/Z

Relative error ΔZ /Z

Δ A Δ B A B

1 n

1 n

A+B

Δ A+ Δ B

A-B

Δ A+ Δ B

n A n - 1^ Δ A

A Δ A

Δ A Δ B A Δ A A

B

n

Δ A A

Δ A Δ B A B

1 n

A+B

Δ A+ Δ B

A-B

Δ A+ Δ B

Δ A Δ B A Δ A A

B

n

Δ A A

x 100

x 100

x 100

x 100

x 100

x 100

(

(

(

(

If Z =

APBq Cr

=p +q +r

P=

a

b

cd

In an expirement four quantities a,b,c

and d are measured with percentage

error1%, 2%, 3% and 4% respectievely.

Quantity P is calculated as shown below.

What is the percentage error in P?

(a) 14% (b) 10%

(c) 7% (d) 4%

If L=2.331cm, B= 2.1cm,then L+B =?

(a) 4.431 cm (b) 4.43 cm

(c) 4.4 cm (d) 4 cm

Dimensional Analysis

INSTRUMENTS

Least Count: Smallest quantity an instrument can measure

mm scale vernier scale screw gauge

a)A-1^ T M L^3 b)A T 2 M

  • L -

c)A T-3^ M L3/2^ d)A (^2) T (^3) M-1 (^) L-

UNITS & MEASUREMENTS

μ 0

DIMENSIONAL FORMULA

  1. Pressure=stress=Young s modulus=ML-1^ T-

  2. Work=Energy=Torque=M L^2 T-

  3. Power P=M L 2 T

  1. Gravitational constant G=M-1^ L^3 T-

  2. Force constant=Spring constant=M T

  1. Coefficient of viscosity=M L-1^ T-

  2. Latent heat = L 2 T-

μ 0

  1. Capacitance=M-1^ L-2^ T 4 A^2

11) Permittivity ε 0 =M-1^ L-3^ T^4 A^2

  1. Angular momentum = planc k‛ s constant =M^1 L^2 T-

=M L^2 T-3^ A-

I

8

9

DIMENSIONLESS

QUANTITIES

1) Strain

2) Refractive index

3) Relative density

4) Plane angle

5) Solid angle

1mm

0.1mm

0.01mm

VERNIER CALIPERS

Least Count = 1 MSD - 1VSD

Least Count = 1MSD -

Total Reading = Main Scale Reading + (coinciding Vernier Scale division x least count)

In a vernier calipers, one main scale division is x cm & n division of vernier scale coincide with n-1 divisions of the main scle. The least count (in cm) of the calipers is;

If n VSD Coincides with (n-1) MSD, then (n-1) MSD= n VSD

1VSD = n-1MSD n

n-1MSD = 1MSD n n

Least Count =

pitch Total no.of divisions on circlular scale

Pitch =

Dimensions of a physical quantity are the powers to which units of base

quantity are raised. Eg: [M] a [L] b [T] c [A] d [K] e

checking the correctness of

various formulae

Eg: If Z=A+B,[Z]=[A]=[B]

Deducing relation

among physical

quantity

conversion of one system

of unit into another

n 1 u 1 =n 2 u 2

Eg: n 1 [M 1 A^ L 1 B^ T 1 C] = n 2 [M 2 A^ L 2 B^ T 2 C]

APPLICATIONS

M 1

M 2 A

[ ]

L 1

L 2 B

[ ]

T 1

T 2 C

n 1 = n 2 [ ]

Main Scale Reading

No.of rotations

a) n- n ( ) x^ b) nx (n-1 )

c) x (n-1 )

d) x n

The least count of the main scale of a screw gauge is 1mm. The minimum no.of divisions on its circular scale required to meas ure 5μ m diameter of wire is;

a) 200 b) 50 c) 400 d) 100

x

b

x

p

b

x

Total Reading = Linear Scale Reading + circular scale reading x least count

SCREW GAUGE

L

R

= RC = LC

T

l g

m k

R

α α α g

Time period

  1. M=^ k^ hc k

G

L= hG

c^2

T=k

hG

c^5

In addition or subtraction, the final result should be reported to the same number of decimal places as that of the original number with minimum number of decimal places

When numbers are multiplied or divided, the number of significant figures in the answer equals the smallest number of significant figures in any of the original numbers

(has two decimal places) (Answer should be reported to two decimal places after rounding off)

Answer = 3.

ADDITION & SUBTRACTION

MULTIPLICATION & DIVISION

(Three significant figures) (Answer should have three significant figures after rounding off) Answer = 66.

x 1.

(^1) n (^1) n -